/*===-- clang-c/Index.h - Indexing Public C Interface -------------*- C -*-===*\ |* *| |* Part of the LLVM Project, under the Apache License v2.0 with LLVM *| |* Exceptions. *| |* See https://llvm.org/LICENSE.txt for license information. *| |* SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception *| |* *| |*===----------------------------------------------------------------------===*| |* *| |* This header provides a public interface to a Clang library for extracting *| |* high-level symbol information from source files without exposing the full *| |* Clang C++ API. *| |* *| \*===----------------------------------------------------------------------===*/ #ifndef LLVM_CLANG_C_INDEX_H #define LLVM_CLANG_C_INDEX_H #include "clang-c/BuildSystem.h" #include "clang-c/CXDiagnostic.h" #include "clang-c/CXErrorCode.h" #include "clang-c/CXFile.h" #include "clang-c/CXSourceLocation.h" #include "clang-c/CXString.h" #include "clang-c/ExternC.h" #include "clang-c/Platform.h" /** * The version constants for the libclang API. * CINDEX_VERSION_MINOR should increase when there are API additions. * CINDEX_VERSION_MAJOR is intended for "major" source/ABI breaking changes. * * The policy about the libclang API was always to keep it source and ABI * compatible, thus CINDEX_VERSION_MAJOR is expected to remain stable. */ #define CINDEX_VERSION_MAJOR 0 #define CINDEX_VERSION_MINOR 64 #define CINDEX_VERSION_ENCODE(major, minor) (((major)*10000) + ((minor)*1)) #define CINDEX_VERSION \ CINDEX_VERSION_ENCODE(CINDEX_VERSION_MAJOR, CINDEX_VERSION_MINOR) #define CINDEX_VERSION_STRINGIZE_(major, minor) #major "." #minor #define CINDEX_VERSION_STRINGIZE(major, minor) \ CINDEX_VERSION_STRINGIZE_(major, minor) #define CINDEX_VERSION_STRING \ CINDEX_VERSION_STRINGIZE(CINDEX_VERSION_MAJOR, CINDEX_VERSION_MINOR) #ifndef __has_feature #define __has_feature(feature) 0 #endif LLVM_CLANG_C_EXTERN_C_BEGIN /** \defgroup CINDEX libclang: C Interface to Clang * * The C Interface to Clang provides a relatively small API that exposes * facilities for parsing source code into an abstract syntax tree (AST), * loading already-parsed ASTs, traversing the AST, associating * physical source locations with elements within the AST, and other * facilities that support Clang-based development tools. * * This C interface to Clang will never provide all of the information * representation stored in Clang's C++ AST, nor should it: the intent is to * maintain an API that is relatively stable from one release to the next, * providing only the basic functionality needed to support development tools. * * To avoid namespace pollution, data types are prefixed with "CX" and * functions are prefixed with "clang_". * * @{ */ /** * An "index" that consists of a set of translation units that would * typically be linked together into an executable or library. */ typedef void *CXIndex; /** * An opaque type representing target information for a given translation * unit. */ typedef struct CXTargetInfoImpl *CXTargetInfo; /** * A single translation unit, which resides in an index. */ typedef struct CXTranslationUnitImpl *CXTranslationUnit; /** * Opaque pointer representing client data that will be passed through * to various callbacks and visitors. */ typedef void *CXClientData; /** * Provides the contents of a file that has not yet been saved to disk. * * Each CXUnsavedFile instance provides the name of a file on the * system along with the current contents of that file that have not * yet been saved to disk. */ struct CXUnsavedFile { /** * The file whose contents have not yet been saved. * * This file must already exist in the file system. */ const char *Filename; /** * A buffer containing the unsaved contents of this file. */ const char *Contents; /** * The length of the unsaved contents of this buffer. */ unsigned long Length; }; /** * Describes the availability of a particular entity, which indicates * whether the use of this entity will result in a warning or error due to * it being deprecated or unavailable. */ enum CXAvailabilityKind { /** * The entity is available. */ CXAvailability_Available, /** * The entity is available, but has been deprecated (and its use is * not recommended). */ CXAvailability_Deprecated, /** * The entity is not available; any use of it will be an error. */ CXAvailability_NotAvailable, /** * The entity is available, but not accessible; any use of it will be * an error. */ CXAvailability_NotAccessible }; /** * Describes a version number of the form major.minor.subminor. */ typedef struct CXVersion { /** * The major version number, e.g., the '10' in '10.7.3'. A negative * value indicates that there is no version number at all. */ int Major; /** * The minor version number, e.g., the '7' in '10.7.3'. This value * will be negative if no minor version number was provided, e.g., for * version '10'. */ int Minor; /** * The subminor version number, e.g., the '3' in '10.7.3'. This value * will be negative if no minor or subminor version number was provided, * e.g., in version '10' or '10.7'. */ int Subminor; } CXVersion; /** * Describes the exception specification of a cursor. * * A negative value indicates that the cursor is not a function declaration. */ enum CXCursor_ExceptionSpecificationKind { /** * The cursor has no exception specification. */ CXCursor_ExceptionSpecificationKind_None, /** * The cursor has exception specification throw() */ CXCursor_ExceptionSpecificationKind_DynamicNone, /** * The cursor has exception specification throw(T1, T2) */ CXCursor_ExceptionSpecificationKind_Dynamic, /** * The cursor has exception specification throw(...). */ CXCursor_ExceptionSpecificationKind_MSAny, /** * The cursor has exception specification basic noexcept. */ CXCursor_ExceptionSpecificationKind_BasicNoexcept, /** * The cursor has exception specification computed noexcept. */ CXCursor_ExceptionSpecificationKind_ComputedNoexcept, /** * The exception specification has not yet been evaluated. */ CXCursor_ExceptionSpecificationKind_Unevaluated, /** * The exception specification has not yet been instantiated. */ CXCursor_ExceptionSpecificationKind_Uninstantiated, /** * The exception specification has not been parsed yet. */ CXCursor_ExceptionSpecificationKind_Unparsed, /** * The cursor has a __declspec(nothrow) exception specification. */ CXCursor_ExceptionSpecificationKind_NoThrow }; /** * Provides a shared context for creating translation units. * * It provides two options: * * - excludeDeclarationsFromPCH: When non-zero, allows enumeration of "local" * declarations (when loading any new translation units). A "local" declaration * is one that belongs in the translation unit itself and not in a precompiled * header that was used by the translation unit. If zero, all declarations * will be enumerated. * * Here is an example: * * \code * // excludeDeclsFromPCH = 1, displayDiagnostics=1 * Idx = clang_createIndex(1, 1); * * // IndexTest.pch was produced with the following command: * // "clang -x c IndexTest.h -emit-ast -o IndexTest.pch" * TU = clang_createTranslationUnit(Idx, "IndexTest.pch"); * * // This will load all the symbols from 'IndexTest.pch' * clang_visitChildren(clang_getTranslationUnitCursor(TU), * TranslationUnitVisitor, 0); * clang_disposeTranslationUnit(TU); * * // This will load all the symbols from 'IndexTest.c', excluding symbols * // from 'IndexTest.pch'. * char *args[] = { "-Xclang", "-include-pch=IndexTest.pch" }; * TU = clang_createTranslationUnitFromSourceFile(Idx, "IndexTest.c", 2, args, * 0, 0); * clang_visitChildren(clang_getTranslationUnitCursor(TU), * TranslationUnitVisitor, 0); * clang_disposeTranslationUnit(TU); * \endcode * * This process of creating the 'pch', loading it separately, and using it (via * -include-pch) allows 'excludeDeclsFromPCH' to remove redundant callbacks * (which gives the indexer the same performance benefit as the compiler). */ CINDEX_LINKAGE CXIndex clang_createIndex(int excludeDeclarationsFromPCH, int displayDiagnostics); /** * Destroy the given index. * * The index must not be destroyed until all of the translation units created * within that index have been destroyed. */ CINDEX_LINKAGE void clang_disposeIndex(CXIndex index); typedef enum { /** * Use the default value of an option that may depend on the process * environment. */ CXChoice_Default = 0, /** * Enable the option. */ CXChoice_Enabled = 1, /** * Disable the option. */ CXChoice_Disabled = 2 } CXChoice; typedef enum { /** * Used to indicate that no special CXIndex options are needed. */ CXGlobalOpt_None = 0x0, /** * Used to indicate that threads that libclang creates for indexing * purposes should use background priority. * * Affects #clang_indexSourceFile, #clang_indexTranslationUnit, * #clang_parseTranslationUnit, #clang_saveTranslationUnit. */ CXGlobalOpt_ThreadBackgroundPriorityForIndexing = 0x1, /** * Used to indicate that threads that libclang creates for editing * purposes should use background priority. * * Affects #clang_reparseTranslationUnit, #clang_codeCompleteAt, * #clang_annotateTokens */ CXGlobalOpt_ThreadBackgroundPriorityForEditing = 0x2, /** * Used to indicate that all threads that libclang creates should use * background priority. */ CXGlobalOpt_ThreadBackgroundPriorityForAll = CXGlobalOpt_ThreadBackgroundPriorityForIndexing | CXGlobalOpt_ThreadBackgroundPriorityForEditing } CXGlobalOptFlags; /** * Index initialization options. * * 0 is the default value of each member of this struct except for Size. * Initialize the struct in one of the following three ways to avoid adapting * code each time a new member is added to it: * \code * CXIndexOptions Opts; * memset(&Opts, 0, sizeof(Opts)); * Opts.Size = sizeof(CXIndexOptions); * \endcode * or explicitly initialize the first data member and zero-initialize the rest: * \code * CXIndexOptions Opts = { sizeof(CXIndexOptions) }; * \endcode * or to prevent the -Wmissing-field-initializers warning for the above version: * \code * CXIndexOptions Opts{}; * Opts.Size = sizeof(CXIndexOptions); * \endcode */ typedef struct CXIndexOptions { /** * The size of struct CXIndexOptions used for option versioning. * * Always initialize this member to sizeof(CXIndexOptions), or assign * sizeof(CXIndexOptions) to it right after creating a CXIndexOptions object. */ unsigned Size; /** * A CXChoice enumerator that specifies the indexing priority policy. * \sa CXGlobalOpt_ThreadBackgroundPriorityForIndexing */ unsigned char ThreadBackgroundPriorityForIndexing; /** * A CXChoice enumerator that specifies the editing priority policy. * \sa CXGlobalOpt_ThreadBackgroundPriorityForEditing */ unsigned char ThreadBackgroundPriorityForEditing; /** * \see clang_createIndex() */ unsigned ExcludeDeclarationsFromPCH : 1; /** * \see clang_createIndex() */ unsigned DisplayDiagnostics : 1; /** * Store PCH in memory. If zero, PCH are stored in temporary files. */ unsigned StorePreamblesInMemory : 1; unsigned /*Reserved*/ : 13; /** * The path to a directory, in which to store temporary PCH files. If null or * empty, the default system temporary directory is used. These PCH files are * deleted on clean exit but stay on disk if the program crashes or is killed. * * This option is ignored if \a StorePreamblesInMemory is non-zero. * * Libclang does not create the directory at the specified path in the file * system. Therefore it must exist, or storing PCH files will fail. */ const char *PreambleStoragePath; /** * Specifies a path which will contain log files for certain libclang * invocations. A null value implies that libclang invocations are not logged. */ const char *InvocationEmissionPath; } CXIndexOptions; /** * Provides a shared context for creating translation units. * * Call this function instead of clang_createIndex() if you need to configure * the additional options in CXIndexOptions. * * \returns The created index or null in case of error, such as an unsupported * value of options->Size. * * For example: * \code * CXIndex createIndex(const char *ApplicationTemporaryPath) { * const int ExcludeDeclarationsFromPCH = 1; * const int DisplayDiagnostics = 1; * CXIndex Idx; * #if CINDEX_VERSION_MINOR >= 64 * CXIndexOptions Opts; * memset(&Opts, 0, sizeof(Opts)); * Opts.Size = sizeof(CXIndexOptions); * Opts.ThreadBackgroundPriorityForIndexing = 1; * Opts.ExcludeDeclarationsFromPCH = ExcludeDeclarationsFromPCH; * Opts.DisplayDiagnostics = DisplayDiagnostics; * Opts.PreambleStoragePath = ApplicationTemporaryPath; * Idx = clang_createIndexWithOptions(&Opts); * if (Idx) * return Idx; * fprintf(stderr, * "clang_createIndexWithOptions() failed. " * "CINDEX_VERSION_MINOR = %d, sizeof(CXIndexOptions) = %u\n", * CINDEX_VERSION_MINOR, Opts.Size); * #else * (void)ApplicationTemporaryPath; * #endif * Idx = clang_createIndex(ExcludeDeclarationsFromPCH, DisplayDiagnostics); * clang_CXIndex_setGlobalOptions( * Idx, clang_CXIndex_getGlobalOptions(Idx) | * CXGlobalOpt_ThreadBackgroundPriorityForIndexing); * return Idx; * } * \endcode * * \sa clang_createIndex() */ CINDEX_LINKAGE CXIndex clang_createIndexWithOptions(const CXIndexOptions *options); /** * Sets general options associated with a CXIndex. * * This function is DEPRECATED. Set * CXIndexOptions::ThreadBackgroundPriorityForIndexing and/or * CXIndexOptions::ThreadBackgroundPriorityForEditing and call * clang_createIndexWithOptions() instead. * * For example: * \code * CXIndex idx = ...; * clang_CXIndex_setGlobalOptions(idx, * clang_CXIndex_getGlobalOptions(idx) | * CXGlobalOpt_ThreadBackgroundPriorityForIndexing); * \endcode * * \param options A bitmask of options, a bitwise OR of CXGlobalOpt_XXX flags. */ CINDEX_LINKAGE void clang_CXIndex_setGlobalOptions(CXIndex, unsigned options); /** * Gets the general options associated with a CXIndex. * * This function allows to obtain the final option values used by libclang after * specifying the option policies via CXChoice enumerators. * * \returns A bitmask of options, a bitwise OR of CXGlobalOpt_XXX flags that * are associated with the given CXIndex object. */ CINDEX_LINKAGE unsigned clang_CXIndex_getGlobalOptions(CXIndex); /** * Sets the invocation emission path option in a CXIndex. * * This function is DEPRECATED. Set CXIndexOptions::InvocationEmissionPath and * call clang_createIndexWithOptions() instead. * * The invocation emission path specifies a path which will contain log * files for certain libclang invocations. A null value (default) implies that * libclang invocations are not logged.. */ CINDEX_LINKAGE void clang_CXIndex_setInvocationEmissionPathOption(CXIndex, const char *Path); /** * Determine whether the given header is guarded against * multiple inclusions, either with the conventional * \#ifndef/\#define/\#endif macro guards or with \#pragma once. */ CINDEX_LINKAGE unsigned clang_isFileMultipleIncludeGuarded(CXTranslationUnit tu, CXFile file); /** * Retrieve a file handle within the given translation unit. * * \param tu the translation unit * * \param file_name the name of the file. * * \returns the file handle for the named file in the translation unit \p tu, * or a NULL file handle if the file was not a part of this translation unit. */ CINDEX_LINKAGE CXFile clang_getFile(CXTranslationUnit tu, const char *file_name); /** * Retrieve the buffer associated with the given file. * * \param tu the translation unit * * \param file the file for which to retrieve the buffer. * * \param size [out] if non-NULL, will be set to the size of the buffer. * * \returns a pointer to the buffer in memory that holds the contents of * \p file, or a NULL pointer when the file is not loaded. */ CINDEX_LINKAGE const char *clang_getFileContents(CXTranslationUnit tu, CXFile file, size_t *size); /** * Retrieves the source location associated with a given file/line/column * in a particular translation unit. */ CINDEX_LINKAGE CXSourceLocation clang_getLocation(CXTranslationUnit tu, CXFile file, unsigned line, unsigned column); /** * Retrieves the source location associated with a given character offset * in a particular translation unit. */ CINDEX_LINKAGE CXSourceLocation clang_getLocationForOffset(CXTranslationUnit tu, CXFile file, unsigned offset); /** * Retrieve all ranges that were skipped by the preprocessor. * * The preprocessor will skip lines when they are surrounded by an * if/ifdef/ifndef directive whose condition does not evaluate to true. */ CINDEX_LINKAGE CXSourceRangeList *clang_getSkippedRanges(CXTranslationUnit tu, CXFile file); /** * Retrieve all ranges from all files that were skipped by the * preprocessor. * * The preprocessor will skip lines when they are surrounded by an * if/ifdef/ifndef directive whose condition does not evaluate to true. */ CINDEX_LINKAGE CXSourceRangeList * clang_getAllSkippedRanges(CXTranslationUnit tu); /** * Determine the number of diagnostics produced for the given * translation unit. */ CINDEX_LINKAGE unsigned clang_getNumDiagnostics(CXTranslationUnit Unit); /** * Retrieve a diagnostic associated with the given translation unit. * * \param Unit the translation unit to query. * \param Index the zero-based diagnostic number to retrieve. * * \returns the requested diagnostic. This diagnostic must be freed * via a call to \c clang_disposeDiagnostic(). */ CINDEX_LINKAGE CXDiagnostic clang_getDiagnostic(CXTranslationUnit Unit, unsigned Index); /** * Retrieve the complete set of diagnostics associated with a * translation unit. * * \param Unit the translation unit to query. */ CINDEX_LINKAGE CXDiagnosticSet clang_getDiagnosticSetFromTU(CXTranslationUnit Unit); /** * \defgroup CINDEX_TRANSLATION_UNIT Translation unit manipulation * * The routines in this group provide the ability to create and destroy * translation units from files, either by parsing the contents of the files or * by reading in a serialized representation of a translation unit. * * @{ */ /** * Get the original translation unit source file name. */ CINDEX_LINKAGE CXString clang_getTranslationUnitSpelling(CXTranslationUnit CTUnit); /** * Return the CXTranslationUnit for a given source file and the provided * command line arguments one would pass to the compiler. * * Note: The 'source_filename' argument is optional. If the caller provides a * NULL pointer, the name of the source file is expected to reside in the * specified command line arguments. * * Note: When encountered in 'clang_command_line_args', the following options * are ignored: * * '-c' * '-emit-ast' * '-fsyntax-only' * '-o \' (both '-o' and '\' are ignored) * * \param CIdx The index object with which the translation unit will be * associated. * * \param source_filename The name of the source file to load, or NULL if the * source file is included in \p clang_command_line_args. * * \param num_clang_command_line_args The number of command-line arguments in * \p clang_command_line_args. * * \param clang_command_line_args The command-line arguments that would be * passed to the \c clang executable if it were being invoked out-of-process. * These command-line options will be parsed and will affect how the translation * unit is parsed. Note that the following options are ignored: '-c', * '-emit-ast', '-fsyntax-only' (which is the default), and '-o \'. * * \param num_unsaved_files the number of unsaved file entries in \p * unsaved_files. * * \param unsaved_files the files that have not yet been saved to disk * but may be required for code completion, including the contents of * those files. The contents and name of these files (as specified by * CXUnsavedFile) are copied when necessary, so the client only needs to * guarantee their validity until the call to this function returns. */ CINDEX_LINKAGE CXTranslationUnit clang_createTranslationUnitFromSourceFile( CXIndex CIdx, const char *source_filename, int num_clang_command_line_args, const char *const *clang_command_line_args, unsigned num_unsaved_files, struct CXUnsavedFile *unsaved_files); /** * Same as \c clang_createTranslationUnit2, but returns * the \c CXTranslationUnit instead of an error code. In case of an error this * routine returns a \c NULL \c CXTranslationUnit, without further detailed * error codes. */ CINDEX_LINKAGE CXTranslationUnit clang_createTranslationUnit(CXIndex CIdx, const char *ast_filename); /** * Create a translation unit from an AST file (\c -emit-ast). * * \param[out] out_TU A non-NULL pointer to store the created * \c CXTranslationUnit. * * \returns Zero on success, otherwise returns an error code. */ CINDEX_LINKAGE enum CXErrorCode clang_createTranslationUnit2(CXIndex CIdx, const char *ast_filename, CXTranslationUnit *out_TU); /** * Flags that control the creation of translation units. * * The enumerators in this enumeration type are meant to be bitwise * ORed together to specify which options should be used when * constructing the translation unit. */ enum CXTranslationUnit_Flags { /** * Used to indicate that no special translation-unit options are * needed. */ CXTranslationUnit_None = 0x0, /** * Used to indicate that the parser should construct a "detailed" * preprocessing record, including all macro definitions and instantiations. * * Constructing a detailed preprocessing record requires more memory * and time to parse, since the information contained in the record * is usually not retained. However, it can be useful for * applications that require more detailed information about the * behavior of the preprocessor. */ CXTranslationUnit_DetailedPreprocessingRecord = 0x01, /** * Used to indicate that the translation unit is incomplete. * * When a translation unit is considered "incomplete", semantic * analysis that is typically performed at the end of the * translation unit will be suppressed. For example, this suppresses * the completion of tentative declarations in C and of * instantiation of implicitly-instantiation function templates in * C++. This option is typically used when parsing a header with the * intent of producing a precompiled header. */ CXTranslationUnit_Incomplete = 0x02, /** * Used to indicate that the translation unit should be built with an * implicit precompiled header for the preamble. * * An implicit precompiled header is used as an optimization when a * particular translation unit is likely to be reparsed many times * when the sources aren't changing that often. In this case, an * implicit precompiled header will be built containing all of the * initial includes at the top of the main file (what we refer to as * the "preamble" of the file). In subsequent parses, if the * preamble or the files in it have not changed, \c * clang_reparseTranslationUnit() will re-use the implicit * precompiled header to improve parsing performance. */ CXTranslationUnit_PrecompiledPreamble = 0x04, /** * Used to indicate that the translation unit should cache some * code-completion results with each reparse of the source file. * * Caching of code-completion results is a performance optimization that * introduces some overhead to reparsing but improves the performance of * code-completion operations. */ CXTranslationUnit_CacheCompletionResults = 0x08, /** * Used to indicate that the translation unit will be serialized with * \c clang_saveTranslationUnit. * * This option is typically used when parsing a header with the intent of * producing a precompiled header. */ CXTranslationUnit_ForSerialization = 0x10, /** * DEPRECATED: Enabled chained precompiled preambles in C++. * * Note: this is a *temporary* option that is available only while * we are testing C++ precompiled preamble support. It is deprecated. */ CXTranslationUnit_CXXChainedPCH = 0x20, /** * Used to indicate that function/method bodies should be skipped while * parsing. * * This option can be used to search for declarations/definitions while * ignoring the usages. */ CXTranslationUnit_SkipFunctionBodies = 0x40, /** * Used to indicate that brief documentation comments should be * included into the set of code completions returned from this translation * unit. */ CXTranslationUnit_IncludeBriefCommentsInCodeCompletion = 0x80, /** * Used to indicate that the precompiled preamble should be created on * the first parse. Otherwise it will be created on the first reparse. This * trades runtime on the first parse (serializing the preamble takes time) for * reduced runtime on the second parse (can now reuse the preamble). */ CXTranslationUnit_CreatePreambleOnFirstParse = 0x100, /** * Do not stop processing when fatal errors are encountered. * * When fatal errors are encountered while parsing a translation unit, * semantic analysis is typically stopped early when compiling code. A common * source for fatal errors are unresolvable include files. For the * purposes of an IDE, this is undesirable behavior and as much information * as possible should be reported. Use this flag to enable this behavior. */ CXTranslationUnit_KeepGoing = 0x200, /** * Sets the preprocessor in a mode for parsing a single file only. */ CXTranslationUnit_SingleFileParse = 0x400, /** * Used in combination with CXTranslationUnit_SkipFunctionBodies to * constrain the skipping of function bodies to the preamble. * * The function bodies of the main file are not skipped. */ CXTranslationUnit_LimitSkipFunctionBodiesToPreamble = 0x800, /** * Used to indicate that attributed types should be included in CXType. */ CXTranslationUnit_IncludeAttributedTypes = 0x1000, /** * Used to indicate that implicit attributes should be visited. */ CXTranslationUnit_VisitImplicitAttributes = 0x2000, /** * Used to indicate that non-errors from included files should be ignored. * * If set, clang_getDiagnosticSetFromTU() will not report e.g. warnings from * included files anymore. This speeds up clang_getDiagnosticSetFromTU() for * the case where these warnings are not of interest, as for an IDE for * example, which typically shows only the diagnostics in the main file. */ CXTranslationUnit_IgnoreNonErrorsFromIncludedFiles = 0x4000, /** * Tells the preprocessor not to skip excluded conditional blocks. */ CXTranslationUnit_RetainExcludedConditionalBlocks = 0x8000 }; /** * Returns the set of flags that is suitable for parsing a translation * unit that is being edited. * * The set of flags returned provide options for \c clang_parseTranslationUnit() * to indicate that the translation unit is likely to be reparsed many times, * either explicitly (via \c clang_reparseTranslationUnit()) or implicitly * (e.g., by code completion (\c clang_codeCompletionAt())). The returned flag * set contains an unspecified set of optimizations (e.g., the precompiled * preamble) geared toward improving the performance of these routines. The * set of optimizations enabled may change from one version to the next. */ CINDEX_LINKAGE unsigned clang_defaultEditingTranslationUnitOptions(void); /** * Same as \c clang_parseTranslationUnit2, but returns * the \c CXTranslationUnit instead of an error code. In case of an error this * routine returns a \c NULL \c CXTranslationUnit, without further detailed * error codes. */ CINDEX_LINKAGE CXTranslationUnit clang_parseTranslationUnit( CXIndex CIdx, const char *source_filename, const char *const *command_line_args, int num_command_line_args, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, unsigned options); /** * Parse the given source file and the translation unit corresponding * to that file. * * This routine is the main entry point for the Clang C API, providing the * ability to parse a source file into a translation unit that can then be * queried by other functions in the API. This routine accepts a set of * command-line arguments so that the compilation can be configured in the same * way that the compiler is configured on the command line. * * \param CIdx The index object with which the translation unit will be * associated. * * \param source_filename The name of the source file to load, or NULL if the * source file is included in \c command_line_args. * * \param command_line_args The command-line arguments that would be * passed to the \c clang executable if it were being invoked out-of-process. * These command-line options will be parsed and will affect how the translation * unit is parsed. Note that the following options are ignored: '-c', * '-emit-ast', '-fsyntax-only' (which is the default), and '-o \'. * * \param num_command_line_args The number of command-line arguments in * \c command_line_args. * * \param unsaved_files the files that have not yet been saved to disk * but may be required for parsing, including the contents of * those files. The contents and name of these files (as specified by * CXUnsavedFile) are copied when necessary, so the client only needs to * guarantee their validity until the call to this function returns. * * \param num_unsaved_files the number of unsaved file entries in \p * unsaved_files. * * \param options A bitmask of options that affects how the translation unit * is managed but not its compilation. This should be a bitwise OR of the * CXTranslationUnit_XXX flags. * * \param[out] out_TU A non-NULL pointer to store the created * \c CXTranslationUnit, describing the parsed code and containing any * diagnostics produced by the compiler. * * \returns Zero on success, otherwise returns an error code. */ CINDEX_LINKAGE enum CXErrorCode clang_parseTranslationUnit2( CXIndex CIdx, const char *source_filename, const char *const *command_line_args, int num_command_line_args, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, unsigned options, CXTranslationUnit *out_TU); /** * Same as clang_parseTranslationUnit2 but requires a full command line * for \c command_line_args including argv[0]. This is useful if the standard * library paths are relative to the binary. */ CINDEX_LINKAGE enum CXErrorCode clang_parseTranslationUnit2FullArgv( CXIndex CIdx, const char *source_filename, const char *const *command_line_args, int num_command_line_args, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, unsigned options, CXTranslationUnit *out_TU); /** * Flags that control how translation units are saved. * * The enumerators in this enumeration type are meant to be bitwise * ORed together to specify which options should be used when * saving the translation unit. */ enum CXSaveTranslationUnit_Flags { /** * Used to indicate that no special saving options are needed. */ CXSaveTranslationUnit_None = 0x0 }; /** * Returns the set of flags that is suitable for saving a translation * unit. * * The set of flags returned provide options for * \c clang_saveTranslationUnit() by default. The returned flag * set contains an unspecified set of options that save translation units with * the most commonly-requested data. */ CINDEX_LINKAGE unsigned clang_defaultSaveOptions(CXTranslationUnit TU); /** * Describes the kind of error that occurred (if any) in a call to * \c clang_saveTranslationUnit(). */ enum CXSaveError { /** * Indicates that no error occurred while saving a translation unit. */ CXSaveError_None = 0, /** * Indicates that an unknown error occurred while attempting to save * the file. * * This error typically indicates that file I/O failed when attempting to * write the file. */ CXSaveError_Unknown = 1, /** * Indicates that errors during translation prevented this attempt * to save the translation unit. * * Errors that prevent the translation unit from being saved can be * extracted using \c clang_getNumDiagnostics() and \c clang_getDiagnostic(). */ CXSaveError_TranslationErrors = 2, /** * Indicates that the translation unit to be saved was somehow * invalid (e.g., NULL). */ CXSaveError_InvalidTU = 3 }; /** * Saves a translation unit into a serialized representation of * that translation unit on disk. * * Any translation unit that was parsed without error can be saved * into a file. The translation unit can then be deserialized into a * new \c CXTranslationUnit with \c clang_createTranslationUnit() or, * if it is an incomplete translation unit that corresponds to a * header, used as a precompiled header when parsing other translation * units. * * \param TU The translation unit to save. * * \param FileName The file to which the translation unit will be saved. * * \param options A bitmask of options that affects how the translation unit * is saved. This should be a bitwise OR of the * CXSaveTranslationUnit_XXX flags. * * \returns A value that will match one of the enumerators of the CXSaveError * enumeration. Zero (CXSaveError_None) indicates that the translation unit was * saved successfully, while a non-zero value indicates that a problem occurred. */ CINDEX_LINKAGE int clang_saveTranslationUnit(CXTranslationUnit TU, const char *FileName, unsigned options); /** * Suspend a translation unit in order to free memory associated with it. * * A suspended translation unit uses significantly less memory but on the other * side does not support any other calls than \c clang_reparseTranslationUnit * to resume it or \c clang_disposeTranslationUnit to dispose it completely. */ CINDEX_LINKAGE unsigned clang_suspendTranslationUnit(CXTranslationUnit); /** * Destroy the specified CXTranslationUnit object. */ CINDEX_LINKAGE void clang_disposeTranslationUnit(CXTranslationUnit); /** * Flags that control the reparsing of translation units. * * The enumerators in this enumeration type are meant to be bitwise * ORed together to specify which options should be used when * reparsing the translation unit. */ enum CXReparse_Flags { /** * Used to indicate that no special reparsing options are needed. */ CXReparse_None = 0x0 }; /** * Returns the set of flags that is suitable for reparsing a translation * unit. * * The set of flags returned provide options for * \c clang_reparseTranslationUnit() by default. The returned flag * set contains an unspecified set of optimizations geared toward common uses * of reparsing. The set of optimizations enabled may change from one version * to the next. */ CINDEX_LINKAGE unsigned clang_defaultReparseOptions(CXTranslationUnit TU); /** * Reparse the source files that produced this translation unit. * * This routine can be used to re-parse the source files that originally * created the given translation unit, for example because those source files * have changed (either on disk or as passed via \p unsaved_files). The * source code will be reparsed with the same command-line options as it * was originally parsed. * * Reparsing a translation unit invalidates all cursors and source locations * that refer into that translation unit. This makes reparsing a translation * unit semantically equivalent to destroying the translation unit and then * creating a new translation unit with the same command-line arguments. * However, it may be more efficient to reparse a translation * unit using this routine. * * \param TU The translation unit whose contents will be re-parsed. The * translation unit must originally have been built with * \c clang_createTranslationUnitFromSourceFile(). * * \param num_unsaved_files The number of unsaved file entries in \p * unsaved_files. * * \param unsaved_files The files that have not yet been saved to disk * but may be required for parsing, including the contents of * those files. The contents and name of these files (as specified by * CXUnsavedFile) are copied when necessary, so the client only needs to * guarantee their validity until the call to this function returns. * * \param options A bitset of options composed of the flags in CXReparse_Flags. * The function \c clang_defaultReparseOptions() produces a default set of * options recommended for most uses, based on the translation unit. * * \returns 0 if the sources could be reparsed. A non-zero error code will be * returned if reparsing was impossible, such that the translation unit is * invalid. In such cases, the only valid call for \c TU is * \c clang_disposeTranslationUnit(TU). The error codes returned by this * routine are described by the \c CXErrorCode enum. */ CINDEX_LINKAGE int clang_reparseTranslationUnit(CXTranslationUnit TU, unsigned num_unsaved_files, struct CXUnsavedFile *unsaved_files, unsigned options); /** * Categorizes how memory is being used by a translation unit. */ enum CXTUResourceUsageKind { CXTUResourceUsage_AST = 1, CXTUResourceUsage_Identifiers = 2, CXTUResourceUsage_Selectors = 3, CXTUResourceUsage_GlobalCompletionResults = 4, CXTUResourceUsage_SourceManagerContentCache = 5, CXTUResourceUsage_AST_SideTables = 6, CXTUResourceUsage_SourceManager_Membuffer_Malloc = 7, CXTUResourceUsage_SourceManager_Membuffer_MMap = 8, CXTUResourceUsage_ExternalASTSource_Membuffer_Malloc = 9, CXTUResourceUsage_ExternalASTSource_Membuffer_MMap = 10, CXTUResourceUsage_Preprocessor = 11, CXTUResourceUsage_PreprocessingRecord = 12, CXTUResourceUsage_SourceManager_DataStructures = 13, CXTUResourceUsage_Preprocessor_HeaderSearch = 14, CXTUResourceUsage_MEMORY_IN_BYTES_BEGIN = CXTUResourceUsage_AST, CXTUResourceUsage_MEMORY_IN_BYTES_END = CXTUResourceUsage_Preprocessor_HeaderSearch, CXTUResourceUsage_First = CXTUResourceUsage_AST, CXTUResourceUsage_Last = CXTUResourceUsage_Preprocessor_HeaderSearch }; /** * Returns the human-readable null-terminated C string that represents * the name of the memory category. This string should never be freed. */ CINDEX_LINKAGE const char *clang_getTUResourceUsageName(enum CXTUResourceUsageKind kind); typedef struct CXTUResourceUsageEntry { /* The memory usage category. */ enum CXTUResourceUsageKind kind; /* Amount of resources used. The units will depend on the resource kind. */ unsigned long amount; } CXTUResourceUsageEntry; /** * The memory usage of a CXTranslationUnit, broken into categories. */ typedef struct CXTUResourceUsage { /* Private data member, used for queries. */ void *data; /* The number of entries in the 'entries' array. */ unsigned numEntries; /* An array of key-value pairs, representing the breakdown of memory usage. */ CXTUResourceUsageEntry *entries; } CXTUResourceUsage; /** * Return the memory usage of a translation unit. This object * should be released with clang_disposeCXTUResourceUsage(). */ CINDEX_LINKAGE CXTUResourceUsage clang_getCXTUResourceUsage(CXTranslationUnit TU); CINDEX_LINKAGE void clang_disposeCXTUResourceUsage(CXTUResourceUsage usage); /** * Get target information for this translation unit. * * The CXTargetInfo object cannot outlive the CXTranslationUnit object. */ CINDEX_LINKAGE CXTargetInfo clang_getTranslationUnitTargetInfo(CXTranslationUnit CTUnit); /** * Destroy the CXTargetInfo object. */ CINDEX_LINKAGE void clang_TargetInfo_dispose(CXTargetInfo Info); /** * Get the normalized target triple as a string. * * Returns the empty string in case of any error. */ CINDEX_LINKAGE CXString clang_TargetInfo_getTriple(CXTargetInfo Info); /** * Get the pointer width of the target in bits. * * Returns -1 in case of error. */ CINDEX_LINKAGE int clang_TargetInfo_getPointerWidth(CXTargetInfo Info); /** * @} */ /** * Describes the kind of entity that a cursor refers to. */ enum CXCursorKind { /* Declarations */ /** * A declaration whose specific kind is not exposed via this * interface. * * Unexposed declarations have the same operations as any other kind * of declaration; one can extract their location information, * spelling, find their definitions, etc. However, the specific kind * of the declaration is not reported. */ CXCursor_UnexposedDecl = 1, /** A C or C++ struct. */ CXCursor_StructDecl = 2, /** A C or C++ union. */ CXCursor_UnionDecl = 3, /** A C++ class. */ CXCursor_ClassDecl = 4, /** An enumeration. */ CXCursor_EnumDecl = 5, /** * A field (in C) or non-static data member (in C++) in a * struct, union, or C++ class. */ CXCursor_FieldDecl = 6, /** An enumerator constant. */ CXCursor_EnumConstantDecl = 7, /** A function. */ CXCursor_FunctionDecl = 8, /** A variable. */ CXCursor_VarDecl = 9, /** A function or method parameter. */ CXCursor_ParmDecl = 10, /** An Objective-C \@interface. */ CXCursor_ObjCInterfaceDecl = 11, /** An Objective-C \@interface for a category. */ CXCursor_ObjCCategoryDecl = 12, /** An Objective-C \@protocol declaration. */ CXCursor_ObjCProtocolDecl = 13, /** An Objective-C \@property declaration. */ CXCursor_ObjCPropertyDecl = 14, /** An Objective-C instance variable. */ CXCursor_ObjCIvarDecl = 15, /** An Objective-C instance method. */ CXCursor_ObjCInstanceMethodDecl = 16, /** An Objective-C class method. */ CXCursor_ObjCClassMethodDecl = 17, /** An Objective-C \@implementation. */ CXCursor_ObjCImplementationDecl = 18, /** An Objective-C \@implementation for a category. */ CXCursor_ObjCCategoryImplDecl = 19, /** A typedef. */ CXCursor_TypedefDecl = 20, /** A C++ class method. */ CXCursor_CXXMethod = 21, /** A C++ namespace. */ CXCursor_Namespace = 22, /** A linkage specification, e.g. 'extern "C"'. */ CXCursor_LinkageSpec = 23, /** A C++ constructor. */ CXCursor_Constructor = 24, /** A C++ destructor. */ CXCursor_Destructor = 25, /** A C++ conversion function. */ CXCursor_ConversionFunction = 26, /** A C++ template type parameter. */ CXCursor_TemplateTypeParameter = 27, /** A C++ non-type template parameter. */ CXCursor_NonTypeTemplateParameter = 28, /** A C++ template template parameter. */ CXCursor_TemplateTemplateParameter = 29, /** A C++ function template. */ CXCursor_FunctionTemplate = 30, /** A C++ class template. */ CXCursor_ClassTemplate = 31, /** A C++ class template partial specialization. */ CXCursor_ClassTemplatePartialSpecialization = 32, /** A C++ namespace alias declaration. */ CXCursor_NamespaceAlias = 33, /** A C++ using directive. */ CXCursor_UsingDirective = 34, /** A C++ using declaration. */ CXCursor_UsingDeclaration = 35, /** A C++ alias declaration */ CXCursor_TypeAliasDecl = 36, /** An Objective-C \@synthesize definition. */ CXCursor_ObjCSynthesizeDecl = 37, /** An Objective-C \@dynamic definition. */ CXCursor_ObjCDynamicDecl = 38, /** An access specifier. */ CXCursor_CXXAccessSpecifier = 39, CXCursor_FirstDecl = CXCursor_UnexposedDecl, CXCursor_LastDecl = CXCursor_CXXAccessSpecifier, /* References */ CXCursor_FirstRef = 40, /* Decl references */ CXCursor_ObjCSuperClassRef = 40, CXCursor_ObjCProtocolRef = 41, CXCursor_ObjCClassRef = 42, /** * A reference to a type declaration. * * A type reference occurs anywhere where a type is named but not * declared. For example, given: * * \code * typedef unsigned size_type; * size_type size; * \endcode * * The typedef is a declaration of size_type (CXCursor_TypedefDecl), * while the type of the variable "size" is referenced. The cursor * referenced by the type of size is the typedef for size_type. */ CXCursor_TypeRef = 43, CXCursor_CXXBaseSpecifier = 44, /** * A reference to a class template, function template, template * template parameter, or class template partial specialization. */ CXCursor_TemplateRef = 45, /** * A reference to a namespace or namespace alias. */ CXCursor_NamespaceRef = 46, /** * A reference to a member of a struct, union, or class that occurs in * some non-expression context, e.g., a designated initializer. */ CXCursor_MemberRef = 47, /** * A reference to a labeled statement. * * This cursor kind is used to describe the jump to "start_over" in the * goto statement in the following example: * * \code * start_over: * ++counter; * * goto start_over; * \endcode * * A label reference cursor refers to a label statement. */ CXCursor_LabelRef = 48, /** * A reference to a set of overloaded functions or function templates * that has not yet been resolved to a specific function or function template. * * An overloaded declaration reference cursor occurs in C++ templates where * a dependent name refers to a function. For example: * * \code * template void swap(T&, T&); * * struct X { ... }; * void swap(X&, X&); * * template * void reverse(T* first, T* last) { * while (first < last - 1) { * swap(*first, *--last); * ++first; * } * } * * struct Y { }; * void swap(Y&, Y&); * \endcode * * Here, the identifier "swap" is associated with an overloaded declaration * reference. In the template definition, "swap" refers to either of the two * "swap" functions declared above, so both results will be available. At * instantiation time, "swap" may also refer to other functions found via * argument-dependent lookup (e.g., the "swap" function at the end of the * example). * * The functions \c clang_getNumOverloadedDecls() and * \c clang_getOverloadedDecl() can be used to retrieve the definitions * referenced by this cursor. */ CXCursor_OverloadedDeclRef = 49, /** * A reference to a variable that occurs in some non-expression * context, e.g., a C++ lambda capture list. */ CXCursor_VariableRef = 50, CXCursor_LastRef = CXCursor_VariableRef, /* Error conditions */ CXCursor_FirstInvalid = 70, CXCursor_InvalidFile = 70, CXCursor_NoDeclFound = 71, CXCursor_NotImplemented = 72, CXCursor_InvalidCode = 73, CXCursor_LastInvalid = CXCursor_InvalidCode, /* Expressions */ CXCursor_FirstExpr = 100, /** * An expression whose specific kind is not exposed via this * interface. * * Unexposed expressions have the same operations as any other kind * of expression; one can extract their location information, * spelling, children, etc. However, the specific kind of the * expression is not reported. */ CXCursor_UnexposedExpr = 100, /** * An expression that refers to some value declaration, such * as a function, variable, or enumerator. */ CXCursor_DeclRefExpr = 101, /** * An expression that refers to a member of a struct, union, * class, Objective-C class, etc. */ CXCursor_MemberRefExpr = 102, /** An expression that calls a function. */ CXCursor_CallExpr = 103, /** An expression that sends a message to an Objective-C object or class. */ CXCursor_ObjCMessageExpr = 104, /** An expression that represents a block literal. */ CXCursor_BlockExpr = 105, /** An integer literal. */ CXCursor_IntegerLiteral = 106, /** A floating point number literal. */ CXCursor_FloatingLiteral = 107, /** An imaginary number literal. */ CXCursor_ImaginaryLiteral = 108, /** A string literal. */ CXCursor_StringLiteral = 109, /** A character literal. */ CXCursor_CharacterLiteral = 110, /** A parenthesized expression, e.g. "(1)". * * This AST node is only formed if full location information is requested. */ CXCursor_ParenExpr = 111, /** This represents the unary-expression's (except sizeof and * alignof). */ CXCursor_UnaryOperator = 112, /** [C99 6.5.2.1] Array Subscripting. */ CXCursor_ArraySubscriptExpr = 113, /** A builtin binary operation expression such as "x + y" or * "x <= y". */ CXCursor_BinaryOperator = 114, /** Compound assignment such as "+=". */ CXCursor_CompoundAssignOperator = 115, /** The ?: ternary operator. */ CXCursor_ConditionalOperator = 116, /** An explicit cast in C (C99 6.5.4) or a C-style cast in C++ * (C++ [expr.cast]), which uses the syntax (Type)expr. * * For example: (int)f. */ CXCursor_CStyleCastExpr = 117, /** [C99 6.5.2.5] */ CXCursor_CompoundLiteralExpr = 118, /** Describes an C or C++ initializer list. */ CXCursor_InitListExpr = 119, /** The GNU address of label extension, representing &&label. */ CXCursor_AddrLabelExpr = 120, /** This is the GNU Statement Expression extension: ({int X=4; X;}) */ CXCursor_StmtExpr = 121, /** Represents a C11 generic selection. */ CXCursor_GenericSelectionExpr = 122, /** Implements the GNU __null extension, which is a name for a null * pointer constant that has integral type (e.g., int or long) and is the same * size and alignment as a pointer. * * The __null extension is typically only used by system headers, which define * NULL as __null in C++ rather than using 0 (which is an integer that may not * match the size of a pointer). */ CXCursor_GNUNullExpr = 123, /** C++'s static_cast<> expression. */ CXCursor_CXXStaticCastExpr = 124, /** C++'s dynamic_cast<> expression. */ CXCursor_CXXDynamicCastExpr = 125, /** C++'s reinterpret_cast<> expression. */ CXCursor_CXXReinterpretCastExpr = 126, /** C++'s const_cast<> expression. */ CXCursor_CXXConstCastExpr = 127, /** Represents an explicit C++ type conversion that uses "functional" * notion (C++ [expr.type.conv]). * * Example: * \code * x = int(0.5); * \endcode */ CXCursor_CXXFunctionalCastExpr = 128, /** A C++ typeid expression (C++ [expr.typeid]). */ CXCursor_CXXTypeidExpr = 129, /** [C++ 2.13.5] C++ Boolean Literal. */ CXCursor_CXXBoolLiteralExpr = 130, /** [C++0x 2.14.7] C++ Pointer Literal. */ CXCursor_CXXNullPtrLiteralExpr = 131, /** Represents the "this" expression in C++ */ CXCursor_CXXThisExpr = 132, /** [C++ 15] C++ Throw Expression. * * This handles 'throw' and 'throw' assignment-expression. When * assignment-expression isn't present, Op will be null. */ CXCursor_CXXThrowExpr = 133, /** A new expression for memory allocation and constructor calls, e.g: * "new CXXNewExpr(foo)". */ CXCursor_CXXNewExpr = 134, /** A delete expression for memory deallocation and destructor calls, * e.g. "delete[] pArray". */ CXCursor_CXXDeleteExpr = 135, /** A unary expression. (noexcept, sizeof, or other traits) */ CXCursor_UnaryExpr = 136, /** An Objective-C string literal i.e. @"foo". */ CXCursor_ObjCStringLiteral = 137, /** An Objective-C \@encode expression. */ CXCursor_ObjCEncodeExpr = 138, /** An Objective-C \@selector expression. */ CXCursor_ObjCSelectorExpr = 139, /** An Objective-C \@protocol expression. */ CXCursor_ObjCProtocolExpr = 140, /** An Objective-C "bridged" cast expression, which casts between * Objective-C pointers and C pointers, transferring ownership in the process. * * \code * NSString *str = (__bridge_transfer NSString *)CFCreateString(); * \endcode */ CXCursor_ObjCBridgedCastExpr = 141, /** Represents a C++0x pack expansion that produces a sequence of * expressions. * * A pack expansion expression contains a pattern (which itself is an * expression) followed by an ellipsis. For example: * * \code * template * void forward(F f, Types &&...args) { * f(static_cast(args)...); * } * \endcode */ CXCursor_PackExpansionExpr = 142, /** Represents an expression that computes the length of a parameter * pack. * * \code * template * struct count { * static const unsigned value = sizeof...(Types); * }; * \endcode */ CXCursor_SizeOfPackExpr = 143, /* Represents a C++ lambda expression that produces a local function * object. * * \code * void abssort(float *x, unsigned N) { * std::sort(x, x + N, * [](float a, float b) { * return std::abs(a) < std::abs(b); * }); * } * \endcode */ CXCursor_LambdaExpr = 144, /** Objective-c Boolean Literal. */ CXCursor_ObjCBoolLiteralExpr = 145, /** Represents the "self" expression in an Objective-C method. */ CXCursor_ObjCSelfExpr = 146, /** OpenMP 5.0 [2.1.5, Array Section]. */ CXCursor_OMPArraySectionExpr = 147, /** Represents an @available(...) check. */ CXCursor_ObjCAvailabilityCheckExpr = 148, /** * Fixed point literal */ CXCursor_FixedPointLiteral = 149, /** OpenMP 5.0 [2.1.4, Array Shaping]. */ CXCursor_OMPArrayShapingExpr = 150, /** * OpenMP 5.0 [2.1.6 Iterators] */ CXCursor_OMPIteratorExpr = 151, /** OpenCL's addrspace_cast<> expression. */ CXCursor_CXXAddrspaceCastExpr = 152, /** * Expression that references a C++20 concept. */ CXCursor_ConceptSpecializationExpr = 153, /** * Expression that references a C++20 concept. */ CXCursor_RequiresExpr = 154, /** * Expression that references a C++20 parenthesized list aggregate * initializer. */ CXCursor_CXXParenListInitExpr = 155, CXCursor_LastExpr = CXCursor_CXXParenListInitExpr, /* Statements */ CXCursor_FirstStmt = 200, /** * A statement whose specific kind is not exposed via this * interface. * * Unexposed statements have the same operations as any other kind of * statement; one can extract their location information, spelling, * children, etc. However, the specific kind of the statement is not * reported. */ CXCursor_UnexposedStmt = 200, /** A labelled statement in a function. * * This cursor kind is used to describe the "start_over:" label statement in * the following example: * * \code * start_over: * ++counter; * \endcode * */ CXCursor_LabelStmt = 201, /** A group of statements like { stmt stmt }. * * This cursor kind is used to describe compound statements, e.g. function * bodies. */ CXCursor_CompoundStmt = 202, /** A case statement. */ CXCursor_CaseStmt = 203, /** A default statement. */ CXCursor_DefaultStmt = 204, /** An if statement */ CXCursor_IfStmt = 205, /** A switch statement. */ CXCursor_SwitchStmt = 206, /** A while statement. */ CXCursor_WhileStmt = 207, /** A do statement. */ CXCursor_DoStmt = 208, /** A for statement. */ CXCursor_ForStmt = 209, /** A goto statement. */ CXCursor_GotoStmt = 210, /** An indirect goto statement. */ CXCursor_IndirectGotoStmt = 211, /** A continue statement. */ CXCursor_ContinueStmt = 212, /** A break statement. */ CXCursor_BreakStmt = 213, /** A return statement. */ CXCursor_ReturnStmt = 214, /** A GCC inline assembly statement extension. */ CXCursor_GCCAsmStmt = 215, CXCursor_AsmStmt = CXCursor_GCCAsmStmt, /** Objective-C's overall \@try-\@catch-\@finally statement. */ CXCursor_ObjCAtTryStmt = 216, /** Objective-C's \@catch statement. */ CXCursor_ObjCAtCatchStmt = 217, /** Objective-C's \@finally statement. */ CXCursor_ObjCAtFinallyStmt = 218, /** Objective-C's \@throw statement. */ CXCursor_ObjCAtThrowStmt = 219, /** Objective-C's \@synchronized statement. */ CXCursor_ObjCAtSynchronizedStmt = 220, /** Objective-C's autorelease pool statement. */ CXCursor_ObjCAutoreleasePoolStmt = 221, /** Objective-C's collection statement. */ CXCursor_ObjCForCollectionStmt = 222, /** C++'s catch statement. */ CXCursor_CXXCatchStmt = 223, /** C++'s try statement. */ CXCursor_CXXTryStmt = 224, /** C++'s for (* : *) statement. */ CXCursor_CXXForRangeStmt = 225, /** Windows Structured Exception Handling's try statement. */ CXCursor_SEHTryStmt = 226, /** Windows Structured Exception Handling's except statement. */ CXCursor_SEHExceptStmt = 227, /** Windows Structured Exception Handling's finally statement. */ CXCursor_SEHFinallyStmt = 228, /** A MS inline assembly statement extension. */ CXCursor_MSAsmStmt = 229, /** The null statement ";": C99 6.8.3p3. * * This cursor kind is used to describe the null statement. */ CXCursor_NullStmt = 230, /** Adaptor class for mixing declarations with statements and * expressions. */ CXCursor_DeclStmt = 231, /** OpenMP parallel directive. */ CXCursor_OMPParallelDirective = 232, /** OpenMP SIMD directive. */ CXCursor_OMPSimdDirective = 233, /** OpenMP for directive. */ CXCursor_OMPForDirective = 234, /** OpenMP sections directive. */ CXCursor_OMPSectionsDirective = 235, /** OpenMP section directive. */ CXCursor_OMPSectionDirective = 236, /** OpenMP single directive. */ CXCursor_OMPSingleDirective = 237, /** OpenMP parallel for directive. */ CXCursor_OMPParallelForDirective = 238, /** OpenMP parallel sections directive. */ CXCursor_OMPParallelSectionsDirective = 239, /** OpenMP task directive. */ CXCursor_OMPTaskDirective = 240, /** OpenMP master directive. */ CXCursor_OMPMasterDirective = 241, /** OpenMP critical directive. */ CXCursor_OMPCriticalDirective = 242, /** OpenMP taskyield directive. */ CXCursor_OMPTaskyieldDirective = 243, /** OpenMP barrier directive. */ CXCursor_OMPBarrierDirective = 244, /** OpenMP taskwait directive. */ CXCursor_OMPTaskwaitDirective = 245, /** OpenMP flush directive. */ CXCursor_OMPFlushDirective = 246, /** Windows Structured Exception Handling's leave statement. */ CXCursor_SEHLeaveStmt = 247, /** OpenMP ordered directive. */ CXCursor_OMPOrderedDirective = 248, /** OpenMP atomic directive. */ CXCursor_OMPAtomicDirective = 249, /** OpenMP for SIMD directive. */ CXCursor_OMPForSimdDirective = 250, /** OpenMP parallel for SIMD directive. */ CXCursor_OMPParallelForSimdDirective = 251, /** OpenMP target directive. */ CXCursor_OMPTargetDirective = 252, /** OpenMP teams directive. */ CXCursor_OMPTeamsDirective = 253, /** OpenMP taskgroup directive. */ CXCursor_OMPTaskgroupDirective = 254, /** OpenMP cancellation point directive. */ CXCursor_OMPCancellationPointDirective = 255, /** OpenMP cancel directive. */ CXCursor_OMPCancelDirective = 256, /** OpenMP target data directive. */ CXCursor_OMPTargetDataDirective = 257, /** OpenMP taskloop directive. */ CXCursor_OMPTaskLoopDirective = 258, /** OpenMP taskloop simd directive. */ CXCursor_OMPTaskLoopSimdDirective = 259, /** OpenMP distribute directive. */ CXCursor_OMPDistributeDirective = 260, /** OpenMP target enter data directive. */ CXCursor_OMPTargetEnterDataDirective = 261, /** OpenMP target exit data directive. */ CXCursor_OMPTargetExitDataDirective = 262, /** OpenMP target parallel directive. */ CXCursor_OMPTargetParallelDirective = 263, /** OpenMP target parallel for directive. */ CXCursor_OMPTargetParallelForDirective = 264, /** OpenMP target update directive. */ CXCursor_OMPTargetUpdateDirective = 265, /** OpenMP distribute parallel for directive. */ CXCursor_OMPDistributeParallelForDirective = 266, /** OpenMP distribute parallel for simd directive. */ CXCursor_OMPDistributeParallelForSimdDirective = 267, /** OpenMP distribute simd directive. */ CXCursor_OMPDistributeSimdDirective = 268, /** OpenMP target parallel for simd directive. */ CXCursor_OMPTargetParallelForSimdDirective = 269, /** OpenMP target simd directive. */ CXCursor_OMPTargetSimdDirective = 270, /** OpenMP teams distribute directive. */ CXCursor_OMPTeamsDistributeDirective = 271, /** OpenMP teams distribute simd directive. */ CXCursor_OMPTeamsDistributeSimdDirective = 272, /** OpenMP teams distribute parallel for simd directive. */ CXCursor_OMPTeamsDistributeParallelForSimdDirective = 273, /** OpenMP teams distribute parallel for directive. */ CXCursor_OMPTeamsDistributeParallelForDirective = 274, /** OpenMP target teams directive. */ CXCursor_OMPTargetTeamsDirective = 275, /** OpenMP target teams distribute directive. */ CXCursor_OMPTargetTeamsDistributeDirective = 276, /** OpenMP target teams distribute parallel for directive. */ CXCursor_OMPTargetTeamsDistributeParallelForDirective = 277, /** OpenMP target teams distribute parallel for simd directive. */ CXCursor_OMPTargetTeamsDistributeParallelForSimdDirective = 278, /** OpenMP target teams distribute simd directive. */ CXCursor_OMPTargetTeamsDistributeSimdDirective = 279, /** C++2a std::bit_cast expression. */ CXCursor_BuiltinBitCastExpr = 280, /** OpenMP master taskloop directive. */ CXCursor_OMPMasterTaskLoopDirective = 281, /** OpenMP parallel master taskloop directive. */ CXCursor_OMPParallelMasterTaskLoopDirective = 282, /** OpenMP master taskloop simd directive. */ CXCursor_OMPMasterTaskLoopSimdDirective = 283, /** OpenMP parallel master taskloop simd directive. */ CXCursor_OMPParallelMasterTaskLoopSimdDirective = 284, /** OpenMP parallel master directive. */ CXCursor_OMPParallelMasterDirective = 285, /** OpenMP depobj directive. */ CXCursor_OMPDepobjDirective = 286, /** OpenMP scan directive. */ CXCursor_OMPScanDirective = 287, /** OpenMP tile directive. */ CXCursor_OMPTileDirective = 288, /** OpenMP canonical loop. */ CXCursor_OMPCanonicalLoop = 289, /** OpenMP interop directive. */ CXCursor_OMPInteropDirective = 290, /** OpenMP dispatch directive. */ CXCursor_OMPDispatchDirective = 291, /** OpenMP masked directive. */ CXCursor_OMPMaskedDirective = 292, /** OpenMP unroll directive. */ CXCursor_OMPUnrollDirective = 293, /** OpenMP metadirective directive. */ CXCursor_OMPMetaDirective = 294, /** OpenMP loop directive. */ CXCursor_OMPGenericLoopDirective = 295, /** OpenMP teams loop directive. */ CXCursor_OMPTeamsGenericLoopDirective = 296, /** OpenMP target teams loop directive. */ CXCursor_OMPTargetTeamsGenericLoopDirective = 297, /** OpenMP parallel loop directive. */ CXCursor_OMPParallelGenericLoopDirective = 298, /** OpenMP target parallel loop directive. */ CXCursor_OMPTargetParallelGenericLoopDirective = 299, /** OpenMP parallel masked directive. */ CXCursor_OMPParallelMaskedDirective = 300, /** OpenMP masked taskloop directive. */ CXCursor_OMPMaskedTaskLoopDirective = 301, /** OpenMP masked taskloop simd directive. */ CXCursor_OMPMaskedTaskLoopSimdDirective = 302, /** OpenMP parallel masked taskloop directive. */ CXCursor_OMPParallelMaskedTaskLoopDirective = 303, /** OpenMP parallel masked taskloop simd directive. */ CXCursor_OMPParallelMaskedTaskLoopSimdDirective = 304, /** OpenMP error directive. */ CXCursor_OMPErrorDirective = 305, CXCursor_LastStmt = CXCursor_OMPErrorDirective, /** * Cursor that represents the translation unit itself. * * The translation unit cursor exists primarily to act as the root * cursor for traversing the contents of a translation unit. */ CXCursor_TranslationUnit = 350, /* Attributes */ CXCursor_FirstAttr = 400, /** * An attribute whose specific kind is not exposed via this * interface. */ CXCursor_UnexposedAttr = 400, CXCursor_IBActionAttr = 401, CXCursor_IBOutletAttr = 402, CXCursor_IBOutletCollectionAttr = 403, CXCursor_CXXFinalAttr = 404, CXCursor_CXXOverrideAttr = 405, CXCursor_AnnotateAttr = 406, CXCursor_AsmLabelAttr = 407, CXCursor_PackedAttr = 408, CXCursor_PureAttr = 409, CXCursor_ConstAttr = 410, CXCursor_NoDuplicateAttr = 411, CXCursor_CUDAConstantAttr = 412, CXCursor_CUDADeviceAttr = 413, CXCursor_CUDAGlobalAttr = 414, CXCursor_CUDAHostAttr = 415, CXCursor_CUDASharedAttr = 416, CXCursor_VisibilityAttr = 417, CXCursor_DLLExport = 418, CXCursor_DLLImport = 419, CXCursor_NSReturnsRetained = 420, CXCursor_NSReturnsNotRetained = 421, CXCursor_NSReturnsAutoreleased = 422, CXCursor_NSConsumesSelf = 423, CXCursor_NSConsumed = 424, CXCursor_ObjCException = 425, CXCursor_ObjCNSObject = 426, CXCursor_ObjCIndependentClass = 427, CXCursor_ObjCPreciseLifetime = 428, CXCursor_ObjCReturnsInnerPointer = 429, CXCursor_ObjCRequiresSuper = 430, CXCursor_ObjCRootClass = 431, CXCursor_ObjCSubclassingRestricted = 432, CXCursor_ObjCExplicitProtocolImpl = 433, CXCursor_ObjCDesignatedInitializer = 434, CXCursor_ObjCRuntimeVisible = 435, CXCursor_ObjCBoxable = 436, CXCursor_FlagEnum = 437, CXCursor_ConvergentAttr = 438, CXCursor_WarnUnusedAttr = 439, CXCursor_WarnUnusedResultAttr = 440, CXCursor_AlignedAttr = 441, CXCursor_LastAttr = CXCursor_AlignedAttr, /* Preprocessing */ CXCursor_PreprocessingDirective = 500, CXCursor_MacroDefinition = 501, CXCursor_MacroExpansion = 502, CXCursor_MacroInstantiation = CXCursor_MacroExpansion, CXCursor_InclusionDirective = 503, CXCursor_FirstPreprocessing = CXCursor_PreprocessingDirective, CXCursor_LastPreprocessing = CXCursor_InclusionDirective, /* Extra Declarations */ /** * A module import declaration. */ CXCursor_ModuleImportDecl = 600, CXCursor_TypeAliasTemplateDecl = 601, /** * A static_assert or _Static_assert node */ CXCursor_StaticAssert = 602, /** * a friend declaration. */ CXCursor_FriendDecl = 603, /** * a concept declaration. */ CXCursor_ConceptDecl = 604, CXCursor_FirstExtraDecl = CXCursor_ModuleImportDecl, CXCursor_LastExtraDecl = CXCursor_ConceptDecl, /** * A code completion overload candidate. */ CXCursor_OverloadCandidate = 700 }; /** * A cursor representing some element in the abstract syntax tree for * a translation unit. * * The cursor abstraction unifies the different kinds of entities in a * program--declaration, statements, expressions, references to declarations, * etc.--under a single "cursor" abstraction with a common set of operations. * Common operation for a cursor include: getting the physical location in * a source file where the cursor points, getting the name associated with a * cursor, and retrieving cursors for any child nodes of a particular cursor. * * Cursors can be produced in two specific ways. * clang_getTranslationUnitCursor() produces a cursor for a translation unit, * from which one can use clang_visitChildren() to explore the rest of the * translation unit. clang_getCursor() maps from a physical source location * to the entity that resides at that location, allowing one to map from the * source code into the AST. */ typedef struct { enum CXCursorKind kind; int xdata; const void *data[3]; } CXCursor; /** * \defgroup CINDEX_CURSOR_MANIP Cursor manipulations * * @{ */ /** * Retrieve the NULL cursor, which represents no entity. */ CINDEX_LINKAGE CXCursor clang_getNullCursor(void); /** * Retrieve the cursor that represents the given translation unit. * * The translation unit cursor can be used to start traversing the * various declarations within the given translation unit. */ CINDEX_LINKAGE CXCursor clang_getTranslationUnitCursor(CXTranslationUnit); /** * Determine whether two cursors are equivalent. */ CINDEX_LINKAGE unsigned clang_equalCursors(CXCursor, CXCursor); /** * Returns non-zero if \p cursor is null. */ CINDEX_LINKAGE int clang_Cursor_isNull(CXCursor cursor); /** * Compute a hash value for the given cursor. */ CINDEX_LINKAGE unsigned clang_hashCursor(CXCursor); /** * Retrieve the kind of the given cursor. */ CINDEX_LINKAGE enum CXCursorKind clang_getCursorKind(CXCursor); /** * Determine whether the given cursor kind represents a declaration. */ CINDEX_LINKAGE unsigned clang_isDeclaration(enum CXCursorKind); /** * Determine whether the given declaration is invalid. * * A declaration is invalid if it could not be parsed successfully. * * \returns non-zero if the cursor represents a declaration and it is * invalid, otherwise NULL. */ CINDEX_LINKAGE unsigned clang_isInvalidDeclaration(CXCursor); /** * Determine whether the given cursor kind represents a simple * reference. * * Note that other kinds of cursors (such as expressions) can also refer to * other cursors. Use clang_getCursorReferenced() to determine whether a * particular cursor refers to another entity. */ CINDEX_LINKAGE unsigned clang_isReference(enum CXCursorKind); /** * Determine whether the given cursor kind represents an expression. */ CINDEX_LINKAGE unsigned clang_isExpression(enum CXCursorKind); /** * Determine whether the given cursor kind represents a statement. */ CINDEX_LINKAGE unsigned clang_isStatement(enum CXCursorKind); /** * Determine whether the given cursor kind represents an attribute. */ CINDEX_LINKAGE unsigned clang_isAttribute(enum CXCursorKind); /** * Determine whether the given cursor has any attributes. */ CINDEX_LINKAGE unsigned clang_Cursor_hasAttrs(CXCursor C); /** * Determine whether the given cursor kind represents an invalid * cursor. */ CINDEX_LINKAGE unsigned clang_isInvalid(enum CXCursorKind); /** * Determine whether the given cursor kind represents a translation * unit. */ CINDEX_LINKAGE unsigned clang_isTranslationUnit(enum CXCursorKind); /*** * Determine whether the given cursor represents a preprocessing * element, such as a preprocessor directive or macro instantiation. */ CINDEX_LINKAGE unsigned clang_isPreprocessing(enum CXCursorKind); /*** * Determine whether the given cursor represents a currently * unexposed piece of the AST (e.g., CXCursor_UnexposedStmt). */ CINDEX_LINKAGE unsigned clang_isUnexposed(enum CXCursorKind); /** * Describe the linkage of the entity referred to by a cursor. */ enum CXLinkageKind { /** This value indicates that no linkage information is available * for a provided CXCursor. */ CXLinkage_Invalid, /** * This is the linkage for variables, parameters, and so on that * have automatic storage. This covers normal (non-extern) local variables. */ CXLinkage_NoLinkage, /** This is the linkage for static variables and static functions. */ CXLinkage_Internal, /** This is the linkage for entities with external linkage that live * in C++ anonymous namespaces.*/ CXLinkage_UniqueExternal, /** This is the linkage for entities with true, external linkage. */ CXLinkage_External }; /** * Determine the linkage of the entity referred to by a given cursor. */ CINDEX_LINKAGE enum CXLinkageKind clang_getCursorLinkage(CXCursor cursor); enum CXVisibilityKind { /** This value indicates that no visibility information is available * for a provided CXCursor. */ CXVisibility_Invalid, /** Symbol not seen by the linker. */ CXVisibility_Hidden, /** Symbol seen by the linker but resolves to a symbol inside this object. */ CXVisibility_Protected, /** Symbol seen by the linker and acts like a normal symbol. */ CXVisibility_Default }; /** * Describe the visibility of the entity referred to by a cursor. * * This returns the default visibility if not explicitly specified by * a visibility attribute. The default visibility may be changed by * commandline arguments. * * \param cursor The cursor to query. * * \returns The visibility of the cursor. */ CINDEX_LINKAGE enum CXVisibilityKind clang_getCursorVisibility(CXCursor cursor); /** * Determine the availability of the entity that this cursor refers to, * taking the current target platform into account. * * \param cursor The cursor to query. * * \returns The availability of the cursor. */ CINDEX_LINKAGE enum CXAvailabilityKind clang_getCursorAvailability(CXCursor cursor); /** * Describes the availability of a given entity on a particular platform, e.g., * a particular class might only be available on Mac OS 10.7 or newer. */ typedef struct CXPlatformAvailability { /** * A string that describes the platform for which this structure * provides availability information. * * Possible values are "ios" or "macos". */ CXString Platform; /** * The version number in which this entity was introduced. */ CXVersion Introduced; /** * The version number in which this entity was deprecated (but is * still available). */ CXVersion Deprecated; /** * The version number in which this entity was obsoleted, and therefore * is no longer available. */ CXVersion Obsoleted; /** * Whether the entity is unconditionally unavailable on this platform. */ int Unavailable; /** * An optional message to provide to a user of this API, e.g., to * suggest replacement APIs. */ CXString Message; } CXPlatformAvailability; /** * Determine the availability of the entity that this cursor refers to * on any platforms for which availability information is known. * * \param cursor The cursor to query. * * \param always_deprecated If non-NULL, will be set to indicate whether the * entity is deprecated on all platforms. * * \param deprecated_message If non-NULL, will be set to the message text * provided along with the unconditional deprecation of this entity. The client * is responsible for deallocating this string. * * \param always_unavailable If non-NULL, will be set to indicate whether the * entity is unavailable on all platforms. * * \param unavailable_message If non-NULL, will be set to the message text * provided along with the unconditional unavailability of this entity. The * client is responsible for deallocating this string. * * \param availability If non-NULL, an array of CXPlatformAvailability instances * that will be populated with platform availability information, up to either * the number of platforms for which availability information is available (as * returned by this function) or \c availability_size, whichever is smaller. * * \param availability_size The number of elements available in the * \c availability array. * * \returns The number of platforms (N) for which availability information is * available (which is unrelated to \c availability_size). * * Note that the client is responsible for calling * \c clang_disposeCXPlatformAvailability to free each of the * platform-availability structures returned. There are * \c min(N, availability_size) such structures. */ CINDEX_LINKAGE int clang_getCursorPlatformAvailability( CXCursor cursor, int *always_deprecated, CXString *deprecated_message, int *always_unavailable, CXString *unavailable_message, CXPlatformAvailability *availability, int availability_size); /** * Free the memory associated with a \c CXPlatformAvailability structure. */ CINDEX_LINKAGE void clang_disposeCXPlatformAvailability(CXPlatformAvailability *availability); /** * If cursor refers to a variable declaration and it has initializer returns * cursor referring to the initializer otherwise return null cursor. */ CINDEX_LINKAGE CXCursor clang_Cursor_getVarDeclInitializer(CXCursor cursor); /** * If cursor refers to a variable declaration that has global storage returns 1. * If cursor refers to a variable declaration that doesn't have global storage * returns 0. Otherwise returns -1. */ CINDEX_LINKAGE int clang_Cursor_hasVarDeclGlobalStorage(CXCursor cursor); /** * If cursor refers to a variable declaration that has external storage * returns 1. If cursor refers to a variable declaration that doesn't have * external storage returns 0. Otherwise returns -1. */ CINDEX_LINKAGE int clang_Cursor_hasVarDeclExternalStorage(CXCursor cursor); /** * Describe the "language" of the entity referred to by a cursor. */ enum CXLanguageKind { CXLanguage_Invalid = 0, CXLanguage_C, CXLanguage_ObjC, CXLanguage_CPlusPlus }; /** * Determine the "language" of the entity referred to by a given cursor. */ CINDEX_LINKAGE enum CXLanguageKind clang_getCursorLanguage(CXCursor cursor); /** * Describe the "thread-local storage (TLS) kind" of the declaration * referred to by a cursor. */ enum CXTLSKind { CXTLS_None = 0, CXTLS_Dynamic, CXTLS_Static }; /** * Determine the "thread-local storage (TLS) kind" of the declaration * referred to by a cursor. */ CINDEX_LINKAGE enum CXTLSKind clang_getCursorTLSKind(CXCursor cursor); /** * Returns the translation unit that a cursor originated from. */ CINDEX_LINKAGE CXTranslationUnit clang_Cursor_getTranslationUnit(CXCursor); /** * A fast container representing a set of CXCursors. */ typedef struct CXCursorSetImpl *CXCursorSet; /** * Creates an empty CXCursorSet. */ CINDEX_LINKAGE CXCursorSet clang_createCXCursorSet(void); /** * Disposes a CXCursorSet and releases its associated memory. */ CINDEX_LINKAGE void clang_disposeCXCursorSet(CXCursorSet cset); /** * Queries a CXCursorSet to see if it contains a specific CXCursor. * * \returns non-zero if the set contains the specified cursor. */ CINDEX_LINKAGE unsigned clang_CXCursorSet_contains(CXCursorSet cset, CXCursor cursor); /** * Inserts a CXCursor into a CXCursorSet. * * \returns zero if the CXCursor was already in the set, and non-zero otherwise. */ CINDEX_LINKAGE unsigned clang_CXCursorSet_insert(CXCursorSet cset, CXCursor cursor); /** * Determine the semantic parent of the given cursor. * * The semantic parent of a cursor is the cursor that semantically contains * the given \p cursor. For many declarations, the lexical and semantic parents * are equivalent (the lexical parent is returned by * \c clang_getCursorLexicalParent()). They diverge when declarations or * definitions are provided out-of-line. For example: * * \code * class C { * void f(); * }; * * void C::f() { } * \endcode * * In the out-of-line definition of \c C::f, the semantic parent is * the class \c C, of which this function is a member. The lexical parent is * the place where the declaration actually occurs in the source code; in this * case, the definition occurs in the translation unit. In general, the * lexical parent for a given entity can change without affecting the semantics * of the program, and the lexical parent of different declarations of the * same entity may be different. Changing the semantic parent of a declaration, * on the other hand, can have a major impact on semantics, and redeclarations * of a particular entity should all have the same semantic context. * * In the example above, both declarations of \c C::f have \c C as their * semantic context, while the lexical context of the first \c C::f is \c C * and the lexical context of the second \c C::f is the translation unit. * * For global declarations, the semantic parent is the translation unit. */ CINDEX_LINKAGE CXCursor clang_getCursorSemanticParent(CXCursor cursor); /** * Determine the lexical parent of the given cursor. * * The lexical parent of a cursor is the cursor in which the given \p cursor * was actually written. For many declarations, the lexical and semantic parents * are equivalent (the semantic parent is returned by * \c clang_getCursorSemanticParent()). They diverge when declarations or * definitions are provided out-of-line. For example: * * \code * class C { * void f(); * }; * * void C::f() { } * \endcode * * In the out-of-line definition of \c C::f, the semantic parent is * the class \c C, of which this function is a member. The lexical parent is * the place where the declaration actually occurs in the source code; in this * case, the definition occurs in the translation unit. In general, the * lexical parent for a given entity can change without affecting the semantics * of the program, and the lexical parent of different declarations of the * same entity may be different. Changing the semantic parent of a declaration, * on the other hand, can have a major impact on semantics, and redeclarations * of a particular entity should all have the same semantic context. * * In the example above, both declarations of \c C::f have \c C as their * semantic context, while the lexical context of the first \c C::f is \c C * and the lexical context of the second \c C::f is the translation unit. * * For declarations written in the global scope, the lexical parent is * the translation unit. */ CINDEX_LINKAGE CXCursor clang_getCursorLexicalParent(CXCursor cursor); /** * Determine the set of methods that are overridden by the given * method. * * In both Objective-C and C++, a method (aka virtual member function, * in C++) can override a virtual method in a base class. For * Objective-C, a method is said to override any method in the class's * base class, its protocols, or its categories' protocols, that has the same * selector and is of the same kind (class or instance). * If no such method exists, the search continues to the class's superclass, * its protocols, and its categories, and so on. A method from an Objective-C * implementation is considered to override the same methods as its * corresponding method in the interface. * * For C++, a virtual member function overrides any virtual member * function with the same signature that occurs in its base * classes. With multiple inheritance, a virtual member function can * override several virtual member functions coming from different * base classes. * * In all cases, this function determines the immediate overridden * method, rather than all of the overridden methods. For example, if * a method is originally declared in a class A, then overridden in B * (which in inherits from A) and also in C (which inherited from B), * then the only overridden method returned from this function when * invoked on C's method will be B's method. The client may then * invoke this function again, given the previously-found overridden * methods, to map out the complete method-override set. * * \param cursor A cursor representing an Objective-C or C++ * method. This routine will compute the set of methods that this * method overrides. * * \param overridden A pointer whose pointee will be replaced with a * pointer to an array of cursors, representing the set of overridden * methods. If there are no overridden methods, the pointee will be * set to NULL. The pointee must be freed via a call to * \c clang_disposeOverriddenCursors(). * * \param num_overridden A pointer to the number of overridden * functions, will be set to the number of overridden functions in the * array pointed to by \p overridden. */ CINDEX_LINKAGE void clang_getOverriddenCursors(CXCursor cursor, CXCursor **overridden, unsigned *num_overridden); /** * Free the set of overridden cursors returned by \c * clang_getOverriddenCursors(). */ CINDEX_LINKAGE void clang_disposeOverriddenCursors(CXCursor *overridden); /** * Retrieve the file that is included by the given inclusion directive * cursor. */ CINDEX_LINKAGE CXFile clang_getIncludedFile(CXCursor cursor); /** * @} */ /** * \defgroup CINDEX_CURSOR_SOURCE Mapping between cursors and source code * * Cursors represent a location within the Abstract Syntax Tree (AST). These * routines help map between cursors and the physical locations where the * described entities occur in the source code. The mapping is provided in * both directions, so one can map from source code to the AST and back. * * @{ */ /** * Map a source location to the cursor that describes the entity at that * location in the source code. * * clang_getCursor() maps an arbitrary source location within a translation * unit down to the most specific cursor that describes the entity at that * location. For example, given an expression \c x + y, invoking * clang_getCursor() with a source location pointing to "x" will return the * cursor for "x"; similarly for "y". If the cursor points anywhere between * "x" or "y" (e.g., on the + or the whitespace around it), clang_getCursor() * will return a cursor referring to the "+" expression. * * \returns a cursor representing the entity at the given source location, or * a NULL cursor if no such entity can be found. */ CINDEX_LINKAGE CXCursor clang_getCursor(CXTranslationUnit, CXSourceLocation); /** * Retrieve the physical location of the source constructor referenced * by the given cursor. * * The location of a declaration is typically the location of the name of that * declaration, where the name of that declaration would occur if it is * unnamed, or some keyword that introduces that particular declaration. * The location of a reference is where that reference occurs within the * source code. */ CINDEX_LINKAGE CXSourceLocation clang_getCursorLocation(CXCursor); /** * Retrieve the physical extent of the source construct referenced by * the given cursor. * * The extent of a cursor starts with the file/line/column pointing at the * first character within the source construct that the cursor refers to and * ends with the last character within that source construct. For a * declaration, the extent covers the declaration itself. For a reference, * the extent covers the location of the reference (e.g., where the referenced * entity was actually used). */ CINDEX_LINKAGE CXSourceRange clang_getCursorExtent(CXCursor); /** * @} */ /** * \defgroup CINDEX_TYPES Type information for CXCursors * * @{ */ /** * Describes the kind of type */ enum CXTypeKind { /** * Represents an invalid type (e.g., where no type is available). */ CXType_Invalid = 0, /** * A type whose specific kind is not exposed via this * interface. */ CXType_Unexposed = 1, /* Builtin types */ CXType_Void = 2, CXType_Bool = 3, CXType_Char_U = 4, CXType_UChar = 5, CXType_Char16 = 6, CXType_Char32 = 7, CXType_UShort = 8, CXType_UInt = 9, CXType_ULong = 10, CXType_ULongLong = 11, CXType_UInt128 = 12, CXType_Char_S = 13, CXType_SChar = 14, CXType_WChar = 15, CXType_Short = 16, CXType_Int = 17, CXType_Long = 18, CXType_LongLong = 19, CXType_Int128 = 20, CXType_Float = 21, CXType_Double = 22, CXType_LongDouble = 23, CXType_NullPtr = 24, CXType_Overload = 25, CXType_Dependent = 26, CXType_ObjCId = 27, CXType_ObjCClass = 28, CXType_ObjCSel = 29, CXType_Float128 = 30, CXType_Half = 31, CXType_Float16 = 32, CXType_ShortAccum = 33, CXType_Accum = 34, CXType_LongAccum = 35, CXType_UShortAccum = 36, CXType_UAccum = 37, CXType_ULongAccum = 38, CXType_BFloat16 = 39, CXType_Ibm128 = 40, CXType_FirstBuiltin = CXType_Void, CXType_LastBuiltin = CXType_Ibm128, CXType_Complex = 100, CXType_Pointer = 101, CXType_BlockPointer = 102, CXType_LValueReference = 103, CXType_RValueReference = 104, CXType_Record = 105, CXType_Enum = 106, CXType_Typedef = 107, CXType_ObjCInterface = 108, CXType_ObjCObjectPointer = 109, CXType_FunctionNoProto = 110, CXType_FunctionProto = 111, CXType_ConstantArray = 112, CXType_Vector = 113, CXType_IncompleteArray = 114, CXType_VariableArray = 115, CXType_DependentSizedArray = 116, CXType_MemberPointer = 117, CXType_Auto = 118, /** * Represents a type that was referred to using an elaborated type keyword. * * E.g., struct S, or via a qualified name, e.g., N::M::type, or both. */ CXType_Elaborated = 119, /* OpenCL PipeType. */ CXType_Pipe = 120, /* OpenCL builtin types. */ CXType_OCLImage1dRO = 121, CXType_OCLImage1dArrayRO = 122, CXType_OCLImage1dBufferRO = 123, CXType_OCLImage2dRO = 124, CXType_OCLImage2dArrayRO = 125, CXType_OCLImage2dDepthRO = 126, CXType_OCLImage2dArrayDepthRO = 127, CXType_OCLImage2dMSAARO = 128, CXType_OCLImage2dArrayMSAARO = 129, CXType_OCLImage2dMSAADepthRO = 130, CXType_OCLImage2dArrayMSAADepthRO = 131, CXType_OCLImage3dRO = 132, CXType_OCLImage1dWO = 133, CXType_OCLImage1dArrayWO = 134, CXType_OCLImage1dBufferWO = 135, CXType_OCLImage2dWO = 136, CXType_OCLImage2dArrayWO = 137, CXType_OCLImage2dDepthWO = 138, CXType_OCLImage2dArrayDepthWO = 139, CXType_OCLImage2dMSAAWO = 140, CXType_OCLImage2dArrayMSAAWO = 141, CXType_OCLImage2dMSAADepthWO = 142, CXType_OCLImage2dArrayMSAADepthWO = 143, CXType_OCLImage3dWO = 144, CXType_OCLImage1dRW = 145, CXType_OCLImage1dArrayRW = 146, CXType_OCLImage1dBufferRW = 147, CXType_OCLImage2dRW = 148, CXType_OCLImage2dArrayRW = 149, CXType_OCLImage2dDepthRW = 150, CXType_OCLImage2dArrayDepthRW = 151, CXType_OCLImage2dMSAARW = 152, CXType_OCLImage2dArrayMSAARW = 153, CXType_OCLImage2dMSAADepthRW = 154, CXType_OCLImage2dArrayMSAADepthRW = 155, CXType_OCLImage3dRW = 156, CXType_OCLSampler = 157, CXType_OCLEvent = 158, CXType_OCLQueue = 159, CXType_OCLReserveID = 160, CXType_ObjCObject = 161, CXType_ObjCTypeParam = 162, CXType_Attributed = 163, CXType_OCLIntelSubgroupAVCMcePayload = 164, CXType_OCLIntelSubgroupAVCImePayload = 165, CXType_OCLIntelSubgroupAVCRefPayload = 166, CXType_OCLIntelSubgroupAVCSicPayload = 167, CXType_OCLIntelSubgroupAVCMceResult = 168, CXType_OCLIntelSubgroupAVCImeResult = 169, CXType_OCLIntelSubgroupAVCRefResult = 170, CXType_OCLIntelSubgroupAVCSicResult = 171, CXType_OCLIntelSubgroupAVCImeResultSingleReferenceStreamout = 172, CXType_OCLIntelSubgroupAVCImeResultDualReferenceStreamout = 173, CXType_OCLIntelSubgroupAVCImeSingleReferenceStreamin = 174, CXType_OCLIntelSubgroupAVCImeDualReferenceStreamin = 175, /* Old aliases for AVC OpenCL extension types. */ CXType_OCLIntelSubgroupAVCImeResultSingleRefStreamout = 172, CXType_OCLIntelSubgroupAVCImeResultDualRefStreamout = 173, CXType_OCLIntelSubgroupAVCImeSingleRefStreamin = 174, CXType_OCLIntelSubgroupAVCImeDualRefStreamin = 175, CXType_ExtVector = 176, CXType_Atomic = 177, CXType_BTFTagAttributed = 178 }; /** * Describes the calling convention of a function type */ enum CXCallingConv { CXCallingConv_Default = 0, CXCallingConv_C = 1, CXCallingConv_X86StdCall = 2, CXCallingConv_X86FastCall = 3, CXCallingConv_X86ThisCall = 4, CXCallingConv_X86Pascal = 5, CXCallingConv_AAPCS = 6, CXCallingConv_AAPCS_VFP = 7, CXCallingConv_X86RegCall = 8, CXCallingConv_IntelOclBicc = 9, CXCallingConv_Win64 = 10, /* Alias for compatibility with older versions of API. */ CXCallingConv_X86_64Win64 = CXCallingConv_Win64, CXCallingConv_X86_64SysV = 11, CXCallingConv_X86VectorCall = 12, CXCallingConv_Swift = 13, CXCallingConv_PreserveMost = 14, CXCallingConv_PreserveAll = 15, CXCallingConv_AArch64VectorCall = 16, CXCallingConv_SwiftAsync = 17, CXCallingConv_AArch64SVEPCS = 18, CXCallingConv_Invalid = 100, CXCallingConv_Unexposed = 200 }; /** * The type of an element in the abstract syntax tree. * */ typedef struct { enum CXTypeKind kind; void *data[2]; } CXType; /** * Retrieve the type of a CXCursor (if any). */ CINDEX_LINKAGE CXType clang_getCursorType(CXCursor C); /** * Pretty-print the underlying type using the rules of the * language of the translation unit from which it came. * * If the type is invalid, an empty string is returned. */ CINDEX_LINKAGE CXString clang_getTypeSpelling(CXType CT); /** * Retrieve the underlying type of a typedef declaration. * * If the cursor does not reference a typedef declaration, an invalid type is * returned. */ CINDEX_LINKAGE CXType clang_getTypedefDeclUnderlyingType(CXCursor C); /** * Retrieve the integer type of an enum declaration. * * If the cursor does not reference an enum declaration, an invalid type is * returned. */ CINDEX_LINKAGE CXType clang_getEnumDeclIntegerType(CXCursor C); /** * Retrieve the integer value of an enum constant declaration as a signed * long long. * * If the cursor does not reference an enum constant declaration, LLONG_MIN is * returned. Since this is also potentially a valid constant value, the kind of * the cursor must be verified before calling this function. */ CINDEX_LINKAGE long long clang_getEnumConstantDeclValue(CXCursor C); /** * Retrieve the integer value of an enum constant declaration as an unsigned * long long. * * If the cursor does not reference an enum constant declaration, ULLONG_MAX is * returned. Since this is also potentially a valid constant value, the kind of * the cursor must be verified before calling this function. */ CINDEX_LINKAGE unsigned long long clang_getEnumConstantDeclUnsignedValue(CXCursor C); /** * Returns non-zero if the cursor specifies a Record member that is a bit-field. */ CINDEX_LINKAGE unsigned clang_Cursor_isBitField(CXCursor C); /** * Retrieve the bit width of a bit-field declaration as an integer. * * If the cursor does not reference a bit-field, or if the bit-field's width * expression cannot be evaluated, -1 is returned. * * For example: * \code * if (clang_Cursor_isBitField(Cursor)) { * int Width = clang_getFieldDeclBitWidth(Cursor); * if (Width != -1) { * // The bit-field width is not value-dependent. * } * } * \endcode */ CINDEX_LINKAGE int clang_getFieldDeclBitWidth(CXCursor C); /** * Retrieve the number of non-variadic arguments associated with a given * cursor. * * The number of arguments can be determined for calls as well as for * declarations of functions or methods. For other cursors -1 is returned. */ CINDEX_LINKAGE int clang_Cursor_getNumArguments(CXCursor C); /** * Retrieve the argument cursor of a function or method. * * The argument cursor can be determined for calls as well as for declarations * of functions or methods. For other cursors and for invalid indices, an * invalid cursor is returned. */ CINDEX_LINKAGE CXCursor clang_Cursor_getArgument(CXCursor C, unsigned i); /** * Describes the kind of a template argument. * * See the definition of llvm::clang::TemplateArgument::ArgKind for full * element descriptions. */ enum CXTemplateArgumentKind { CXTemplateArgumentKind_Null, CXTemplateArgumentKind_Type, CXTemplateArgumentKind_Declaration, CXTemplateArgumentKind_NullPtr, CXTemplateArgumentKind_Integral, CXTemplateArgumentKind_Template, CXTemplateArgumentKind_TemplateExpansion, CXTemplateArgumentKind_Expression, CXTemplateArgumentKind_Pack, /* Indicates an error case, preventing the kind from being deduced. */ CXTemplateArgumentKind_Invalid }; /** * Returns the number of template args of a function, struct, or class decl * representing a template specialization. * * If the argument cursor cannot be converted into a template function * declaration, -1 is returned. * * For example, for the following declaration and specialization: * template * void foo() { ... } * * template <> * void foo(); * * The value 3 would be returned from this call. */ CINDEX_LINKAGE int clang_Cursor_getNumTemplateArguments(CXCursor C); /** * Retrieve the kind of the I'th template argument of the CXCursor C. * * If the argument CXCursor does not represent a FunctionDecl, StructDecl, or * ClassTemplatePartialSpecialization, an invalid template argument kind is * returned. * * For example, for the following declaration and specialization: * template * void foo() { ... } * * template <> * void foo(); * * For I = 0, 1, and 2, Type, Integral, and Integral will be returned, * respectively. */ CINDEX_LINKAGE enum CXTemplateArgumentKind clang_Cursor_getTemplateArgumentKind(CXCursor C, unsigned I); /** * Retrieve a CXType representing the type of a TemplateArgument of a * function decl representing a template specialization. * * If the argument CXCursor does not represent a FunctionDecl, StructDecl, * ClassDecl or ClassTemplatePartialSpecialization whose I'th template argument * has a kind of CXTemplateArgKind_Integral, an invalid type is returned. * * For example, for the following declaration and specialization: * template * void foo() { ... } * * template <> * void foo(); * * If called with I = 0, "float", will be returned. * Invalid types will be returned for I == 1 or 2. */ CINDEX_LINKAGE CXType clang_Cursor_getTemplateArgumentType(CXCursor C, unsigned I); /** * Retrieve the value of an Integral TemplateArgument (of a function * decl representing a template specialization) as a signed long long. * * It is undefined to call this function on a CXCursor that does not represent a * FunctionDecl, StructDecl, ClassDecl or ClassTemplatePartialSpecialization * whose I'th template argument is not an integral value. * * For example, for the following declaration and specialization: * template * void foo() { ... } * * template <> * void foo(); * * If called with I = 1 or 2, -7 or true will be returned, respectively. * For I == 0, this function's behavior is undefined. */ CINDEX_LINKAGE long long clang_Cursor_getTemplateArgumentValue(CXCursor C, unsigned I); /** * Retrieve the value of an Integral TemplateArgument (of a function * decl representing a template specialization) as an unsigned long long. * * It is undefined to call this function on a CXCursor that does not represent a * FunctionDecl, StructDecl, ClassDecl or ClassTemplatePartialSpecialization or * whose I'th template argument is not an integral value. * * For example, for the following declaration and specialization: * template * void foo() { ... } * * template <> * void foo(); * * If called with I = 1 or 2, 2147483649 or true will be returned, respectively. * For I == 0, this function's behavior is undefined. */ CINDEX_LINKAGE unsigned long long clang_Cursor_getTemplateArgumentUnsignedValue(CXCursor C, unsigned I); /** * Determine whether two CXTypes represent the same type. * * \returns non-zero if the CXTypes represent the same type and * zero otherwise. */ CINDEX_LINKAGE unsigned clang_equalTypes(CXType A, CXType B); /** * Return the canonical type for a CXType. * * Clang's type system explicitly models typedefs and all the ways * a specific type can be represented. The canonical type is the underlying * type with all the "sugar" removed. For example, if 'T' is a typedef * for 'int', the canonical type for 'T' would be 'int'. */ CINDEX_LINKAGE CXType clang_getCanonicalType(CXType T); /** * Determine whether a CXType has the "const" qualifier set, * without looking through typedefs that may have added "const" at a * different level. */ CINDEX_LINKAGE unsigned clang_isConstQualifiedType(CXType T); /** * Determine whether a CXCursor that is a macro, is * function like. */ CINDEX_LINKAGE unsigned clang_Cursor_isMacroFunctionLike(CXCursor C); /** * Determine whether a CXCursor that is a macro, is a * builtin one. */ CINDEX_LINKAGE unsigned clang_Cursor_isMacroBuiltin(CXCursor C); /** * Determine whether a CXCursor that is a function declaration, is an * inline declaration. */ CINDEX_LINKAGE unsigned clang_Cursor_isFunctionInlined(CXCursor C); /** * Determine whether a CXType has the "volatile" qualifier set, * without looking through typedefs that may have added "volatile" at * a different level. */ CINDEX_LINKAGE unsigned clang_isVolatileQualifiedType(CXType T); /** * Determine whether a CXType has the "restrict" qualifier set, * without looking through typedefs that may have added "restrict" at a * different level. */ CINDEX_LINKAGE unsigned clang_isRestrictQualifiedType(CXType T); /** * Returns the address space of the given type. */ CINDEX_LINKAGE unsigned clang_getAddressSpace(CXType T); /** * Returns the typedef name of the given type. */ CINDEX_LINKAGE CXString clang_getTypedefName(CXType CT); /** * For pointer types, returns the type of the pointee. */ CINDEX_LINKAGE CXType clang_getPointeeType(CXType T); /** * Retrieve the unqualified variant of the given type, removing as * little sugar as possible. * * For example, given the following series of typedefs: * * \code * typedef int Integer; * typedef const Integer CInteger; * typedef CInteger DifferenceType; * \endcode * * Executing \c clang_getUnqualifiedType() on a \c CXType that * represents \c DifferenceType, will desugar to a type representing * \c Integer, that has no qualifiers. * * And, executing \c clang_getUnqualifiedType() on the type of the * first argument of the following function declaration: * * \code * void foo(const int); * \endcode * * Will return a type representing \c int, removing the \c const * qualifier. * * Sugar over array types is not desugared. * * A type can be checked for qualifiers with \c * clang_isConstQualifiedType(), \c clang_isVolatileQualifiedType() * and \c clang_isRestrictQualifiedType(). * * A type that resulted from a call to \c clang_getUnqualifiedType * will return \c false for all of the above calls. */ CINDEX_LINKAGE CXType clang_getUnqualifiedType(CXType CT); /** * For reference types (e.g., "const int&"), returns the type that the * reference refers to (e.g "const int"). * * Otherwise, returns the type itself. * * A type that has kind \c CXType_LValueReference or * \c CXType_RValueReference is a reference type. */ CINDEX_LINKAGE CXType clang_getNonReferenceType(CXType CT); /** * Return the cursor for the declaration of the given type. */ CINDEX_LINKAGE CXCursor clang_getTypeDeclaration(CXType T); /** * Returns the Objective-C type encoding for the specified declaration. */ CINDEX_LINKAGE CXString clang_getDeclObjCTypeEncoding(CXCursor C); /** * Returns the Objective-C type encoding for the specified CXType. */ CINDEX_LINKAGE CXString clang_Type_getObjCEncoding(CXType type); /** * Retrieve the spelling of a given CXTypeKind. */ CINDEX_LINKAGE CXString clang_getTypeKindSpelling(enum CXTypeKind K); /** * Retrieve the calling convention associated with a function type. * * If a non-function type is passed in, CXCallingConv_Invalid is returned. */ CINDEX_LINKAGE enum CXCallingConv clang_getFunctionTypeCallingConv(CXType T); /** * Retrieve the return type associated with a function type. * * If a non-function type is passed in, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_getResultType(CXType T); /** * Retrieve the exception specification type associated with a function type. * This is a value of type CXCursor_ExceptionSpecificationKind. * * If a non-function type is passed in, an error code of -1 is returned. */ CINDEX_LINKAGE int clang_getExceptionSpecificationType(CXType T); /** * Retrieve the number of non-variadic parameters associated with a * function type. * * If a non-function type is passed in, -1 is returned. */ CINDEX_LINKAGE int clang_getNumArgTypes(CXType T); /** * Retrieve the type of a parameter of a function type. * * If a non-function type is passed in or the function does not have enough * parameters, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_getArgType(CXType T, unsigned i); /** * Retrieves the base type of the ObjCObjectType. * * If the type is not an ObjC object, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getObjCObjectBaseType(CXType T); /** * Retrieve the number of protocol references associated with an ObjC object/id. * * If the type is not an ObjC object, 0 is returned. */ CINDEX_LINKAGE unsigned clang_Type_getNumObjCProtocolRefs(CXType T); /** * Retrieve the decl for a protocol reference for an ObjC object/id. * * If the type is not an ObjC object or there are not enough protocol * references, an invalid cursor is returned. */ CINDEX_LINKAGE CXCursor clang_Type_getObjCProtocolDecl(CXType T, unsigned i); /** * Retrieve the number of type arguments associated with an ObjC object. * * If the type is not an ObjC object, 0 is returned. */ CINDEX_LINKAGE unsigned clang_Type_getNumObjCTypeArgs(CXType T); /** * Retrieve a type argument associated with an ObjC object. * * If the type is not an ObjC or the index is not valid, * an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getObjCTypeArg(CXType T, unsigned i); /** * Return 1 if the CXType is a variadic function type, and 0 otherwise. */ CINDEX_LINKAGE unsigned clang_isFunctionTypeVariadic(CXType T); /** * Retrieve the return type associated with a given cursor. * * This only returns a valid type if the cursor refers to a function or method. */ CINDEX_LINKAGE CXType clang_getCursorResultType(CXCursor C); /** * Retrieve the exception specification type associated with a given cursor. * This is a value of type CXCursor_ExceptionSpecificationKind. * * This only returns a valid result if the cursor refers to a function or * method. */ CINDEX_LINKAGE int clang_getCursorExceptionSpecificationType(CXCursor C); /** * Return 1 if the CXType is a POD (plain old data) type, and 0 * otherwise. */ CINDEX_LINKAGE unsigned clang_isPODType(CXType T); /** * Return the element type of an array, complex, or vector type. * * If a type is passed in that is not an array, complex, or vector type, * an invalid type is returned. */ CINDEX_LINKAGE CXType clang_getElementType(CXType T); /** * Return the number of elements of an array or vector type. * * If a type is passed in that is not an array or vector type, * -1 is returned. */ CINDEX_LINKAGE long long clang_getNumElements(CXType T); /** * Return the element type of an array type. * * If a non-array type is passed in, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_getArrayElementType(CXType T); /** * Return the array size of a constant array. * * If a non-array type is passed in, -1 is returned. */ CINDEX_LINKAGE long long clang_getArraySize(CXType T); /** * Retrieve the type named by the qualified-id. * * If a non-elaborated type is passed in, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getNamedType(CXType T); /** * Determine if a typedef is 'transparent' tag. * * A typedef is considered 'transparent' if it shares a name and spelling * location with its underlying tag type, as is the case with the NS_ENUM macro. * * \returns non-zero if transparent and zero otherwise. */ CINDEX_LINKAGE unsigned clang_Type_isTransparentTagTypedef(CXType T); enum CXTypeNullabilityKind { /** * Values of this type can never be null. */ CXTypeNullability_NonNull = 0, /** * Values of this type can be null. */ CXTypeNullability_Nullable = 1, /** * Whether values of this type can be null is (explicitly) * unspecified. This captures a (fairly rare) case where we * can't conclude anything about the nullability of the type even * though it has been considered. */ CXTypeNullability_Unspecified = 2, /** * Nullability is not applicable to this type. */ CXTypeNullability_Invalid = 3, /** * Generally behaves like Nullable, except when used in a block parameter that * was imported into a swift async method. There, swift will assume that the * parameter can get null even if no error occurred. _Nullable parameters are * assumed to only get null on error. */ CXTypeNullability_NullableResult = 4 }; /** * Retrieve the nullability kind of a pointer type. */ CINDEX_LINKAGE enum CXTypeNullabilityKind clang_Type_getNullability(CXType T); /** * List the possible error codes for \c clang_Type_getSizeOf, * \c clang_Type_getAlignOf, \c clang_Type_getOffsetOf and * \c clang_Cursor_getOffsetOf. * * A value of this enumeration type can be returned if the target type is not * a valid argument to sizeof, alignof or offsetof. */ enum CXTypeLayoutError { /** * Type is of kind CXType_Invalid. */ CXTypeLayoutError_Invalid = -1, /** * The type is an incomplete Type. */ CXTypeLayoutError_Incomplete = -2, /** * The type is a dependent Type. */ CXTypeLayoutError_Dependent = -3, /** * The type is not a constant size type. */ CXTypeLayoutError_NotConstantSize = -4, /** * The Field name is not valid for this record. */ CXTypeLayoutError_InvalidFieldName = -5, /** * The type is undeduced. */ CXTypeLayoutError_Undeduced = -6 }; /** * Return the alignment of a type in bytes as per C++[expr.alignof] * standard. * * If the type declaration is invalid, CXTypeLayoutError_Invalid is returned. * If the type declaration is an incomplete type, CXTypeLayoutError_Incomplete * is returned. * If the type declaration is a dependent type, CXTypeLayoutError_Dependent is * returned. * If the type declaration is not a constant size type, * CXTypeLayoutError_NotConstantSize is returned. */ CINDEX_LINKAGE long long clang_Type_getAlignOf(CXType T); /** * Return the class type of an member pointer type. * * If a non-member-pointer type is passed in, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getClassType(CXType T); /** * Return the size of a type in bytes as per C++[expr.sizeof] standard. * * If the type declaration is invalid, CXTypeLayoutError_Invalid is returned. * If the type declaration is an incomplete type, CXTypeLayoutError_Incomplete * is returned. * If the type declaration is a dependent type, CXTypeLayoutError_Dependent is * returned. */ CINDEX_LINKAGE long long clang_Type_getSizeOf(CXType T); /** * Return the offset of a field named S in a record of type T in bits * as it would be returned by __offsetof__ as per C++11[18.2p4] * * If the cursor is not a record field declaration, CXTypeLayoutError_Invalid * is returned. * If the field's type declaration is an incomplete type, * CXTypeLayoutError_Incomplete is returned. * If the field's type declaration is a dependent type, * CXTypeLayoutError_Dependent is returned. * If the field's name S is not found, * CXTypeLayoutError_InvalidFieldName is returned. */ CINDEX_LINKAGE long long clang_Type_getOffsetOf(CXType T, const char *S); /** * Return the type that was modified by this attributed type. * * If the type is not an attributed type, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getModifiedType(CXType T); /** * Gets the type contained by this atomic type. * * If a non-atomic type is passed in, an invalid type is returned. */ CINDEX_LINKAGE CXType clang_Type_getValueType(CXType CT); /** * Return the offset of the field represented by the Cursor. * * If the cursor is not a field declaration, -1 is returned. * If the cursor semantic parent is not a record field declaration, * CXTypeLayoutError_Invalid is returned. * If the field's type declaration is an incomplete type, * CXTypeLayoutError_Incomplete is returned. * If the field's type declaration is a dependent type, * CXTypeLayoutError_Dependent is returned. * If the field's name S is not found, * CXTypeLayoutError_InvalidFieldName is returned. */ CINDEX_LINKAGE long long clang_Cursor_getOffsetOfField(CXCursor C); /** * Determine whether the given cursor represents an anonymous * tag or namespace */ CINDEX_LINKAGE unsigned clang_Cursor_isAnonymous(CXCursor C); /** * Determine whether the given cursor represents an anonymous record * declaration. */ CINDEX_LINKAGE unsigned clang_Cursor_isAnonymousRecordDecl(CXCursor C); /** * Determine whether the given cursor represents an inline namespace * declaration. */ CINDEX_LINKAGE unsigned clang_Cursor_isInlineNamespace(CXCursor C); enum CXRefQualifierKind { /** No ref-qualifier was provided. */ CXRefQualifier_None = 0, /** An lvalue ref-qualifier was provided (\c &). */ CXRefQualifier_LValue, /** An rvalue ref-qualifier was provided (\c &&). */ CXRefQualifier_RValue }; /** * Returns the number of template arguments for given template * specialization, or -1 if type \c T is not a template specialization. */ CINDEX_LINKAGE int clang_Type_getNumTemplateArguments(CXType T); /** * Returns the type template argument of a template class specialization * at given index. * * This function only returns template type arguments and does not handle * template template arguments or variadic packs. */ CINDEX_LINKAGE CXType clang_Type_getTemplateArgumentAsType(CXType T, unsigned i); /** * Retrieve the ref-qualifier kind of a function or method. * * The ref-qualifier is returned for C++ functions or methods. For other types * or non-C++ declarations, CXRefQualifier_None is returned. */ CINDEX_LINKAGE enum CXRefQualifierKind clang_Type_getCXXRefQualifier(CXType T); /** * Returns 1 if the base class specified by the cursor with kind * CX_CXXBaseSpecifier is virtual. */ CINDEX_LINKAGE unsigned clang_isVirtualBase(CXCursor); /** * Represents the C++ access control level to a base class for a * cursor with kind CX_CXXBaseSpecifier. */ enum CX_CXXAccessSpecifier { CX_CXXInvalidAccessSpecifier, CX_CXXPublic, CX_CXXProtected, CX_CXXPrivate }; /** * Returns the access control level for the referenced object. * * If the cursor refers to a C++ declaration, its access control level within * its parent scope is returned. Otherwise, if the cursor refers to a base * specifier or access specifier, the specifier itself is returned. */ CINDEX_LINKAGE enum CX_CXXAccessSpecifier clang_getCXXAccessSpecifier(CXCursor); /** * Represents the storage classes as declared in the source. CX_SC_Invalid * was added for the case that the passed cursor in not a declaration. */ enum CX_StorageClass { CX_SC_Invalid, CX_SC_None, CX_SC_Extern, CX_SC_Static, CX_SC_PrivateExtern, CX_SC_OpenCLWorkGroupLocal, CX_SC_Auto, CX_SC_Register }; /** * Returns the storage class for a function or variable declaration. * * If the passed in Cursor is not a function or variable declaration, * CX_SC_Invalid is returned else the storage class. */ CINDEX_LINKAGE enum CX_StorageClass clang_Cursor_getStorageClass(CXCursor); /** * Determine the number of overloaded declarations referenced by a * \c CXCursor_OverloadedDeclRef cursor. * * \param cursor The cursor whose overloaded declarations are being queried. * * \returns The number of overloaded declarations referenced by \c cursor. If it * is not a \c CXCursor_OverloadedDeclRef cursor, returns 0. */ CINDEX_LINKAGE unsigned clang_getNumOverloadedDecls(CXCursor cursor); /** * Retrieve a cursor for one of the overloaded declarations referenced * by a \c CXCursor_OverloadedDeclRef cursor. * * \param cursor The cursor whose overloaded declarations are being queried. * * \param index The zero-based index into the set of overloaded declarations in * the cursor. * * \returns A cursor representing the declaration referenced by the given * \c cursor at the specified \c index. If the cursor does not have an * associated set of overloaded declarations, or if the index is out of bounds, * returns \c clang_getNullCursor(); */ CINDEX_LINKAGE CXCursor clang_getOverloadedDecl(CXCursor cursor, unsigned index); /** * @} */ /** * \defgroup CINDEX_ATTRIBUTES Information for attributes * * @{ */ /** * For cursors representing an iboutletcollection attribute, * this function returns the collection element type. * */ CINDEX_LINKAGE CXType clang_getIBOutletCollectionType(CXCursor); /** * @} */ /** * \defgroup CINDEX_CURSOR_TRAVERSAL Traversing the AST with cursors * * These routines provide the ability to traverse the abstract syntax tree * using cursors. * * @{ */ /** * Describes how the traversal of the children of a particular * cursor should proceed after visiting a particular child cursor. * * A value of this enumeration type should be returned by each * \c CXCursorVisitor to indicate how clang_visitChildren() proceed. */ enum CXChildVisitResult { /** * Terminates the cursor traversal. */ CXChildVisit_Break, /** * Continues the cursor traversal with the next sibling of * the cursor just visited, without visiting its children. */ CXChildVisit_Continue, /** * Recursively traverse the children of this cursor, using * the same visitor and client data. */ CXChildVisit_Recurse }; /** * Visitor invoked for each cursor found by a traversal. * * This visitor function will be invoked for each cursor found by * clang_visitCursorChildren(). Its first argument is the cursor being * visited, its second argument is the parent visitor for that cursor, * and its third argument is the client data provided to * clang_visitCursorChildren(). * * The visitor should return one of the \c CXChildVisitResult values * to direct clang_visitCursorChildren(). */ typedef enum CXChildVisitResult (*CXCursorVisitor)(CXCursor cursor, CXCursor parent, CXClientData client_data); /** * Visit the children of a particular cursor. * * This function visits all the direct children of the given cursor, * invoking the given \p visitor function with the cursors of each * visited child. The traversal may be recursive, if the visitor returns * \c CXChildVisit_Recurse. The traversal may also be ended prematurely, if * the visitor returns \c CXChildVisit_Break. * * \param parent the cursor whose child may be visited. All kinds of * cursors can be visited, including invalid cursors (which, by * definition, have no children). * * \param visitor the visitor function that will be invoked for each * child of \p parent. * * \param client_data pointer data supplied by the client, which will * be passed to the visitor each time it is invoked. * * \returns a non-zero value if the traversal was terminated * prematurely by the visitor returning \c CXChildVisit_Break. */ CINDEX_LINKAGE unsigned clang_visitChildren(CXCursor parent, CXCursorVisitor visitor, CXClientData client_data); /** * Visitor invoked for each cursor found by a traversal. * * This visitor block will be invoked for each cursor found by * clang_visitChildrenWithBlock(). Its first argument is the cursor being * visited, its second argument is the parent visitor for that cursor. * * The visitor should return one of the \c CXChildVisitResult values * to direct clang_visitChildrenWithBlock(). */ #if __has_feature(blocks) typedef enum CXChildVisitResult (^CXCursorVisitorBlock)(CXCursor cursor, CXCursor parent); #else typedef struct _CXChildVisitResult *CXCursorVisitorBlock; #endif /** * Visits the children of a cursor using the specified block. Behaves * identically to clang_visitChildren() in all other respects. */ CINDEX_LINKAGE unsigned clang_visitChildrenWithBlock(CXCursor parent, CXCursorVisitorBlock block); /** * @} */ /** * \defgroup CINDEX_CURSOR_XREF Cross-referencing in the AST * * These routines provide the ability to determine references within and * across translation units, by providing the names of the entities referenced * by cursors, follow reference cursors to the declarations they reference, * and associate declarations with their definitions. * * @{ */ /** * Retrieve a Unified Symbol Resolution (USR) for the entity referenced * by the given cursor. * * A Unified Symbol Resolution (USR) is a string that identifies a particular * entity (function, class, variable, etc.) within a program. USRs can be * compared across translation units to determine, e.g., when references in * one translation refer to an entity defined in another translation unit. */ CINDEX_LINKAGE CXString clang_getCursorUSR(CXCursor); /** * Construct a USR for a specified Objective-C class. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCClass(const char *class_name); /** * Construct a USR for a specified Objective-C category. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCCategory( const char *class_name, const char *category_name); /** * Construct a USR for a specified Objective-C protocol. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCProtocol(const char *protocol_name); /** * Construct a USR for a specified Objective-C instance variable and * the USR for its containing class. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCIvar(const char *name, CXString classUSR); /** * Construct a USR for a specified Objective-C method and * the USR for its containing class. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCMethod(const char *name, unsigned isInstanceMethod, CXString classUSR); /** * Construct a USR for a specified Objective-C property and the USR * for its containing class. */ CINDEX_LINKAGE CXString clang_constructUSR_ObjCProperty(const char *property, CXString classUSR); /** * Retrieve a name for the entity referenced by this cursor. */ CINDEX_LINKAGE CXString clang_getCursorSpelling(CXCursor); /** * Retrieve a range for a piece that forms the cursors spelling name. * Most of the times there is only one range for the complete spelling but for * Objective-C methods and Objective-C message expressions, there are multiple * pieces for each selector identifier. * * \param pieceIndex the index of the spelling name piece. If this is greater * than the actual number of pieces, it will return a NULL (invalid) range. * * \param options Reserved. */ CINDEX_LINKAGE CXSourceRange clang_Cursor_getSpellingNameRange( CXCursor, unsigned pieceIndex, unsigned options); /** * Opaque pointer representing a policy that controls pretty printing * for \c clang_getCursorPrettyPrinted. */ typedef void *CXPrintingPolicy; /** * Properties for the printing policy. * * See \c clang::PrintingPolicy for more information. */ enum CXPrintingPolicyProperty { CXPrintingPolicy_Indentation, CXPrintingPolicy_SuppressSpecifiers, CXPrintingPolicy_SuppressTagKeyword, CXPrintingPolicy_IncludeTagDefinition, CXPrintingPolicy_SuppressScope, CXPrintingPolicy_SuppressUnwrittenScope, CXPrintingPolicy_SuppressInitializers, CXPrintingPolicy_ConstantArraySizeAsWritten, CXPrintingPolicy_AnonymousTagLocations, CXPrintingPolicy_SuppressStrongLifetime, CXPrintingPolicy_SuppressLifetimeQualifiers, CXPrintingPolicy_SuppressTemplateArgsInCXXConstructors, CXPrintingPolicy_Bool, CXPrintingPolicy_Restrict, CXPrintingPolicy_Alignof, CXPrintingPolicy_UnderscoreAlignof, CXPrintingPolicy_UseVoidForZeroParams, CXPrintingPolicy_TerseOutput, CXPrintingPolicy_PolishForDeclaration, CXPrintingPolicy_Half, CXPrintingPolicy_MSWChar, CXPrintingPolicy_IncludeNewlines, CXPrintingPolicy_MSVCFormatting, CXPrintingPolicy_ConstantsAsWritten, CXPrintingPolicy_SuppressImplicitBase, CXPrintingPolicy_FullyQualifiedName, CXPrintingPolicy_LastProperty = CXPrintingPolicy_FullyQualifiedName }; /** * Get a property value for the given printing policy. */ CINDEX_LINKAGE unsigned clang_PrintingPolicy_getProperty(CXPrintingPolicy Policy, enum CXPrintingPolicyProperty Property); /** * Set a property value for the given printing policy. */ CINDEX_LINKAGE void clang_PrintingPolicy_setProperty(CXPrintingPolicy Policy, enum CXPrintingPolicyProperty Property, unsigned Value); /** * Retrieve the default policy for the cursor. * * The policy should be released after use with \c * clang_PrintingPolicy_dispose. */ CINDEX_LINKAGE CXPrintingPolicy clang_getCursorPrintingPolicy(CXCursor); /** * Release a printing policy. */ CINDEX_LINKAGE void clang_PrintingPolicy_dispose(CXPrintingPolicy Policy); /** * Pretty print declarations. * * \param Cursor The cursor representing a declaration. * * \param Policy The policy to control the entities being printed. If * NULL, a default policy is used. * * \returns The pretty printed declaration or the empty string for * other cursors. */ CINDEX_LINKAGE CXString clang_getCursorPrettyPrinted(CXCursor Cursor, CXPrintingPolicy Policy); /** * Retrieve the display name for the entity referenced by this cursor. * * The display name contains extra information that helps identify the cursor, * such as the parameters of a function or template or the arguments of a * class template specialization. */ CINDEX_LINKAGE CXString clang_getCursorDisplayName(CXCursor); /** For a cursor that is a reference, retrieve a cursor representing the * entity that it references. * * Reference cursors refer to other entities in the AST. For example, an * Objective-C superclass reference cursor refers to an Objective-C class. * This function produces the cursor for the Objective-C class from the * cursor for the superclass reference. If the input cursor is a declaration or * definition, it returns that declaration or definition unchanged. * Otherwise, returns the NULL cursor. */ CINDEX_LINKAGE CXCursor clang_getCursorReferenced(CXCursor); /** * For a cursor that is either a reference to or a declaration * of some entity, retrieve a cursor that describes the definition of * that entity. * * Some entities can be declared multiple times within a translation * unit, but only one of those declarations can also be a * definition. For example, given: * * \code * int f(int, int); * int g(int x, int y) { return f(x, y); } * int f(int a, int b) { return a + b; } * int f(int, int); * \endcode * * there are three declarations of the function "f", but only the * second one is a definition. The clang_getCursorDefinition() * function will take any cursor pointing to a declaration of "f" * (the first or fourth lines of the example) or a cursor referenced * that uses "f" (the call to "f' inside "g") and will return a * declaration cursor pointing to the definition (the second "f" * declaration). * * If given a cursor for which there is no corresponding definition, * e.g., because there is no definition of that entity within this * translation unit, returns a NULL cursor. */ CINDEX_LINKAGE CXCursor clang_getCursorDefinition(CXCursor); /** * Determine whether the declaration pointed to by this cursor * is also a definition of that entity. */ CINDEX_LINKAGE unsigned clang_isCursorDefinition(CXCursor); /** * Retrieve the canonical cursor corresponding to the given cursor. * * In the C family of languages, many kinds of entities can be declared several * times within a single translation unit. For example, a structure type can * be forward-declared (possibly multiple times) and later defined: * * \code * struct X; * struct X; * struct X { * int member; * }; * \endcode * * The declarations and the definition of \c X are represented by three * different cursors, all of which are declarations of the same underlying * entity. One of these cursor is considered the "canonical" cursor, which * is effectively the representative for the underlying entity. One can * determine if two cursors are declarations of the same underlying entity by * comparing their canonical cursors. * * \returns The canonical cursor for the entity referred to by the given cursor. */ CINDEX_LINKAGE CXCursor clang_getCanonicalCursor(CXCursor); /** * If the cursor points to a selector identifier in an Objective-C * method or message expression, this returns the selector index. * * After getting a cursor with #clang_getCursor, this can be called to * determine if the location points to a selector identifier. * * \returns The selector index if the cursor is an Objective-C method or message * expression and the cursor is pointing to a selector identifier, or -1 * otherwise. */ CINDEX_LINKAGE int clang_Cursor_getObjCSelectorIndex(CXCursor); /** * Given a cursor pointing to a C++ method call or an Objective-C * message, returns non-zero if the method/message is "dynamic", meaning: * * For a C++ method: the call is virtual. * For an Objective-C message: the receiver is an object instance, not 'super' * or a specific class. * * If the method/message is "static" or the cursor does not point to a * method/message, it will return zero. */ CINDEX_LINKAGE int clang_Cursor_isDynamicCall(CXCursor C); /** * Given a cursor pointing to an Objective-C message or property * reference, or C++ method call, returns the CXType of the receiver. */ CINDEX_LINKAGE CXType clang_Cursor_getReceiverType(CXCursor C); /** * Property attributes for a \c CXCursor_ObjCPropertyDecl. */ typedef enum { CXObjCPropertyAttr_noattr = 0x00, CXObjCPropertyAttr_readonly = 0x01, CXObjCPropertyAttr_getter = 0x02, CXObjCPropertyAttr_assign = 0x04, CXObjCPropertyAttr_readwrite = 0x08, CXObjCPropertyAttr_retain = 0x10, CXObjCPropertyAttr_copy = 0x20, CXObjCPropertyAttr_nonatomic = 0x40, CXObjCPropertyAttr_setter = 0x80, CXObjCPropertyAttr_atomic = 0x100, CXObjCPropertyAttr_weak = 0x200, CXObjCPropertyAttr_strong = 0x400, CXObjCPropertyAttr_unsafe_unretained = 0x800, CXObjCPropertyAttr_class = 0x1000 } CXObjCPropertyAttrKind; /** * Given a cursor that represents a property declaration, return the * associated property attributes. The bits are formed from * \c CXObjCPropertyAttrKind. * * \param reserved Reserved for future use, pass 0. */ CINDEX_LINKAGE unsigned clang_Cursor_getObjCPropertyAttributes(CXCursor C, unsigned reserved); /** * Given a cursor that represents a property declaration, return the * name of the method that implements the getter. */ CINDEX_LINKAGE CXString clang_Cursor_getObjCPropertyGetterName(CXCursor C); /** * Given a cursor that represents a property declaration, return the * name of the method that implements the setter, if any. */ CINDEX_LINKAGE CXString clang_Cursor_getObjCPropertySetterName(CXCursor C); /** * 'Qualifiers' written next to the return and parameter types in * Objective-C method declarations. */ typedef enum { CXObjCDeclQualifier_None = 0x0, CXObjCDeclQualifier_In = 0x1, CXObjCDeclQualifier_Inout = 0x2, CXObjCDeclQualifier_Out = 0x4, CXObjCDeclQualifier_Bycopy = 0x8, CXObjCDeclQualifier_Byref = 0x10, CXObjCDeclQualifier_Oneway = 0x20 } CXObjCDeclQualifierKind; /** * Given a cursor that represents an Objective-C method or parameter * declaration, return the associated Objective-C qualifiers for the return * type or the parameter respectively. The bits are formed from * CXObjCDeclQualifierKind. */ CINDEX_LINKAGE unsigned clang_Cursor_getObjCDeclQualifiers(CXCursor C); /** * Given a cursor that represents an Objective-C method or property * declaration, return non-zero if the declaration was affected by "\@optional". * Returns zero if the cursor is not such a declaration or it is "\@required". */ CINDEX_LINKAGE unsigned clang_Cursor_isObjCOptional(CXCursor C); /** * Returns non-zero if the given cursor is a variadic function or method. */ CINDEX_LINKAGE unsigned clang_Cursor_isVariadic(CXCursor C); /** * Returns non-zero if the given cursor points to a symbol marked with * external_source_symbol attribute. * * \param language If non-NULL, and the attribute is present, will be set to * the 'language' string from the attribute. * * \param definedIn If non-NULL, and the attribute is present, will be set to * the 'definedIn' string from the attribute. * * \param isGenerated If non-NULL, and the attribute is present, will be set to * non-zero if the 'generated_declaration' is set in the attribute. */ CINDEX_LINKAGE unsigned clang_Cursor_isExternalSymbol(CXCursor C, CXString *language, CXString *definedIn, unsigned *isGenerated); /** * Given a cursor that represents a declaration, return the associated * comment's source range. The range may include multiple consecutive comments * with whitespace in between. */ CINDEX_LINKAGE CXSourceRange clang_Cursor_getCommentRange(CXCursor C); /** * Given a cursor that represents a declaration, return the associated * comment text, including comment markers. */ CINDEX_LINKAGE CXString clang_Cursor_getRawCommentText(CXCursor C); /** * Given a cursor that represents a documentable entity (e.g., * declaration), return the associated \paragraph; otherwise return the * first paragraph. */ CINDEX_LINKAGE CXString clang_Cursor_getBriefCommentText(CXCursor C); /** * @} */ /** \defgroup CINDEX_MANGLE Name Mangling API Functions * * @{ */ /** * Retrieve the CXString representing the mangled name of the cursor. */ CINDEX_LINKAGE CXString clang_Cursor_getMangling(CXCursor); /** * Retrieve the CXStrings representing the mangled symbols of the C++ * constructor or destructor at the cursor. */ CINDEX_LINKAGE CXStringSet *clang_Cursor_getCXXManglings(CXCursor); /** * Retrieve the CXStrings representing the mangled symbols of the ObjC * class interface or implementation at the cursor. */ CINDEX_LINKAGE CXStringSet *clang_Cursor_getObjCManglings(CXCursor); /** * @} */ /** * \defgroup CINDEX_MODULE Module introspection * * The functions in this group provide access to information about modules. * * @{ */ typedef void *CXModule; /** * Given a CXCursor_ModuleImportDecl cursor, return the associated module. */ CINDEX_LINKAGE CXModule clang_Cursor_getModule(CXCursor C); /** * Given a CXFile header file, return the module that contains it, if one * exists. */ CINDEX_LINKAGE CXModule clang_getModuleForFile(CXTranslationUnit, CXFile); /** * \param Module a module object. * * \returns the module file where the provided module object came from. */ CINDEX_LINKAGE CXFile clang_Module_getASTFile(CXModule Module); /** * \param Module a module object. * * \returns the parent of a sub-module or NULL if the given module is top-level, * e.g. for 'std.vector' it will return the 'std' module. */ CINDEX_LINKAGE CXModule clang_Module_getParent(CXModule Module); /** * \param Module a module object. * * \returns the name of the module, e.g. for the 'std.vector' sub-module it * will return "vector". */ CINDEX_LINKAGE CXString clang_Module_getName(CXModule Module); /** * \param Module a module object. * * \returns the full name of the module, e.g. "std.vector". */ CINDEX_LINKAGE CXString clang_Module_getFullName(CXModule Module); /** * \param Module a module object. * * \returns non-zero if the module is a system one. */ CINDEX_LINKAGE int clang_Module_isSystem(CXModule Module); /** * \param Module a module object. * * \returns the number of top level headers associated with this module. */ CINDEX_LINKAGE unsigned clang_Module_getNumTopLevelHeaders(CXTranslationUnit, CXModule Module); /** * \param Module a module object. * * \param Index top level header index (zero-based). * * \returns the specified top level header associated with the module. */ CINDEX_LINKAGE CXFile clang_Module_getTopLevelHeader(CXTranslationUnit, CXModule Module, unsigned Index); /** * @} */ /** * \defgroup CINDEX_CPP C++ AST introspection * * The routines in this group provide access information in the ASTs specific * to C++ language features. * * @{ */ /** * Determine if a C++ constructor is a converting constructor. */ CINDEX_LINKAGE unsigned clang_CXXConstructor_isConvertingConstructor(CXCursor C); /** * Determine if a C++ constructor is a copy constructor. */ CINDEX_LINKAGE unsigned clang_CXXConstructor_isCopyConstructor(CXCursor C); /** * Determine if a C++ constructor is the default constructor. */ CINDEX_LINKAGE unsigned clang_CXXConstructor_isDefaultConstructor(CXCursor C); /** * Determine if a C++ constructor is a move constructor. */ CINDEX_LINKAGE unsigned clang_CXXConstructor_isMoveConstructor(CXCursor C); /** * Determine if a C++ field is declared 'mutable'. */ CINDEX_LINKAGE unsigned clang_CXXField_isMutable(CXCursor C); /** * Determine if a C++ method is declared '= default'. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isDefaulted(CXCursor C); /** * Determine if a C++ method is declared '= delete'. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isDeleted(CXCursor C); /** * Determine if a C++ member function or member function template is * pure virtual. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isPureVirtual(CXCursor C); /** * Determine if a C++ member function or member function template is * declared 'static'. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isStatic(CXCursor C); /** * Determine if a C++ member function or member function template is * explicitly declared 'virtual' or if it overrides a virtual method from * one of the base classes. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isVirtual(CXCursor C); /** * Determine if a C++ member function is a copy-assignment operator, * returning 1 if such is the case and 0 otherwise. * * > A copy-assignment operator `X::operator=` is a non-static, * > non-template member function of _class_ `X` with exactly one * > parameter of type `X`, `X&`, `const X&`, `volatile X&` or `const * > volatile X&`. * * That is, for example, the `operator=` in: * * class Foo { * bool operator=(const volatile Foo&); * }; * * Is a copy-assignment operator, while the `operator=` in: * * class Bar { * bool operator=(const int&); * }; * * Is not. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isCopyAssignmentOperator(CXCursor C); /** * Determine if a C++ member function is a move-assignment operator, * returning 1 if such is the case and 0 otherwise. * * > A move-assignment operator `X::operator=` is a non-static, * > non-template member function of _class_ `X` with exactly one * > parameter of type `X&&`, `const X&&`, `volatile X&&` or `const * > volatile X&&`. * * That is, for example, the `operator=` in: * * class Foo { * bool operator=(const volatile Foo&&); * }; * * Is a move-assignment operator, while the `operator=` in: * * class Bar { * bool operator=(const int&&); * }; * * Is not. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isMoveAssignmentOperator(CXCursor C); /** * Determines if a C++ constructor or conversion function was declared * explicit, returning 1 if such is the case and 0 otherwise. * * Constructors or conversion functions are declared explicit through * the use of the explicit specifier. * * For example, the following constructor and conversion function are * not explicit as they lack the explicit specifier: * * class Foo { * Foo(); * operator int(); * }; * * While the following constructor and conversion function are * explicit as they are declared with the explicit specifier. * * class Foo { * explicit Foo(); * explicit operator int(); * }; * * This function will return 0 when given a cursor pointing to one of * the former declarations and it will return 1 for a cursor pointing * to the latter declarations. * * The explicit specifier allows the user to specify a * conditional compile-time expression whose value decides * whether the marked element is explicit or not. * * For example: * * constexpr bool foo(int i) { return i % 2 == 0; } * * class Foo { * explicit(foo(1)) Foo(); * explicit(foo(2)) operator int(); * } * * This function will return 0 for the constructor and 1 for * the conversion function. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isExplicit(CXCursor C); /** * Determine if a C++ record is abstract, i.e. whether a class or struct * has a pure virtual member function. */ CINDEX_LINKAGE unsigned clang_CXXRecord_isAbstract(CXCursor C); /** * Determine if an enum declaration refers to a scoped enum. */ CINDEX_LINKAGE unsigned clang_EnumDecl_isScoped(CXCursor C); /** * Determine if a C++ member function or member function template is * declared 'const'. */ CINDEX_LINKAGE unsigned clang_CXXMethod_isConst(CXCursor C); /** * Given a cursor that represents a template, determine * the cursor kind of the specializations would be generated by instantiating * the template. * * This routine can be used to determine what flavor of function template, * class template, or class template partial specialization is stored in the * cursor. For example, it can describe whether a class template cursor is * declared with "struct", "class" or "union". * * \param C The cursor to query. This cursor should represent a template * declaration. * * \returns The cursor kind of the specializations that would be generated * by instantiating the template \p C. If \p C is not a template, returns * \c CXCursor_NoDeclFound. */ CINDEX_LINKAGE enum CXCursorKind clang_getTemplateCursorKind(CXCursor C); /** * Given a cursor that may represent a specialization or instantiation * of a template, retrieve the cursor that represents the template that it * specializes or from which it was instantiated. * * This routine determines the template involved both for explicit * specializations of templates and for implicit instantiations of the template, * both of which are referred to as "specializations". For a class template * specialization (e.g., \c std::vector), this routine will return * either the primary template (\c std::vector) or, if the specialization was * instantiated from a class template partial specialization, the class template * partial specialization. For a class template partial specialization and a * function template specialization (including instantiations), this * this routine will return the specialized template. * * For members of a class template (e.g., member functions, member classes, or * static data members), returns the specialized or instantiated member. * Although not strictly "templates" in the C++ language, members of class * templates have the same notions of specializations and instantiations that * templates do, so this routine treats them similarly. * * \param C A cursor that may be a specialization of a template or a member * of a template. * * \returns If the given cursor is a specialization or instantiation of a * template or a member thereof, the template or member that it specializes or * from which it was instantiated. Otherwise, returns a NULL cursor. */ CINDEX_LINKAGE CXCursor clang_getSpecializedCursorTemplate(CXCursor C); /** * Given a cursor that references something else, return the source range * covering that reference. * * \param C A cursor pointing to a member reference, a declaration reference, or * an operator call. * \param NameFlags A bitset with three independent flags: * CXNameRange_WantQualifier, CXNameRange_WantTemplateArgs, and * CXNameRange_WantSinglePiece. * \param PieceIndex For contiguous names or when passing the flag * CXNameRange_WantSinglePiece, only one piece with index 0 is * available. When the CXNameRange_WantSinglePiece flag is not passed for a * non-contiguous names, this index can be used to retrieve the individual * pieces of the name. See also CXNameRange_WantSinglePiece. * * \returns The piece of the name pointed to by the given cursor. If there is no * name, or if the PieceIndex is out-of-range, a null-cursor will be returned. */ CINDEX_LINKAGE CXSourceRange clang_getCursorReferenceNameRange( CXCursor C, unsigned NameFlags, unsigned PieceIndex); enum CXNameRefFlags { /** * Include the nested-name-specifier, e.g. Foo:: in x.Foo::y, in the * range. */ CXNameRange_WantQualifier = 0x1, /** * Include the explicit template arguments, e.g. \ in x.f, * in the range. */ CXNameRange_WantTemplateArgs = 0x2, /** * If the name is non-contiguous, return the full spanning range. * * Non-contiguous names occur in Objective-C when a selector with two or more * parameters is used, or in C++ when using an operator: * \code * [object doSomething:here withValue:there]; // Objective-C * return some_vector[1]; // C++ * \endcode */ CXNameRange_WantSinglePiece = 0x4 }; /** * @} */ /** * \defgroup CINDEX_LEX Token extraction and manipulation * * The routines in this group provide access to the tokens within a * translation unit, along with a semantic mapping of those tokens to * their corresponding cursors. * * @{ */ /** * Describes a kind of token. */ typedef enum CXTokenKind { /** * A token that contains some kind of punctuation. */ CXToken_Punctuation, /** * A language keyword. */ CXToken_Keyword, /** * An identifier (that is not a keyword). */ CXToken_Identifier, /** * A numeric, string, or character literal. */ CXToken_Literal, /** * A comment. */ CXToken_Comment } CXTokenKind; /** * Describes a single preprocessing token. */ typedef struct { unsigned int_data[4]; void *ptr_data; } CXToken; /** * Get the raw lexical token starting with the given location. * * \param TU the translation unit whose text is being tokenized. * * \param Location the source location with which the token starts. * * \returns The token starting with the given location or NULL if no such token * exist. The returned pointer must be freed with clang_disposeTokens before the * translation unit is destroyed. */ CINDEX_LINKAGE CXToken *clang_getToken(CXTranslationUnit TU, CXSourceLocation Location); /** * Determine the kind of the given token. */ CINDEX_LINKAGE CXTokenKind clang_getTokenKind(CXToken); /** * Determine the spelling of the given token. * * The spelling of a token is the textual representation of that token, e.g., * the text of an identifier or keyword. */ CINDEX_LINKAGE CXString clang_getTokenSpelling(CXTranslationUnit, CXToken); /** * Retrieve the source location of the given token. */ CINDEX_LINKAGE CXSourceLocation clang_getTokenLocation(CXTranslationUnit, CXToken); /** * Retrieve a source range that covers the given token. */ CINDEX_LINKAGE CXSourceRange clang_getTokenExtent(CXTranslationUnit, CXToken); /** * Tokenize the source code described by the given range into raw * lexical tokens. * * \param TU the translation unit whose text is being tokenized. * * \param Range the source range in which text should be tokenized. All of the * tokens produced by tokenization will fall within this source range, * * \param Tokens this pointer will be set to point to the array of tokens * that occur within the given source range. The returned pointer must be * freed with clang_disposeTokens() before the translation unit is destroyed. * * \param NumTokens will be set to the number of tokens in the \c *Tokens * array. * */ CINDEX_LINKAGE void clang_tokenize(CXTranslationUnit TU, CXSourceRange Range, CXToken **Tokens, unsigned *NumTokens); /** * Annotate the given set of tokens by providing cursors for each token * that can be mapped to a specific entity within the abstract syntax tree. * * This token-annotation routine is equivalent to invoking * clang_getCursor() for the source locations of each of the * tokens. The cursors provided are filtered, so that only those * cursors that have a direct correspondence to the token are * accepted. For example, given a function call \c f(x), * clang_getCursor() would provide the following cursors: * * * when the cursor is over the 'f', a DeclRefExpr cursor referring to 'f'. * * when the cursor is over the '(' or the ')', a CallExpr referring to 'f'. * * when the cursor is over the 'x', a DeclRefExpr cursor referring to 'x'. * * Only the first and last of these cursors will occur within the * annotate, since the tokens "f" and "x' directly refer to a function * and a variable, respectively, but the parentheses are just a small * part of the full syntax of the function call expression, which is * not provided as an annotation. * * \param TU the translation unit that owns the given tokens. * * \param Tokens the set of tokens to annotate. * * \param NumTokens the number of tokens in \p Tokens. * * \param Cursors an array of \p NumTokens cursors, whose contents will be * replaced with the cursors corresponding to each token. */ CINDEX_LINKAGE void clang_annotateTokens(CXTranslationUnit TU, CXToken *Tokens, unsigned NumTokens, CXCursor *Cursors); /** * Free the given set of tokens. */ CINDEX_LINKAGE void clang_disposeTokens(CXTranslationUnit TU, CXToken *Tokens, unsigned NumTokens); /** * @} */ /** * \defgroup CINDEX_DEBUG Debugging facilities * * These routines are used for testing and debugging, only, and should not * be relied upon. * * @{ */ /* for debug/testing */ CINDEX_LINKAGE CXString clang_getCursorKindSpelling(enum CXCursorKind Kind); CINDEX_LINKAGE void clang_getDefinitionSpellingAndExtent( CXCursor, const char **startBuf, const char **endBuf, unsigned *startLine, unsigned *startColumn, unsigned *endLine, unsigned *endColumn); CINDEX_LINKAGE void clang_enableStackTraces(void); CINDEX_LINKAGE void clang_executeOnThread(void (*fn)(void *), void *user_data, unsigned stack_size); /** * @} */ /** * \defgroup CINDEX_CODE_COMPLET Code completion * * Code completion involves taking an (incomplete) source file, along with * knowledge of where the user is actively editing that file, and suggesting * syntactically- and semantically-valid constructs that the user might want to * use at that particular point in the source code. These data structures and * routines provide support for code completion. * * @{ */ /** * A semantic string that describes a code-completion result. * * A semantic string that describes the formatting of a code-completion * result as a single "template" of text that should be inserted into the * source buffer when a particular code-completion result is selected. * Each semantic string is made up of some number of "chunks", each of which * contains some text along with a description of what that text means, e.g., * the name of the entity being referenced, whether the text chunk is part of * the template, or whether it is a "placeholder" that the user should replace * with actual code,of a specific kind. See \c CXCompletionChunkKind for a * description of the different kinds of chunks. */ typedef void *CXCompletionString; /** * A single result of code completion. */ typedef struct { /** * The kind of entity that this completion refers to. * * The cursor kind will be a macro, keyword, or a declaration (one of the * *Decl cursor kinds), describing the entity that the completion is * referring to. * * \todo In the future, we would like to provide a full cursor, to allow * the client to extract additional information from declaration. */ enum CXCursorKind CursorKind; /** * The code-completion string that describes how to insert this * code-completion result into the editing buffer. */ CXCompletionString CompletionString; } CXCompletionResult; /** * Describes a single piece of text within a code-completion string. * * Each "chunk" within a code-completion string (\c CXCompletionString) is * either a piece of text with a specific "kind" that describes how that text * should be interpreted by the client or is another completion string. */ enum CXCompletionChunkKind { /** * A code-completion string that describes "optional" text that * could be a part of the template (but is not required). * * The Optional chunk is the only kind of chunk that has a code-completion * string for its representation, which is accessible via * \c clang_getCompletionChunkCompletionString(). The code-completion string * describes an additional part of the template that is completely optional. * For example, optional chunks can be used to describe the placeholders for * arguments that match up with defaulted function parameters, e.g. given: * * \code * void f(int x, float y = 3.14, double z = 2.71828); * \endcode * * The code-completion string for this function would contain: * - a TypedText chunk for "f". * - a LeftParen chunk for "(". * - a Placeholder chunk for "int x" * - an Optional chunk containing the remaining defaulted arguments, e.g., * - a Comma chunk for "," * - a Placeholder chunk for "float y" * - an Optional chunk containing the last defaulted argument: * - a Comma chunk for "," * - a Placeholder chunk for "double z" * - a RightParen chunk for ")" * * There are many ways to handle Optional chunks. Two simple approaches are: * - Completely ignore optional chunks, in which case the template for the * function "f" would only include the first parameter ("int x"). * - Fully expand all optional chunks, in which case the template for the * function "f" would have all of the parameters. */ CXCompletionChunk_Optional, /** * Text that a user would be expected to type to get this * code-completion result. * * There will be exactly one "typed text" chunk in a semantic string, which * will typically provide the spelling of a keyword or the name of a * declaration that could be used at the current code point. Clients are * expected to filter the code-completion results based on the text in this * chunk. */ CXCompletionChunk_TypedText, /** * Text that should be inserted as part of a code-completion result. * * A "text" chunk represents text that is part of the template to be * inserted into user code should this particular code-completion result * be selected. */ CXCompletionChunk_Text, /** * Placeholder text that should be replaced by the user. * * A "placeholder" chunk marks a place where the user should insert text * into the code-completion template. For example, placeholders might mark * the function parameters for a function declaration, to indicate that the * user should provide arguments for each of those parameters. The actual * text in a placeholder is a suggestion for the text to display before * the user replaces the placeholder with real code. */ CXCompletionChunk_Placeholder, /** * Informative text that should be displayed but never inserted as * part of the template. * * An "informative" chunk contains annotations that can be displayed to * help the user decide whether a particular code-completion result is the * right option, but which is not part of the actual template to be inserted * by code completion. */ CXCompletionChunk_Informative, /** * Text that describes the current parameter when code-completion is * referring to function call, message send, or template specialization. * * A "current parameter" chunk occurs when code-completion is providing * information about a parameter corresponding to the argument at the * code-completion point. For example, given a function * * \code * int add(int x, int y); * \endcode * * and the source code \c add(, where the code-completion point is after the * "(", the code-completion string will contain a "current parameter" chunk * for "int x", indicating that the current argument will initialize that * parameter. After typing further, to \c add(17, (where the code-completion * point is after the ","), the code-completion string will contain a * "current parameter" chunk to "int y". */ CXCompletionChunk_CurrentParameter, /** * A left parenthesis ('('), used to initiate a function call or * signal the beginning of a function parameter list. */ CXCompletionChunk_LeftParen, /** * A right parenthesis (')'), used to finish a function call or * signal the end of a function parameter list. */ CXCompletionChunk_RightParen, /** * A left bracket ('['). */ CXCompletionChunk_LeftBracket, /** * A right bracket (']'). */ CXCompletionChunk_RightBracket, /** * A left brace ('{'). */ CXCompletionChunk_LeftBrace, /** * A right brace ('}'). */ CXCompletionChunk_RightBrace, /** * A left angle bracket ('<'). */ CXCompletionChunk_LeftAngle, /** * A right angle bracket ('>'). */ CXCompletionChunk_RightAngle, /** * A comma separator (','). */ CXCompletionChunk_Comma, /** * Text that specifies the result type of a given result. * * This special kind of informative chunk is not meant to be inserted into * the text buffer. Rather, it is meant to illustrate the type that an * expression using the given completion string would have. */ CXCompletionChunk_ResultType, /** * A colon (':'). */ CXCompletionChunk_Colon, /** * A semicolon (';'). */ CXCompletionChunk_SemiColon, /** * An '=' sign. */ CXCompletionChunk_Equal, /** * Horizontal space (' '). */ CXCompletionChunk_HorizontalSpace, /** * Vertical space ('\\n'), after which it is generally a good idea to * perform indentation. */ CXCompletionChunk_VerticalSpace }; /** * Determine the kind of a particular chunk within a completion string. * * \param completion_string the completion string to query. * * \param chunk_number the 0-based index of the chunk in the completion string. * * \returns the kind of the chunk at the index \c chunk_number. */ CINDEX_LINKAGE enum CXCompletionChunkKind clang_getCompletionChunkKind(CXCompletionString completion_string, unsigned chunk_number); /** * Retrieve the text associated with a particular chunk within a * completion string. * * \param completion_string the completion string to query. * * \param chunk_number the 0-based index of the chunk in the completion string. * * \returns the text associated with the chunk at index \c chunk_number. */ CINDEX_LINKAGE CXString clang_getCompletionChunkText( CXCompletionString completion_string, unsigned chunk_number); /** * Retrieve the completion string associated with a particular chunk * within a completion string. * * \param completion_string the completion string to query. * * \param chunk_number the 0-based index of the chunk in the completion string. * * \returns the completion string associated with the chunk at index * \c chunk_number. */ CINDEX_LINKAGE CXCompletionString clang_getCompletionChunkCompletionString( CXCompletionString completion_string, unsigned chunk_number); /** * Retrieve the number of chunks in the given code-completion string. */ CINDEX_LINKAGE unsigned clang_getNumCompletionChunks(CXCompletionString completion_string); /** * Determine the priority of this code completion. * * The priority of a code completion indicates how likely it is that this * particular completion is the completion that the user will select. The * priority is selected by various internal heuristics. * * \param completion_string The completion string to query. * * \returns The priority of this completion string. Smaller values indicate * higher-priority (more likely) completions. */ CINDEX_LINKAGE unsigned clang_getCompletionPriority(CXCompletionString completion_string); /** * Determine the availability of the entity that this code-completion * string refers to. * * \param completion_string The completion string to query. * * \returns The availability of the completion string. */ CINDEX_LINKAGE enum CXAvailabilityKind clang_getCompletionAvailability(CXCompletionString completion_string); /** * Retrieve the number of annotations associated with the given * completion string. * * \param completion_string the completion string to query. * * \returns the number of annotations associated with the given completion * string. */ CINDEX_LINKAGE unsigned clang_getCompletionNumAnnotations(CXCompletionString completion_string); /** * Retrieve the annotation associated with the given completion string. * * \param completion_string the completion string to query. * * \param annotation_number the 0-based index of the annotation of the * completion string. * * \returns annotation string associated with the completion at index * \c annotation_number, or a NULL string if that annotation is not available. */ CINDEX_LINKAGE CXString clang_getCompletionAnnotation( CXCompletionString completion_string, unsigned annotation_number); /** * Retrieve the parent context of the given completion string. * * The parent context of a completion string is the semantic parent of * the declaration (if any) that the code completion represents. For example, * a code completion for an Objective-C method would have the method's class * or protocol as its context. * * \param completion_string The code completion string whose parent is * being queried. * * \param kind DEPRECATED: always set to CXCursor_NotImplemented if non-NULL. * * \returns The name of the completion parent, e.g., "NSObject" if * the completion string represents a method in the NSObject class. */ CINDEX_LINKAGE CXString clang_getCompletionParent( CXCompletionString completion_string, enum CXCursorKind *kind); /** * Retrieve the brief documentation comment attached to the declaration * that corresponds to the given completion string. */ CINDEX_LINKAGE CXString clang_getCompletionBriefComment(CXCompletionString completion_string); /** * Retrieve a completion string for an arbitrary declaration or macro * definition cursor. * * \param cursor The cursor to query. * * \returns A non-context-sensitive completion string for declaration and macro * definition cursors, or NULL for other kinds of cursors. */ CINDEX_LINKAGE CXCompletionString clang_getCursorCompletionString(CXCursor cursor); /** * Contains the results of code-completion. * * This data structure contains the results of code completion, as * produced by \c clang_codeCompleteAt(). Its contents must be freed by * \c clang_disposeCodeCompleteResults. */ typedef struct { /** * The code-completion results. */ CXCompletionResult *Results; /** * The number of code-completion results stored in the * \c Results array. */ unsigned NumResults; } CXCodeCompleteResults; /** * Retrieve the number of fix-its for the given completion index. * * Calling this makes sense only if CXCodeComplete_IncludeCompletionsWithFixIts * option was set. * * \param results The structure keeping all completion results * * \param completion_index The index of the completion * * \return The number of fix-its which must be applied before the completion at * completion_index can be applied */ CINDEX_LINKAGE unsigned clang_getCompletionNumFixIts(CXCodeCompleteResults *results, unsigned completion_index); /** * Fix-its that *must* be applied before inserting the text for the * corresponding completion. * * By default, clang_codeCompleteAt() only returns completions with empty * fix-its. Extra completions with non-empty fix-its should be explicitly * requested by setting CXCodeComplete_IncludeCompletionsWithFixIts. * * For the clients to be able to compute position of the cursor after applying * fix-its, the following conditions are guaranteed to hold for * replacement_range of the stored fix-its: * - Ranges in the fix-its are guaranteed to never contain the completion * point (or identifier under completion point, if any) inside them, except * at the start or at the end of the range. * - If a fix-it range starts or ends with completion point (or starts or * ends after the identifier under completion point), it will contain at * least one character. It allows to unambiguously recompute completion * point after applying the fix-it. * * The intuition is that provided fix-its change code around the identifier we * complete, but are not allowed to touch the identifier itself or the * completion point. One example of completions with corrections are the ones * replacing '.' with '->' and vice versa: * * std::unique_ptr> vec_ptr; * In 'vec_ptr.^', one of the completions is 'push_back', it requires * replacing '.' with '->'. * In 'vec_ptr->^', one of the completions is 'release', it requires * replacing '->' with '.'. * * \param results The structure keeping all completion results * * \param completion_index The index of the completion * * \param fixit_index The index of the fix-it for the completion at * completion_index * * \param replacement_range The fix-it range that must be replaced before the * completion at completion_index can be applied * * \returns The fix-it string that must replace the code at replacement_range * before the completion at completion_index can be applied */ CINDEX_LINKAGE CXString clang_getCompletionFixIt( CXCodeCompleteResults *results, unsigned completion_index, unsigned fixit_index, CXSourceRange *replacement_range); /** * Flags that can be passed to \c clang_codeCompleteAt() to * modify its behavior. * * The enumerators in this enumeration can be bitwise-OR'd together to * provide multiple options to \c clang_codeCompleteAt(). */ enum CXCodeComplete_Flags { /** * Whether to include macros within the set of code * completions returned. */ CXCodeComplete_IncludeMacros = 0x01, /** * Whether to include code patterns for language constructs * within the set of code completions, e.g., for loops. */ CXCodeComplete_IncludeCodePatterns = 0x02, /** * Whether to include brief documentation within the set of code * completions returned. */ CXCodeComplete_IncludeBriefComments = 0x04, /** * Whether to speed up completion by omitting top- or namespace-level entities * defined in the preamble. There's no guarantee any particular entity is * omitted. This may be useful if the headers are indexed externally. */ CXCodeComplete_SkipPreamble = 0x08, /** * Whether to include completions with small * fix-its, e.g. change '.' to '->' on member access, etc. */ CXCodeComplete_IncludeCompletionsWithFixIts = 0x10 }; /** * Bits that represent the context under which completion is occurring. * * The enumerators in this enumeration may be bitwise-OR'd together if multiple * contexts are occurring simultaneously. */ enum CXCompletionContext { /** * The context for completions is unexposed, as only Clang results * should be included. (This is equivalent to having no context bits set.) */ CXCompletionContext_Unexposed = 0, /** * Completions for any possible type should be included in the results. */ CXCompletionContext_AnyType = 1 << 0, /** * Completions for any possible value (variables, function calls, etc.) * should be included in the results. */ CXCompletionContext_AnyValue = 1 << 1, /** * Completions for values that resolve to an Objective-C object should * be included in the results. */ CXCompletionContext_ObjCObjectValue = 1 << 2, /** * Completions for values that resolve to an Objective-C selector * should be included in the results. */ CXCompletionContext_ObjCSelectorValue = 1 << 3, /** * Completions for values that resolve to a C++ class type should be * included in the results. */ CXCompletionContext_CXXClassTypeValue = 1 << 4, /** * Completions for fields of the member being accessed using the dot * operator should be included in the results. */ CXCompletionContext_DotMemberAccess = 1 << 5, /** * Completions for fields of the member being accessed using the arrow * operator should be included in the results. */ CXCompletionContext_ArrowMemberAccess = 1 << 6, /** * Completions for properties of the Objective-C object being accessed * using the dot operator should be included in the results. */ CXCompletionContext_ObjCPropertyAccess = 1 << 7, /** * Completions for enum tags should be included in the results. */ CXCompletionContext_EnumTag = 1 << 8, /** * Completions for union tags should be included in the results. */ CXCompletionContext_UnionTag = 1 << 9, /** * Completions for struct tags should be included in the results. */ CXCompletionContext_StructTag = 1 << 10, /** * Completions for C++ class names should be included in the results. */ CXCompletionContext_ClassTag = 1 << 11, /** * Completions for C++ namespaces and namespace aliases should be * included in the results. */ CXCompletionContext_Namespace = 1 << 12, /** * Completions for C++ nested name specifiers should be included in * the results. */ CXCompletionContext_NestedNameSpecifier = 1 << 13, /** * Completions for Objective-C interfaces (classes) should be included * in the results. */ CXCompletionContext_ObjCInterface = 1 << 14, /** * Completions for Objective-C protocols should be included in * the results. */ CXCompletionContext_ObjCProtocol = 1 << 15, /** * Completions for Objective-C categories should be included in * the results. */ CXCompletionContext_ObjCCategory = 1 << 16, /** * Completions for Objective-C instance messages should be included * in the results. */ CXCompletionContext_ObjCInstanceMessage = 1 << 17, /** * Completions for Objective-C class messages should be included in * the results. */ CXCompletionContext_ObjCClassMessage = 1 << 18, /** * Completions for Objective-C selector names should be included in * the results. */ CXCompletionContext_ObjCSelectorName = 1 << 19, /** * Completions for preprocessor macro names should be included in * the results. */ CXCompletionContext_MacroName = 1 << 20, /** * Natural language completions should be included in the results. */ CXCompletionContext_NaturalLanguage = 1 << 21, /** * #include file completions should be included in the results. */ CXCompletionContext_IncludedFile = 1 << 22, /** * The current context is unknown, so set all contexts. */ CXCompletionContext_Unknown = ((1 << 23) - 1) }; /** * Returns a default set of code-completion options that can be * passed to\c clang_codeCompleteAt(). */ CINDEX_LINKAGE unsigned clang_defaultCodeCompleteOptions(void); /** * Perform code completion at a given location in a translation unit. * * This function performs code completion at a particular file, line, and * column within source code, providing results that suggest potential * code snippets based on the context of the completion. The basic model * for code completion is that Clang will parse a complete source file, * performing syntax checking up to the location where code-completion has * been requested. At that point, a special code-completion token is passed * to the parser, which recognizes this token and determines, based on the * current location in the C/Objective-C/C++ grammar and the state of * semantic analysis, what completions to provide. These completions are * returned via a new \c CXCodeCompleteResults structure. * * Code completion itself is meant to be triggered by the client when the * user types punctuation characters or whitespace, at which point the * code-completion location will coincide with the cursor. For example, if \c p * is a pointer, code-completion might be triggered after the "-" and then * after the ">" in \c p->. When the code-completion location is after the ">", * the completion results will provide, e.g., the members of the struct that * "p" points to. The client is responsible for placing the cursor at the * beginning of the token currently being typed, then filtering the results * based on the contents of the token. For example, when code-completing for * the expression \c p->get, the client should provide the location just after * the ">" (e.g., pointing at the "g") to this code-completion hook. Then, the * client can filter the results based on the current token text ("get"), only * showing those results that start with "get". The intent of this interface * is to separate the relatively high-latency acquisition of code-completion * results from the filtering of results on a per-character basis, which must * have a lower latency. * * \param TU The translation unit in which code-completion should * occur. The source files for this translation unit need not be * completely up-to-date (and the contents of those source files may * be overridden via \p unsaved_files). Cursors referring into the * translation unit may be invalidated by this invocation. * * \param complete_filename The name of the source file where code * completion should be performed. This filename may be any file * included in the translation unit. * * \param complete_line The line at which code-completion should occur. * * \param complete_column The column at which code-completion should occur. * Note that the column should point just after the syntactic construct that * initiated code completion, and not in the middle of a lexical token. * * \param unsaved_files the Files that have not yet been saved to disk * but may be required for parsing or code completion, including the * contents of those files. The contents and name of these files (as * specified by CXUnsavedFile) are copied when necessary, so the * client only needs to guarantee their validity until the call to * this function returns. * * \param num_unsaved_files The number of unsaved file entries in \p * unsaved_files. * * \param options Extra options that control the behavior of code * completion, expressed as a bitwise OR of the enumerators of the * CXCodeComplete_Flags enumeration. The * \c clang_defaultCodeCompleteOptions() function returns a default set * of code-completion options. * * \returns If successful, a new \c CXCodeCompleteResults structure * containing code-completion results, which should eventually be * freed with \c clang_disposeCodeCompleteResults(). If code * completion fails, returns NULL. */ CINDEX_LINKAGE CXCodeCompleteResults * clang_codeCompleteAt(CXTranslationUnit TU, const char *complete_filename, unsigned complete_line, unsigned complete_column, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, unsigned options); /** * Sort the code-completion results in case-insensitive alphabetical * order. * * \param Results The set of results to sort. * \param NumResults The number of results in \p Results. */ CINDEX_LINKAGE void clang_sortCodeCompletionResults(CXCompletionResult *Results, unsigned NumResults); /** * Free the given set of code-completion results. */ CINDEX_LINKAGE void clang_disposeCodeCompleteResults(CXCodeCompleteResults *Results); /** * Determine the number of diagnostics produced prior to the * location where code completion was performed. */ CINDEX_LINKAGE unsigned clang_codeCompleteGetNumDiagnostics(CXCodeCompleteResults *Results); /** * Retrieve a diagnostic associated with the given code completion. * * \param Results the code completion results to query. * \param Index the zero-based diagnostic number to retrieve. * * \returns the requested diagnostic. This diagnostic must be freed * via a call to \c clang_disposeDiagnostic(). */ CINDEX_LINKAGE CXDiagnostic clang_codeCompleteGetDiagnostic(CXCodeCompleteResults *Results, unsigned Index); /** * Determines what completions are appropriate for the context * the given code completion. * * \param Results the code completion results to query * * \returns the kinds of completions that are appropriate for use * along with the given code completion results. */ CINDEX_LINKAGE unsigned long long clang_codeCompleteGetContexts(CXCodeCompleteResults *Results); /** * Returns the cursor kind for the container for the current code * completion context. The container is only guaranteed to be set for * contexts where a container exists (i.e. member accesses or Objective-C * message sends); if there is not a container, this function will return * CXCursor_InvalidCode. * * \param Results the code completion results to query * * \param IsIncomplete on return, this value will be false if Clang has complete * information about the container. If Clang does not have complete * information, this value will be true. * * \returns the container kind, or CXCursor_InvalidCode if there is not a * container */ CINDEX_LINKAGE enum CXCursorKind clang_codeCompleteGetContainerKind(CXCodeCompleteResults *Results, unsigned *IsIncomplete); /** * Returns the USR for the container for the current code completion * context. If there is not a container for the current context, this * function will return the empty string. * * \param Results the code completion results to query * * \returns the USR for the container */ CINDEX_LINKAGE CXString clang_codeCompleteGetContainerUSR(CXCodeCompleteResults *Results); /** * Returns the currently-entered selector for an Objective-C message * send, formatted like "initWithFoo:bar:". Only guaranteed to return a * non-empty string for CXCompletionContext_ObjCInstanceMessage and * CXCompletionContext_ObjCClassMessage. * * \param Results the code completion results to query * * \returns the selector (or partial selector) that has been entered thus far * for an Objective-C message send. */ CINDEX_LINKAGE CXString clang_codeCompleteGetObjCSelector(CXCodeCompleteResults *Results); /** * @} */ /** * \defgroup CINDEX_MISC Miscellaneous utility functions * * @{ */ /** * Return a version string, suitable for showing to a user, but not * intended to be parsed (the format is not guaranteed to be stable). */ CINDEX_LINKAGE CXString clang_getClangVersion(void); /** * Enable/disable crash recovery. * * \param isEnabled Flag to indicate if crash recovery is enabled. A non-zero * value enables crash recovery, while 0 disables it. */ CINDEX_LINKAGE void clang_toggleCrashRecovery(unsigned isEnabled); /** * Visitor invoked for each file in a translation unit * (used with clang_getInclusions()). * * This visitor function will be invoked by clang_getInclusions() for each * file included (either at the top-level or by \#include directives) within * a translation unit. The first argument is the file being included, and * the second and third arguments provide the inclusion stack. The * array is sorted in order of immediate inclusion. For example, * the first element refers to the location that included 'included_file'. */ typedef void (*CXInclusionVisitor)(CXFile included_file, CXSourceLocation *inclusion_stack, unsigned include_len, CXClientData client_data); /** * Visit the set of preprocessor inclusions in a translation unit. * The visitor function is called with the provided data for every included * file. This does not include headers included by the PCH file (unless one * is inspecting the inclusions in the PCH file itself). */ CINDEX_LINKAGE void clang_getInclusions(CXTranslationUnit tu, CXInclusionVisitor visitor, CXClientData client_data); typedef enum { CXEval_Int = 1, CXEval_Float = 2, CXEval_ObjCStrLiteral = 3, CXEval_StrLiteral = 4, CXEval_CFStr = 5, CXEval_Other = 6, CXEval_UnExposed = 0 } CXEvalResultKind; /** * Evaluation result of a cursor */ typedef void *CXEvalResult; /** * If cursor is a statement declaration tries to evaluate the * statement and if its variable, tries to evaluate its initializer, * into its corresponding type. * If it's an expression, tries to evaluate the expression. */ CINDEX_LINKAGE CXEvalResult clang_Cursor_Evaluate(CXCursor C); /** * Returns the kind of the evaluated result. */ CINDEX_LINKAGE CXEvalResultKind clang_EvalResult_getKind(CXEvalResult E); /** * Returns the evaluation result as integer if the * kind is Int. */ CINDEX_LINKAGE int clang_EvalResult_getAsInt(CXEvalResult E); /** * Returns the evaluation result as a long long integer if the * kind is Int. This prevents overflows that may happen if the result is * returned with clang_EvalResult_getAsInt. */ CINDEX_LINKAGE long long clang_EvalResult_getAsLongLong(CXEvalResult E); /** * Returns a non-zero value if the kind is Int and the evaluation * result resulted in an unsigned integer. */ CINDEX_LINKAGE unsigned clang_EvalResult_isUnsignedInt(CXEvalResult E); /** * Returns the evaluation result as an unsigned integer if * the kind is Int and clang_EvalResult_isUnsignedInt is non-zero. */ CINDEX_LINKAGE unsigned long long clang_EvalResult_getAsUnsigned(CXEvalResult E); /** * Returns the evaluation result as double if the * kind is double. */ CINDEX_LINKAGE double clang_EvalResult_getAsDouble(CXEvalResult E); /** * Returns the evaluation result as a constant string if the * kind is other than Int or float. User must not free this pointer, * instead call clang_EvalResult_dispose on the CXEvalResult returned * by clang_Cursor_Evaluate. */ CINDEX_LINKAGE const char *clang_EvalResult_getAsStr(CXEvalResult E); /** * Disposes the created Eval memory. */ CINDEX_LINKAGE void clang_EvalResult_dispose(CXEvalResult E); /** * @} */ /** \defgroup CINDEX_REMAPPING Remapping functions * * @{ */ /** * A remapping of original source files and their translated files. */ typedef void *CXRemapping; /** * Retrieve a remapping. * * \param path the path that contains metadata about remappings. * * \returns the requested remapping. This remapping must be freed * via a call to \c clang_remap_dispose(). Can return NULL if an error occurred. */ CINDEX_LINKAGE CXRemapping clang_getRemappings(const char *path); /** * Retrieve a remapping. * * \param filePaths pointer to an array of file paths containing remapping info. * * \param numFiles number of file paths. * * \returns the requested remapping. This remapping must be freed * via a call to \c clang_remap_dispose(). Can return NULL if an error occurred. */ CINDEX_LINKAGE CXRemapping clang_getRemappingsFromFileList(const char **filePaths, unsigned numFiles); /** * Determine the number of remappings. */ CINDEX_LINKAGE unsigned clang_remap_getNumFiles(CXRemapping); /** * Get the original and the associated filename from the remapping. * * \param original If non-NULL, will be set to the original filename. * * \param transformed If non-NULL, will be set to the filename that the original * is associated with. */ CINDEX_LINKAGE void clang_remap_getFilenames(CXRemapping, unsigned index, CXString *original, CXString *transformed); /** * Dispose the remapping. */ CINDEX_LINKAGE void clang_remap_dispose(CXRemapping); /** * @} */ /** \defgroup CINDEX_HIGH Higher level API functions * * @{ */ enum CXVisitorResult { CXVisit_Break, CXVisit_Continue }; typedef struct CXCursorAndRangeVisitor { void *context; enum CXVisitorResult (*visit)(void *context, CXCursor, CXSourceRange); } CXCursorAndRangeVisitor; typedef enum { /** * Function returned successfully. */ CXResult_Success = 0, /** * One of the parameters was invalid for the function. */ CXResult_Invalid = 1, /** * The function was terminated by a callback (e.g. it returned * CXVisit_Break) */ CXResult_VisitBreak = 2 } CXResult; /** * Find references of a declaration in a specific file. * * \param cursor pointing to a declaration or a reference of one. * * \param file to search for references. * * \param visitor callback that will receive pairs of CXCursor/CXSourceRange for * each reference found. * The CXSourceRange will point inside the file; if the reference is inside * a macro (and not a macro argument) the CXSourceRange will be invalid. * * \returns one of the CXResult enumerators. */ CINDEX_LINKAGE CXResult clang_findReferencesInFile( CXCursor cursor, CXFile file, CXCursorAndRangeVisitor visitor); /** * Find #import/#include directives in a specific file. * * \param TU translation unit containing the file to query. * * \param file to search for #import/#include directives. * * \param visitor callback that will receive pairs of CXCursor/CXSourceRange for * each directive found. * * \returns one of the CXResult enumerators. */ CINDEX_LINKAGE CXResult clang_findIncludesInFile( CXTranslationUnit TU, CXFile file, CXCursorAndRangeVisitor visitor); #if __has_feature(blocks) typedef enum CXVisitorResult (^CXCursorAndRangeVisitorBlock)(CXCursor, CXSourceRange); #else typedef struct _CXCursorAndRangeVisitorBlock *CXCursorAndRangeVisitorBlock; #endif CINDEX_LINKAGE CXResult clang_findReferencesInFileWithBlock(CXCursor, CXFile, CXCursorAndRangeVisitorBlock); CINDEX_LINKAGE CXResult clang_findIncludesInFileWithBlock(CXTranslationUnit, CXFile, CXCursorAndRangeVisitorBlock); /** * The client's data object that is associated with a CXFile. */ typedef void *CXIdxClientFile; /** * The client's data object that is associated with a semantic entity. */ typedef void *CXIdxClientEntity; /** * The client's data object that is associated with a semantic container * of entities. */ typedef void *CXIdxClientContainer; /** * The client's data object that is associated with an AST file (PCH * or module). */ typedef void *CXIdxClientASTFile; /** * Source location passed to index callbacks. */ typedef struct { void *ptr_data[2]; unsigned int_data; } CXIdxLoc; /** * Data for ppIncludedFile callback. */ typedef struct { /** * Location of '#' in the \#include/\#import directive. */ CXIdxLoc hashLoc; /** * Filename as written in the \#include/\#import directive. */ const char *filename; /** * The actual file that the \#include/\#import directive resolved to. */ CXFile file; int isImport; int isAngled; /** * Non-zero if the directive was automatically turned into a module * import. */ int isModuleImport; } CXIdxIncludedFileInfo; /** * Data for IndexerCallbacks#importedASTFile. */ typedef struct { /** * Top level AST file containing the imported PCH, module or submodule. */ CXFile file; /** * The imported module or NULL if the AST file is a PCH. */ CXModule module; /** * Location where the file is imported. Applicable only for modules. */ CXIdxLoc loc; /** * Non-zero if an inclusion directive was automatically turned into * a module import. Applicable only for modules. */ int isImplicit; } CXIdxImportedASTFileInfo; typedef enum { CXIdxEntity_Unexposed = 0, CXIdxEntity_Typedef = 1, CXIdxEntity_Function = 2, CXIdxEntity_Variable = 3, CXIdxEntity_Field = 4, CXIdxEntity_EnumConstant = 5, CXIdxEntity_ObjCClass = 6, CXIdxEntity_ObjCProtocol = 7, CXIdxEntity_ObjCCategory = 8, CXIdxEntity_ObjCInstanceMethod = 9, CXIdxEntity_ObjCClassMethod = 10, CXIdxEntity_ObjCProperty = 11, CXIdxEntity_ObjCIvar = 12, CXIdxEntity_Enum = 13, CXIdxEntity_Struct = 14, CXIdxEntity_Union = 15, CXIdxEntity_CXXClass = 16, CXIdxEntity_CXXNamespace = 17, CXIdxEntity_CXXNamespaceAlias = 18, CXIdxEntity_CXXStaticVariable = 19, CXIdxEntity_CXXStaticMethod = 20, CXIdxEntity_CXXInstanceMethod = 21, CXIdxEntity_CXXConstructor = 22, CXIdxEntity_CXXDestructor = 23, CXIdxEntity_CXXConversionFunction = 24, CXIdxEntity_CXXTypeAlias = 25, CXIdxEntity_CXXInterface = 26, CXIdxEntity_CXXConcept = 27 } CXIdxEntityKind; typedef enum { CXIdxEntityLang_None = 0, CXIdxEntityLang_C = 1, CXIdxEntityLang_ObjC = 2, CXIdxEntityLang_CXX = 3, CXIdxEntityLang_Swift = 4 } CXIdxEntityLanguage; /** * Extra C++ template information for an entity. This can apply to: * CXIdxEntity_Function * CXIdxEntity_CXXClass * CXIdxEntity_CXXStaticMethod * CXIdxEntity_CXXInstanceMethod * CXIdxEntity_CXXConstructor * CXIdxEntity_CXXConversionFunction * CXIdxEntity_CXXTypeAlias */ typedef enum { CXIdxEntity_NonTemplate = 0, CXIdxEntity_Template = 1, CXIdxEntity_TemplatePartialSpecialization = 2, CXIdxEntity_TemplateSpecialization = 3 } CXIdxEntityCXXTemplateKind; typedef enum { CXIdxAttr_Unexposed = 0, CXIdxAttr_IBAction = 1, CXIdxAttr_IBOutlet = 2, CXIdxAttr_IBOutletCollection = 3 } CXIdxAttrKind; typedef struct { CXIdxAttrKind kind; CXCursor cursor; CXIdxLoc loc; } CXIdxAttrInfo; typedef struct { CXIdxEntityKind kind; CXIdxEntityCXXTemplateKind templateKind; CXIdxEntityLanguage lang; const char *name; const char *USR; CXCursor cursor; const CXIdxAttrInfo *const *attributes; unsigned numAttributes; } CXIdxEntityInfo; typedef struct { CXCursor cursor; } CXIdxContainerInfo; typedef struct { const CXIdxAttrInfo *attrInfo; const CXIdxEntityInfo *objcClass; CXCursor classCursor; CXIdxLoc classLoc; } CXIdxIBOutletCollectionAttrInfo; typedef enum { CXIdxDeclFlag_Skipped = 0x1 } CXIdxDeclInfoFlags; typedef struct { const CXIdxEntityInfo *entityInfo; CXCursor cursor; CXIdxLoc loc; const CXIdxContainerInfo *semanticContainer; /** * Generally same as #semanticContainer but can be different in * cases like out-of-line C++ member functions. */ const CXIdxContainerInfo *lexicalContainer; int isRedeclaration; int isDefinition; int isContainer; const CXIdxContainerInfo *declAsContainer; /** * Whether the declaration exists in code or was created implicitly * by the compiler, e.g. implicit Objective-C methods for properties. */ int isImplicit; const CXIdxAttrInfo *const *attributes; unsigned numAttributes; unsigned flags; } CXIdxDeclInfo; typedef enum { CXIdxObjCContainer_ForwardRef = 0, CXIdxObjCContainer_Interface = 1, CXIdxObjCContainer_Implementation = 2 } CXIdxObjCContainerKind; typedef struct { const CXIdxDeclInfo *declInfo; CXIdxObjCContainerKind kind; } CXIdxObjCContainerDeclInfo; typedef struct { const CXIdxEntityInfo *base; CXCursor cursor; CXIdxLoc loc; } CXIdxBaseClassInfo; typedef struct { const CXIdxEntityInfo *protocol; CXCursor cursor; CXIdxLoc loc; } CXIdxObjCProtocolRefInfo; typedef struct { const CXIdxObjCProtocolRefInfo *const *protocols; unsigned numProtocols; } CXIdxObjCProtocolRefListInfo; typedef struct { const CXIdxObjCContainerDeclInfo *containerInfo; const CXIdxBaseClassInfo *superInfo; const CXIdxObjCProtocolRefListInfo *protocols; } CXIdxObjCInterfaceDeclInfo; typedef struct { const CXIdxObjCContainerDeclInfo *containerInfo; const CXIdxEntityInfo *objcClass; CXCursor classCursor; CXIdxLoc classLoc; const CXIdxObjCProtocolRefListInfo *protocols; } CXIdxObjCCategoryDeclInfo; typedef struct { const CXIdxDeclInfo *declInfo; const CXIdxEntityInfo *getter; const CXIdxEntityInfo *setter; } CXIdxObjCPropertyDeclInfo; typedef struct { const CXIdxDeclInfo *declInfo; const CXIdxBaseClassInfo *const *bases; unsigned numBases; } CXIdxCXXClassDeclInfo; /** * Data for IndexerCallbacks#indexEntityReference. * * This may be deprecated in a future version as this duplicates * the \c CXSymbolRole_Implicit bit in \c CXSymbolRole. */ typedef enum { /** * The entity is referenced directly in user's code. */ CXIdxEntityRef_Direct = 1, /** * An implicit reference, e.g. a reference of an Objective-C method * via the dot syntax. */ CXIdxEntityRef_Implicit = 2 } CXIdxEntityRefKind; /** * Roles that are attributed to symbol occurrences. * * Internal: this currently mirrors low 9 bits of clang::index::SymbolRole with * higher bits zeroed. These high bits may be exposed in the future. */ typedef enum { CXSymbolRole_None = 0, CXSymbolRole_Declaration = 1 << 0, CXSymbolRole_Definition = 1 << 1, CXSymbolRole_Reference = 1 << 2, CXSymbolRole_Read = 1 << 3, CXSymbolRole_Write = 1 << 4, CXSymbolRole_Call = 1 << 5, CXSymbolRole_Dynamic = 1 << 6, CXSymbolRole_AddressOf = 1 << 7, CXSymbolRole_Implicit = 1 << 8 } CXSymbolRole; /** * Data for IndexerCallbacks#indexEntityReference. */ typedef struct { CXIdxEntityRefKind kind; /** * Reference cursor. */ CXCursor cursor; CXIdxLoc loc; /** * The entity that gets referenced. */ const CXIdxEntityInfo *referencedEntity; /** * Immediate "parent" of the reference. For example: * * \code * Foo *var; * \endcode * * The parent of reference of type 'Foo' is the variable 'var'. * For references inside statement bodies of functions/methods, * the parentEntity will be the function/method. */ const CXIdxEntityInfo *parentEntity; /** * Lexical container context of the reference. */ const CXIdxContainerInfo *container; /** * Sets of symbol roles of the reference. */ CXSymbolRole role; } CXIdxEntityRefInfo; /** * A group of callbacks used by #clang_indexSourceFile and * #clang_indexTranslationUnit. */ typedef struct { /** * Called periodically to check whether indexing should be aborted. * Should return 0 to continue, and non-zero to abort. */ int (*abortQuery)(CXClientData client_data, void *reserved); /** * Called at the end of indexing; passes the complete diagnostic set. */ void (*diagnostic)(CXClientData client_data, CXDiagnosticSet, void *reserved); CXIdxClientFile (*enteredMainFile)(CXClientData client_data, CXFile mainFile, void *reserved); /** * Called when a file gets \#included/\#imported. */ CXIdxClientFile (*ppIncludedFile)(CXClientData client_data, const CXIdxIncludedFileInfo *); /** * Called when a AST file (PCH or module) gets imported. * * AST files will not get indexed (there will not be callbacks to index all * the entities in an AST file). The recommended action is that, if the AST * file is not already indexed, to initiate a new indexing job specific to * the AST file. */ CXIdxClientASTFile (*importedASTFile)(CXClientData client_data, const CXIdxImportedASTFileInfo *); /** * Called at the beginning of indexing a translation unit. */ CXIdxClientContainer (*startedTranslationUnit)(CXClientData client_data, void *reserved); void (*indexDeclaration)(CXClientData client_data, const CXIdxDeclInfo *); /** * Called to index a reference of an entity. */ void (*indexEntityReference)(CXClientData client_data, const CXIdxEntityRefInfo *); } IndexerCallbacks; CINDEX_LINKAGE int clang_index_isEntityObjCContainerKind(CXIdxEntityKind); CINDEX_LINKAGE const CXIdxObjCContainerDeclInfo * clang_index_getObjCContainerDeclInfo(const CXIdxDeclInfo *); CINDEX_LINKAGE const CXIdxObjCInterfaceDeclInfo * clang_index_getObjCInterfaceDeclInfo(const CXIdxDeclInfo *); CINDEX_LINKAGE const CXIdxObjCCategoryDeclInfo * clang_index_getObjCCategoryDeclInfo(const CXIdxDeclInfo *); CINDEX_LINKAGE const CXIdxObjCProtocolRefListInfo * clang_index_getObjCProtocolRefListInfo(const CXIdxDeclInfo *); CINDEX_LINKAGE const CXIdxObjCPropertyDeclInfo * clang_index_getObjCPropertyDeclInfo(const CXIdxDeclInfo *); CINDEX_LINKAGE const CXIdxIBOutletCollectionAttrInfo * clang_index_getIBOutletCollectionAttrInfo(const CXIdxAttrInfo *); CINDEX_LINKAGE const CXIdxCXXClassDeclInfo * clang_index_getCXXClassDeclInfo(const CXIdxDeclInfo *); /** * For retrieving a custom CXIdxClientContainer attached to a * container. */ CINDEX_LINKAGE CXIdxClientContainer clang_index_getClientContainer(const CXIdxContainerInfo *); /** * For setting a custom CXIdxClientContainer attached to a * container. */ CINDEX_LINKAGE void clang_index_setClientContainer(const CXIdxContainerInfo *, CXIdxClientContainer); /** * For retrieving a custom CXIdxClientEntity attached to an entity. */ CINDEX_LINKAGE CXIdxClientEntity clang_index_getClientEntity(const CXIdxEntityInfo *); /** * For setting a custom CXIdxClientEntity attached to an entity. */ CINDEX_LINKAGE void clang_index_setClientEntity(const CXIdxEntityInfo *, CXIdxClientEntity); /** * An indexing action/session, to be applied to one or multiple * translation units. */ typedef void *CXIndexAction; /** * An indexing action/session, to be applied to one or multiple * translation units. * * \param CIdx The index object with which the index action will be associated. */ CINDEX_LINKAGE CXIndexAction clang_IndexAction_create(CXIndex CIdx); /** * Destroy the given index action. * * The index action must not be destroyed until all of the translation units * created within that index action have been destroyed. */ CINDEX_LINKAGE void clang_IndexAction_dispose(CXIndexAction); typedef enum { /** * Used to indicate that no special indexing options are needed. */ CXIndexOpt_None = 0x0, /** * Used to indicate that IndexerCallbacks#indexEntityReference should * be invoked for only one reference of an entity per source file that does * not also include a declaration/definition of the entity. */ CXIndexOpt_SuppressRedundantRefs = 0x1, /** * Function-local symbols should be indexed. If this is not set * function-local symbols will be ignored. */ CXIndexOpt_IndexFunctionLocalSymbols = 0x2, /** * Implicit function/class template instantiations should be indexed. * If this is not set, implicit instantiations will be ignored. */ CXIndexOpt_IndexImplicitTemplateInstantiations = 0x4, /** * Suppress all compiler warnings when parsing for indexing. */ CXIndexOpt_SuppressWarnings = 0x8, /** * Skip a function/method body that was already parsed during an * indexing session associated with a \c CXIndexAction object. * Bodies in system headers are always skipped. */ CXIndexOpt_SkipParsedBodiesInSession = 0x10 } CXIndexOptFlags; /** * Index the given source file and the translation unit corresponding * to that file via callbacks implemented through #IndexerCallbacks. * * \param client_data pointer data supplied by the client, which will * be passed to the invoked callbacks. * * \param index_callbacks Pointer to indexing callbacks that the client * implements. * * \param index_callbacks_size Size of #IndexerCallbacks structure that gets * passed in index_callbacks. * * \param index_options A bitmask of options that affects how indexing is * performed. This should be a bitwise OR of the CXIndexOpt_XXX flags. * * \param[out] out_TU pointer to store a \c CXTranslationUnit that can be * reused after indexing is finished. Set to \c NULL if you do not require it. * * \returns 0 on success or if there were errors from which the compiler could * recover. If there is a failure from which there is no recovery, returns * a non-zero \c CXErrorCode. * * The rest of the parameters are the same as #clang_parseTranslationUnit. */ CINDEX_LINKAGE int clang_indexSourceFile( CXIndexAction, CXClientData client_data, IndexerCallbacks *index_callbacks, unsigned index_callbacks_size, unsigned index_options, const char *source_filename, const char *const *command_line_args, int num_command_line_args, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, CXTranslationUnit *out_TU, unsigned TU_options); /** * Same as clang_indexSourceFile but requires a full command line * for \c command_line_args including argv[0]. This is useful if the standard * library paths are relative to the binary. */ CINDEX_LINKAGE int clang_indexSourceFileFullArgv( CXIndexAction, CXClientData client_data, IndexerCallbacks *index_callbacks, unsigned index_callbacks_size, unsigned index_options, const char *source_filename, const char *const *command_line_args, int num_command_line_args, struct CXUnsavedFile *unsaved_files, unsigned num_unsaved_files, CXTranslationUnit *out_TU, unsigned TU_options); /** * Index the given translation unit via callbacks implemented through * #IndexerCallbacks. * * The order of callback invocations is not guaranteed to be the same as * when indexing a source file. The high level order will be: * * -Preprocessor callbacks invocations * -Declaration/reference callbacks invocations * -Diagnostic callback invocations * * The parameters are the same as #clang_indexSourceFile. * * \returns If there is a failure from which there is no recovery, returns * non-zero, otherwise returns 0. */ CINDEX_LINKAGE int clang_indexTranslationUnit( CXIndexAction, CXClientData client_data, IndexerCallbacks *index_callbacks, unsigned index_callbacks_size, unsigned index_options, CXTranslationUnit); /** * Retrieve the CXIdxFile, file, line, column, and offset represented by * the given CXIdxLoc. * * If the location refers into a macro expansion, retrieves the * location of the macro expansion and if it refers into a macro argument * retrieves the location of the argument. */ CINDEX_LINKAGE void clang_indexLoc_getFileLocation(CXIdxLoc loc, CXIdxClientFile *indexFile, CXFile *file, unsigned *line, unsigned *column, unsigned *offset); /** * Retrieve the CXSourceLocation represented by the given CXIdxLoc. */ CINDEX_LINKAGE CXSourceLocation clang_indexLoc_getCXSourceLocation(CXIdxLoc loc); /** * Visitor invoked for each field found by a traversal. * * This visitor function will be invoked for each field found by * \c clang_Type_visitFields. Its first argument is the cursor being * visited, its second argument is the client data provided to * \c clang_Type_visitFields. * * The visitor should return one of the \c CXVisitorResult values * to direct \c clang_Type_visitFields. */ typedef enum CXVisitorResult (*CXFieldVisitor)(CXCursor C, CXClientData client_data); /** * Visit the fields of a particular type. * * This function visits all the direct fields of the given cursor, * invoking the given \p visitor function with the cursors of each * visited field. The traversal may be ended prematurely, if * the visitor returns \c CXFieldVisit_Break. * * \param T the record type whose field may be visited. * * \param visitor the visitor function that will be invoked for each * field of \p T. * * \param client_data pointer data supplied by the client, which will * be passed to the visitor each time it is invoked. * * \returns a non-zero value if the traversal was terminated * prematurely by the visitor returning \c CXFieldVisit_Break. */ CINDEX_LINKAGE unsigned clang_Type_visitFields(CXType T, CXFieldVisitor visitor, CXClientData client_data); /** * Describes the kind of binary operators. */ enum CXBinaryOperatorKind { /** This value describes cursors which are not binary operators. */ CXBinaryOperator_Invalid, /** C++ Pointer - to - member operator. */ CXBinaryOperator_PtrMemD, /** C++ Pointer - to - member operator. */ CXBinaryOperator_PtrMemI, /** Multiplication operator. */ CXBinaryOperator_Mul, /** Division operator. */ CXBinaryOperator_Div, /** Remainder operator. */ CXBinaryOperator_Rem, /** Addition operator. */ CXBinaryOperator_Add, /** Subtraction operator. */ CXBinaryOperator_Sub, /** Bitwise shift left operator. */ CXBinaryOperator_Shl, /** Bitwise shift right operator. */ CXBinaryOperator_Shr, /** C++ three-way comparison (spaceship) operator. */ CXBinaryOperator_Cmp, /** Less than operator. */ CXBinaryOperator_LT, /** Greater than operator. */ CXBinaryOperator_GT, /** Less or equal operator. */ CXBinaryOperator_LE, /** Greater or equal operator. */ CXBinaryOperator_GE, /** Equal operator. */ CXBinaryOperator_EQ, /** Not equal operator. */ CXBinaryOperator_NE, /** Bitwise AND operator. */ CXBinaryOperator_And, /** Bitwise XOR operator. */ CXBinaryOperator_Xor, /** Bitwise OR operator. */ CXBinaryOperator_Or, /** Logical AND operator. */ CXBinaryOperator_LAnd, /** Logical OR operator. */ CXBinaryOperator_LOr, /** Assignment operator. */ CXBinaryOperator_Assign, /** Multiplication assignment operator. */ CXBinaryOperator_MulAssign, /** Division assignment operator. */ CXBinaryOperator_DivAssign, /** Remainder assignment operator. */ CXBinaryOperator_RemAssign, /** Addition assignment operator. */ CXBinaryOperator_AddAssign, /** Subtraction assignment operator. */ CXBinaryOperator_SubAssign, /** Bitwise shift left assignment operator. */ CXBinaryOperator_ShlAssign, /** Bitwise shift right assignment operator. */ CXBinaryOperator_ShrAssign, /** Bitwise AND assignment operator. */ CXBinaryOperator_AndAssign, /** Bitwise XOR assignment operator. */ CXBinaryOperator_XorAssign, /** Bitwise OR assignment operator. */ CXBinaryOperator_OrAssign, /** Comma operator. */ CXBinaryOperator_Comma }; /** * Retrieve the spelling of a given CXBinaryOperatorKind. */ CINDEX_LINKAGE CXString clang_getBinaryOperatorKindSpelling(enum CXBinaryOperatorKind kind); /** * Retrieve the binary operator kind of this cursor. * * If this cursor is not a binary operator then returns Invalid. */ CINDEX_LINKAGE enum CXBinaryOperatorKind clang_getCursorBinaryOperatorKind(CXCursor cursor); /** * Describes the kind of unary operators. */ enum CXUnaryOperatorKind { /** This value describes cursors which are not unary operators. */ CXUnaryOperator_Invalid, /** Postfix increment operator. */ CXUnaryOperator_PostInc, /** Postfix decrement operator. */ CXUnaryOperator_PostDec, /** Prefix increment operator. */ CXUnaryOperator_PreInc, /** Prefix decrement operator. */ CXUnaryOperator_PreDec, /** Address of operator. */ CXUnaryOperator_AddrOf, /** Dereference operator. */ CXUnaryOperator_Deref, /** Plus operator. */ CXUnaryOperator_Plus, /** Minus operator. */ CXUnaryOperator_Minus, /** Not operator. */ CXUnaryOperator_Not, /** LNot operator. */ CXUnaryOperator_LNot, /** "__real expr" operator. */ CXUnaryOperator_Real, /** "__imag expr" operator. */ CXUnaryOperator_Imag, /** __extension__ marker operator. */ CXUnaryOperator_Extension, /** C++ co_await operator. */ CXUnaryOperator_Coawait }; /** * Retrieve the spelling of a given CXUnaryOperatorKind. */ CINDEX_LINKAGE CXString clang_getUnaryOperatorKindSpelling(enum CXUnaryOperatorKind kind); /** * Retrieve the unary operator kind of this cursor. * * If this cursor is not a unary operator then returns Invalid. */ CINDEX_LINKAGE enum CXUnaryOperatorKind clang_getCursorUnaryOperatorKind(CXCursor cursor); /** * @} */ /** * @} */ LLVM_CLANG_C_EXTERN_C_END #endif