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1 /*===-- clang-c/Index.h - Indexing Public C Interface -------------*- C -*-===*\
2 |*                                                                            *|
3 |*                     The LLVM Compiler Infrastructure                       *|
4 |*                                                                            *|
5 |* This file is distributed under the University of Illinois Open Source      *|
6 |* License. See LICENSE.TXT for details.                                      *|
7 |*                                                                            *|
8 |*===----------------------------------------------------------------------===*|
9 |*                                                                            *|
10 |* This header provides a public inferface to a Clang library for extracting  *|
11 |* high-level symbol information from source files without exposing the full  *|
12 |* Clang C++ API.                                                             *|
13 |*                                                                            *|
14 \*===----------------------------------------------------------------------===*/
15 
16 #ifndef CLANG_C_INDEX_H
17 #define CLANG_C_INDEX_H
18 
19 #include <sys/stat.h>
20 #include <time.h>
21 #include <stdio.h>
22 
23 #ifdef __cplusplus
24 extern "C" {
25 #endif
26 
27 /* MSVC DLL import/export. */
28 #ifdef _MSC_VER
29   #ifdef _CINDEX_LIB_
30     #define CINDEX_LINKAGE __declspec(dllexport)
31   #else
32     #define CINDEX_LINKAGE __declspec(dllimport)
33   #endif
34 #else
35   #define CINDEX_LINKAGE
36 #endif
37 
38 /** \defgroup CINDEX libclang: C Interface to Clang
39  *
40  * The C Interface to Clang provides a relatively small API that exposes
41  * facilities for parsing source code into an abstract syntax tree (AST),
42  * loading already-parsed ASTs, traversing the AST, associating
43  * physical source locations with elements within the AST, and other
44  * facilities that support Clang-based development tools.
45  *
46  * This C interface to Clang will never provide all of the information
47  * representation stored in Clang's C++ AST, nor should it: the intent is to
48  * maintain an API that is relatively stable from one release to the next,
49  * providing only the basic functionality needed to support development tools.
50  *
51  * To avoid namespace pollution, data types are prefixed with "CX" and
52  * functions are prefixed with "clang_".
53  *
54  * @{
55  */
56 
57 /**
58  * \brief An "index" that consists of a set of translation units that would
59  * typically be linked together into an executable or library.
60  */
61 typedef void *CXIndex;
62 
63 /**
64  * \brief A single translation unit, which resides in an index.
65  */
66 typedef struct CXTranslationUnitImpl *CXTranslationUnit;
67 
68 /**
69  * \brief Opaque pointer representing client data that will be passed through
70  * to various callbacks and visitors.
71  */
72 typedef void *CXClientData;
73 
74 /**
75  * \brief Provides the contents of a file that has not yet been saved to disk.
76  *
77  * Each CXUnsavedFile instance provides the name of a file on the
78  * system along with the current contents of that file that have not
79  * yet been saved to disk.
80  */
81 struct CXUnsavedFile {
82   /**
83    * \brief The file whose contents have not yet been saved.
84    *
85    * This file must already exist in the file system.
86    */
87   const char *Filename;
88 
89   /**
90    * \brief A buffer containing the unsaved contents of this file.
91    */
92   const char *Contents;
93 
94   /**
95    * \brief The length of the unsaved contents of this buffer.
96    */
97   unsigned long Length;
98 };
99 
100 /**
101  * \brief Describes the availability of a particular entity, which indicates
102  * whether the use of this entity will result in a warning or error due to
103  * it being deprecated or unavailable.
104  */
105 enum CXAvailabilityKind {
106   /**
107    * \brief The entity is available.
108    */
109   CXAvailability_Available,
110   /**
111    * \brief The entity is available, but has been deprecated (and its use is
112    * not recommended).
113    */
114   CXAvailability_Deprecated,
115   /**
116    * \brief The entity is not available; any use of it will be an error.
117    */
118   CXAvailability_NotAvailable
119 };
120 
121 /**
122  * \defgroup CINDEX_STRING String manipulation routines
123  *
124  * @{
125  */
126 
127 /**
128  * \brief A character string.
129  *
130  * The \c CXString type is used to return strings from the interface when
131  * the ownership of that string might different from one call to the next.
132  * Use \c clang_getCString() to retrieve the string data and, once finished
133  * with the string data, call \c clang_disposeString() to free the string.
134  */
135 typedef struct {
136   void *data;
137   unsigned private_flags;
138 } CXString;
139 
140 /**
141  * \brief Retrieve the character data associated with the given string.
142  */
143 CINDEX_LINKAGE const char *clang_getCString(CXString string);
144 
145 /**
146  * \brief Free the given string,
147  */
148 CINDEX_LINKAGE void clang_disposeString(CXString string);
149 
150 /**
151  * @}
152  */
153 
154 /**
155  * \brief clang_createIndex() provides a shared context for creating
156  * translation units. It provides two options:
157  *
158  * - excludeDeclarationsFromPCH: When non-zero, allows enumeration of "local"
159  * declarations (when loading any new translation units). A "local" declaration
160  * is one that belongs in the translation unit itself and not in a precompiled
161  * header that was used by the translation unit. If zero, all declarations
162  * will be enumerated.
163  *
164  * Here is an example:
165  *
166  *   // excludeDeclsFromPCH = 1, displayDiagnostics=1
167  *   Idx = clang_createIndex(1, 1);
168  *
169  *   // IndexTest.pch was produced with the following command:
170  *   // "clang -x c IndexTest.h -emit-ast -o IndexTest.pch"
171  *   TU = clang_createTranslationUnit(Idx, "IndexTest.pch");
172  *
173  *   // This will load all the symbols from 'IndexTest.pch'
174  *   clang_visitChildren(clang_getTranslationUnitCursor(TU),
175  *                       TranslationUnitVisitor, 0);
176  *   clang_disposeTranslationUnit(TU);
177  *
178  *   // This will load all the symbols from 'IndexTest.c', excluding symbols
179  *   // from 'IndexTest.pch'.
180  *   char *args[] = { "-Xclang", "-include-pch=IndexTest.pch" };
181  *   TU = clang_createTranslationUnitFromSourceFile(Idx, "IndexTest.c", 2, args,
182  *                                                  0, 0);
183  *   clang_visitChildren(clang_getTranslationUnitCursor(TU),
184  *                       TranslationUnitVisitor, 0);
185  *   clang_disposeTranslationUnit(TU);
186  *
187  * This process of creating the 'pch', loading it separately, and using it (via
188  * -include-pch) allows 'excludeDeclsFromPCH' to remove redundant callbacks
189  * (which gives the indexer the same performance benefit as the compiler).
190  */
191 CINDEX_LINKAGE CXIndex clang_createIndex(int excludeDeclarationsFromPCH,
192                                          int displayDiagnostics);
193 
194 /**
195  * \brief Destroy the given index.
196  *
197  * The index must not be destroyed until all of the translation units created
198  * within that index have been destroyed.
199  */
200 CINDEX_LINKAGE void clang_disposeIndex(CXIndex index);
201 
202 /**
203  * \defgroup CINDEX_FILES File manipulation routines
204  *
205  * @{
206  */
207 
208 /**
209  * \brief A particular source file that is part of a translation unit.
210  */
211 typedef void *CXFile;
212 
213 
214 /**
215  * \brief Retrieve the complete file and path name of the given file.
216  */
217 CINDEX_LINKAGE CXString clang_getFileName(CXFile SFile);
218 
219 /**
220  * \brief Retrieve the last modification time of the given file.
221  */
222 CINDEX_LINKAGE time_t clang_getFileTime(CXFile SFile);
223 
224 /**
225  * \brief Determine whether the given header is guarded against
226  * multiple inclusions, either with the conventional
227  * #ifndef/#define/#endif macro guards or with #pragma once.
228  */
229 CINDEX_LINKAGE unsigned
230 clang_isFileMultipleIncludeGuarded(CXTranslationUnit tu, CXFile file);
231 
232 /**
233  * \brief Retrieve a file handle within the given translation unit.
234  *
235  * \param tu the translation unit
236  *
237  * \param file_name the name of the file.
238  *
239  * \returns the file handle for the named file in the translation unit \p tu,
240  * or a NULL file handle if the file was not a part of this translation unit.
241  */
242 CINDEX_LINKAGE CXFile clang_getFile(CXTranslationUnit tu,
243                                     const char *file_name);
244 
245 /**
246  * @}
247  */
248 
249 /**
250  * \defgroup CINDEX_LOCATIONS Physical source locations
251  *
252  * Clang represents physical source locations in its abstract syntax tree in
253  * great detail, with file, line, and column information for the majority of
254  * the tokens parsed in the source code. These data types and functions are
255  * used to represent source location information, either for a particular
256  * point in the program or for a range of points in the program, and extract
257  * specific location information from those data types.
258  *
259  * @{
260  */
261 
262 /**
263  * \brief Identifies a specific source location within a translation
264  * unit.
265  *
266  * Use clang_getInstantiationLocation() or clang_getSpellingLocation()
267  * to map a source location to a particular file, line, and column.
268  */
269 typedef struct {
270   void *ptr_data[2];
271   unsigned int_data;
272 } CXSourceLocation;
273 
274 /**
275  * \brief Identifies a half-open character range in the source code.
276  *
277  * Use clang_getRangeStart() and clang_getRangeEnd() to retrieve the
278  * starting and end locations from a source range, respectively.
279  */
280 typedef struct {
281   void *ptr_data[2];
282   unsigned begin_int_data;
283   unsigned end_int_data;
284 } CXSourceRange;
285 
286 /**
287  * \brief Retrieve a NULL (invalid) source location.
288  */
289 CINDEX_LINKAGE CXSourceLocation clang_getNullLocation();
290 
291 /**
292  * \determine Determine whether two source locations, which must refer into
293  * the same translation unit, refer to exactly the same point in the source
294  * code.
295  *
296  * \returns non-zero if the source locations refer to the same location, zero
297  * if they refer to different locations.
298  */
299 CINDEX_LINKAGE unsigned clang_equalLocations(CXSourceLocation loc1,
300                                              CXSourceLocation loc2);
301 
302 /**
303  * \brief Retrieves the source location associated with a given file/line/column
304  * in a particular translation unit.
305  */
306 CINDEX_LINKAGE CXSourceLocation clang_getLocation(CXTranslationUnit tu,
307                                                   CXFile file,
308                                                   unsigned line,
309                                                   unsigned column);
310 /**
311  * \brief Retrieves the source location associated with a given character offset
312  * in a particular translation unit.
313  */
314 CINDEX_LINKAGE CXSourceLocation clang_getLocationForOffset(CXTranslationUnit tu,
315                                                            CXFile file,
316                                                            unsigned offset);
317 
318 /**
319  * \brief Retrieve a NULL (invalid) source range.
320  */
321 CINDEX_LINKAGE CXSourceRange clang_getNullRange();
322 
323 /**
324  * \brief Retrieve a source range given the beginning and ending source
325  * locations.
326  */
327 CINDEX_LINKAGE CXSourceRange clang_getRange(CXSourceLocation begin,
328                                             CXSourceLocation end);
329 
330 /**
331  * \brief Retrieve the file, line, column, and offset represented by
332  * the given source location.
333  *
334  * If the location refers into a macro instantiation, retrieves the
335  * location of the macro instantiation.
336  *
337  * \param location the location within a source file that will be decomposed
338  * into its parts.
339  *
340  * \param file [out] if non-NULL, will be set to the file to which the given
341  * source location points.
342  *
343  * \param line [out] if non-NULL, will be set to the line to which the given
344  * source location points.
345  *
346  * \param column [out] if non-NULL, will be set to the column to which the given
347  * source location points.
348  *
349  * \param offset [out] if non-NULL, will be set to the offset into the
350  * buffer to which the given source location points.
351  */
352 CINDEX_LINKAGE void clang_getInstantiationLocation(CXSourceLocation location,
353                                                    CXFile *file,
354                                                    unsigned *line,
355                                                    unsigned *column,
356                                                    unsigned *offset);
357 
358 /**
359  * \brief Retrieve the file, line, column, and offset represented by
360  * the given source location.
361  *
362  * If the location refers into a macro instantiation, return where the
363  * location was originally spelled in the source file.
364  *
365  * \param location the location within a source file that will be decomposed
366  * into its parts.
367  *
368  * \param file [out] if non-NULL, will be set to the file to which the given
369  * source location points.
370  *
371  * \param line [out] if non-NULL, will be set to the line to which the given
372  * source location points.
373  *
374  * \param column [out] if non-NULL, will be set to the column to which the given
375  * source location points.
376  *
377  * \param offset [out] if non-NULL, will be set to the offset into the
378  * buffer to which the given source location points.
379  */
380 CINDEX_LINKAGE void clang_getSpellingLocation(CXSourceLocation location,
381                                               CXFile *file,
382                                               unsigned *line,
383                                               unsigned *column,
384                                               unsigned *offset);
385 
386 /**
387  * \brief Retrieve a source location representing the first character within a
388  * source range.
389  */
390 CINDEX_LINKAGE CXSourceLocation clang_getRangeStart(CXSourceRange range);
391 
392 /**
393  * \brief Retrieve a source location representing the last character within a
394  * source range.
395  */
396 CINDEX_LINKAGE CXSourceLocation clang_getRangeEnd(CXSourceRange range);
397 
398 /**
399  * @}
400  */
401 
402 /**
403  * \defgroup CINDEX_DIAG Diagnostic reporting
404  *
405  * @{
406  */
407 
408 /**
409  * \brief Describes the severity of a particular diagnostic.
410  */
411 enum CXDiagnosticSeverity {
412   /**
413    * \brief A diagnostic that has been suppressed, e.g., by a command-line
414    * option.
415    */
416   CXDiagnostic_Ignored = 0,
417 
418   /**
419    * \brief This diagnostic is a note that should be attached to the
420    * previous (non-note) diagnostic.
421    */
422   CXDiagnostic_Note    = 1,
423 
424   /**
425    * \brief This diagnostic indicates suspicious code that may not be
426    * wrong.
427    */
428   CXDiagnostic_Warning = 2,
429 
430   /**
431    * \brief This diagnostic indicates that the code is ill-formed.
432    */
433   CXDiagnostic_Error   = 3,
434 
435   /**
436    * \brief This diagnostic indicates that the code is ill-formed such
437    * that future parser recovery is unlikely to produce useful
438    * results.
439    */
440   CXDiagnostic_Fatal   = 4
441 };
442 
443 /**
444  * \brief A single diagnostic, containing the diagnostic's severity,
445  * location, text, source ranges, and fix-it hints.
446  */
447 typedef void *CXDiagnostic;
448 
449 /**
450  * \brief Determine the number of diagnostics produced for the given
451  * translation unit.
452  */
453 CINDEX_LINKAGE unsigned clang_getNumDiagnostics(CXTranslationUnit Unit);
454 
455 /**
456  * \brief Retrieve a diagnostic associated with the given translation unit.
457  *
458  * \param Unit the translation unit to query.
459  * \param Index the zero-based diagnostic number to retrieve.
460  *
461  * \returns the requested diagnostic. This diagnostic must be freed
462  * via a call to \c clang_disposeDiagnostic().
463  */
464 CINDEX_LINKAGE CXDiagnostic clang_getDiagnostic(CXTranslationUnit Unit,
465                                                 unsigned Index);
466 
467 /**
468  * \brief Destroy a diagnostic.
469  */
470 CINDEX_LINKAGE void clang_disposeDiagnostic(CXDiagnostic Diagnostic);
471 
472 /**
473  * \brief Options to control the display of diagnostics.
474  *
475  * The values in this enum are meant to be combined to customize the
476  * behavior of \c clang_displayDiagnostic().
477  */
478 enum CXDiagnosticDisplayOptions {
479   /**
480    * \brief Display the source-location information where the
481    * diagnostic was located.
482    *
483    * When set, diagnostics will be prefixed by the file, line, and
484    * (optionally) column to which the diagnostic refers. For example,
485    *
486    * \code
487    * test.c:28: warning: extra tokens at end of #endif directive
488    * \endcode
489    *
490    * This option corresponds to the clang flag \c -fshow-source-location.
491    */
492   CXDiagnostic_DisplaySourceLocation = 0x01,
493 
494   /**
495    * \brief If displaying the source-location information of the
496    * diagnostic, also include the column number.
497    *
498    * This option corresponds to the clang flag \c -fshow-column.
499    */
500   CXDiagnostic_DisplayColumn = 0x02,
501 
502   /**
503    * \brief If displaying the source-location information of the
504    * diagnostic, also include information about source ranges in a
505    * machine-parsable format.
506    *
507    * This option corresponds to the clang flag
508    * \c -fdiagnostics-print-source-range-info.
509    */
510   CXDiagnostic_DisplaySourceRanges = 0x04,
511 
512   /**
513    * \brief Display the option name associated with this diagnostic, if any.
514    *
515    * The option name displayed (e.g., -Wconversion) will be placed in brackets
516    * after the diagnostic text. This option corresponds to the clang flag
517    * \c -fdiagnostics-show-option.
518    */
519   CXDiagnostic_DisplayOption = 0x08,
520 
521   /**
522    * \brief Display the category number associated with this diagnostic, if any.
523    *
524    * The category number is displayed within brackets after the diagnostic text.
525    * This option corresponds to the clang flag
526    * \c -fdiagnostics-show-category=id.
527    */
528   CXDiagnostic_DisplayCategoryId = 0x10,
529 
530   /**
531    * \brief Display the category name associated with this diagnostic, if any.
532    *
533    * The category name is displayed within brackets after the diagnostic text.
534    * This option corresponds to the clang flag
535    * \c -fdiagnostics-show-category=name.
536    */
537   CXDiagnostic_DisplayCategoryName = 0x20
538 };
539 
540 /**
541  * \brief Format the given diagnostic in a manner that is suitable for display.
542  *
543  * This routine will format the given diagnostic to a string, rendering
544  * the diagnostic according to the various options given. The
545  * \c clang_defaultDiagnosticDisplayOptions() function returns the set of
546  * options that most closely mimics the behavior of the clang compiler.
547  *
548  * \param Diagnostic The diagnostic to print.
549  *
550  * \param Options A set of options that control the diagnostic display,
551  * created by combining \c CXDiagnosticDisplayOptions values.
552  *
553  * \returns A new string containing for formatted diagnostic.
554  */
555 CINDEX_LINKAGE CXString clang_formatDiagnostic(CXDiagnostic Diagnostic,
556                                                unsigned Options);
557 
558 /**
559  * \brief Retrieve the set of display options most similar to the
560  * default behavior of the clang compiler.
561  *
562  * \returns A set of display options suitable for use with \c
563  * clang_displayDiagnostic().
564  */
565 CINDEX_LINKAGE unsigned clang_defaultDiagnosticDisplayOptions(void);
566 
567 /**
568  * \brief Determine the severity of the given diagnostic.
569  */
570 CINDEX_LINKAGE enum CXDiagnosticSeverity
571 clang_getDiagnosticSeverity(CXDiagnostic);
572 
573 /**
574  * \brief Retrieve the source location of the given diagnostic.
575  *
576  * This location is where Clang would print the caret ('^') when
577  * displaying the diagnostic on the command line.
578  */
579 CINDEX_LINKAGE CXSourceLocation clang_getDiagnosticLocation(CXDiagnostic);
580 
581 /**
582  * \brief Retrieve the text of the given diagnostic.
583  */
584 CINDEX_LINKAGE CXString clang_getDiagnosticSpelling(CXDiagnostic);
585 
586 /**
587  * \brief Retrieve the name of the command-line option that enabled this
588  * diagnostic.
589  *
590  * \param Diag The diagnostic to be queried.
591  *
592  * \param Disable If non-NULL, will be set to the option that disables this
593  * diagnostic (if any).
594  *
595  * \returns A string that contains the command-line option used to enable this
596  * warning, such as "-Wconversion" or "-pedantic".
597  */
598 CINDEX_LINKAGE CXString clang_getDiagnosticOption(CXDiagnostic Diag,
599                                                   CXString *Disable);
600 
601 /**
602  * \brief Retrieve the category number for this diagnostic.
603  *
604  * Diagnostics can be categorized into groups along with other, related
605  * diagnostics (e.g., diagnostics under the same warning flag). This routine
606  * retrieves the category number for the given diagnostic.
607  *
608  * \returns The number of the category that contains this diagnostic, or zero
609  * if this diagnostic is uncategorized.
610  */
611 CINDEX_LINKAGE unsigned clang_getDiagnosticCategory(CXDiagnostic);
612 
613 /**
614  * \brief Retrieve the name of a particular diagnostic category.
615  *
616  * \param Category A diagnostic category number, as returned by
617  * \c clang_getDiagnosticCategory().
618  *
619  * \returns The name of the given diagnostic category.
620  */
621 CINDEX_LINKAGE CXString clang_getDiagnosticCategoryName(unsigned Category);
622 
623 /**
624  * \brief Determine the number of source ranges associated with the given
625  * diagnostic.
626  */
627 CINDEX_LINKAGE unsigned clang_getDiagnosticNumRanges(CXDiagnostic);
628 
629 /**
630  * \brief Retrieve a source range associated with the diagnostic.
631  *
632  * A diagnostic's source ranges highlight important elements in the source
633  * code. On the command line, Clang displays source ranges by
634  * underlining them with '~' characters.
635  *
636  * \param Diagnostic the diagnostic whose range is being extracted.
637  *
638  * \param Range the zero-based index specifying which range to
639  *
640  * \returns the requested source range.
641  */
642 CINDEX_LINKAGE CXSourceRange clang_getDiagnosticRange(CXDiagnostic Diagnostic,
643                                                       unsigned Range);
644 
645 /**
646  * \brief Determine the number of fix-it hints associated with the
647  * given diagnostic.
648  */
649 CINDEX_LINKAGE unsigned clang_getDiagnosticNumFixIts(CXDiagnostic Diagnostic);
650 
651 /**
652  * \brief Retrieve the replacement information for a given fix-it.
653  *
654  * Fix-its are described in terms of a source range whose contents
655  * should be replaced by a string. This approach generalizes over
656  * three kinds of operations: removal of source code (the range covers
657  * the code to be removed and the replacement string is empty),
658  * replacement of source code (the range covers the code to be
659  * replaced and the replacement string provides the new code), and
660  * insertion (both the start and end of the range point at the
661  * insertion location, and the replacement string provides the text to
662  * insert).
663  *
664  * \param Diagnostic The diagnostic whose fix-its are being queried.
665  *
666  * \param FixIt The zero-based index of the fix-it.
667  *
668  * \param ReplacementRange The source range whose contents will be
669  * replaced with the returned replacement string. Note that source
670  * ranges are half-open ranges [a, b), so the source code should be
671  * replaced from a and up to (but not including) b.
672  *
673  * \returns A string containing text that should be replace the source
674  * code indicated by the \c ReplacementRange.
675  */
676 CINDEX_LINKAGE CXString clang_getDiagnosticFixIt(CXDiagnostic Diagnostic,
677                                                  unsigned FixIt,
678                                                CXSourceRange *ReplacementRange);
679 
680 /**
681  * @}
682  */
683 
684 /**
685  * \defgroup CINDEX_TRANSLATION_UNIT Translation unit manipulation
686  *
687  * The routines in this group provide the ability to create and destroy
688  * translation units from files, either by parsing the contents of the files or
689  * by reading in a serialized representation of a translation unit.
690  *
691  * @{
692  */
693 
694 /**
695  * \brief Get the original translation unit source file name.
696  */
697 CINDEX_LINKAGE CXString
698 clang_getTranslationUnitSpelling(CXTranslationUnit CTUnit);
699 
700 /**
701  * \brief Return the CXTranslationUnit for a given source file and the provided
702  * command line arguments one would pass to the compiler.
703  *
704  * Note: The 'source_filename' argument is optional.  If the caller provides a
705  * NULL pointer, the name of the source file is expected to reside in the
706  * specified command line arguments.
707  *
708  * Note: When encountered in 'clang_command_line_args', the following options
709  * are ignored:
710  *
711  *   '-c'
712  *   '-emit-ast'
713  *   '-fsyntax-only'
714  *   '-o <output file>'  (both '-o' and '<output file>' are ignored)
715  *
716  * \param CIdx The index object with which the translation unit will be
717  * associated.
718  *
719  * \param source_filename - The name of the source file to load, or NULL if the
720  * source file is included in \p clang_command_line_args.
721  *
722  * \param num_clang_command_line_args The number of command-line arguments in
723  * \p clang_command_line_args.
724  *
725  * \param clang_command_line_args The command-line arguments that would be
726  * passed to the \c clang executable if it were being invoked out-of-process.
727  * These command-line options will be parsed and will affect how the translation
728  * unit is parsed. Note that the following options are ignored: '-c',
729  * '-emit-ast', '-fsyntex-only' (which is the default), and '-o <output file>'.
730  *
731  * \param num_unsaved_files the number of unsaved file entries in \p
732  * unsaved_files.
733  *
734  * \param unsaved_files the files that have not yet been saved to disk
735  * but may be required for code completion, including the contents of
736  * those files.  The contents and name of these files (as specified by
737  * CXUnsavedFile) are copied when necessary, so the client only needs to
738  * guarantee their validity until the call to this function returns.
739  */
740 CINDEX_LINKAGE CXTranslationUnit clang_createTranslationUnitFromSourceFile(
741                                          CXIndex CIdx,
742                                          const char *source_filename,
743                                          int num_clang_command_line_args,
744                                    const char * const *clang_command_line_args,
745                                          unsigned num_unsaved_files,
746                                          struct CXUnsavedFile *unsaved_files);
747 
748 /**
749  * \brief Create a translation unit from an AST file (-emit-ast).
750  */
751 CINDEX_LINKAGE CXTranslationUnit clang_createTranslationUnit(CXIndex,
752                                              const char *ast_filename);
753 
754 /**
755  * \brief Flags that control the creation of translation units.
756  *
757  * The enumerators in this enumeration type are meant to be bitwise
758  * ORed together to specify which options should be used when
759  * constructing the translation unit.
760  */
761 enum CXTranslationUnit_Flags {
762   /**
763    * \brief Used to indicate that no special translation-unit options are
764    * needed.
765    */
766   CXTranslationUnit_None = 0x0,
767 
768   /**
769    * \brief Used to indicate that the parser should construct a "detailed"
770    * preprocessing record, including all macro definitions and instantiations.
771    *
772    * Constructing a detailed preprocessing record requires more memory
773    * and time to parse, since the information contained in the record
774    * is usually not retained. However, it can be useful for
775    * applications that require more detailed information about the
776    * behavior of the preprocessor.
777    */
778   CXTranslationUnit_DetailedPreprocessingRecord = 0x01,
779 
780   /**
781    * \brief Used to indicate that the translation unit is incomplete.
782    *
783    * When a translation unit is considered "incomplete", semantic
784    * analysis that is typically performed at the end of the
785    * translation unit will be suppressed. For example, this suppresses
786    * the completion of tentative declarations in C and of
787    * instantiation of implicitly-instantiation function templates in
788    * C++. This option is typically used when parsing a header with the
789    * intent of producing a precompiled header.
790    */
791   CXTranslationUnit_Incomplete = 0x02,
792 
793   /**
794    * \brief Used to indicate that the translation unit should be built with an
795    * implicit precompiled header for the preamble.
796    *
797    * An implicit precompiled header is used as an optimization when a
798    * particular translation unit is likely to be reparsed many times
799    * when the sources aren't changing that often. In this case, an
800    * implicit precompiled header will be built containing all of the
801    * initial includes at the top of the main file (what we refer to as
802    * the "preamble" of the file). In subsequent parses, if the
803    * preamble or the files in it have not changed, \c
804    * clang_reparseTranslationUnit() will re-use the implicit
805    * precompiled header to improve parsing performance.
806    */
807   CXTranslationUnit_PrecompiledPreamble = 0x04,
808 
809   /**
810    * \brief Used to indicate that the translation unit should cache some
811    * code-completion results with each reparse of the source file.
812    *
813    * Caching of code-completion results is a performance optimization that
814    * introduces some overhead to reparsing but improves the performance of
815    * code-completion operations.
816    */
817   CXTranslationUnit_CacheCompletionResults = 0x08,
818   /**
819    * \brief Enable precompiled preambles in C++.
820    *
821    * Note: this is a *temporary* option that is available only while
822    * we are testing C++ precompiled preamble support.
823    */
824   CXTranslationUnit_CXXPrecompiledPreamble = 0x10,
825 
826   /**
827    * \brief Enabled chained precompiled preambles in C++.
828    *
829    * Note: this is a *temporary* option that is available only while
830    * we are testing C++ precompiled preamble support.
831    */
832   CXTranslationUnit_CXXChainedPCH = 0x20,
833 
834   /**
835    * \brief Used to indicate that the "detailed" preprocessing record,
836    * if requested, should also contain nested macro expansions.
837    *
838    * Nested macro expansions (i.e., macro expansions that occur
839    * inside another macro expansion) can, in some code bases, require
840    * a large amount of storage to due preprocessor metaprogramming. Moreover,
841    * its fairly rare that this information is useful for libclang clients.
842    */
843   CXTranslationUnit_NestedMacroExpansions = 0x40,
844 
845   /**
846    * \brief Legacy name to indicate that the "detailed" preprocessing record,
847    * if requested, should contain nested macro expansions.
848    *
849    * \see CXTranslationUnit_NestedMacroExpansions for the current name for this
850    * value, and its semantics. This is just an alias.
851    */
852   CXTranslationUnit_NestedMacroInstantiations =
853     CXTranslationUnit_NestedMacroExpansions
854 };
855 
856 /**
857  * \brief Returns the set of flags that is suitable for parsing a translation
858  * unit that is being edited.
859  *
860  * The set of flags returned provide options for \c clang_parseTranslationUnit()
861  * to indicate that the translation unit is likely to be reparsed many times,
862  * either explicitly (via \c clang_reparseTranslationUnit()) or implicitly
863  * (e.g., by code completion (\c clang_codeCompletionAt())). The returned flag
864  * set contains an unspecified set of optimizations (e.g., the precompiled
865  * preamble) geared toward improving the performance of these routines. The
866  * set of optimizations enabled may change from one version to the next.
867  */
868 CINDEX_LINKAGE unsigned clang_defaultEditingTranslationUnitOptions(void);
869 
870 /**
871  * \brief Parse the given source file and the translation unit corresponding
872  * to that file.
873  *
874  * This routine is the main entry point for the Clang C API, providing the
875  * ability to parse a source file into a translation unit that can then be
876  * queried by other functions in the API. This routine accepts a set of
877  * command-line arguments so that the compilation can be configured in the same
878  * way that the compiler is configured on the command line.
879  *
880  * \param CIdx The index object with which the translation unit will be
881  * associated.
882  *
883  * \param source_filename The name of the source file to load, or NULL if the
884  * source file is included in \p command_line_args.
885  *
886  * \param command_line_args The command-line arguments that would be
887  * passed to the \c clang executable if it were being invoked out-of-process.
888  * These command-line options will be parsed and will affect how the translation
889  * unit is parsed. Note that the following options are ignored: '-c',
890  * '-emit-ast', '-fsyntex-only' (which is the default), and '-o <output file>'.
891  *
892  * \param num_command_line_args The number of command-line arguments in
893  * \p command_line_args.
894  *
895  * \param unsaved_files the files that have not yet been saved to disk
896  * but may be required for parsing, including the contents of
897  * those files.  The contents and name of these files (as specified by
898  * CXUnsavedFile) are copied when necessary, so the client only needs to
899  * guarantee their validity until the call to this function returns.
900  *
901  * \param num_unsaved_files the number of unsaved file entries in \p
902  * unsaved_files.
903  *
904  * \param options A bitmask of options that affects how the translation unit
905  * is managed but not its compilation. This should be a bitwise OR of the
906  * CXTranslationUnit_XXX flags.
907  *
908  * \returns A new translation unit describing the parsed code and containing
909  * any diagnostics produced by the compiler. If there is a failure from which
910  * the compiler cannot recover, returns NULL.
911  */
912 CINDEX_LINKAGE CXTranslationUnit clang_parseTranslationUnit(CXIndex CIdx,
913                                                     const char *source_filename,
914                                          const char * const *command_line_args,
915                                                       int num_command_line_args,
916                                             struct CXUnsavedFile *unsaved_files,
917                                                      unsigned num_unsaved_files,
918                                                             unsigned options);
919 
920 /**
921  * \brief Flags that control how translation units are saved.
922  *
923  * The enumerators in this enumeration type are meant to be bitwise
924  * ORed together to specify which options should be used when
925  * saving the translation unit.
926  */
927 enum CXSaveTranslationUnit_Flags {
928   /**
929    * \brief Used to indicate that no special saving options are needed.
930    */
931   CXSaveTranslationUnit_None = 0x0
932 };
933 
934 /**
935  * \brief Returns the set of flags that is suitable for saving a translation
936  * unit.
937  *
938  * The set of flags returned provide options for
939  * \c clang_saveTranslationUnit() by default. The returned flag
940  * set contains an unspecified set of options that save translation units with
941  * the most commonly-requested data.
942  */
943 CINDEX_LINKAGE unsigned clang_defaultSaveOptions(CXTranslationUnit TU);
944 
945 /**
946  * \brief Describes the kind of error that occurred (if any) in a call to
947  * \c clang_saveTranslationUnit().
948  */
949 enum CXSaveError {
950   /**
951    * \brief Indicates that no error occurred while saving a translation unit.
952    */
953   CXSaveError_None = 0,
954 
955   /**
956    * \brief Indicates that an unknown error occurred while attempting to save
957    * the file.
958    *
959    * This error typically indicates that file I/O failed when attempting to
960    * write the file.
961    */
962   CXSaveError_Unknown = 1,
963 
964   /**
965    * \brief Indicates that errors during translation prevented this attempt
966    * to save the translation unit.
967    *
968    * Errors that prevent the translation unit from being saved can be
969    * extracted using \c clang_getNumDiagnostics() and \c clang_getDiagnostic().
970    */
971   CXSaveError_TranslationErrors = 2,
972 
973   /**
974    * \brief Indicates that the translation unit to be saved was somehow
975    * invalid (e.g., NULL).
976    */
977   CXSaveError_InvalidTU = 3
978 };
979 
980 /**
981  * \brief Saves a translation unit into a serialized representation of
982  * that translation unit on disk.
983  *
984  * Any translation unit that was parsed without error can be saved
985  * into a file. The translation unit can then be deserialized into a
986  * new \c CXTranslationUnit with \c clang_createTranslationUnit() or,
987  * if it is an incomplete translation unit that corresponds to a
988  * header, used as a precompiled header when parsing other translation
989  * units.
990  *
991  * \param TU The translation unit to save.
992  *
993  * \param FileName The file to which the translation unit will be saved.
994  *
995  * \param options A bitmask of options that affects how the translation unit
996  * is saved. This should be a bitwise OR of the
997  * CXSaveTranslationUnit_XXX flags.
998  *
999  * \returns A value that will match one of the enumerators of the CXSaveError
1000  * enumeration. Zero (CXSaveError_None) indicates that the translation unit was
1001  * saved successfully, while a non-zero value indicates that a problem occurred.
1002  */
1003 CINDEX_LINKAGE int clang_saveTranslationUnit(CXTranslationUnit TU,
1004                                              const char *FileName,
1005                                              unsigned options);
1006 
1007 /**
1008  * \brief Destroy the specified CXTranslationUnit object.
1009  */
1010 CINDEX_LINKAGE void clang_disposeTranslationUnit(CXTranslationUnit);
1011 
1012 /**
1013  * \brief Flags that control the reparsing of translation units.
1014  *
1015  * The enumerators in this enumeration type are meant to be bitwise
1016  * ORed together to specify which options should be used when
1017  * reparsing the translation unit.
1018  */
1019 enum CXReparse_Flags {
1020   /**
1021    * \brief Used to indicate that no special reparsing options are needed.
1022    */
1023   CXReparse_None = 0x0
1024 };
1025 
1026 /**
1027  * \brief Returns the set of flags that is suitable for reparsing a translation
1028  * unit.
1029  *
1030  * The set of flags returned provide options for
1031  * \c clang_reparseTranslationUnit() by default. The returned flag
1032  * set contains an unspecified set of optimizations geared toward common uses
1033  * of reparsing. The set of optimizations enabled may change from one version
1034  * to the next.
1035  */
1036 CINDEX_LINKAGE unsigned clang_defaultReparseOptions(CXTranslationUnit TU);
1037 
1038 /**
1039  * \brief Reparse the source files that produced this translation unit.
1040  *
1041  * This routine can be used to re-parse the source files that originally
1042  * created the given translation unit, for example because those source files
1043  * have changed (either on disk or as passed via \p unsaved_files). The
1044  * source code will be reparsed with the same command-line options as it
1045  * was originally parsed.
1046  *
1047  * Reparsing a translation unit invalidates all cursors and source locations
1048  * that refer into that translation unit. This makes reparsing a translation
1049  * unit semantically equivalent to destroying the translation unit and then
1050  * creating a new translation unit with the same command-line arguments.
1051  * However, it may be more efficient to reparse a translation
1052  * unit using this routine.
1053  *
1054  * \param TU The translation unit whose contents will be re-parsed. The
1055  * translation unit must originally have been built with
1056  * \c clang_createTranslationUnitFromSourceFile().
1057  *
1058  * \param num_unsaved_files The number of unsaved file entries in \p
1059  * unsaved_files.
1060  *
1061  * \param unsaved_files The files that have not yet been saved to disk
1062  * but may be required for parsing, including the contents of
1063  * those files.  The contents and name of these files (as specified by
1064  * CXUnsavedFile) are copied when necessary, so the client only needs to
1065  * guarantee their validity until the call to this function returns.
1066  *
1067  * \param options A bitset of options composed of the flags in CXReparse_Flags.
1068  * The function \c clang_defaultReparseOptions() produces a default set of
1069  * options recommended for most uses, based on the translation unit.
1070  *
1071  * \returns 0 if the sources could be reparsed. A non-zero value will be
1072  * returned if reparsing was impossible, such that the translation unit is
1073  * invalid. In such cases, the only valid call for \p TU is
1074  * \c clang_disposeTranslationUnit(TU).
1075  */
1076 CINDEX_LINKAGE int clang_reparseTranslationUnit(CXTranslationUnit TU,
1077                                                 unsigned num_unsaved_files,
1078                                           struct CXUnsavedFile *unsaved_files,
1079                                                 unsigned options);
1080 
1081 /**
1082   * \brief Categorizes how memory is being used by a translation unit.
1083   */
1084 enum CXTUResourceUsageKind {
1085   CXTUResourceUsage_AST = 1,
1086   CXTUResourceUsage_Identifiers = 2,
1087   CXTUResourceUsage_Selectors = 3,
1088   CXTUResourceUsage_GlobalCompletionResults = 4,
1089   CXTUResourceUsage_SourceManagerContentCache = 5,
1090   CXTUResourceUsage_AST_SideTables = 6,
1091   CXTUResourceUsage_SourceManager_Membuffer_Malloc = 7,
1092   CXTUResourceUsage_SourceManager_Membuffer_MMap = 8,
1093   CXTUResourceUsage_ExternalASTSource_Membuffer_Malloc = 9,
1094   CXTUResourceUsage_ExternalASTSource_Membuffer_MMap = 10,
1095   CXTUResourceUsage_Preprocessor = 11,
1096   CXTUResourceUsage_PreprocessingRecord = 12,
1097   CXTUResourceUsage_MEMORY_IN_BYTES_BEGIN = CXTUResourceUsage_AST,
1098   CXTUResourceUsage_MEMORY_IN_BYTES_END =
1099     CXTUResourceUsage_PreprocessingRecord,
1100 
1101   CXTUResourceUsage_First = CXTUResourceUsage_AST,
1102   CXTUResourceUsage_Last = CXTUResourceUsage_PreprocessingRecord
1103 };
1104 
1105 /**
1106   * \brief Returns the human-readable null-terminated C string that represents
1107   *  the name of the memory category.  This string should never be freed.
1108   */
1109 CINDEX_LINKAGE
1110 const char *clang_getTUResourceUsageName(enum CXTUResourceUsageKind kind);
1111 
1112 typedef struct CXTUResourceUsageEntry {
1113   /* \brief The memory usage category. */
1114   enum CXTUResourceUsageKind kind;
1115   /* \brief Amount of resources used.
1116       The units will depend on the resource kind. */
1117   unsigned long amount;
1118 } CXTUResourceUsageEntry;
1119 
1120 /**
1121   * \brief The memory usage of a CXTranslationUnit, broken into categories.
1122   */
1123 typedef struct CXTUResourceUsage {
1124   /* \brief Private data member, used for queries. */
1125   void *data;
1126 
1127   /* \brief The number of entries in the 'entries' array. */
1128   unsigned numEntries;
1129 
1130   /* \brief An array of key-value pairs, representing the breakdown of memory
1131             usage. */
1132   CXTUResourceUsageEntry *entries;
1133 
1134 } CXTUResourceUsage;
1135 
1136 /**
1137   * \brief Return the memory usage of a translation unit.  This object
1138   *  should be released with clang_disposeCXTUResourceUsage().
1139   */
1140 CINDEX_LINKAGE CXTUResourceUsage clang_getCXTUResourceUsage(CXTranslationUnit TU);
1141 
1142 CINDEX_LINKAGE void clang_disposeCXTUResourceUsage(CXTUResourceUsage usage);
1143 
1144 /**
1145  * @}
1146  */
1147 
1148 /**
1149  * \brief Describes the kind of entity that a cursor refers to.
1150  */
1151 enum CXCursorKind {
1152   /* Declarations */
1153   /**
1154    * \brief A declaration whose specific kind is not exposed via this
1155    * interface.
1156    *
1157    * Unexposed declarations have the same operations as any other kind
1158    * of declaration; one can extract their location information,
1159    * spelling, find their definitions, etc. However, the specific kind
1160    * of the declaration is not reported.
1161    */
1162   CXCursor_UnexposedDecl                 = 1,
1163   /** \brief A C or C++ struct. */
1164   CXCursor_StructDecl                    = 2,
1165   /** \brief A C or C++ union. */
1166   CXCursor_UnionDecl                     = 3,
1167   /** \brief A C++ class. */
1168   CXCursor_ClassDecl                     = 4,
1169   /** \brief An enumeration. */
1170   CXCursor_EnumDecl                      = 5,
1171   /**
1172    * \brief A field (in C) or non-static data member (in C++) in a
1173    * struct, union, or C++ class.
1174    */
1175   CXCursor_FieldDecl                     = 6,
1176   /** \brief An enumerator constant. */
1177   CXCursor_EnumConstantDecl              = 7,
1178   /** \brief A function. */
1179   CXCursor_FunctionDecl                  = 8,
1180   /** \brief A variable. */
1181   CXCursor_VarDecl                       = 9,
1182   /** \brief A function or method parameter. */
1183   CXCursor_ParmDecl                      = 10,
1184   /** \brief An Objective-C @interface. */
1185   CXCursor_ObjCInterfaceDecl             = 11,
1186   /** \brief An Objective-C @interface for a category. */
1187   CXCursor_ObjCCategoryDecl              = 12,
1188   /** \brief An Objective-C @protocol declaration. */
1189   CXCursor_ObjCProtocolDecl              = 13,
1190   /** \brief An Objective-C @property declaration. */
1191   CXCursor_ObjCPropertyDecl              = 14,
1192   /** \brief An Objective-C instance variable. */
1193   CXCursor_ObjCIvarDecl                  = 15,
1194   /** \brief An Objective-C instance method. */
1195   CXCursor_ObjCInstanceMethodDecl        = 16,
1196   /** \brief An Objective-C class method. */
1197   CXCursor_ObjCClassMethodDecl           = 17,
1198   /** \brief An Objective-C @implementation. */
1199   CXCursor_ObjCImplementationDecl        = 18,
1200   /** \brief An Objective-C @implementation for a category. */
1201   CXCursor_ObjCCategoryImplDecl          = 19,
1202   /** \brief A typedef */
1203   CXCursor_TypedefDecl                   = 20,
1204   /** \brief A C++ class method. */
1205   CXCursor_CXXMethod                     = 21,
1206   /** \brief A C++ namespace. */
1207   CXCursor_Namespace                     = 22,
1208   /** \brief A linkage specification, e.g. 'extern "C"'. */
1209   CXCursor_LinkageSpec                   = 23,
1210   /** \brief A C++ constructor. */
1211   CXCursor_Constructor                   = 24,
1212   /** \brief A C++ destructor. */
1213   CXCursor_Destructor                    = 25,
1214   /** \brief A C++ conversion function. */
1215   CXCursor_ConversionFunction            = 26,
1216   /** \brief A C++ template type parameter. */
1217   CXCursor_TemplateTypeParameter         = 27,
1218   /** \brief A C++ non-type template parameter. */
1219   CXCursor_NonTypeTemplateParameter      = 28,
1220   /** \brief A C++ template template parameter. */
1221   CXCursor_TemplateTemplateParameter     = 29,
1222   /** \brief A C++ function template. */
1223   CXCursor_FunctionTemplate              = 30,
1224   /** \brief A C++ class template. */
1225   CXCursor_ClassTemplate                 = 31,
1226   /** \brief A C++ class template partial specialization. */
1227   CXCursor_ClassTemplatePartialSpecialization = 32,
1228   /** \brief A C++ namespace alias declaration. */
1229   CXCursor_NamespaceAlias                = 33,
1230   /** \brief A C++ using directive. */
1231   CXCursor_UsingDirective                = 34,
1232   /** \brief A C++ using declaration. */
1233   CXCursor_UsingDeclaration              = 35,
1234   /** \brief A C++ alias declaration */
1235   CXCursor_TypeAliasDecl                 = 36,
1236   /** \brief An Objective-C @synthesize definition. */
1237   CXCursor_ObjCSynthesizeDecl            = 37,
1238   /** \brief An Objective-C @dynamic definition. */
1239   CXCursor_ObjCDynamicDecl               = 38,
1240   CXCursor_FirstDecl                     = CXCursor_UnexposedDecl,
1241   CXCursor_LastDecl                      = CXCursor_ObjCDynamicDecl,
1242 
1243   /* References */
1244   CXCursor_FirstRef                      = 40, /* Decl references */
1245   CXCursor_ObjCSuperClassRef             = 40,
1246   CXCursor_ObjCProtocolRef               = 41,
1247   CXCursor_ObjCClassRef                  = 42,
1248   /**
1249    * \brief A reference to a type declaration.
1250    *
1251    * A type reference occurs anywhere where a type is named but not
1252    * declared. For example, given:
1253    *
1254    * \code
1255    * typedef unsigned size_type;
1256    * size_type size;
1257    * \endcode
1258    *
1259    * The typedef is a declaration of size_type (CXCursor_TypedefDecl),
1260    * while the type of the variable "size" is referenced. The cursor
1261    * referenced by the type of size is the typedef for size_type.
1262    */
1263   CXCursor_TypeRef                       = 43,
1264   CXCursor_CXXBaseSpecifier              = 44,
1265   /**
1266    * \brief A reference to a class template, function template, template
1267    * template parameter, or class template partial specialization.
1268    */
1269   CXCursor_TemplateRef                   = 45,
1270   /**
1271    * \brief A reference to a namespace or namespace alias.
1272    */
1273   CXCursor_NamespaceRef                  = 46,
1274   /**
1275    * \brief A reference to a member of a struct, union, or class that occurs in
1276    * some non-expression context, e.g., a designated initializer.
1277    */
1278   CXCursor_MemberRef                     = 47,
1279   /**
1280    * \brief A reference to a labeled statement.
1281    *
1282    * This cursor kind is used to describe the jump to "start_over" in the
1283    * goto statement in the following example:
1284    *
1285    * \code
1286    *   start_over:
1287    *     ++counter;
1288    *
1289    *     goto start_over;
1290    * \endcode
1291    *
1292    * A label reference cursor refers to a label statement.
1293    */
1294   CXCursor_LabelRef                      = 48,
1295 
1296   /**
1297    * \brief A reference to a set of overloaded functions or function templates
1298    * that has not yet been resolved to a specific function or function template.
1299    *
1300    * An overloaded declaration reference cursor occurs in C++ templates where
1301    * a dependent name refers to a function. For example:
1302    *
1303    * \code
1304    * template<typename T> void swap(T&, T&);
1305    *
1306    * struct X { ... };
1307    * void swap(X&, X&);
1308    *
1309    * template<typename T>
1310    * void reverse(T* first, T* last) {
1311    *   while (first < last - 1) {
1312    *     swap(*first, *--last);
1313    *     ++first;
1314    *   }
1315    * }
1316    *
1317    * struct Y { };
1318    * void swap(Y&, Y&);
1319    * \endcode
1320    *
1321    * Here, the identifier "swap" is associated with an overloaded declaration
1322    * reference. In the template definition, "swap" refers to either of the two
1323    * "swap" functions declared above, so both results will be available. At
1324    * instantiation time, "swap" may also refer to other functions found via
1325    * argument-dependent lookup (e.g., the "swap" function at the end of the
1326    * example).
1327    *
1328    * The functions \c clang_getNumOverloadedDecls() and
1329    * \c clang_getOverloadedDecl() can be used to retrieve the definitions
1330    * referenced by this cursor.
1331    */
1332   CXCursor_OverloadedDeclRef             = 49,
1333 
1334   CXCursor_LastRef                       = CXCursor_OverloadedDeclRef,
1335 
1336   /* Error conditions */
1337   CXCursor_FirstInvalid                  = 70,
1338   CXCursor_InvalidFile                   = 70,
1339   CXCursor_NoDeclFound                   = 71,
1340   CXCursor_NotImplemented                = 72,
1341   CXCursor_InvalidCode                   = 73,
1342   CXCursor_LastInvalid                   = CXCursor_InvalidCode,
1343 
1344   /* Expressions */
1345   CXCursor_FirstExpr                     = 100,
1346 
1347   /**
1348    * \brief An expression whose specific kind is not exposed via this
1349    * interface.
1350    *
1351    * Unexposed expressions have the same operations as any other kind
1352    * of expression; one can extract their location information,
1353    * spelling, children, etc. However, the specific kind of the
1354    * expression is not reported.
1355    */
1356   CXCursor_UnexposedExpr                 = 100,
1357 
1358   /**
1359    * \brief An expression that refers to some value declaration, such
1360    * as a function, varible, or enumerator.
1361    */
1362   CXCursor_DeclRefExpr                   = 101,
1363 
1364   /**
1365    * \brief An expression that refers to a member of a struct, union,
1366    * class, Objective-C class, etc.
1367    */
1368   CXCursor_MemberRefExpr                 = 102,
1369 
1370   /** \brief An expression that calls a function. */
1371   CXCursor_CallExpr                      = 103,
1372 
1373   /** \brief An expression that sends a message to an Objective-C
1374    object or class. */
1375   CXCursor_ObjCMessageExpr               = 104,
1376 
1377   /** \brief An expression that represents a block literal. */
1378   CXCursor_BlockExpr                     = 105,
1379 
1380   CXCursor_LastExpr                      = 105,
1381 
1382   /* Statements */
1383   CXCursor_FirstStmt                     = 200,
1384   /**
1385    * \brief A statement whose specific kind is not exposed via this
1386    * interface.
1387    *
1388    * Unexposed statements have the same operations as any other kind of
1389    * statement; one can extract their location information, spelling,
1390    * children, etc. However, the specific kind of the statement is not
1391    * reported.
1392    */
1393   CXCursor_UnexposedStmt                 = 200,
1394 
1395   /** \brief A labelled statement in a function.
1396    *
1397    * This cursor kind is used to describe the "start_over:" label statement in
1398    * the following example:
1399    *
1400    * \code
1401    *   start_over:
1402    *     ++counter;
1403    * \endcode
1404    *
1405    */
1406   CXCursor_LabelStmt                     = 201,
1407 
1408   CXCursor_LastStmt                      = CXCursor_LabelStmt,
1409 
1410   /**
1411    * \brief Cursor that represents the translation unit itself.
1412    *
1413    * The translation unit cursor exists primarily to act as the root
1414    * cursor for traversing the contents of a translation unit.
1415    */
1416   CXCursor_TranslationUnit               = 300,
1417 
1418   /* Attributes */
1419   CXCursor_FirstAttr                     = 400,
1420   /**
1421    * \brief An attribute whose specific kind is not exposed via this
1422    * interface.
1423    */
1424   CXCursor_UnexposedAttr                 = 400,
1425 
1426   CXCursor_IBActionAttr                  = 401,
1427   CXCursor_IBOutletAttr                  = 402,
1428   CXCursor_IBOutletCollectionAttr        = 403,
1429   CXCursor_LastAttr                      = CXCursor_IBOutletCollectionAttr,
1430 
1431   /* Preprocessing */
1432   CXCursor_PreprocessingDirective        = 500,
1433   CXCursor_MacroDefinition               = 501,
1434   CXCursor_MacroExpansion                = 502,
1435   CXCursor_MacroInstantiation            = CXCursor_MacroExpansion,
1436   CXCursor_InclusionDirective            = 503,
1437   CXCursor_FirstPreprocessing            = CXCursor_PreprocessingDirective,
1438   CXCursor_LastPreprocessing             = CXCursor_InclusionDirective
1439 };
1440 
1441 /**
1442  * \brief A cursor representing some element in the abstract syntax tree for
1443  * a translation unit.
1444  *
1445  * The cursor abstraction unifies the different kinds of entities in a
1446  * program--declaration, statements, expressions, references to declarations,
1447  * etc.--under a single "cursor" abstraction with a common set of operations.
1448  * Common operation for a cursor include: getting the physical location in
1449  * a source file where the cursor points, getting the name associated with a
1450  * cursor, and retrieving cursors for any child nodes of a particular cursor.
1451  *
1452  * Cursors can be produced in two specific ways.
1453  * clang_getTranslationUnitCursor() produces a cursor for a translation unit,
1454  * from which one can use clang_visitChildren() to explore the rest of the
1455  * translation unit. clang_getCursor() maps from a physical source location
1456  * to the entity that resides at that location, allowing one to map from the
1457  * source code into the AST.
1458  */
1459 typedef struct {
1460   enum CXCursorKind kind;
1461   void *data[3];
1462 } CXCursor;
1463 
1464 /**
1465  * \defgroup CINDEX_CURSOR_MANIP Cursor manipulations
1466  *
1467  * @{
1468  */
1469 
1470 /**
1471  * \brief Retrieve the NULL cursor, which represents no entity.
1472  */
1473 CINDEX_LINKAGE CXCursor clang_getNullCursor(void);
1474 
1475 /**
1476  * \brief Retrieve the cursor that represents the given translation unit.
1477  *
1478  * The translation unit cursor can be used to start traversing the
1479  * various declarations within the given translation unit.
1480  */
1481 CINDEX_LINKAGE CXCursor clang_getTranslationUnitCursor(CXTranslationUnit);
1482 
1483 /**
1484  * \brief Determine whether two cursors are equivalent.
1485  */
1486 CINDEX_LINKAGE unsigned clang_equalCursors(CXCursor, CXCursor);
1487 
1488 /**
1489  * \brief Compute a hash value for the given cursor.
1490  */
1491 CINDEX_LINKAGE unsigned clang_hashCursor(CXCursor);
1492 
1493 /**
1494  * \brief Retrieve the kind of the given cursor.
1495  */
1496 CINDEX_LINKAGE enum CXCursorKind clang_getCursorKind(CXCursor);
1497 
1498 /**
1499  * \brief Determine whether the given cursor kind represents a declaration.
1500  */
1501 CINDEX_LINKAGE unsigned clang_isDeclaration(enum CXCursorKind);
1502 
1503 /**
1504  * \brief Determine whether the given cursor kind represents a simple
1505  * reference.
1506  *
1507  * Note that other kinds of cursors (such as expressions) can also refer to
1508  * other cursors. Use clang_getCursorReferenced() to determine whether a
1509  * particular cursor refers to another entity.
1510  */
1511 CINDEX_LINKAGE unsigned clang_isReference(enum CXCursorKind);
1512 
1513 /**
1514  * \brief Determine whether the given cursor kind represents an expression.
1515  */
1516 CINDEX_LINKAGE unsigned clang_isExpression(enum CXCursorKind);
1517 
1518 /**
1519  * \brief Determine whether the given cursor kind represents a statement.
1520  */
1521 CINDEX_LINKAGE unsigned clang_isStatement(enum CXCursorKind);
1522 
1523 /**
1524  * \brief Determine whether the given cursor kind represents an attribute.
1525  */
1526 CINDEX_LINKAGE unsigned clang_isAttribute(enum CXCursorKind);
1527 
1528 /**
1529  * \brief Determine whether the given cursor kind represents an invalid
1530  * cursor.
1531  */
1532 CINDEX_LINKAGE unsigned clang_isInvalid(enum CXCursorKind);
1533 
1534 /**
1535  * \brief Determine whether the given cursor kind represents a translation
1536  * unit.
1537  */
1538 CINDEX_LINKAGE unsigned clang_isTranslationUnit(enum CXCursorKind);
1539 
1540 /***
1541  * \brief Determine whether the given cursor represents a preprocessing
1542  * element, such as a preprocessor directive or macro instantiation.
1543  */
1544 CINDEX_LINKAGE unsigned clang_isPreprocessing(enum CXCursorKind);
1545 
1546 /***
1547  * \brief Determine whether the given cursor represents a currently
1548  *  unexposed piece of the AST (e.g., CXCursor_UnexposedStmt).
1549  */
1550 CINDEX_LINKAGE unsigned clang_isUnexposed(enum CXCursorKind);
1551 
1552 /**
1553  * \brief Describe the linkage of the entity referred to by a cursor.
1554  */
1555 enum CXLinkageKind {
1556   /** \brief This value indicates that no linkage information is available
1557    * for a provided CXCursor. */
1558   CXLinkage_Invalid,
1559   /**
1560    * \brief This is the linkage for variables, parameters, and so on that
1561    *  have automatic storage.  This covers normal (non-extern) local variables.
1562    */
1563   CXLinkage_NoLinkage,
1564   /** \brief This is the linkage for static variables and static functions. */
1565   CXLinkage_Internal,
1566   /** \brief This is the linkage for entities with external linkage that live
1567    * in C++ anonymous namespaces.*/
1568   CXLinkage_UniqueExternal,
1569   /** \brief This is the linkage for entities with true, external linkage. */
1570   CXLinkage_External
1571 };
1572 
1573 /**
1574  * \brief Determine the linkage of the entity referred to by a given cursor.
1575  */
1576 CINDEX_LINKAGE enum CXLinkageKind clang_getCursorLinkage(CXCursor cursor);
1577 
1578 /**
1579  * \brief Determine the availability of the entity that this cursor refers to.
1580  *
1581  * \param cursor The cursor to query.
1582  *
1583  * \returns The availability of the cursor.
1584  */
1585 CINDEX_LINKAGE enum CXAvailabilityKind
1586 clang_getCursorAvailability(CXCursor cursor);
1587 
1588 /**
1589  * \brief Describe the "language" of the entity referred to by a cursor.
1590  */
1591 CINDEX_LINKAGE enum CXLanguageKind {
1592   CXLanguage_Invalid = 0,
1593   CXLanguage_C,
1594   CXLanguage_ObjC,
1595   CXLanguage_CPlusPlus
1596 };
1597 
1598 /**
1599  * \brief Determine the "language" of the entity referred to by a given cursor.
1600  */
1601 CINDEX_LINKAGE enum CXLanguageKind clang_getCursorLanguage(CXCursor cursor);
1602 
1603 
1604 /**
1605  * \brief A fast container representing a set of CXCursors.
1606  */
1607 typedef struct CXCursorSetImpl *CXCursorSet;
1608 
1609 /**
1610  * \brief Creates an empty CXCursorSet.
1611  */
1612 CINDEX_LINKAGE CXCursorSet clang_createCXCursorSet();
1613 
1614 /**
1615  * \brief Disposes a CXCursorSet and releases its associated memory.
1616  */
1617 CINDEX_LINKAGE void clang_disposeCXCursorSet(CXCursorSet cset);
1618 
1619 /**
1620  * \brief Queries a CXCursorSet to see if it contains a specific CXCursor.
1621  *
1622  * \returns non-zero if the set contains the specified cursor.
1623 */
1624 CINDEX_LINKAGE unsigned clang_CXCursorSet_contains(CXCursorSet cset,
1625                                                    CXCursor cursor);
1626 
1627 /**
1628  * \brief Inserts a CXCursor into a CXCursorSet.
1629  *
1630  * \returns zero if the CXCursor was already in the set, and non-zero otherwise.
1631 */
1632 CINDEX_LINKAGE unsigned clang_CXCursorSet_insert(CXCursorSet cset,
1633                                                  CXCursor cursor);
1634 
1635 /**
1636  * \brief Determine the semantic parent of the given cursor.
1637  *
1638  * The semantic parent of a cursor is the cursor that semantically contains
1639  * the given \p cursor. For many declarations, the lexical and semantic parents
1640  * are equivalent (the lexical parent is returned by
1641  * \c clang_getCursorLexicalParent()). They diverge when declarations or
1642  * definitions are provided out-of-line. For example:
1643  *
1644  * \code
1645  * class C {
1646  *  void f();
1647  * };
1648  *
1649  * void C::f() { }
1650  * \endcode
1651  *
1652  * In the out-of-line definition of \c C::f, the semantic parent is the
1653  * the class \c C, of which this function is a member. The lexical parent is
1654  * the place where the declaration actually occurs in the source code; in this
1655  * case, the definition occurs in the translation unit. In general, the
1656  * lexical parent for a given entity can change without affecting the semantics
1657  * of the program, and the lexical parent of different declarations of the
1658  * same entity may be different. Changing the semantic parent of a declaration,
1659  * on the other hand, can have a major impact on semantics, and redeclarations
1660  * of a particular entity should all have the same semantic context.
1661  *
1662  * In the example above, both declarations of \c C::f have \c C as their
1663  * semantic context, while the lexical context of the first \c C::f is \c C
1664  * and the lexical context of the second \c C::f is the translation unit.
1665  *
1666  * For global declarations, the semantic parent is the translation unit.
1667  */
1668 CINDEX_LINKAGE CXCursor clang_getCursorSemanticParent(CXCursor cursor);
1669 
1670 /**
1671  * \brief Determine the lexical parent of the given cursor.
1672  *
1673  * The lexical parent of a cursor is the cursor in which the given \p cursor
1674  * was actually written. For many declarations, the lexical and semantic parents
1675  * are equivalent (the semantic parent is returned by
1676  * \c clang_getCursorSemanticParent()). They diverge when declarations or
1677  * definitions are provided out-of-line. For example:
1678  *
1679  * \code
1680  * class C {
1681  *  void f();
1682  * };
1683  *
1684  * void C::f() { }
1685  * \endcode
1686  *
1687  * In the out-of-line definition of \c C::f, the semantic parent is the
1688  * the class \c C, of which this function is a member. The lexical parent is
1689  * the place where the declaration actually occurs in the source code; in this
1690  * case, the definition occurs in the translation unit. In general, the
1691  * lexical parent for a given entity can change without affecting the semantics
1692  * of the program, and the lexical parent of different declarations of the
1693  * same entity may be different. Changing the semantic parent of a declaration,
1694  * on the other hand, can have a major impact on semantics, and redeclarations
1695  * of a particular entity should all have the same semantic context.
1696  *
1697  * In the example above, both declarations of \c C::f have \c C as their
1698  * semantic context, while the lexical context of the first \c C::f is \c C
1699  * and the lexical context of the second \c C::f is the translation unit.
1700  *
1701  * For declarations written in the global scope, the lexical parent is
1702  * the translation unit.
1703  */
1704 CINDEX_LINKAGE CXCursor clang_getCursorLexicalParent(CXCursor cursor);
1705 
1706 /**
1707  * \brief Determine the set of methods that are overridden by the given
1708  * method.
1709  *
1710  * In both Objective-C and C++, a method (aka virtual member function,
1711  * in C++) can override a virtual method in a base class. For
1712  * Objective-C, a method is said to override any method in the class's
1713  * interface (if we're coming from an implementation), its protocols,
1714  * or its categories, that has the same selector and is of the same
1715  * kind (class or instance). If no such method exists, the search
1716  * continues to the class's superclass, its protocols, and its
1717  * categories, and so on.
1718  *
1719  * For C++, a virtual member function overrides any virtual member
1720  * function with the same signature that occurs in its base
1721  * classes. With multiple inheritance, a virtual member function can
1722  * override several virtual member functions coming from different
1723  * base classes.
1724  *
1725  * In all cases, this function determines the immediate overridden
1726  * method, rather than all of the overridden methods. For example, if
1727  * a method is originally declared in a class A, then overridden in B
1728  * (which in inherits from A) and also in C (which inherited from B),
1729  * then the only overridden method returned from this function when
1730  * invoked on C's method will be B's method. The client may then
1731  * invoke this function again, given the previously-found overridden
1732  * methods, to map out the complete method-override set.
1733  *
1734  * \param cursor A cursor representing an Objective-C or C++
1735  * method. This routine will compute the set of methods that this
1736  * method overrides.
1737  *
1738  * \param overridden A pointer whose pointee will be replaced with a
1739  * pointer to an array of cursors, representing the set of overridden
1740  * methods. If there are no overridden methods, the pointee will be
1741  * set to NULL. The pointee must be freed via a call to
1742  * \c clang_disposeOverriddenCursors().
1743  *
1744  * \param num_overridden A pointer to the number of overridden
1745  * functions, will be set to the number of overridden functions in the
1746  * array pointed to by \p overridden.
1747  */
1748 CINDEX_LINKAGE void clang_getOverriddenCursors(CXCursor cursor,
1749                                                CXCursor **overridden,
1750                                                unsigned *num_overridden);
1751 
1752 /**
1753  * \brief Free the set of overridden cursors returned by \c
1754  * clang_getOverriddenCursors().
1755  */
1756 CINDEX_LINKAGE void clang_disposeOverriddenCursors(CXCursor *overridden);
1757 
1758 /**
1759  * \brief Retrieve the file that is included by the given inclusion directive
1760  * cursor.
1761  */
1762 CINDEX_LINKAGE CXFile clang_getIncludedFile(CXCursor cursor);
1763 
1764 /**
1765  * @}
1766  */
1767 
1768 /**
1769  * \defgroup CINDEX_CURSOR_SOURCE Mapping between cursors and source code
1770  *
1771  * Cursors represent a location within the Abstract Syntax Tree (AST). These
1772  * routines help map between cursors and the physical locations where the
1773  * described entities occur in the source code. The mapping is provided in
1774  * both directions, so one can map from source code to the AST and back.
1775  *
1776  * @{
1777  */
1778 
1779 /**
1780  * \brief Map a source location to the cursor that describes the entity at that
1781  * location in the source code.
1782  *
1783  * clang_getCursor() maps an arbitrary source location within a translation
1784  * unit down to the most specific cursor that describes the entity at that
1785  * location. For example, given an expression \c x + y, invoking
1786  * clang_getCursor() with a source location pointing to "x" will return the
1787  * cursor for "x"; similarly for "y". If the cursor points anywhere between
1788  * "x" or "y" (e.g., on the + or the whitespace around it), clang_getCursor()
1789  * will return a cursor referring to the "+" expression.
1790  *
1791  * \returns a cursor representing the entity at the given source location, or
1792  * a NULL cursor if no such entity can be found.
1793  */
1794 CINDEX_LINKAGE CXCursor clang_getCursor(CXTranslationUnit, CXSourceLocation);
1795 
1796 /**
1797  * \brief Retrieve the physical location of the source constructor referenced
1798  * by the given cursor.
1799  *
1800  * The location of a declaration is typically the location of the name of that
1801  * declaration, where the name of that declaration would occur if it is
1802  * unnamed, or some keyword that introduces that particular declaration.
1803  * The location of a reference is where that reference occurs within the
1804  * source code.
1805  */
1806 CINDEX_LINKAGE CXSourceLocation clang_getCursorLocation(CXCursor);
1807 
1808 /**
1809  * \brief Retrieve the physical extent of the source construct referenced by
1810  * the given cursor.
1811  *
1812  * The extent of a cursor starts with the file/line/column pointing at the
1813  * first character within the source construct that the cursor refers to and
1814  * ends with the last character withinin that source construct. For a
1815  * declaration, the extent covers the declaration itself. For a reference,
1816  * the extent covers the location of the reference (e.g., where the referenced
1817  * entity was actually used).
1818  */
1819 CINDEX_LINKAGE CXSourceRange clang_getCursorExtent(CXCursor);
1820 
1821 /**
1822  * @}
1823  */
1824 
1825 /**
1826  * \defgroup CINDEX_TYPES Type information for CXCursors
1827  *
1828  * @{
1829  */
1830 
1831 /**
1832  * \brief Describes the kind of type
1833  */
1834 enum CXTypeKind {
1835   /**
1836    * \brief Reprents an invalid type (e.g., where no type is available).
1837    */
1838   CXType_Invalid = 0,
1839 
1840   /**
1841    * \brief A type whose specific kind is not exposed via this
1842    * interface.
1843    */
1844   CXType_Unexposed = 1,
1845 
1846   /* Builtin types */
1847   CXType_Void = 2,
1848   CXType_Bool = 3,
1849   CXType_Char_U = 4,
1850   CXType_UChar = 5,
1851   CXType_Char16 = 6,
1852   CXType_Char32 = 7,
1853   CXType_UShort = 8,
1854   CXType_UInt = 9,
1855   CXType_ULong = 10,
1856   CXType_ULongLong = 11,
1857   CXType_UInt128 = 12,
1858   CXType_Char_S = 13,
1859   CXType_SChar = 14,
1860   CXType_WChar = 15,
1861   CXType_Short = 16,
1862   CXType_Int = 17,
1863   CXType_Long = 18,
1864   CXType_LongLong = 19,
1865   CXType_Int128 = 20,
1866   CXType_Float = 21,
1867   CXType_Double = 22,
1868   CXType_LongDouble = 23,
1869   CXType_NullPtr = 24,
1870   CXType_Overload = 25,
1871   CXType_Dependent = 26,
1872   CXType_ObjCId = 27,
1873   CXType_ObjCClass = 28,
1874   CXType_ObjCSel = 29,
1875   CXType_FirstBuiltin = CXType_Void,
1876   CXType_LastBuiltin  = CXType_ObjCSel,
1877 
1878   CXType_Complex = 100,
1879   CXType_Pointer = 101,
1880   CXType_BlockPointer = 102,
1881   CXType_LValueReference = 103,
1882   CXType_RValueReference = 104,
1883   CXType_Record = 105,
1884   CXType_Enum = 106,
1885   CXType_Typedef = 107,
1886   CXType_ObjCInterface = 108,
1887   CXType_ObjCObjectPointer = 109,
1888   CXType_FunctionNoProto = 110,
1889   CXType_FunctionProto = 111
1890 };
1891 
1892 /**
1893  * \brief The type of an element in the abstract syntax tree.
1894  *
1895  */
1896 typedef struct {
1897   enum CXTypeKind kind;
1898   void *data[2];
1899 } CXType;
1900 
1901 /**
1902  * \brief Retrieve the type of a CXCursor (if any).
1903  */
1904 CINDEX_LINKAGE CXType clang_getCursorType(CXCursor C);
1905 
1906 /**
1907  * \determine Determine whether two CXTypes represent the same type.
1908  *
1909  * \returns non-zero if the CXTypes represent the same type and
1910             zero otherwise.
1911  */
1912 CINDEX_LINKAGE unsigned clang_equalTypes(CXType A, CXType B);
1913 
1914 /**
1915  * \brief Return the canonical type for a CXType.
1916  *
1917  * Clang's type system explicitly models typedefs and all the ways
1918  * a specific type can be represented.  The canonical type is the underlying
1919  * type with all the "sugar" removed.  For example, if 'T' is a typedef
1920  * for 'int', the canonical type for 'T' would be 'int'.
1921  */
1922 CINDEX_LINKAGE CXType clang_getCanonicalType(CXType T);
1923 
1924 /**
1925  *  \determine Determine whether a CXType has the "const" qualifier set,
1926  *  without looking through typedefs that may have added "const" at a different level.
1927  */
1928 CINDEX_LINKAGE unsigned clang_isConstQualifiedType(CXType T);
1929 
1930 /**
1931  *  \determine Determine whether a CXType has the "volatile" qualifier set,
1932  *  without looking through typedefs that may have added "volatile" at a different level.
1933  */
1934 CINDEX_LINKAGE unsigned clang_isVolatileQualifiedType(CXType T);
1935 
1936 /**
1937  *  \determine Determine whether a CXType has the "restrict" qualifier set,
1938  *  without looking through typedefs that may have added "restrict" at a different level.
1939  */
1940 CINDEX_LINKAGE unsigned clang_isRestrictQualifiedType(CXType T);
1941 
1942 /**
1943  * \brief For pointer types, returns the type of the pointee.
1944  *
1945  */
1946 CINDEX_LINKAGE CXType clang_getPointeeType(CXType T);
1947 
1948 /**
1949  * \brief Return the cursor for the declaration of the given type.
1950  */
1951 CINDEX_LINKAGE CXCursor clang_getTypeDeclaration(CXType T);
1952 
1953 /**
1954  * Returns the Objective-C type encoding for the specified declaration.
1955  */
1956 CINDEX_LINKAGE CXString clang_getDeclObjCTypeEncoding(CXCursor C);
1957 
1958 /**
1959  * \brief Retrieve the spelling of a given CXTypeKind.
1960  */
1961 CINDEX_LINKAGE CXString clang_getTypeKindSpelling(enum CXTypeKind K);
1962 
1963 /**
1964  * \brief Retrieve the result type associated with a function type.
1965  */
1966 CINDEX_LINKAGE CXType clang_getResultType(CXType T);
1967 
1968 /**
1969  * \brief Retrieve the result type associated with a given cursor.  This only
1970  *  returns a valid type of the cursor refers to a function or method.
1971  */
1972 CINDEX_LINKAGE CXType clang_getCursorResultType(CXCursor C);
1973 
1974 /**
1975  * \brief Return 1 if the CXType is a POD (plain old data) type, and 0
1976  *  otherwise.
1977  */
1978 CINDEX_LINKAGE unsigned clang_isPODType(CXType T);
1979 
1980 /**
1981  * \brief Returns 1 if the base class specified by the cursor with kind
1982  *   CX_CXXBaseSpecifier is virtual.
1983  */
1984 CINDEX_LINKAGE unsigned clang_isVirtualBase(CXCursor);
1985 
1986 /**
1987  * \brief Represents the C++ access control level to a base class for a
1988  * cursor with kind CX_CXXBaseSpecifier.
1989  */
1990 enum CX_CXXAccessSpecifier {
1991   CX_CXXInvalidAccessSpecifier,
1992   CX_CXXPublic,
1993   CX_CXXProtected,
1994   CX_CXXPrivate
1995 };
1996 
1997 /**
1998  * \brief Returns the access control level for the C++ base specifier
1999  *  represented by a cursor with kind CX_CXXBaseSpecifier.
2000  */
2001 CINDEX_LINKAGE enum CX_CXXAccessSpecifier clang_getCXXAccessSpecifier(CXCursor);
2002 
2003 /**
2004  * \brief Determine the number of overloaded declarations referenced by a
2005  * \c CXCursor_OverloadedDeclRef cursor.
2006  *
2007  * \param cursor The cursor whose overloaded declarations are being queried.
2008  *
2009  * \returns The number of overloaded declarations referenced by \c cursor. If it
2010  * is not a \c CXCursor_OverloadedDeclRef cursor, returns 0.
2011  */
2012 CINDEX_LINKAGE unsigned clang_getNumOverloadedDecls(CXCursor cursor);
2013 
2014 /**
2015  * \brief Retrieve a cursor for one of the overloaded declarations referenced
2016  * by a \c CXCursor_OverloadedDeclRef cursor.
2017  *
2018  * \param cursor The cursor whose overloaded declarations are being queried.
2019  *
2020  * \param index The zero-based index into the set of overloaded declarations in
2021  * the cursor.
2022  *
2023  * \returns A cursor representing the declaration referenced by the given
2024  * \c cursor at the specified \c index. If the cursor does not have an
2025  * associated set of overloaded declarations, or if the index is out of bounds,
2026  * returns \c clang_getNullCursor();
2027  */
2028 CINDEX_LINKAGE CXCursor clang_getOverloadedDecl(CXCursor cursor,
2029                                                 unsigned index);
2030 
2031 /**
2032  * @}
2033  */
2034 
2035 /**
2036  * \defgroup CINDEX_ATTRIBUTES Information for attributes
2037  *
2038  * @{
2039  */
2040 
2041 
2042 /**
2043  * \brief For cursors representing an iboutletcollection attribute,
2044  *  this function returns the collection element type.
2045  *
2046  */
2047 CINDEX_LINKAGE CXType clang_getIBOutletCollectionType(CXCursor);
2048 
2049 /**
2050  * @}
2051  */
2052 
2053 /**
2054  * \defgroup CINDEX_CURSOR_TRAVERSAL Traversing the AST with cursors
2055  *
2056  * These routines provide the ability to traverse the abstract syntax tree
2057  * using cursors.
2058  *
2059  * @{
2060  */
2061 
2062 /**
2063  * \brief Describes how the traversal of the children of a particular
2064  * cursor should proceed after visiting a particular child cursor.
2065  *
2066  * A value of this enumeration type should be returned by each
2067  * \c CXCursorVisitor to indicate how clang_visitChildren() proceed.
2068  */
2069 enum CXChildVisitResult {
2070   /**
2071    * \brief Terminates the cursor traversal.
2072    */
2073   CXChildVisit_Break,
2074   /**
2075    * \brief Continues the cursor traversal with the next sibling of
2076    * the cursor just visited, without visiting its children.
2077    */
2078   CXChildVisit_Continue,
2079   /**
2080    * \brief Recursively traverse the children of this cursor, using
2081    * the same visitor and client data.
2082    */
2083   CXChildVisit_Recurse
2084 };
2085 
2086 /**
2087  * \brief Visitor invoked for each cursor found by a traversal.
2088  *
2089  * This visitor function will be invoked for each cursor found by
2090  * clang_visitCursorChildren(). Its first argument is the cursor being
2091  * visited, its second argument is the parent visitor for that cursor,
2092  * and its third argument is the client data provided to
2093  * clang_visitCursorChildren().
2094  *
2095  * The visitor should return one of the \c CXChildVisitResult values
2096  * to direct clang_visitCursorChildren().
2097  */
2098 typedef enum CXChildVisitResult (*CXCursorVisitor)(CXCursor cursor,
2099                                                    CXCursor parent,
2100                                                    CXClientData client_data);
2101 
2102 /**
2103  * \brief Visit the children of a particular cursor.
2104  *
2105  * This function visits all the direct children of the given cursor,
2106  * invoking the given \p visitor function with the cursors of each
2107  * visited child. The traversal may be recursive, if the visitor returns
2108  * \c CXChildVisit_Recurse. The traversal may also be ended prematurely, if
2109  * the visitor returns \c CXChildVisit_Break.
2110  *
2111  * \param parent the cursor whose child may be visited. All kinds of
2112  * cursors can be visited, including invalid cursors (which, by
2113  * definition, have no children).
2114  *
2115  * \param visitor the visitor function that will be invoked for each
2116  * child of \p parent.
2117  *
2118  * \param client_data pointer data supplied by the client, which will
2119  * be passed to the visitor each time it is invoked.
2120  *
2121  * \returns a non-zero value if the traversal was terminated
2122  * prematurely by the visitor returning \c CXChildVisit_Break.
2123  */
2124 CINDEX_LINKAGE unsigned clang_visitChildren(CXCursor parent,
2125                                             CXCursorVisitor visitor,
2126                                             CXClientData client_data);
2127 #ifdef __has_feature
2128 #  if __has_feature(blocks)
2129 /**
2130  * \brief Visitor invoked for each cursor found by a traversal.
2131  *
2132  * This visitor block will be invoked for each cursor found by
2133  * clang_visitChildrenWithBlock(). Its first argument is the cursor being
2134  * visited, its second argument is the parent visitor for that cursor.
2135  *
2136  * The visitor should return one of the \c CXChildVisitResult values
2137  * to direct clang_visitChildrenWithBlock().
2138  */
2139 typedef enum CXChildVisitResult
2140      (^CXCursorVisitorBlock)(CXCursor cursor, CXCursor parent);
2141 
2142 /**
2143  * Visits the children of a cursor using the specified block.  Behaves
2144  * identically to clang_visitChildren() in all other respects.
2145  */
2146 unsigned clang_visitChildrenWithBlock(CXCursor parent,
2147                                       CXCursorVisitorBlock block);
2148 #  endif
2149 #endif
2150 
2151 /**
2152  * @}
2153  */
2154 
2155 /**
2156  * \defgroup CINDEX_CURSOR_XREF Cross-referencing in the AST
2157  *
2158  * These routines provide the ability to determine references within and
2159  * across translation units, by providing the names of the entities referenced
2160  * by cursors, follow reference cursors to the declarations they reference,
2161  * and associate declarations with their definitions.
2162  *
2163  * @{
2164  */
2165 
2166 /**
2167  * \brief Retrieve a Unified Symbol Resolution (USR) for the entity referenced
2168  * by the given cursor.
2169  *
2170  * A Unified Symbol Resolution (USR) is a string that identifies a particular
2171  * entity (function, class, variable, etc.) within a program. USRs can be
2172  * compared across translation units to determine, e.g., when references in
2173  * one translation refer to an entity defined in another translation unit.
2174  */
2175 CINDEX_LINKAGE CXString clang_getCursorUSR(CXCursor);
2176 
2177 /**
2178  * \brief Construct a USR for a specified Objective-C class.
2179  */
2180 CINDEX_LINKAGE CXString clang_constructUSR_ObjCClass(const char *class_name);
2181 
2182 /**
2183  * \brief Construct a USR for a specified Objective-C category.
2184  */
2185 CINDEX_LINKAGE CXString
2186   clang_constructUSR_ObjCCategory(const char *class_name,
2187                                  const char *category_name);
2188 
2189 /**
2190  * \brief Construct a USR for a specified Objective-C protocol.
2191  */
2192 CINDEX_LINKAGE CXString
2193   clang_constructUSR_ObjCProtocol(const char *protocol_name);
2194 
2195 
2196 /**
2197  * \brief Construct a USR for a specified Objective-C instance variable and
2198  *   the USR for its containing class.
2199  */
2200 CINDEX_LINKAGE CXString clang_constructUSR_ObjCIvar(const char *name,
2201                                                     CXString classUSR);
2202 
2203 /**
2204  * \brief Construct a USR for a specified Objective-C method and
2205  *   the USR for its containing class.
2206  */
2207 CINDEX_LINKAGE CXString clang_constructUSR_ObjCMethod(const char *name,
2208                                                       unsigned isInstanceMethod,
2209                                                       CXString classUSR);
2210 
2211 /**
2212  * \brief Construct a USR for a specified Objective-C property and the USR
2213  *  for its containing class.
2214  */
2215 CINDEX_LINKAGE CXString clang_constructUSR_ObjCProperty(const char *property,
2216                                                         CXString classUSR);
2217 
2218 /**
2219  * \brief Retrieve a name for the entity referenced by this cursor.
2220  */
2221 CINDEX_LINKAGE CXString clang_getCursorSpelling(CXCursor);
2222 
2223 /**
2224  * \brief Retrieve the display name for the entity referenced by this cursor.
2225  *
2226  * The display name contains extra information that helps identify the cursor,
2227  * such as the parameters of a function or template or the arguments of a
2228  * class template specialization.
2229  */
2230 CINDEX_LINKAGE CXString clang_getCursorDisplayName(CXCursor);
2231 
2232 /** \brief For a cursor that is a reference, retrieve a cursor representing the
2233  * entity that it references.
2234  *
2235  * Reference cursors refer to other entities in the AST. For example, an
2236  * Objective-C superclass reference cursor refers to an Objective-C class.
2237  * This function produces the cursor for the Objective-C class from the
2238  * cursor for the superclass reference. If the input cursor is a declaration or
2239  * definition, it returns that declaration or definition unchanged.
2240  * Otherwise, returns the NULL cursor.
2241  */
2242 CINDEX_LINKAGE CXCursor clang_getCursorReferenced(CXCursor);
2243 
2244 /**
2245  *  \brief For a cursor that is either a reference to or a declaration
2246  *  of some entity, retrieve a cursor that describes the definition of
2247  *  that entity.
2248  *
2249  *  Some entities can be declared multiple times within a translation
2250  *  unit, but only one of those declarations can also be a
2251  *  definition. For example, given:
2252  *
2253  *  \code
2254  *  int f(int, int);
2255  *  int g(int x, int y) { return f(x, y); }
2256  *  int f(int a, int b) { return a + b; }
2257  *  int f(int, int);
2258  *  \endcode
2259  *
2260  *  there are three declarations of the function "f", but only the
2261  *  second one is a definition. The clang_getCursorDefinition()
2262  *  function will take any cursor pointing to a declaration of "f"
2263  *  (the first or fourth lines of the example) or a cursor referenced
2264  *  that uses "f" (the call to "f' inside "g") and will return a
2265  *  declaration cursor pointing to the definition (the second "f"
2266  *  declaration).
2267  *
2268  *  If given a cursor for which there is no corresponding definition,
2269  *  e.g., because there is no definition of that entity within this
2270  *  translation unit, returns a NULL cursor.
2271  */
2272 CINDEX_LINKAGE CXCursor clang_getCursorDefinition(CXCursor);
2273 
2274 /**
2275  * \brief Determine whether the declaration pointed to by this cursor
2276  * is also a definition of that entity.
2277  */
2278 CINDEX_LINKAGE unsigned clang_isCursorDefinition(CXCursor);
2279 
2280 /**
2281  * \brief Retrieve the canonical cursor corresponding to the given cursor.
2282  *
2283  * In the C family of languages, many kinds of entities can be declared several
2284  * times within a single translation unit. For example, a structure type can
2285  * be forward-declared (possibly multiple times) and later defined:
2286  *
2287  * \code
2288  * struct X;
2289  * struct X;
2290  * struct X {
2291  *   int member;
2292  * };
2293  * \endcode
2294  *
2295  * The declarations and the definition of \c X are represented by three
2296  * different cursors, all of which are declarations of the same underlying
2297  * entity. One of these cursor is considered the "canonical" cursor, which
2298  * is effectively the representative for the underlying entity. One can
2299  * determine if two cursors are declarations of the same underlying entity by
2300  * comparing their canonical cursors.
2301  *
2302  * \returns The canonical cursor for the entity referred to by the given cursor.
2303  */
2304 CINDEX_LINKAGE CXCursor clang_getCanonicalCursor(CXCursor);
2305 
2306 /**
2307  * @}
2308  */
2309 
2310 /**
2311  * \defgroup CINDEX_CPP C++ AST introspection
2312  *
2313  * The routines in this group provide access information in the ASTs specific
2314  * to C++ language features.
2315  *
2316  * @{
2317  */
2318 
2319 /**
2320  * \brief Determine if a C++ member function or member function template is
2321  * declared 'static'.
2322  */
2323 CINDEX_LINKAGE unsigned clang_CXXMethod_isStatic(CXCursor C);
2324 
2325 /**
2326  * \brief Determine if a C++ member function or member function template is
2327  * explicitly declared 'virtual' or if it overrides a virtual method from
2328  * one of the base classes.
2329  */
2330 CINDEX_LINKAGE unsigned clang_CXXMethod_isVirtual(CXCursor C);
2331 
2332 /**
2333  * \brief Given a cursor that represents a template, determine
2334  * the cursor kind of the specializations would be generated by instantiating
2335  * the template.
2336  *
2337  * This routine can be used to determine what flavor of function template,
2338  * class template, or class template partial specialization is stored in the
2339  * cursor. For example, it can describe whether a class template cursor is
2340  * declared with "struct", "class" or "union".
2341  *
2342  * \param C The cursor to query. This cursor should represent a template
2343  * declaration.
2344  *
2345  * \returns The cursor kind of the specializations that would be generated
2346  * by instantiating the template \p C. If \p C is not a template, returns
2347  * \c CXCursor_NoDeclFound.
2348  */
2349 CINDEX_LINKAGE enum CXCursorKind clang_getTemplateCursorKind(CXCursor C);
2350 
2351 /**
2352  * \brief Given a cursor that may represent a specialization or instantiation
2353  * of a template, retrieve the cursor that represents the template that it
2354  * specializes or from which it was instantiated.
2355  *
2356  * This routine determines the template involved both for explicit
2357  * specializations of templates and for implicit instantiations of the template,
2358  * both of which are referred to as "specializations". For a class template
2359  * specialization (e.g., \c std::vector<bool>), this routine will return
2360  * either the primary template (\c std::vector) or, if the specialization was
2361  * instantiated from a class template partial specialization, the class template
2362  * partial specialization. For a class template partial specialization and a
2363  * function template specialization (including instantiations), this
2364  * this routine will return the specialized template.
2365  *
2366  * For members of a class template (e.g., member functions, member classes, or
2367  * static data members), returns the specialized or instantiated member.
2368  * Although not strictly "templates" in the C++ language, members of class
2369  * templates have the same notions of specializations and instantiations that
2370  * templates do, so this routine treats them similarly.
2371  *
2372  * \param C A cursor that may be a specialization of a template or a member
2373  * of a template.
2374  *
2375  * \returns If the given cursor is a specialization or instantiation of a
2376  * template or a member thereof, the template or member that it specializes or
2377  * from which it was instantiated. Otherwise, returns a NULL cursor.
2378  */
2379 CINDEX_LINKAGE CXCursor clang_getSpecializedCursorTemplate(CXCursor C);
2380 
2381 /**
2382  * @}
2383  */
2384 
2385 /**
2386  * \defgroup CINDEX_LEX Token extraction and manipulation
2387  *
2388  * The routines in this group provide access to the tokens within a
2389  * translation unit, along with a semantic mapping of those tokens to
2390  * their corresponding cursors.
2391  *
2392  * @{
2393  */
2394 
2395 /**
2396  * \brief Describes a kind of token.
2397  */
2398 typedef enum CXTokenKind {
2399   /**
2400    * \brief A token that contains some kind of punctuation.
2401    */
2402   CXToken_Punctuation,
2403 
2404   /**
2405    * \brief A language keyword.
2406    */
2407   CXToken_Keyword,
2408 
2409   /**
2410    * \brief An identifier (that is not a keyword).
2411    */
2412   CXToken_Identifier,
2413 
2414   /**
2415    * \brief A numeric, string, or character literal.
2416    */
2417   CXToken_Literal,
2418 
2419   /**
2420    * \brief A comment.
2421    */
2422   CXToken_Comment
2423 } CXTokenKind;
2424 
2425 /**
2426  * \brief Describes a single preprocessing token.
2427  */
2428 typedef struct {
2429   unsigned int_data[4];
2430   void *ptr_data;
2431 } CXToken;
2432 
2433 /**
2434  * \brief Determine the kind of the given token.
2435  */
2436 CINDEX_LINKAGE CXTokenKind clang_getTokenKind(CXToken);
2437 
2438 /**
2439  * \brief Determine the spelling of the given token.
2440  *
2441  * The spelling of a token is the textual representation of that token, e.g.,
2442  * the text of an identifier or keyword.
2443  */
2444 CINDEX_LINKAGE CXString clang_getTokenSpelling(CXTranslationUnit, CXToken);
2445 
2446 /**
2447  * \brief Retrieve the source location of the given token.
2448  */
2449 CINDEX_LINKAGE CXSourceLocation clang_getTokenLocation(CXTranslationUnit,
2450                                                        CXToken);
2451 
2452 /**
2453  * \brief Retrieve a source range that covers the given token.
2454  */
2455 CINDEX_LINKAGE CXSourceRange clang_getTokenExtent(CXTranslationUnit, CXToken);
2456 
2457 /**
2458  * \brief Tokenize the source code described by the given range into raw
2459  * lexical tokens.
2460  *
2461  * \param TU the translation unit whose text is being tokenized.
2462  *
2463  * \param Range the source range in which text should be tokenized. All of the
2464  * tokens produced by tokenization will fall within this source range,
2465  *
2466  * \param Tokens this pointer will be set to point to the array of tokens
2467  * that occur within the given source range. The returned pointer must be
2468  * freed with clang_disposeTokens() before the translation unit is destroyed.
2469  *
2470  * \param NumTokens will be set to the number of tokens in the \c *Tokens
2471  * array.
2472  *
2473  */
2474 CINDEX_LINKAGE void clang_tokenize(CXTranslationUnit TU, CXSourceRange Range,
2475                                    CXToken **Tokens, unsigned *NumTokens);
2476 
2477 /**
2478  * \brief Annotate the given set of tokens by providing cursors for each token
2479  * that can be mapped to a specific entity within the abstract syntax tree.
2480  *
2481  * This token-annotation routine is equivalent to invoking
2482  * clang_getCursor() for the source locations of each of the
2483  * tokens. The cursors provided are filtered, so that only those
2484  * cursors that have a direct correspondence to the token are
2485  * accepted. For example, given a function call \c f(x),
2486  * clang_getCursor() would provide the following cursors:
2487  *
2488  *   * when the cursor is over the 'f', a DeclRefExpr cursor referring to 'f'.
2489  *   * when the cursor is over the '(' or the ')', a CallExpr referring to 'f'.
2490  *   * when the cursor is over the 'x', a DeclRefExpr cursor referring to 'x'.
2491  *
2492  * Only the first and last of these cursors will occur within the
2493  * annotate, since the tokens "f" and "x' directly refer to a function
2494  * and a variable, respectively, but the parentheses are just a small
2495  * part of the full syntax of the function call expression, which is
2496  * not provided as an annotation.
2497  *
2498  * \param TU the translation unit that owns the given tokens.
2499  *
2500  * \param Tokens the set of tokens to annotate.
2501  *
2502  * \param NumTokens the number of tokens in \p Tokens.
2503  *
2504  * \param Cursors an array of \p NumTokens cursors, whose contents will be
2505  * replaced with the cursors corresponding to each token.
2506  */
2507 CINDEX_LINKAGE void clang_annotateTokens(CXTranslationUnit TU,
2508                                          CXToken *Tokens, unsigned NumTokens,
2509                                          CXCursor *Cursors);
2510 
2511 /**
2512  * \brief Free the given set of tokens.
2513  */
2514 CINDEX_LINKAGE void clang_disposeTokens(CXTranslationUnit TU,
2515                                         CXToken *Tokens, unsigned NumTokens);
2516 
2517 /**
2518  * @}
2519  */
2520 
2521 /**
2522  * \defgroup CINDEX_DEBUG Debugging facilities
2523  *
2524  * These routines are used for testing and debugging, only, and should not
2525  * be relied upon.
2526  *
2527  * @{
2528  */
2529 
2530 /* for debug/testing */
2531 CINDEX_LINKAGE CXString clang_getCursorKindSpelling(enum CXCursorKind Kind);
2532 CINDEX_LINKAGE void clang_getDefinitionSpellingAndExtent(CXCursor,
2533                                           const char **startBuf,
2534                                           const char **endBuf,
2535                                           unsigned *startLine,
2536                                           unsigned *startColumn,
2537                                           unsigned *endLine,
2538                                           unsigned *endColumn);
2539 CINDEX_LINKAGE void clang_enableStackTraces(void);
2540 CINDEX_LINKAGE void clang_executeOnThread(void (*fn)(void*), void *user_data,
2541                                           unsigned stack_size);
2542 
2543 /**
2544  * @}
2545  */
2546 
2547 /**
2548  * \defgroup CINDEX_CODE_COMPLET Code completion
2549  *
2550  * Code completion involves taking an (incomplete) source file, along with
2551  * knowledge of where the user is actively editing that file, and suggesting
2552  * syntactically- and semantically-valid constructs that the user might want to
2553  * use at that particular point in the source code. These data structures and
2554  * routines provide support for code completion.
2555  *
2556  * @{
2557  */
2558 
2559 /**
2560  * \brief A semantic string that describes a code-completion result.
2561  *
2562  * A semantic string that describes the formatting of a code-completion
2563  * result as a single "template" of text that should be inserted into the
2564  * source buffer when a particular code-completion result is selected.
2565  * Each semantic string is made up of some number of "chunks", each of which
2566  * contains some text along with a description of what that text means, e.g.,
2567  * the name of the entity being referenced, whether the text chunk is part of
2568  * the template, or whether it is a "placeholder" that the user should replace
2569  * with actual code,of a specific kind. See \c CXCompletionChunkKind for a
2570  * description of the different kinds of chunks.
2571  */
2572 typedef void *CXCompletionString;
2573 
2574 /**
2575  * \brief A single result of code completion.
2576  */
2577 typedef struct {
2578   /**
2579    * \brief The kind of entity that this completion refers to.
2580    *
2581    * The cursor kind will be a macro, keyword, or a declaration (one of the
2582    * *Decl cursor kinds), describing the entity that the completion is
2583    * referring to.
2584    *
2585    * \todo In the future, we would like to provide a full cursor, to allow
2586    * the client to extract additional information from declaration.
2587    */
2588   enum CXCursorKind CursorKind;
2589 
2590   /**
2591    * \brief The code-completion string that describes how to insert this
2592    * code-completion result into the editing buffer.
2593    */
2594   CXCompletionString CompletionString;
2595 } CXCompletionResult;
2596 
2597 /**
2598  * \brief Describes a single piece of text within a code-completion string.
2599  *
2600  * Each "chunk" within a code-completion string (\c CXCompletionString) is
2601  * either a piece of text with a specific "kind" that describes how that text
2602  * should be interpreted by the client or is another completion string.
2603  */
2604 enum CXCompletionChunkKind {
2605   /**
2606    * \brief A code-completion string that describes "optional" text that
2607    * could be a part of the template (but is not required).
2608    *
2609    * The Optional chunk is the only kind of chunk that has a code-completion
2610    * string for its representation, which is accessible via
2611    * \c clang_getCompletionChunkCompletionString(). The code-completion string
2612    * describes an additional part of the template that is completely optional.
2613    * For example, optional chunks can be used to describe the placeholders for
2614    * arguments that match up with defaulted function parameters, e.g. given:
2615    *
2616    * \code
2617    * void f(int x, float y = 3.14, double z = 2.71828);
2618    * \endcode
2619    *
2620    * The code-completion string for this function would contain:
2621    *   - a TypedText chunk for "f".
2622    *   - a LeftParen chunk for "(".
2623    *   - a Placeholder chunk for "int x"
2624    *   - an Optional chunk containing the remaining defaulted arguments, e.g.,
2625    *       - a Comma chunk for ","
2626    *       - a Placeholder chunk for "float y"
2627    *       - an Optional chunk containing the last defaulted argument:
2628    *           - a Comma chunk for ","
2629    *           - a Placeholder chunk for "double z"
2630    *   - a RightParen chunk for ")"
2631    *
2632    * There are many ways to handle Optional chunks. Two simple approaches are:
2633    *   - Completely ignore optional chunks, in which case the template for the
2634    *     function "f" would only include the first parameter ("int x").
2635    *   - Fully expand all optional chunks, in which case the template for the
2636    *     function "f" would have all of the parameters.
2637    */
2638   CXCompletionChunk_Optional,
2639   /**
2640    * \brief Text that a user would be expected to type to get this
2641    * code-completion result.
2642    *
2643    * There will be exactly one "typed text" chunk in a semantic string, which
2644    * will typically provide the spelling of a keyword or the name of a
2645    * declaration that could be used at the current code point. Clients are
2646    * expected to filter the code-completion results based on the text in this
2647    * chunk.
2648    */
2649   CXCompletionChunk_TypedText,
2650   /**
2651    * \brief Text that should be inserted as part of a code-completion result.
2652    *
2653    * A "text" chunk represents text that is part of the template to be
2654    * inserted into user code should this particular code-completion result
2655    * be selected.
2656    */
2657   CXCompletionChunk_Text,
2658   /**
2659    * \brief Placeholder text that should be replaced by the user.
2660    *
2661    * A "placeholder" chunk marks a place where the user should insert text
2662    * into the code-completion template. For example, placeholders might mark
2663    * the function parameters for a function declaration, to indicate that the
2664    * user should provide arguments for each of those parameters. The actual
2665    * text in a placeholder is a suggestion for the text to display before
2666    * the user replaces the placeholder with real code.
2667    */
2668   CXCompletionChunk_Placeholder,
2669   /**
2670    * \brief Informative text that should be displayed but never inserted as
2671    * part of the template.
2672    *
2673    * An "informative" chunk contains annotations that can be displayed to
2674    * help the user decide whether a particular code-completion result is the
2675    * right option, but which is not part of the actual template to be inserted
2676    * by code completion.
2677    */
2678   CXCompletionChunk_Informative,
2679   /**
2680    * \brief Text that describes the current parameter when code-completion is
2681    * referring to function call, message send, or template specialization.
2682    *
2683    * A "current parameter" chunk occurs when code-completion is providing
2684    * information about a parameter corresponding to the argument at the
2685    * code-completion point. For example, given a function
2686    *
2687    * \code
2688    * int add(int x, int y);
2689    * \endcode
2690    *
2691    * and the source code \c add(, where the code-completion point is after the
2692    * "(", the code-completion string will contain a "current parameter" chunk
2693    * for "int x", indicating that the current argument will initialize that
2694    * parameter. After typing further, to \c add(17, (where the code-completion
2695    * point is after the ","), the code-completion string will contain a
2696    * "current paremeter" chunk to "int y".
2697    */
2698   CXCompletionChunk_CurrentParameter,
2699   /**
2700    * \brief A left parenthesis ('('), used to initiate a function call or
2701    * signal the beginning of a function parameter list.
2702    */
2703   CXCompletionChunk_LeftParen,
2704   /**
2705    * \brief A right parenthesis (')'), used to finish a function call or
2706    * signal the end of a function parameter list.
2707    */
2708   CXCompletionChunk_RightParen,
2709   /**
2710    * \brief A left bracket ('[').
2711    */
2712   CXCompletionChunk_LeftBracket,
2713   /**
2714    * \brief A right bracket (']').
2715    */
2716   CXCompletionChunk_RightBracket,
2717   /**
2718    * \brief A left brace ('{').
2719    */
2720   CXCompletionChunk_LeftBrace,
2721   /**
2722    * \brief A right brace ('}').
2723    */
2724   CXCompletionChunk_RightBrace,
2725   /**
2726    * \brief A left angle bracket ('<').
2727    */
2728   CXCompletionChunk_LeftAngle,
2729   /**
2730    * \brief A right angle bracket ('>').
2731    */
2732   CXCompletionChunk_RightAngle,
2733   /**
2734    * \brief A comma separator (',').
2735    */
2736   CXCompletionChunk_Comma,
2737   /**
2738    * \brief Text that specifies the result type of a given result.
2739    *
2740    * This special kind of informative chunk is not meant to be inserted into
2741    * the text buffer. Rather, it is meant to illustrate the type that an
2742    * expression using the given completion string would have.
2743    */
2744   CXCompletionChunk_ResultType,
2745   /**
2746    * \brief A colon (':').
2747    */
2748   CXCompletionChunk_Colon,
2749   /**
2750    * \brief A semicolon (';').
2751    */
2752   CXCompletionChunk_SemiColon,
2753   /**
2754    * \brief An '=' sign.
2755    */
2756   CXCompletionChunk_Equal,
2757   /**
2758    * Horizontal space (' ').
2759    */
2760   CXCompletionChunk_HorizontalSpace,
2761   /**
2762    * Vertical space ('\n'), after which it is generally a good idea to
2763    * perform indentation.
2764    */
2765   CXCompletionChunk_VerticalSpace
2766 };
2767 
2768 /**
2769  * \brief Determine the kind of a particular chunk within a completion string.
2770  *
2771  * \param completion_string the completion string to query.
2772  *
2773  * \param chunk_number the 0-based index of the chunk in the completion string.
2774  *
2775  * \returns the kind of the chunk at the index \c chunk_number.
2776  */
2777 CINDEX_LINKAGE enum CXCompletionChunkKind
2778 clang_getCompletionChunkKind(CXCompletionString completion_string,
2779                              unsigned chunk_number);
2780 
2781 /**
2782  * \brief Retrieve the text associated with a particular chunk within a
2783  * completion string.
2784  *
2785  * \param completion_string the completion string to query.
2786  *
2787  * \param chunk_number the 0-based index of the chunk in the completion string.
2788  *
2789  * \returns the text associated with the chunk at index \c chunk_number.
2790  */
2791 CINDEX_LINKAGE CXString
2792 clang_getCompletionChunkText(CXCompletionString completion_string,
2793                              unsigned chunk_number);
2794 
2795 /**
2796  * \brief Retrieve the completion string associated with a particular chunk
2797  * within a completion string.
2798  *
2799  * \param completion_string the completion string to query.
2800  *
2801  * \param chunk_number the 0-based index of the chunk in the completion string.
2802  *
2803  * \returns the completion string associated with the chunk at index
2804  * \c chunk_number, or NULL if that chunk is not represented by a completion
2805  * string.
2806  */
2807 CINDEX_LINKAGE CXCompletionString
2808 clang_getCompletionChunkCompletionString(CXCompletionString completion_string,
2809                                          unsigned chunk_number);
2810 
2811 /**
2812  * \brief Retrieve the number of chunks in the given code-completion string.
2813  */
2814 CINDEX_LINKAGE unsigned
2815 clang_getNumCompletionChunks(CXCompletionString completion_string);
2816 
2817 /**
2818  * \brief Determine the priority of this code completion.
2819  *
2820  * The priority of a code completion indicates how likely it is that this
2821  * particular completion is the completion that the user will select. The
2822  * priority is selected by various internal heuristics.
2823  *
2824  * \param completion_string The completion string to query.
2825  *
2826  * \returns The priority of this completion string. Smaller values indicate
2827  * higher-priority (more likely) completions.
2828  */
2829 CINDEX_LINKAGE unsigned
2830 clang_getCompletionPriority(CXCompletionString completion_string);
2831 
2832 /**
2833  * \brief Determine the availability of the entity that this code-completion
2834  * string refers to.
2835  *
2836  * \param completion_string The completion string to query.
2837  *
2838  * \returns The availability of the completion string.
2839  */
2840 CINDEX_LINKAGE enum CXAvailabilityKind
2841 clang_getCompletionAvailability(CXCompletionString completion_string);
2842 
2843 /**
2844  * \brief Contains the results of code-completion.
2845  *
2846  * This data structure contains the results of code completion, as
2847  * produced by \c clang_codeCompleteAt(). Its contents must be freed by
2848  * \c clang_disposeCodeCompleteResults.
2849  */
2850 typedef struct {
2851   /**
2852    * \brief The code-completion results.
2853    */
2854   CXCompletionResult *Results;
2855 
2856   /**
2857    * \brief The number of code-completion results stored in the
2858    * \c Results array.
2859    */
2860   unsigned NumResults;
2861 } CXCodeCompleteResults;
2862 
2863 /**
2864  * \brief Flags that can be passed to \c clang_codeCompleteAt() to
2865  * modify its behavior.
2866  *
2867  * The enumerators in this enumeration can be bitwise-OR'd together to
2868  * provide multiple options to \c clang_codeCompleteAt().
2869  */
2870 enum CXCodeComplete_Flags {
2871   /**
2872    * \brief Whether to include macros within the set of code
2873    * completions returned.
2874    */
2875   CXCodeComplete_IncludeMacros = 0x01,
2876 
2877   /**
2878    * \brief Whether to include code patterns for language constructs
2879    * within the set of code completions, e.g., for loops.
2880    */
2881   CXCodeComplete_IncludeCodePatterns = 0x02
2882 };
2883 
2884 /**
2885  * \brief Bits that represent the context under which completion is occurring.
2886  *
2887  * The enumerators in this enumeration may be bitwise-OR'd together if multiple
2888  * contexts are occurring simultaneously.
2889  */
2890 enum CXCompletionContext {
2891   /**
2892    * \brief The context for completions is unexposed, as only Clang results
2893    * should be included. (This is equivalent to having no context bits set.)
2894    */
2895   CXCompletionContext_Unexposed = 0,
2896 
2897   /**
2898    * \brief Completions for any possible type should be included in the results.
2899    */
2900   CXCompletionContext_AnyType = 1 << 0,
2901 
2902   /**
2903    * \brief Completions for any possible value (variables, function calls, etc.)
2904    * should be included in the results.
2905    */
2906   CXCompletionContext_AnyValue = 1 << 1,
2907   /**
2908    * \brief Completions for values that resolve to an Objective-C object should
2909    * be included in the results.
2910    */
2911   CXCompletionContext_ObjCObjectValue = 1 << 2,
2912   /**
2913    * \brief Completions for values that resolve to an Objective-C selector
2914    * should be included in the results.
2915    */
2916   CXCompletionContext_ObjCSelectorValue = 1 << 3,
2917   /**
2918    * \brief Completions for values that resolve to a C++ class type should be
2919    * included in the results.
2920    */
2921   CXCompletionContext_CXXClassTypeValue = 1 << 4,
2922 
2923   /**
2924    * \brief Completions for fields of the member being accessed using the dot
2925    * operator should be included in the results.
2926    */
2927   CXCompletionContext_DotMemberAccess = 1 << 5,
2928   /**
2929    * \brief Completions for fields of the member being accessed using the arrow
2930    * operator should be included in the results.
2931    */
2932   CXCompletionContext_ArrowMemberAccess = 1 << 6,
2933   /**
2934    * \brief Completions for properties of the Objective-C object being accessed
2935    * using the dot operator should be included in the results.
2936    */
2937   CXCompletionContext_ObjCPropertyAccess = 1 << 7,
2938 
2939   /**
2940    * \brief Completions for enum tags should be included in the results.
2941    */
2942   CXCompletionContext_EnumTag = 1 << 8,
2943   /**
2944    * \brief Completions for union tags should be included in the results.
2945    */
2946   CXCompletionContext_UnionTag = 1 << 9,
2947   /**
2948    * \brief Completions for struct tags should be included in the results.
2949    */
2950   CXCompletionContext_StructTag = 1 << 10,
2951 
2952   /**
2953    * \brief Completions for C++ class names should be included in the results.
2954    */
2955   CXCompletionContext_ClassTag = 1 << 11,
2956   /**
2957    * \brief Completions for C++ namespaces and namespace aliases should be
2958    * included in the results.
2959    */
2960   CXCompletionContext_Namespace = 1 << 12,
2961   /**
2962    * \brief Completions for C++ nested name specifiers should be included in
2963    * the results.
2964    */
2965   CXCompletionContext_NestedNameSpecifier = 1 << 13,
2966 
2967   /**
2968    * \brief Completions for Objective-C interfaces (classes) should be included
2969    * in the results.
2970    */
2971   CXCompletionContext_ObjCInterface = 1 << 14,
2972   /**
2973    * \brief Completions for Objective-C protocols should be included in
2974    * the results.
2975    */
2976   CXCompletionContext_ObjCProtocol = 1 << 15,
2977   /**
2978    * \brief Completions for Objective-C categories should be included in
2979    * the results.
2980    */
2981   CXCompletionContext_ObjCCategory = 1 << 16,
2982   /**
2983    * \brief Completions for Objective-C instance messages should be included
2984    * in the results.
2985    */
2986   CXCompletionContext_ObjCInstanceMessage = 1 << 17,
2987   /**
2988    * \brief Completions for Objective-C class messages should be included in
2989    * the results.
2990    */
2991   CXCompletionContext_ObjCClassMessage = 1 << 18,
2992   /**
2993    * \brief Completions for Objective-C selector names should be included in
2994    * the results.
2995    */
2996   CXCompletionContext_ObjCSelectorName = 1 << 19,
2997 
2998   /**
2999    * \brief Completions for preprocessor macro names should be included in
3000    * the results.
3001    */
3002   CXCompletionContext_MacroName = 1 << 20,
3003 
3004   /**
3005    * \brief Natural language completions should be included in the results.
3006    */
3007   CXCompletionContext_NaturalLanguage = 1 << 21,
3008 
3009   /**
3010    * \brief The current context is unknown, so set all contexts.
3011    */
3012   CXCompletionContext_Unknown = ((1 << 22) - 1)
3013 };
3014 
3015 /**
3016  * \brief Returns a default set of code-completion options that can be
3017  * passed to\c clang_codeCompleteAt().
3018  */
3019 CINDEX_LINKAGE unsigned clang_defaultCodeCompleteOptions(void);
3020 
3021 /**
3022  * \brief Perform code completion at a given location in a translation unit.
3023  *
3024  * This function performs code completion at a particular file, line, and
3025  * column within source code, providing results that suggest potential
3026  * code snippets based on the context of the completion. The basic model
3027  * for code completion is that Clang will parse a complete source file,
3028  * performing syntax checking up to the location where code-completion has
3029  * been requested. At that point, a special code-completion token is passed
3030  * to the parser, which recognizes this token and determines, based on the
3031  * current location in the C/Objective-C/C++ grammar and the state of
3032  * semantic analysis, what completions to provide. These completions are
3033  * returned via a new \c CXCodeCompleteResults structure.
3034  *
3035  * Code completion itself is meant to be triggered by the client when the
3036  * user types punctuation characters or whitespace, at which point the
3037  * code-completion location will coincide with the cursor. For example, if \c p
3038  * is a pointer, code-completion might be triggered after the "-" and then
3039  * after the ">" in \c p->. When the code-completion location is afer the ">",
3040  * the completion results will provide, e.g., the members of the struct that
3041  * "p" points to. The client is responsible for placing the cursor at the
3042  * beginning of the token currently being typed, then filtering the results
3043  * based on the contents of the token. For example, when code-completing for
3044  * the expression \c p->get, the client should provide the location just after
3045  * the ">" (e.g., pointing at the "g") to this code-completion hook. Then, the
3046  * client can filter the results based on the current token text ("get"), only
3047  * showing those results that start with "get". The intent of this interface
3048  * is to separate the relatively high-latency acquisition of code-completion
3049  * results from the filtering of results on a per-character basis, which must
3050  * have a lower latency.
3051  *
3052  * \param TU The translation unit in which code-completion should
3053  * occur. The source files for this translation unit need not be
3054  * completely up-to-date (and the contents of those source files may
3055  * be overridden via \p unsaved_files). Cursors referring into the
3056  * translation unit may be invalidated by this invocation.
3057  *
3058  * \param complete_filename The name of the source file where code
3059  * completion should be performed. This filename may be any file
3060  * included in the translation unit.
3061  *
3062  * \param complete_line The line at which code-completion should occur.
3063  *
3064  * \param complete_column The column at which code-completion should occur.
3065  * Note that the column should point just after the syntactic construct that
3066  * initiated code completion, and not in the middle of a lexical token.
3067  *
3068  * \param unsaved_files the Tiles that have not yet been saved to disk
3069  * but may be required for parsing or code completion, including the
3070  * contents of those files.  The contents and name of these files (as
3071  * specified by CXUnsavedFile) are copied when necessary, so the
3072  * client only needs to guarantee their validity until the call to
3073  * this function returns.
3074  *
3075  * \param num_unsaved_files The number of unsaved file entries in \p
3076  * unsaved_files.
3077  *
3078  * \param options Extra options that control the behavior of code
3079  * completion, expressed as a bitwise OR of the enumerators of the
3080  * CXCodeComplete_Flags enumeration. The
3081  * \c clang_defaultCodeCompleteOptions() function returns a default set
3082  * of code-completion options.
3083  *
3084  * \returns If successful, a new \c CXCodeCompleteResults structure
3085  * containing code-completion results, which should eventually be
3086  * freed with \c clang_disposeCodeCompleteResults(). If code
3087  * completion fails, returns NULL.
3088  */
3089 CINDEX_LINKAGE
3090 CXCodeCompleteResults *clang_codeCompleteAt(CXTranslationUnit TU,
3091                                             const char *complete_filename,
3092                                             unsigned complete_line,
3093                                             unsigned complete_column,
3094                                             struct CXUnsavedFile *unsaved_files,
3095                                             unsigned num_unsaved_files,
3096                                             unsigned options);
3097 
3098 /**
3099  * \brief Sort the code-completion results in case-insensitive alphabetical
3100  * order.
3101  *
3102  * \param Results The set of results to sort.
3103  * \param NumResults The number of results in \p Results.
3104  */
3105 CINDEX_LINKAGE
3106 void clang_sortCodeCompletionResults(CXCompletionResult *Results,
3107                                      unsigned NumResults);
3108 
3109 /**
3110  * \brief Free the given set of code-completion results.
3111  */
3112 CINDEX_LINKAGE
3113 void clang_disposeCodeCompleteResults(CXCodeCompleteResults *Results);
3114 
3115 /**
3116  * \brief Determine the number of diagnostics produced prior to the
3117  * location where code completion was performed.
3118  */
3119 CINDEX_LINKAGE
3120 unsigned clang_codeCompleteGetNumDiagnostics(CXCodeCompleteResults *Results);
3121 
3122 /**
3123  * \brief Retrieve a diagnostic associated with the given code completion.
3124  *
3125  * \param Result the code completion results to query.
3126  * \param Index the zero-based diagnostic number to retrieve.
3127  *
3128  * \returns the requested diagnostic. This diagnostic must be freed
3129  * via a call to \c clang_disposeDiagnostic().
3130  */
3131 CINDEX_LINKAGE
3132 CXDiagnostic clang_codeCompleteGetDiagnostic(CXCodeCompleteResults *Results,
3133                                              unsigned Index);
3134 
3135 /**
3136  * \brief Determines what compeltions are appropriate for the context
3137  * the given code completion.
3138  *
3139  * \param Results the code completion results to query
3140  *
3141  * \returns the kinds of completions that are appropriate for use
3142  * along with the given code completion results.
3143  */
3144 CINDEX_LINKAGE
3145 unsigned long long clang_codeCompleteGetContexts(
3146                                                 CXCodeCompleteResults *Results);
3147 
3148 /**
3149  * @}
3150  */
3151 
3152 
3153 /**
3154  * \defgroup CINDEX_MISC Miscellaneous utility functions
3155  *
3156  * @{
3157  */
3158 
3159 /**
3160  * \brief Return a version string, suitable for showing to a user, but not
3161  *        intended to be parsed (the format is not guaranteed to be stable).
3162  */
3163 CINDEX_LINKAGE CXString clang_getClangVersion();
3164 
3165 
3166 /**
3167  * \brief Enable/disable crash recovery.
3168  *
3169  * \param Flag to indicate if crash recovery is enabled.  A non-zero value
3170  *        enables crash recovery, while 0 disables it.
3171  */
3172 CINDEX_LINKAGE void clang_toggleCrashRecovery(unsigned isEnabled);
3173 
3174  /**
3175   * \brief Visitor invoked for each file in a translation unit
3176   *        (used with clang_getInclusions()).
3177   *
3178   * This visitor function will be invoked by clang_getInclusions() for each
3179   * file included (either at the top-level or by #include directives) within
3180   * a translation unit.  The first argument is the file being included, and
3181   * the second and third arguments provide the inclusion stack.  The
3182   * array is sorted in order of immediate inclusion.  For example,
3183   * the first element refers to the location that included 'included_file'.
3184   */
3185 typedef void (*CXInclusionVisitor)(CXFile included_file,
3186                                    CXSourceLocation* inclusion_stack,
3187                                    unsigned include_len,
3188                                    CXClientData client_data);
3189 
3190 /**
3191  * \brief Visit the set of preprocessor inclusions in a translation unit.
3192  *   The visitor function is called with the provided data for every included
3193  *   file.  This does not include headers included by the PCH file (unless one
3194  *   is inspecting the inclusions in the PCH file itself).
3195  */
3196 CINDEX_LINKAGE void clang_getInclusions(CXTranslationUnit tu,
3197                                         CXInclusionVisitor visitor,
3198                                         CXClientData client_data);
3199 
3200 /**
3201  * @}
3202  */
3203 
3204 /** \defgroup CINDEX_REMAPPING Remapping functions
3205  *
3206  * @{
3207  */
3208 
3209 /**
3210  * \brief A remapping of original source files and their translated files.
3211  */
3212 typedef void *CXRemapping;
3213 
3214 /**
3215  * \brief Retrieve a remapping.
3216  *
3217  * \param path the path that contains metadata about remappings.
3218  *
3219  * \returns the requested remapping. This remapping must be freed
3220  * via a call to \c clang_remap_dispose(). Can return NULL if an error occurred.
3221  */
3222 CINDEX_LINKAGE CXRemapping clang_getRemappings(const char *path);
3223 
3224 /**
3225  * \brief Determine the number of remappings.
3226  */
3227 CINDEX_LINKAGE unsigned clang_remap_getNumFiles(CXRemapping);
3228 
3229 /**
3230  * \brief Get the original and the associated filename from the remapping.
3231  *
3232  * \param original If non-NULL, will be set to the original filename.
3233  *
3234  * \param transformed If non-NULL, will be set to the filename that the original
3235  * is associated with.
3236  */
3237 CINDEX_LINKAGE void clang_remap_getFilenames(CXRemapping, unsigned index,
3238                                      CXString *original, CXString *transformed);
3239 
3240 /**
3241  * \brief Dispose the remapping.
3242  */
3243 CINDEX_LINKAGE void clang_remap_dispose(CXRemapping);
3244 
3245 /**
3246  * @}
3247  */
3248 
3249 /**
3250  * @}
3251  */
3252 
3253 #ifdef __cplusplus
3254 }
3255 #endif
3256 #endif
3257 
3258