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[binutils-gdb.git] / gdb / symtab.h
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1 /* Symbol table definitions for GDB.
3 Copyright (C) 1986-2022 Free Software Foundation, Inc.
5 This file is part of GDB.
7 This program is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3 of the License, or
10 (at your option) any later version.
12 This program is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with this program. If not, see <http://www.gnu.org/licenses/>. */
20 #if !defined (SYMTAB_H)
21 #define SYMTAB_H 1
23 #include <array>
24 #include <vector>
25 #include <string>
26 #include <set>
27 #include "gdbsupport/gdb_vecs.h"
28 #include "gdbtypes.h"
29 #include "gdbsupport/gdb_obstack.h"
30 #include "gdbsupport/gdb_regex.h"
31 #include "gdbsupport/enum-flags.h"
32 #include "gdbsupport/function-view.h"
33 #include "gdbsupport/gdb_optional.h"
34 #include "gdbsupport/gdb_string_view.h"
35 #include "gdbsupport/next-iterator.h"
36 #include "gdbsupport/iterator-range.h"
37 #include "completer.h"
38 #include "gdb-demangle.h"
39 #include "split-name.h"
41 /* Opaque declarations. */
42 struct ui_file;
43 struct frame_info;
44 struct symbol;
45 struct obstack;
46 struct objfile;
47 struct block;
48 struct blockvector;
49 struct axs_value;
50 struct agent_expr;
51 struct program_space;
52 struct language_defn;
53 struct common_block;
54 struct obj_section;
55 struct cmd_list_element;
56 class probe;
57 struct lookup_name_info;
59 /* How to match a lookup name against a symbol search name. */
60 enum class symbol_name_match_type
62 /* Wild matching. Matches unqualified symbol names in all
63 namespace/module/packages, etc. */
64 WILD,
66 /* Full matching. The lookup name indicates a fully-qualified name,
67 and only matches symbol search names in the specified
68 namespace/module/package. */
69 FULL,
71 /* Search name matching. This is like FULL, but the search name did
72 not come from the user; instead it is already a search name
73 retrieved from a search_name () call.
74 For Ada, this avoids re-encoding an already-encoded search name
75 (which would potentially incorrectly lowercase letters in the
76 linkage/search name that should remain uppercase). For C++, it
77 avoids trying to demangle a name we already know is
78 demangled. */
79 SEARCH_NAME,
81 /* Expression matching. The same as FULL matching in most
82 languages. The same as WILD matching in Ada. */
83 EXPRESSION,
86 /* Hash the given symbol search name according to LANGUAGE's
87 rules. */
88 extern unsigned int search_name_hash (enum language language,
89 const char *search_name);
91 /* Ada-specific bits of a lookup_name_info object. This is lazily
92 constructed on demand. */
94 class ada_lookup_name_info final
96 public:
97 /* Construct. */
98 explicit ada_lookup_name_info (const lookup_name_info &lookup_name);
100 /* Compare SYMBOL_SEARCH_NAME with our lookup name, using MATCH_TYPE
101 as name match type. Returns true if there's a match, false
102 otherwise. If non-NULL, store the matching results in MATCH. */
103 bool matches (const char *symbol_search_name,
104 symbol_name_match_type match_type,
105 completion_match_result *comp_match_res) const;
107 /* The Ada-encoded lookup name. */
108 const std::string &lookup_name () const
109 { return m_encoded_name; }
111 /* Return true if we're supposed to be doing a wild match look
112 up. */
113 bool wild_match_p () const
114 { return m_wild_match_p; }
116 /* Return true if we're looking up a name inside package
117 Standard. */
118 bool standard_p () const
119 { return m_standard_p; }
121 /* Return true if doing a verbatim match. */
122 bool verbatim_p () const
123 { return m_verbatim_p; }
125 /* A wrapper for ::split_name that handles some Ada-specific
126 peculiarities. */
127 std::vector<gdb::string_view> split_name () const
129 if (m_verbatim_p || m_standard_p)
131 std::vector<gdb::string_view> result;
132 if (m_standard_p)
133 result.emplace_back ("standard");
134 result.emplace_back (m_encoded_name);
135 return result;
137 return ::split_name (m_encoded_name.c_str (), split_style::UNDERSCORE);
140 private:
141 /* The Ada-encoded lookup name. */
142 std::string m_encoded_name;
144 /* Whether the user-provided lookup name was Ada encoded. If so,
145 then return encoded names in the 'matches' method's 'completion
146 match result' output. */
147 bool m_encoded_p : 1;
149 /* True if really doing wild matching. Even if the user requests
150 wild matching, some cases require full matching. */
151 bool m_wild_match_p : 1;
153 /* True if doing a verbatim match. This is true if the decoded
154 version of the symbol name is wrapped in '<'/'>'. This is an
155 escape hatch users can use to look up symbols the Ada encoding
156 does not understand. */
157 bool m_verbatim_p : 1;
159 /* True if the user specified a symbol name that is inside package
160 Standard. Symbol names inside package Standard are handled
161 specially. We always do a non-wild match of the symbol name
162 without the "standard__" prefix, and only search static and
163 global symbols. This was primarily introduced in order to allow
164 the user to specifically access the standard exceptions using,
165 for instance, Standard.Constraint_Error when Constraint_Error is
166 ambiguous (due to the user defining its own Constraint_Error
167 entity inside its program). */
168 bool m_standard_p : 1;
171 /* Language-specific bits of a lookup_name_info object, for languages
172 that do name searching using demangled names (C++/D/Go). This is
173 lazily constructed on demand. */
175 struct demangle_for_lookup_info final
177 public:
178 demangle_for_lookup_info (const lookup_name_info &lookup_name,
179 language lang);
181 /* The demangled lookup name. */
182 const std::string &lookup_name () const
183 { return m_demangled_name; }
185 private:
186 /* The demangled lookup name. */
187 std::string m_demangled_name;
190 /* Object that aggregates all information related to a symbol lookup
191 name. I.e., the name that is matched against the symbol's search
192 name. Caches per-language information so that it doesn't require
193 recomputing it for every symbol comparison, like for example the
194 Ada encoded name and the symbol's name hash for a given language.
195 The object is conceptually immutable once constructed, and thus has
196 no setters. This is to prevent some code path from tweaking some
197 property of the lookup name for some local reason and accidentally
198 altering the results of any continuing search(es).
199 lookup_name_info objects are generally passed around as a const
200 reference to reinforce that. (They're not passed around by value
201 because they're not small.) */
202 class lookup_name_info final
204 public:
205 /* We delete this overload so that the callers are required to
206 explicitly handle the lifetime of the name. */
207 lookup_name_info (std::string &&name,
208 symbol_name_match_type match_type,
209 bool completion_mode = false,
210 bool ignore_parameters = false) = delete;
212 /* This overload requires that NAME have a lifetime at least as long
213 as the lifetime of this object. */
214 lookup_name_info (const std::string &name,
215 symbol_name_match_type match_type,
216 bool completion_mode = false,
217 bool ignore_parameters = false)
218 : m_match_type (match_type),
219 m_completion_mode (completion_mode),
220 m_ignore_parameters (ignore_parameters),
221 m_name (name)
224 /* This overload requires that NAME have a lifetime at least as long
225 as the lifetime of this object. */
226 lookup_name_info (const char *name,
227 symbol_name_match_type match_type,
228 bool completion_mode = false,
229 bool ignore_parameters = false)
230 : m_match_type (match_type),
231 m_completion_mode (completion_mode),
232 m_ignore_parameters (ignore_parameters),
233 m_name (name)
236 /* Getters. See description of each corresponding field. */
237 symbol_name_match_type match_type () const { return m_match_type; }
238 bool completion_mode () const { return m_completion_mode; }
239 gdb::string_view name () const { return m_name; }
240 const bool ignore_parameters () const { return m_ignore_parameters; }
242 /* Like the "name" method but guarantees that the returned string is
243 \0-terminated. */
244 const char *c_str () const
246 /* Actually this is always guaranteed due to how the class is
247 constructed. */
248 return m_name.data ();
251 /* Return a version of this lookup name that is usable with
252 comparisons against symbols have no parameter info, such as
253 psymbols and GDB index symbols. */
254 lookup_name_info make_ignore_params () const
256 return lookup_name_info (c_str (), m_match_type, m_completion_mode,
257 true /* ignore params */);
260 /* Get the search name hash for searches in language LANG. */
261 unsigned int search_name_hash (language lang) const
263 /* Only compute each language's hash once. */
264 if (!m_demangled_hashes_p[lang])
266 m_demangled_hashes[lang]
267 = ::search_name_hash (lang, language_lookup_name (lang));
268 m_demangled_hashes_p[lang] = true;
270 return m_demangled_hashes[lang];
273 /* Get the search name for searches in language LANG. */
274 const char *language_lookup_name (language lang) const
276 switch (lang)
278 case language_ada:
279 return ada ().lookup_name ().c_str ();
280 case language_cplus:
281 return cplus ().lookup_name ().c_str ();
282 case language_d:
283 return d ().lookup_name ().c_str ();
284 case language_go:
285 return go ().lookup_name ().c_str ();
286 default:
287 return m_name.data ();
291 /* A wrapper for ::split_name (see split-name.h) that splits this
292 name, and that handles any language-specific peculiarities. */
293 std::vector<gdb::string_view> split_name (language lang) const
295 if (lang == language_ada)
296 return ada ().split_name ();
297 split_style style = split_style::NONE;
298 switch (lang)
300 case language_cplus:
301 case language_rust:
302 style = split_style::CXX;
303 break;
304 case language_d:
305 case language_go:
306 style = split_style::DOT;
307 break;
309 return ::split_name (language_lookup_name (lang), style);
312 /* Get the Ada-specific lookup info. */
313 const ada_lookup_name_info &ada () const
315 maybe_init (m_ada);
316 return *m_ada;
319 /* Get the C++-specific lookup info. */
320 const demangle_for_lookup_info &cplus () const
322 maybe_init (m_cplus, language_cplus);
323 return *m_cplus;
326 /* Get the D-specific lookup info. */
327 const demangle_for_lookup_info &d () const
329 maybe_init (m_d, language_d);
330 return *m_d;
333 /* Get the Go-specific lookup info. */
334 const demangle_for_lookup_info &go () const
336 maybe_init (m_go, language_go);
337 return *m_go;
340 /* Get a reference to a lookup_name_info object that matches any
341 symbol name. */
342 static const lookup_name_info &match_any ();
344 private:
345 /* Initialize FIELD, if not initialized yet. */
346 template<typename Field, typename... Args>
347 void maybe_init (Field &field, Args&&... args) const
349 if (!field)
350 field.emplace (*this, std::forward<Args> (args)...);
353 /* The lookup info as passed to the ctor. */
354 symbol_name_match_type m_match_type;
355 bool m_completion_mode;
356 bool m_ignore_parameters;
357 gdb::string_view m_name;
359 /* Language-specific info. These fields are filled lazily the first
360 time a lookup is done in the corresponding language. They're
361 mutable because lookup_name_info objects are typically passed
362 around by const reference (see intro), and they're conceptually
363 "cache" that can always be reconstructed from the non-mutable
364 fields. */
365 mutable gdb::optional<ada_lookup_name_info> m_ada;
366 mutable gdb::optional<demangle_for_lookup_info> m_cplus;
367 mutable gdb::optional<demangle_for_lookup_info> m_d;
368 mutable gdb::optional<demangle_for_lookup_info> m_go;
370 /* The demangled hashes. Stored in an array with one entry for each
371 possible language. The second array records whether we've
372 already computed the each language's hash. (These are separate
373 arrays instead of a single array of optional<unsigned> to avoid
374 alignment padding). */
375 mutable std::array<unsigned int, nr_languages> m_demangled_hashes;
376 mutable std::array<bool, nr_languages> m_demangled_hashes_p {};
379 /* Comparison function for completion symbol lookup.
381 Returns true if the symbol name matches against LOOKUP_NAME.
383 SYMBOL_SEARCH_NAME should be a symbol's "search" name.
385 On success and if non-NULL, COMP_MATCH_RES->match is set to point
386 to the symbol name as should be presented to the user as a
387 completion match list element. In most languages, this is the same
388 as the symbol's search name, but in some, like Ada, the display
389 name is dynamically computed within the comparison routine.
391 Also, on success and if non-NULL, COMP_MATCH_RES->match_for_lcd
392 points the part of SYMBOL_SEARCH_NAME that was considered to match
393 LOOKUP_NAME. E.g., in C++, in linespec/wild mode, if the symbol is
394 "foo::function()" and LOOKUP_NAME is "function(", MATCH_FOR_LCD
395 points to "function()" inside SYMBOL_SEARCH_NAME. */
396 typedef bool (symbol_name_matcher_ftype)
397 (const char *symbol_search_name,
398 const lookup_name_info &lookup_name,
399 completion_match_result *comp_match_res);
401 /* Some of the structures in this file are space critical.
402 The space-critical structures are:
404 struct general_symbol_info
405 struct symbol
406 struct partial_symbol
408 These structures are laid out to encourage good packing.
409 They use ENUM_BITFIELD and short int fields, and they order the
410 structure members so that fields less than a word are next
411 to each other so they can be packed together. */
413 /* Rearranged: used ENUM_BITFIELD and rearranged field order in
414 all the space critical structures (plus struct minimal_symbol).
415 Memory usage dropped from 99360768 bytes to 90001408 bytes.
416 I measured this with before-and-after tests of
417 "HEAD-old-gdb -readnow HEAD-old-gdb" and
418 "HEAD-new-gdb -readnow HEAD-old-gdb" on native i686-pc-linux-gnu,
419 red hat linux 8, with LD_LIBRARY_PATH=/usr/lib/debug,
420 typing "maint space 1" at the first command prompt.
422 Here is another measurement (from andrew c):
423 # no /usr/lib/debug, just plain glibc, like a normal user
424 gdb HEAD-old-gdb
425 (gdb) break internal_error
426 (gdb) run
427 (gdb) maint internal-error
428 (gdb) backtrace
429 (gdb) maint space 1
431 gdb gdb_6_0_branch 2003-08-19 space used: 8896512
432 gdb HEAD 2003-08-19 space used: 8904704
433 gdb HEAD 2003-08-21 space used: 8396800 (+symtab.h)
434 gdb HEAD 2003-08-21 space used: 8265728 (+gdbtypes.h)
436 The third line shows the savings from the optimizations in symtab.h.
437 The fourth line shows the savings from the optimizations in
438 gdbtypes.h. Both optimizations are in gdb HEAD now.
440 --chastain 2003-08-21 */
442 /* Define a structure for the information that is common to all symbol types,
443 including minimal symbols, partial symbols, and full symbols. In a
444 multilanguage environment, some language specific information may need to
445 be recorded along with each symbol. */
447 /* This structure is space critical. See space comments at the top. */
449 struct general_symbol_info
451 /* Short version as to when to use which name accessor:
452 Use natural_name () to refer to the name of the symbol in the original
453 source code. Use linkage_name () if you want to know what the linker
454 thinks the symbol's name is. Use print_name () for output. Use
455 demangled_name () if you specifically need to know whether natural_name ()
456 and linkage_name () are different. */
458 const char *linkage_name () const
459 { return m_name; }
461 /* Return SYMBOL's "natural" name, i.e. the name that it was called in
462 the original source code. In languages like C++ where symbols may
463 be mangled for ease of manipulation by the linker, this is the
464 demangled name. */
465 const char *natural_name () const;
467 /* Returns a version of the name of a symbol that is
468 suitable for output. In C++ this is the "demangled" form of the
469 name if demangle is on and the "mangled" form of the name if
470 demangle is off. In other languages this is just the symbol name.
471 The result should never be NULL. Don't use this for internal
472 purposes (e.g. storing in a hashtable): it's only suitable for output. */
473 const char *print_name () const
474 { return demangle ? natural_name () : linkage_name (); }
476 /* Return the demangled name for a symbol based on the language for
477 that symbol. If no demangled name exists, return NULL. */
478 const char *demangled_name () const;
480 /* Returns the name to be used when sorting and searching symbols.
481 In C++, we search for the demangled form of a name,
482 and so sort symbols accordingly. In Ada, however, we search by mangled
483 name. If there is no distinct demangled name, then this
484 returns the same value (same pointer) as linkage_name (). */
485 const char *search_name () const;
487 /* Set just the linkage name of a symbol; do not try to demangle
488 it. Used for constructs which do not have a mangled name,
489 e.g. struct tags. Unlike compute_and_set_names, linkage_name must
490 be terminated and either already on the objfile's obstack or
491 permanently allocated. */
492 void set_linkage_name (const char *linkage_name)
493 { m_name = linkage_name; }
495 /* Set the demangled name of this symbol to NAME. NAME must be
496 already correctly allocated. If the symbol's language is Ada,
497 then the name is ignored and the obstack is set. */
498 void set_demangled_name (const char *name, struct obstack *obstack);
500 enum language language () const
501 { return m_language; }
503 /* Initializes the language dependent portion of a symbol
504 depending upon the language for the symbol. */
505 void set_language (enum language language, struct obstack *obstack);
507 /* Set the linkage and natural names of a symbol, by demangling
508 the linkage name. If linkage_name may not be nullterminated,
509 copy_name must be set to true. */
510 void compute_and_set_names (gdb::string_view linkage_name, bool copy_name,
511 struct objfile_per_bfd_storage *per_bfd,
512 gdb::optional<hashval_t> hash
513 = gdb::optional<hashval_t> ());
515 CORE_ADDR value_address () const
517 return m_value.address;
520 void set_value_address (CORE_ADDR address)
522 m_value.address = address;
525 /* Name of the symbol. This is a required field. Storage for the
526 name is allocated on the objfile_obstack for the associated
527 objfile. For languages like C++ that make a distinction between
528 the mangled name and demangled name, this is the mangled
529 name. */
531 const char *m_name;
533 /* Value of the symbol. Which member of this union to use, and what
534 it means, depends on what kind of symbol this is and its
535 SYMBOL_CLASS. See comments there for more details. All of these
536 are in host byte order (though what they point to might be in
537 target byte order, e.g. LOC_CONST_BYTES). */
539 union
541 LONGEST ivalue;
543 const struct block *block;
545 const gdb_byte *bytes;
547 CORE_ADDR address;
549 /* A common block. Used with LOC_COMMON_BLOCK. */
551 const struct common_block *common_block;
553 /* For opaque typedef struct chain. */
555 struct symbol *chain;
557 m_value;
559 /* Since one and only one language can apply, wrap the language specific
560 information inside a union. */
562 union
564 /* A pointer to an obstack that can be used for storage associated
565 with this symbol. This is only used by Ada, and only when the
566 'ada_mangled' field is zero. */
567 struct obstack *obstack;
569 /* This is used by languages which wish to store a demangled name.
570 currently used by Ada, C++, and Objective C. */
571 const char *demangled_name;
573 language_specific;
575 /* Record the source code language that applies to this symbol.
576 This is used to select one of the fields from the language specific
577 union above. */
579 ENUM_BITFIELD(language) m_language : LANGUAGE_BITS;
581 /* This is only used by Ada. If set, then the 'demangled_name' field
582 of language_specific is valid. Otherwise, the 'obstack' field is
583 valid. */
584 unsigned int ada_mangled : 1;
586 /* Which section is this symbol in? This is an index into
587 section_offsets for this objfile. Negative means that the symbol
588 does not get relocated relative to a section. */
590 short m_section;
592 /* Set the index into the obj_section list (within the containing
593 objfile) for the section that contains this symbol. See M_SECTION
594 for more details. */
596 void set_section_index (short idx)
597 { m_section = idx; }
599 /* Return the index into the obj_section list (within the containing
600 objfile) for the section that contains this symbol. See M_SECTION
601 for more details. */
603 short section_index () const
604 { return m_section; }
606 /* Return the obj_section from OBJFILE for this symbol. The symbol
607 returned is based on the SECTION member variable, and can be nullptr
608 if SECTION is negative. */
610 struct obj_section *obj_section (const struct objfile *objfile) const;
613 extern CORE_ADDR symbol_overlayed_address (CORE_ADDR, struct obj_section *);
615 /* Return the address of SYM. The MAYBE_COPIED flag must be set on
616 SYM. If SYM appears in the main program's minimal symbols, then
617 that minsym's address is returned; otherwise, SYM's address is
618 returned. This should generally only be used via the
619 SYMBOL_VALUE_ADDRESS macro. */
621 extern CORE_ADDR get_symbol_address (const struct symbol *sym);
623 /* Try to determine the demangled name for a symbol, based on the
624 language of that symbol. If the language is set to language_auto,
625 it will attempt to find any demangling algorithm that works and
626 then set the language appropriately. The returned name is allocated
627 by the demangler and should be xfree'd. */
629 extern gdb::unique_xmalloc_ptr<char> symbol_find_demangled_name
630 (struct general_symbol_info *gsymbol, const char *mangled);
632 /* Return true if NAME matches the "search" name of GSYMBOL, according
633 to the symbol's language. */
634 extern bool symbol_matches_search_name
635 (const struct general_symbol_info *gsymbol,
636 const lookup_name_info &name);
638 /* Compute the hash of the given symbol search name of a symbol of
639 language LANGUAGE. */
640 extern unsigned int search_name_hash (enum language language,
641 const char *search_name);
643 /* Classification types for a minimal symbol. These should be taken as
644 "advisory only", since if gdb can't easily figure out a
645 classification it simply selects mst_unknown. It may also have to
646 guess when it can't figure out which is a better match between two
647 types (mst_data versus mst_bss) for example. Since the minimal
648 symbol info is sometimes derived from the BFD library's view of a
649 file, we need to live with what information bfd supplies. */
651 enum minimal_symbol_type
653 mst_unknown = 0, /* Unknown type, the default */
654 mst_text, /* Generally executable instructions */
656 /* A GNU ifunc symbol, in the .text section. GDB uses to know
657 whether the user is setting a breakpoint on a GNU ifunc function,
658 and thus GDB needs to actually set the breakpoint on the target
659 function. It is also used to know whether the program stepped
660 into an ifunc resolver -- the resolver may get a separate
661 symbol/alias under a different name, but it'll have the same
662 address as the ifunc symbol. */
663 mst_text_gnu_ifunc, /* Executable code returning address
664 of executable code */
666 /* A GNU ifunc function descriptor symbol, in a data section
667 (typically ".opd"). Seen on architectures that use function
668 descriptors, like PPC64/ELFv1. In this case, this symbol's value
669 is the address of the descriptor. There'll be a corresponding
670 mst_text_gnu_ifunc synthetic symbol for the text/entry
671 address. */
672 mst_data_gnu_ifunc, /* Executable code returning address
673 of executable code */
675 mst_slot_got_plt, /* GOT entries for .plt sections */
676 mst_data, /* Generally initialized data */
677 mst_bss, /* Generally uninitialized data */
678 mst_abs, /* Generally absolute (nonrelocatable) */
679 /* GDB uses mst_solib_trampoline for the start address of a shared
680 library trampoline entry. Breakpoints for shared library functions
681 are put there if the shared library is not yet loaded.
682 After the shared library is loaded, lookup_minimal_symbol will
683 prefer the minimal symbol from the shared library (usually
684 a mst_text symbol) over the mst_solib_trampoline symbol, and the
685 breakpoints will be moved to their true address in the shared
686 library via breakpoint_re_set. */
687 mst_solib_trampoline, /* Shared library trampoline code */
688 /* For the mst_file* types, the names are only guaranteed to be unique
689 within a given .o file. */
690 mst_file_text, /* Static version of mst_text */
691 mst_file_data, /* Static version of mst_data */
692 mst_file_bss, /* Static version of mst_bss */
693 nr_minsym_types
696 /* The number of enum minimal_symbol_type values, with some padding for
697 reasonable growth. */
698 #define MINSYM_TYPE_BITS 4
699 gdb_static_assert (nr_minsym_types <= (1 << MINSYM_TYPE_BITS));
701 /* Return the address of MINSYM, which comes from OBJF. The
702 MAYBE_COPIED flag must be set on MINSYM. If MINSYM appears in the
703 main program's minimal symbols, then that minsym's address is
704 returned; otherwise, MINSYM's address is returned. This should
705 generally only be used via the MSYMBOL_VALUE_ADDRESS macro. */
707 extern CORE_ADDR get_msymbol_address (struct objfile *objf,
708 const struct minimal_symbol *minsym);
710 /* Define a simple structure used to hold some very basic information about
711 all defined global symbols (text, data, bss, abs, etc). The only required
712 information is the general_symbol_info.
714 In many cases, even if a file was compiled with no special options for
715 debugging at all, as long as was not stripped it will contain sufficient
716 information to build a useful minimal symbol table using this structure.
717 Even when a file contains enough debugging information to build a full
718 symbol table, these minimal symbols are still useful for quickly mapping
719 between names and addresses, and vice versa. They are also sometimes
720 used to figure out what full symbol table entries need to be read in. */
722 struct minimal_symbol : public general_symbol_info
724 LONGEST value_longest () const
726 return m_value.ivalue;
729 /* The relocated address of the minimal symbol, using the section
730 offsets from OBJFILE. */
731 CORE_ADDR value_address (objfile *objfile) const;
733 /* The unrelocated address of the minimal symbol. */
734 CORE_ADDR value_raw_address () const
736 return m_value.address;
739 /* Return this minimal symbol's type. */
741 minimal_symbol_type type () const
743 return m_type;
746 /* Set this minimal symbol's type. */
748 void set_type (minimal_symbol_type type)
750 m_type = type;
753 /* Return this minimal symbol's size. */
755 unsigned long size () const
757 return m_size;
760 /* Set this minimal symbol's size. */
762 void set_size (unsigned long size)
764 m_size = size;
765 m_has_size = 1;
768 /* Return true if this minimal symbol's size is known. */
770 bool has_size () const
772 return m_has_size;
775 /* Return this minimal symbol's first target-specific flag. */
777 bool target_flag_1 () const
779 return m_target_flag_1;
782 /* Set this minimal symbol's first target-specific flag. */
784 void set_target_flag_1 (bool target_flag_1)
786 m_target_flag_1 = target_flag_1;
789 /* Return this minimal symbol's second target-specific flag. */
791 bool target_flag_2 () const
793 return m_target_flag_2;
796 /* Set this minimal symbol's second target-specific flag. */
798 void set_target_flag_2 (bool target_flag_2)
800 m_target_flag_2 = target_flag_2;
803 /* Size of this symbol. dbx_end_psymtab in dbxread.c uses this
804 information to calculate the end of the partial symtab based on the
805 address of the last symbol plus the size of the last symbol. */
807 unsigned long m_size;
809 /* Which source file is this symbol in? Only relevant for mst_file_*. */
810 const char *filename;
812 /* Classification type for this minimal symbol. */
814 ENUM_BITFIELD(minimal_symbol_type) m_type : MINSYM_TYPE_BITS;
816 /* Non-zero if this symbol was created by gdb.
817 Such symbols do not appear in the output of "info var|fun". */
818 unsigned int created_by_gdb : 1;
820 /* Two flag bits provided for the use of the target. */
821 unsigned int m_target_flag_1 : 1;
822 unsigned int m_target_flag_2 : 1;
824 /* Nonzero iff the size of the minimal symbol has been set.
825 Symbol size information can sometimes not be determined, because
826 the object file format may not carry that piece of information. */
827 unsigned int m_has_size : 1;
829 /* For data symbols only, if this is set, then the symbol might be
830 subject to copy relocation. In this case, a minimal symbol
831 matching the symbol's linkage name is first looked for in the
832 main objfile. If found, then that address is used; otherwise the
833 address in this symbol is used. */
835 unsigned maybe_copied : 1;
837 /* Non-zero if this symbol ever had its demangled name set (even if
838 it was set to NULL). */
839 unsigned int name_set : 1;
841 /* Minimal symbols with the same hash key are kept on a linked
842 list. This is the link. */
844 struct minimal_symbol *hash_next;
846 /* Minimal symbols are stored in two different hash tables. This is
847 the `next' pointer for the demangled hash table. */
849 struct minimal_symbol *demangled_hash_next;
851 /* True if this symbol is of some data type. */
853 bool data_p () const;
855 /* True if MSYMBOL is of some text type. */
857 bool text_p () const;
860 #include "minsyms.h"
864 /* Represent one symbol name; a variable, constant, function or typedef. */
866 /* Different name domains for symbols. Looking up a symbol specifies a
867 domain and ignores symbol definitions in other name domains. */
869 typedef enum domain_enum_tag
871 /* UNDEF_DOMAIN is used when a domain has not been discovered or
872 none of the following apply. This usually indicates an error either
873 in the symbol information or in gdb's handling of symbols. */
875 UNDEF_DOMAIN,
877 /* VAR_DOMAIN is the usual domain. In C, this contains variables,
878 function names, typedef names and enum type values. */
880 VAR_DOMAIN,
882 /* STRUCT_DOMAIN is used in C to hold struct, union and enum type names.
883 Thus, if `struct foo' is used in a C program, it produces a symbol named
884 `foo' in the STRUCT_DOMAIN. */
886 STRUCT_DOMAIN,
888 /* MODULE_DOMAIN is used in Fortran to hold module type names. */
890 MODULE_DOMAIN,
892 /* LABEL_DOMAIN may be used for names of labels (for gotos). */
894 LABEL_DOMAIN,
896 /* Fortran common blocks. Their naming must be separate from VAR_DOMAIN.
897 They also always use LOC_COMMON_BLOCK. */
898 COMMON_BLOCK_DOMAIN,
900 /* This must remain last. */
901 NR_DOMAINS
902 } domain_enum;
904 /* The number of bits in a symbol used to represent the domain. */
906 #define SYMBOL_DOMAIN_BITS 3
907 gdb_static_assert (NR_DOMAINS <= (1 << SYMBOL_DOMAIN_BITS));
909 extern const char *domain_name (domain_enum);
911 /* Searching domains, used when searching for symbols. Element numbers are
912 hardcoded in GDB, check all enum uses before changing it. */
914 enum search_domain
916 /* Everything in VAR_DOMAIN minus FUNCTIONS_DOMAIN and
917 TYPES_DOMAIN. */
918 VARIABLES_DOMAIN = 0,
920 /* All functions -- for some reason not methods, though. */
921 FUNCTIONS_DOMAIN = 1,
923 /* All defined types */
924 TYPES_DOMAIN = 2,
926 /* All modules. */
927 MODULES_DOMAIN = 3,
929 /* Any type. */
930 ALL_DOMAIN = 4
933 extern const char *search_domain_name (enum search_domain);
935 /* An address-class says where to find the value of a symbol. */
937 enum address_class
939 /* Not used; catches errors. */
941 LOC_UNDEF,
943 /* Value is constant int SYMBOL_VALUE, host byteorder. */
945 LOC_CONST,
947 /* Value is at fixed address SYMBOL_VALUE_ADDRESS. */
949 LOC_STATIC,
951 /* Value is in register. SYMBOL_VALUE is the register number
952 in the original debug format. SYMBOL_REGISTER_OPS holds a
953 function that can be called to transform this into the
954 actual register number this represents in a specific target
955 architecture (gdbarch).
957 For some symbol formats (stabs, for some compilers at least),
958 the compiler generates two symbols, an argument and a register.
959 In some cases we combine them to a single LOC_REGISTER in symbol
960 reading, but currently not for all cases (e.g. it's passed on the
961 stack and then loaded into a register). */
963 LOC_REGISTER,
965 /* It's an argument; the value is at SYMBOL_VALUE offset in arglist. */
967 LOC_ARG,
969 /* Value address is at SYMBOL_VALUE offset in arglist. */
971 LOC_REF_ARG,
973 /* Value is in specified register. Just like LOC_REGISTER except the
974 register holds the address of the argument instead of the argument
975 itself. This is currently used for the passing of structs and unions
976 on sparc and hppa. It is also used for call by reference where the
977 address is in a register, at least by mipsread.c. */
979 LOC_REGPARM_ADDR,
981 /* Value is a local variable at SYMBOL_VALUE offset in stack frame. */
983 LOC_LOCAL,
985 /* Value not used; definition in SYMBOL_TYPE. Symbols in the domain
986 STRUCT_DOMAIN all have this class. */
988 LOC_TYPEDEF,
990 /* Value is address SYMBOL_VALUE_ADDRESS in the code. */
992 LOC_LABEL,
994 /* In a symbol table, value is SYMBOL_BLOCK_VALUE of a `struct block'.
995 In a partial symbol table, SYMBOL_VALUE_ADDRESS is the start address
996 of the block. Function names have this class. */
998 LOC_BLOCK,
1000 /* Value is a constant byte-sequence pointed to by SYMBOL_VALUE_BYTES, in
1001 target byte order. */
1003 LOC_CONST_BYTES,
1005 /* Value is at fixed address, but the address of the variable has
1006 to be determined from the minimal symbol table whenever the
1007 variable is referenced.
1008 This happens if debugging information for a global symbol is
1009 emitted and the corresponding minimal symbol is defined
1010 in another object file or runtime common storage.
1011 The linker might even remove the minimal symbol if the global
1012 symbol is never referenced, in which case the symbol remains
1013 unresolved.
1015 GDB would normally find the symbol in the minimal symbol table if it will
1016 not find it in the full symbol table. But a reference to an external
1017 symbol in a local block shadowing other definition requires full symbol
1018 without possibly having its address available for LOC_STATIC. Testcase
1019 is provided as `gdb.dwarf2/dw2-unresolved.exp'.
1021 This is also used for thread local storage (TLS) variables. In this case,
1022 the address of the TLS variable must be determined when the variable is
1023 referenced, from the MSYMBOL_VALUE_RAW_ADDRESS, which is the offset
1024 of the TLS variable in the thread local storage of the shared
1025 library/object. */
1027 LOC_UNRESOLVED,
1029 /* The variable does not actually exist in the program.
1030 The value is ignored. */
1032 LOC_OPTIMIZED_OUT,
1034 /* The variable's address is computed by a set of location
1035 functions (see "struct symbol_computed_ops" below). */
1036 LOC_COMPUTED,
1038 /* The variable uses general_symbol_info->value->common_block field.
1039 It also always uses COMMON_BLOCK_DOMAIN. */
1040 LOC_COMMON_BLOCK,
1042 /* Not used, just notes the boundary of the enum. */
1043 LOC_FINAL_VALUE
1046 /* The number of bits needed for values in enum address_class, with some
1047 padding for reasonable growth, and room for run-time registered address
1048 classes. See symtab.c:MAX_SYMBOL_IMPLS.
1049 This is a #define so that we can have a assertion elsewhere to
1050 verify that we have reserved enough space for synthetic address
1051 classes. */
1052 #define SYMBOL_ACLASS_BITS 5
1053 gdb_static_assert (LOC_FINAL_VALUE <= (1 << SYMBOL_ACLASS_BITS));
1055 /* The methods needed to implement LOC_COMPUTED. These methods can
1056 use the symbol's .aux_value for additional per-symbol information.
1058 At present this is only used to implement location expressions. */
1060 struct symbol_computed_ops
1063 /* Return the value of the variable SYMBOL, relative to the stack
1064 frame FRAME. If the variable has been optimized out, return
1065 zero.
1067 Iff `read_needs_frame (SYMBOL)' is not SYMBOL_NEEDS_FRAME, then
1068 FRAME may be zero. */
1070 struct value *(*read_variable) (struct symbol * symbol,
1071 struct frame_info * frame);
1073 /* Read variable SYMBOL like read_variable at (callee) FRAME's function
1074 entry. SYMBOL should be a function parameter, otherwise
1075 NO_ENTRY_VALUE_ERROR will be thrown. */
1076 struct value *(*read_variable_at_entry) (struct symbol *symbol,
1077 struct frame_info *frame);
1079 /* Find the "symbol_needs_kind" value for the given symbol. This
1080 value determines whether reading the symbol needs memory (e.g., a
1081 global variable), just registers (a thread-local), or a frame (a
1082 local variable). */
1083 enum symbol_needs_kind (*get_symbol_read_needs) (struct symbol * symbol);
1085 /* Write to STREAM a natural-language description of the location of
1086 SYMBOL, in the context of ADDR. */
1087 void (*describe_location) (struct symbol * symbol, CORE_ADDR addr,
1088 struct ui_file * stream);
1090 /* Non-zero if this symbol's address computation is dependent on PC. */
1091 unsigned char location_has_loclist;
1093 /* Tracepoint support. Append bytecodes to the tracepoint agent
1094 expression AX that push the address of the object SYMBOL. Set
1095 VALUE appropriately. Note --- for objects in registers, this
1096 needn't emit any code; as long as it sets VALUE properly, then
1097 the caller will generate the right code in the process of
1098 treating this as an lvalue or rvalue. */
1100 void (*tracepoint_var_ref) (struct symbol *symbol, struct agent_expr *ax,
1101 struct axs_value *value);
1103 /* Generate C code to compute the location of SYMBOL. The C code is
1104 emitted to STREAM. GDBARCH is the current architecture and PC is
1105 the PC at which SYMBOL's location should be evaluated.
1106 REGISTERS_USED is a vector indexed by register number; the
1107 generator function should set an element in this vector if the
1108 corresponding register is needed by the location computation.
1109 The generated C code must assign the location to a local
1110 variable; this variable's name is RESULT_NAME. */
1112 void (*generate_c_location) (struct symbol *symbol, string_file *stream,
1113 struct gdbarch *gdbarch,
1114 std::vector<bool> &registers_used,
1115 CORE_ADDR pc, const char *result_name);
1119 /* The methods needed to implement LOC_BLOCK for inferior functions.
1120 These methods can use the symbol's .aux_value for additional
1121 per-symbol information. */
1123 struct symbol_block_ops
1125 /* Fill in *START and *LENGTH with DWARF block data of function
1126 FRAMEFUNC valid for inferior context address PC. Set *LENGTH to
1127 zero if such location is not valid for PC; *START is left
1128 uninitialized in such case. */
1129 void (*find_frame_base_location) (struct symbol *framefunc, CORE_ADDR pc,
1130 const gdb_byte **start, size_t *length);
1132 /* Return the frame base address. FRAME is the frame for which we want to
1133 compute the base address while FRAMEFUNC is the symbol for the
1134 corresponding function. Return 0 on failure (FRAMEFUNC may not hold the
1135 information we need).
1137 This method is designed to work with static links (nested functions
1138 handling). Static links are function properties whose evaluation returns
1139 the frame base address for the enclosing frame. However, there are
1140 multiple definitions for "frame base": the content of the frame base
1141 register, the CFA as defined by DWARF unwinding information, ...
1143 So this specific method is supposed to compute the frame base address such
1144 as for nested functions, the static link computes the same address. For
1145 instance, considering DWARF debugging information, the static link is
1146 computed with DW_AT_static_link and this method must be used to compute
1147 the corresponding DW_AT_frame_base attribute. */
1148 CORE_ADDR (*get_frame_base) (struct symbol *framefunc,
1149 struct frame_info *frame);
1152 /* Functions used with LOC_REGISTER and LOC_REGPARM_ADDR. */
1154 struct symbol_register_ops
1156 int (*register_number) (struct symbol *symbol, struct gdbarch *gdbarch);
1159 /* Objects of this type are used to find the address class and the
1160 various computed ops vectors of a symbol. */
1162 struct symbol_impl
1164 enum address_class aclass;
1166 /* Used with LOC_COMPUTED. */
1167 const struct symbol_computed_ops *ops_computed;
1169 /* Used with LOC_BLOCK. */
1170 const struct symbol_block_ops *ops_block;
1172 /* Used with LOC_REGISTER and LOC_REGPARM_ADDR. */
1173 const struct symbol_register_ops *ops_register;
1176 /* struct symbol has some subclasses. This enum is used to
1177 differentiate between them. */
1179 enum symbol_subclass_kind
1181 /* Plain struct symbol. */
1182 SYMBOL_NONE,
1184 /* struct template_symbol. */
1185 SYMBOL_TEMPLATE,
1187 /* struct rust_vtable_symbol. */
1188 SYMBOL_RUST_VTABLE
1191 extern const struct symbol_impl *symbol_impls;
1193 /* This structure is space critical. See space comments at the top. */
1195 struct symbol : public general_symbol_info, public allocate_on_obstack
1197 symbol ()
1198 /* Class-initialization of bitfields is only allowed in C++20. */
1199 : m_domain (UNDEF_DOMAIN),
1200 m_aclass_index (0),
1201 m_is_objfile_owned (1),
1202 m_is_argument (0),
1203 m_is_inlined (0),
1204 maybe_copied (0),
1205 subclass (SYMBOL_NONE),
1206 artificial (false)
1208 /* We can't use an initializer list for members of a base class, and
1209 general_symbol_info needs to stay a POD type. */
1210 m_name = nullptr;
1211 m_value.ivalue = 0;
1212 language_specific.obstack = nullptr;
1213 m_language = language_unknown;
1214 ada_mangled = 0;
1215 m_section = -1;
1216 /* GCC 4.8.5 (on CentOS 7) does not correctly compile class-
1217 initialization of unions, so we initialize it manually here. */
1218 owner.symtab = nullptr;
1221 symbol (const symbol &) = default;
1222 symbol &operator= (const symbol &) = default;
1224 unsigned int aclass_index () const
1226 return m_aclass_index;
1229 void set_aclass_index (unsigned int aclass_index)
1231 m_aclass_index = aclass_index;
1234 const symbol_impl &impl () const
1236 return symbol_impls[this->aclass_index ()];
1239 address_class aclass () const
1241 return this->impl ().aclass;
1244 domain_enum domain () const
1246 return m_domain;
1249 void set_domain (domain_enum domain)
1251 m_domain = domain;
1254 bool is_objfile_owned () const
1256 return m_is_objfile_owned;
1259 void set_is_objfile_owned (bool is_objfile_owned)
1261 m_is_objfile_owned = is_objfile_owned;
1264 bool is_argument () const
1266 return m_is_argument;
1269 void set_is_argument (bool is_argument)
1271 m_is_argument = is_argument;
1274 bool is_inlined () const
1276 return m_is_inlined;
1279 void set_is_inlined (bool is_inlined)
1281 m_is_inlined = is_inlined;
1284 bool is_cplus_template_function () const
1286 return this->subclass == SYMBOL_TEMPLATE;
1289 struct type *type () const
1291 return m_type;
1294 void set_type (struct type *type)
1296 m_type = type;
1299 unsigned short line () const
1301 return m_line;
1304 void set_line (unsigned short line)
1306 m_line = line;
1309 LONGEST value_longest () const
1311 return m_value.ivalue;
1314 void set_value_longest (LONGEST value)
1316 m_value.ivalue = value;
1319 CORE_ADDR value_address () const
1321 if (this->maybe_copied)
1322 return get_symbol_address (this);
1323 else
1324 return m_value.address;
1327 void set_value_address (CORE_ADDR address)
1329 m_value.address = address;
1332 const gdb_byte *value_bytes () const
1334 return m_value.bytes;
1337 void set_value_bytes (const gdb_byte *bytes)
1339 m_value.bytes = bytes;
1342 const common_block *value_common_block () const
1344 return m_value.common_block;
1347 void set_value_common_block (const common_block *common_block)
1349 m_value.common_block = common_block;
1352 const block *value_block () const
1354 return m_value.block;
1357 void set_value_block (const block *block)
1359 m_value.block = block;
1362 symbol *value_chain () const
1364 return m_value.chain;
1367 void set_value_chain (symbol *sym)
1369 m_value.chain = sym;
1372 /* Data type of value */
1374 struct type *m_type = nullptr;
1376 /* The owner of this symbol.
1377 Which one to use is defined by symbol.is_objfile_owned. */
1379 union
1381 /* The symbol table containing this symbol. This is the file associated
1382 with LINE. It can be NULL during symbols read-in but it is never NULL
1383 during normal operation. */
1384 struct symtab *symtab;
1386 /* For types defined by the architecture. */
1387 struct gdbarch *arch;
1388 } owner;
1390 /* Domain code. */
1392 ENUM_BITFIELD(domain_enum_tag) m_domain : SYMBOL_DOMAIN_BITS;
1394 /* Address class. This holds an index into the 'symbol_impls'
1395 table. The actual enum address_class value is stored there,
1396 alongside any per-class ops vectors. */
1398 unsigned int m_aclass_index : SYMBOL_ACLASS_BITS;
1400 /* If non-zero then symbol is objfile-owned, use owner.symtab.
1401 Otherwise symbol is arch-owned, use owner.arch. */
1403 unsigned int m_is_objfile_owned : 1;
1405 /* Whether this is an argument. */
1407 unsigned m_is_argument : 1;
1409 /* Whether this is an inlined function (class LOC_BLOCK only). */
1410 unsigned m_is_inlined : 1;
1412 /* For LOC_STATIC only, if this is set, then the symbol might be
1413 subject to copy relocation. In this case, a minimal symbol
1414 matching the symbol's linkage name is first looked for in the
1415 main objfile. If found, then that address is used; otherwise the
1416 address in this symbol is used. */
1418 unsigned maybe_copied : 1;
1420 /* The concrete type of this symbol. */
1422 ENUM_BITFIELD (symbol_subclass_kind) subclass : 2;
1424 /* Whether this symbol is artificial. */
1426 bool artificial : 1;
1428 /* Line number of this symbol's definition, except for inlined
1429 functions. For an inlined function (class LOC_BLOCK and
1430 SYMBOL_INLINED set) this is the line number of the function's call
1431 site. Inlined function symbols are not definitions, and they are
1432 never found by symbol table lookup.
1433 If this symbol is arch-owned, LINE shall be zero.
1435 FIXME: Should we really make the assumption that nobody will try
1436 to debug files longer than 64K lines? What about machine
1437 generated programs? */
1439 unsigned short m_line = 0;
1441 /* An arbitrary data pointer, allowing symbol readers to record
1442 additional information on a per-symbol basis. Note that this data
1443 must be allocated using the same obstack as the symbol itself. */
1444 /* So far it is only used by:
1445 LOC_COMPUTED: to find the location information
1446 LOC_BLOCK (DWARF2 function): information used internally by the
1447 DWARF 2 code --- specifically, the location expression for the frame
1448 base for this function. */
1449 /* FIXME drow/2003-02-21: For the LOC_BLOCK case, it might be better
1450 to add a magic symbol to the block containing this information,
1451 or to have a generic debug info annotation slot for symbols. */
1453 void *aux_value = nullptr;
1455 struct symbol *hash_next = nullptr;
1458 /* Several lookup functions return both a symbol and the block in which the
1459 symbol is found. This structure is used in these cases. */
1461 struct block_symbol
1463 /* The symbol that was found, or NULL if no symbol was found. */
1464 struct symbol *symbol;
1466 /* If SYMBOL is not NULL, then this is the block in which the symbol is
1467 defined. */
1468 const struct block *block;
1471 /* Note: There is no accessor macro for symbol.owner because it is
1472 "private". */
1474 #define SYMBOL_COMPUTED_OPS(symbol) ((symbol)->impl ().ops_computed)
1475 #define SYMBOL_BLOCK_OPS(symbol) ((symbol)->impl ().ops_block)
1476 #define SYMBOL_REGISTER_OPS(symbol) ((symbol)->impl ().ops_register)
1477 #define SYMBOL_LOCATION_BATON(symbol) (symbol)->aux_value
1479 extern int register_symbol_computed_impl (enum address_class,
1480 const struct symbol_computed_ops *);
1482 extern int register_symbol_block_impl (enum address_class aclass,
1483 const struct symbol_block_ops *ops);
1485 extern int register_symbol_register_impl (enum address_class,
1486 const struct symbol_register_ops *);
1488 /* Return the OBJFILE of SYMBOL.
1489 It is an error to call this if symbol.is_objfile_owned is false, which
1490 only happens for architecture-provided types. */
1492 extern struct objfile *symbol_objfile (const struct symbol *symbol);
1494 /* Return the ARCH of SYMBOL. */
1496 extern struct gdbarch *symbol_arch (const struct symbol *symbol);
1498 /* Return the SYMTAB of SYMBOL.
1499 It is an error to call this if symbol.is_objfile_owned is false, which
1500 only happens for architecture-provided types. */
1502 extern struct symtab *symbol_symtab (const struct symbol *symbol);
1504 /* Set the symtab of SYMBOL to SYMTAB.
1505 It is an error to call this if symbol.is_objfile_owned is false, which
1506 only happens for architecture-provided types. */
1508 extern void symbol_set_symtab (struct symbol *symbol, struct symtab *symtab);
1510 /* An instance of this type is used to represent a C++ template
1511 function. A symbol is really of this type iff
1512 symbol::is_cplus_template_function is true. */
1514 struct template_symbol : public symbol
1516 /* The number of template arguments. */
1517 int n_template_arguments = 0;
1519 /* The template arguments. This is an array with
1520 N_TEMPLATE_ARGUMENTS elements. */
1521 struct symbol **template_arguments = nullptr;
1524 /* A symbol that represents a Rust virtual table object. */
1526 struct rust_vtable_symbol : public symbol
1528 /* The concrete type for which this vtable was created; that is, in
1529 "impl Trait for Type", this is "Type". */
1530 struct type *concrete_type = nullptr;
1534 /* Each item represents a line-->pc (or the reverse) mapping. This is
1535 somewhat more wasteful of space than one might wish, but since only
1536 the files which are actually debugged are read in to core, we don't
1537 waste much space. */
1539 struct linetable_entry
1541 /* The line number for this entry. */
1542 int line;
1544 /* True if this PC is a good location to place a breakpoint for LINE. */
1545 unsigned is_stmt : 1;
1547 /* True if this location is a good location to place a breakpoint after a
1548 function prologue. */
1549 bool prologue_end : 1;
1551 /* The address for this entry. */
1552 CORE_ADDR pc;
1555 /* The order of entries in the linetable is significant. They should
1556 be sorted by increasing values of the pc field. If there is more than
1557 one entry for a given pc, then I'm not sure what should happen (and
1558 I not sure whether we currently handle it the best way).
1560 Example: a C for statement generally looks like this
1562 10 0x100 - for the init/test part of a for stmt.
1563 20 0x200
1564 30 0x300
1565 10 0x400 - for the increment part of a for stmt.
1567 If an entry has a line number of zero, it marks the start of a PC
1568 range for which no line number information is available. It is
1569 acceptable, though wasteful of table space, for such a range to be
1570 zero length. */
1572 struct linetable
1574 int nitems;
1576 /* Actually NITEMS elements. If you don't like this use of the
1577 `struct hack', you can shove it up your ANSI (seriously, if the
1578 committee tells us how to do it, we can probably go along). */
1579 struct linetable_entry item[1];
1582 /* How to relocate the symbols from each section in a symbol file.
1583 The ordering and meaning of the offsets is file-type-dependent;
1584 typically it is indexed by section numbers or symbol types or
1585 something like that. */
1587 typedef std::vector<CORE_ADDR> section_offsets;
1589 /* Each source file or header is represented by a struct symtab.
1590 The name "symtab" is historical, another name for it is "filetab".
1591 These objects are chained through the `next' field. */
1593 struct symtab
1595 struct compunit_symtab *compunit () const
1597 return m_compunit;
1600 void set_compunit (struct compunit_symtab *compunit)
1602 m_compunit = compunit;
1605 struct linetable *linetable () const
1607 return m_linetable;
1610 void set_linetable (struct linetable *linetable)
1612 m_linetable = linetable;
1615 enum language language () const
1617 return m_language;
1620 void set_language (enum language language)
1622 m_language = language;
1625 /* Unordered chain of all filetabs in the compunit, with the exception
1626 that the "main" source file is the first entry in the list. */
1628 struct symtab *next;
1630 /* Backlink to containing compunit symtab. */
1632 struct compunit_symtab *m_compunit;
1634 /* Table mapping core addresses to line numbers for this file.
1635 Can be NULL if none. Never shared between different symtabs. */
1637 struct linetable *m_linetable;
1639 /* Name of this source file. This pointer is never NULL. */
1641 const char *filename;
1643 /* Language of this source file. */
1645 enum language m_language;
1647 /* Full name of file as found by searching the source path.
1648 NULL if not yet known. */
1650 char *fullname;
1653 /* A range adapter to allowing iterating over all the file tables in a list. */
1655 using symtab_range = next_range<symtab>;
1657 /* Compunit symtabs contain the actual "symbol table", aka blockvector, as well
1658 as the list of all source files (what gdb has historically associated with
1659 the term "symtab").
1660 Additional information is recorded here that is common to all symtabs in a
1661 compilation unit (DWARF or otherwise).
1663 Example:
1664 For the case of a program built out of these files:
1666 foo.c
1667 foo1.h
1668 foo2.h
1669 bar.c
1670 foo1.h
1671 bar.h
1673 This is recorded as:
1675 objfile -> foo.c(cu) -> bar.c(cu) -> NULL
1678 foo.c bar.c
1681 foo1.h foo1.h
1684 foo2.h bar.h
1687 NULL NULL
1689 where "foo.c(cu)" and "bar.c(cu)" are struct compunit_symtab objects,
1690 and the files foo.c, etc. are struct symtab objects. */
1692 struct compunit_symtab
1694 struct objfile *objfile () const
1696 return m_objfile;
1699 void set_objfile (struct objfile *objfile)
1701 m_objfile = objfile;
1704 symtab_range filetabs () const
1706 return symtab_range (m_filetabs);
1709 void add_filetab (symtab *filetab)
1711 if (m_filetabs == nullptr)
1713 m_filetabs = filetab;
1714 m_last_filetab = filetab;
1716 else
1718 m_last_filetab->next = filetab;
1719 m_last_filetab = filetab;
1723 const char *debugformat () const
1725 return m_debugformat;
1728 void set_debugformat (const char *debugformat)
1730 m_debugformat = debugformat;
1733 const char *producer () const
1735 return m_producer;
1738 void set_producer (const char *producer)
1740 m_producer = producer;
1743 const char *dirname () const
1745 return m_dirname;
1748 void set_dirname (const char *dirname)
1750 m_dirname = dirname;
1753 const struct blockvector *blockvector () const
1755 return m_blockvector;
1758 void set_blockvector (const struct blockvector *blockvector)
1760 m_blockvector = blockvector;
1763 int block_line_section () const
1765 return m_block_line_section;
1768 void set_block_line_section (int block_line_section)
1770 m_block_line_section = block_line_section;
1773 bool locations_valid () const
1775 return m_locations_valid;
1778 void set_locations_valid (bool locations_valid)
1780 m_locations_valid = locations_valid;
1783 bool epilogue_unwind_valid () const
1785 return m_epilogue_unwind_valid;
1788 void set_epilogue_unwind_valid (bool epilogue_unwind_valid)
1790 m_epilogue_unwind_valid = epilogue_unwind_valid;
1793 struct macro_table *macro_table () const
1795 return m_macro_table;
1798 void set_macro_table (struct macro_table *macro_table)
1800 m_macro_table = macro_table;
1803 /* Make PRIMARY_FILETAB the primary filetab of this compunit symtab.
1805 PRIMARY_FILETAB must already be a filetab of this compunit symtab. */
1807 void set_primary_filetab (symtab *primary_filetab);
1809 /* Return the primary filetab of the compunit. */
1810 symtab *primary_filetab () const;
1812 /* Set m_call_site_htab. */
1813 void set_call_site_htab (htab_t call_site_htab);
1815 /* Find call_site info for PC. */
1816 call_site *find_call_site (CORE_ADDR pc) const;
1818 /* Unordered chain of all compunit symtabs of this objfile. */
1819 struct compunit_symtab *next;
1821 /* Object file from which this symtab information was read. */
1822 struct objfile *m_objfile;
1824 /* Name of the symtab.
1825 This is *not* intended to be a usable filename, and is
1826 for debugging purposes only. */
1827 const char *name;
1829 /* Unordered list of file symtabs, except that by convention the "main"
1830 source file (e.g., .c, .cc) is guaranteed to be first.
1831 Each symtab is a file, either the "main" source file (e.g., .c, .cc)
1832 or header (e.g., .h). */
1833 symtab *m_filetabs;
1835 /* Last entry in FILETABS list.
1836 Subfiles are added to the end of the list so they accumulate in order,
1837 with the main source subfile living at the front.
1838 The main reason is so that the main source file symtab is at the head
1839 of the list, and the rest appear in order for debugging convenience. */
1840 symtab *m_last_filetab;
1842 /* Non-NULL string that identifies the format of the debugging information,
1843 such as "stabs", "dwarf 1", "dwarf 2", "coff", etc. This is mostly useful
1844 for automated testing of gdb but may also be information that is
1845 useful to the user. */
1846 const char *m_debugformat;
1848 /* String of producer version information, or NULL if we don't know. */
1849 const char *m_producer;
1851 /* Directory in which it was compiled, or NULL if we don't know. */
1852 const char *m_dirname;
1854 /* List of all symbol scope blocks for this symtab. It is shared among
1855 all symtabs in a given compilation unit. */
1856 const struct blockvector *m_blockvector;
1858 /* Section in objfile->section_offsets for the blockvector and
1859 the linetable. Probably always SECT_OFF_TEXT. */
1860 int m_block_line_section;
1862 /* Symtab has been compiled with both optimizations and debug info so that
1863 GDB may stop skipping prologues as variables locations are valid already
1864 at function entry points. */
1865 unsigned int m_locations_valid : 1;
1867 /* DWARF unwinder for this CU is valid even for epilogues (PC at the return
1868 instruction). This is supported by GCC since 4.5.0. */
1869 unsigned int m_epilogue_unwind_valid : 1;
1871 /* struct call_site entries for this compilation unit or NULL. */
1872 htab_t m_call_site_htab;
1874 /* The macro table for this symtab. Like the blockvector, this
1875 is shared between different symtabs in a given compilation unit.
1876 It's debatable whether it *should* be shared among all the symtabs in
1877 the given compilation unit, but it currently is. */
1878 struct macro_table *m_macro_table;
1880 /* If non-NULL, then this points to a NULL-terminated vector of
1881 included compunits. When searching the static or global
1882 block of this compunit, the corresponding block of all
1883 included compunits will also be searched. Note that this
1884 list must be flattened -- the symbol reader is responsible for
1885 ensuring that this vector contains the transitive closure of all
1886 included compunits. */
1887 struct compunit_symtab **includes;
1889 /* If this is an included compunit, this points to one includer
1890 of the table. This user is considered the canonical compunit
1891 containing this one. An included compunit may itself be
1892 included by another. */
1893 struct compunit_symtab *user;
1896 using compunit_symtab_range = next_range<compunit_symtab>;
1898 /* Return the language of CUST. */
1900 extern enum language compunit_language (const struct compunit_symtab *cust);
1902 /* Return true if this symtab is the "main" symtab of its compunit_symtab. */
1904 static inline bool
1905 is_main_symtab_of_compunit_symtab (struct symtab *symtab)
1907 return symtab == symtab->compunit ()->primary_filetab ();
1911 /* The virtual function table is now an array of structures which have the
1912 form { int16 offset, delta; void *pfn; }.
1914 In normal virtual function tables, OFFSET is unused.
1915 DELTA is the amount which is added to the apparent object's base
1916 address in order to point to the actual object to which the
1917 virtual function should be applied.
1918 PFN is a pointer to the virtual function.
1920 Note that this macro is g++ specific (FIXME). */
1922 #define VTBL_FNADDR_OFFSET 2
1924 /* External variables and functions for the objects described above. */
1926 /* True if we are nested inside psymtab_to_symtab. */
1928 extern int currently_reading_symtab;
1930 /* symtab.c lookup functions */
1932 extern const char multiple_symbols_ask[];
1933 extern const char multiple_symbols_all[];
1934 extern const char multiple_symbols_cancel[];
1936 const char *multiple_symbols_select_mode (void);
1938 bool symbol_matches_domain (enum language symbol_language,
1939 domain_enum symbol_domain,
1940 domain_enum domain);
1942 /* lookup a symbol table by source file name. */
1944 extern struct symtab *lookup_symtab (const char *);
1946 /* An object of this type is passed as the 'is_a_field_of_this'
1947 argument to lookup_symbol and lookup_symbol_in_language. */
1949 struct field_of_this_result
1951 /* The type in which the field was found. If this is NULL then the
1952 symbol was not found in 'this'. If non-NULL, then one of the
1953 other fields will be non-NULL as well. */
1955 struct type *type;
1957 /* If the symbol was found as an ordinary field of 'this', then this
1958 is non-NULL and points to the particular field. */
1960 struct field *field;
1962 /* If the symbol was found as a function field of 'this', then this
1963 is non-NULL and points to the particular field. */
1965 struct fn_fieldlist *fn_field;
1968 /* Find the definition for a specified symbol name NAME
1969 in domain DOMAIN in language LANGUAGE, visible from lexical block BLOCK
1970 if non-NULL or from global/static blocks if BLOCK is NULL.
1971 Returns the struct symbol pointer, or NULL if no symbol is found.
1972 C++: if IS_A_FIELD_OF_THIS is non-NULL on entry, check to see if
1973 NAME is a field of the current implied argument `this'. If so fill in the
1974 fields of IS_A_FIELD_OF_THIS, otherwise the fields are set to NULL.
1975 The symbol's section is fixed up if necessary. */
1977 extern struct block_symbol
1978 lookup_symbol_in_language (const char *,
1979 const struct block *,
1980 const domain_enum,
1981 enum language,
1982 struct field_of_this_result *);
1984 /* Same as lookup_symbol_in_language, but using the current language. */
1986 extern struct block_symbol lookup_symbol (const char *,
1987 const struct block *,
1988 const domain_enum,
1989 struct field_of_this_result *);
1991 /* Find the definition for a specified symbol search name in domain
1992 DOMAIN, visible from lexical block BLOCK if non-NULL or from
1993 global/static blocks if BLOCK is NULL. The passed-in search name
1994 should not come from the user; instead it should already be a
1995 search name as retrieved from a search_name () call. See definition of
1996 symbol_name_match_type::SEARCH_NAME. Returns the struct symbol
1997 pointer, or NULL if no symbol is found. The symbol's section is
1998 fixed up if necessary. */
2000 extern struct block_symbol lookup_symbol_search_name (const char *search_name,
2001 const struct block *block,
2002 domain_enum domain);
2004 /* Some helper functions for languages that need to write their own
2005 lookup_symbol_nonlocal functions. */
2007 /* Lookup a symbol in the static block associated to BLOCK, if there
2008 is one; do nothing if BLOCK is NULL or a global block.
2009 Upon success fixes up the symbol's section if necessary. */
2011 extern struct block_symbol
2012 lookup_symbol_in_static_block (const char *name,
2013 const struct block *block,
2014 const domain_enum domain);
2016 /* Search all static file-level symbols for NAME from DOMAIN.
2017 Upon success fixes up the symbol's section if necessary. */
2019 extern struct block_symbol lookup_static_symbol (const char *name,
2020 const domain_enum domain);
2022 /* Lookup a symbol in all files' global blocks.
2024 If BLOCK is non-NULL then it is used for two things:
2025 1) If a target-specific lookup routine for libraries exists, then use the
2026 routine for the objfile of BLOCK, and
2027 2) The objfile of BLOCK is used to assist in determining the search order
2028 if the target requires it.
2029 See gdbarch_iterate_over_objfiles_in_search_order.
2031 Upon success fixes up the symbol's section if necessary. */
2033 extern struct block_symbol
2034 lookup_global_symbol (const char *name,
2035 const struct block *block,
2036 const domain_enum domain);
2038 /* Lookup a symbol in block BLOCK.
2039 Upon success fixes up the symbol's section if necessary. */
2041 extern struct symbol *
2042 lookup_symbol_in_block (const char *name,
2043 symbol_name_match_type match_type,
2044 const struct block *block,
2045 const domain_enum domain);
2047 /* Look up the `this' symbol for LANG in BLOCK. Return the symbol if
2048 found, or NULL if not found. */
2050 extern struct block_symbol
2051 lookup_language_this (const struct language_defn *lang,
2052 const struct block *block);
2054 /* Lookup a [struct, union, enum] by name, within a specified block. */
2056 extern struct type *lookup_struct (const char *, const struct block *);
2058 extern struct type *lookup_union (const char *, const struct block *);
2060 extern struct type *lookup_enum (const char *, const struct block *);
2062 /* from blockframe.c: */
2064 /* lookup the function symbol corresponding to the address. The
2065 return value will not be an inlined function; the containing
2066 function will be returned instead. */
2068 extern struct symbol *find_pc_function (CORE_ADDR);
2070 /* lookup the function corresponding to the address and section. The
2071 return value will not be an inlined function; the containing
2072 function will be returned instead. */
2074 extern struct symbol *find_pc_sect_function (CORE_ADDR, struct obj_section *);
2076 /* lookup the function symbol corresponding to the address and
2077 section. The return value will be the closest enclosing function,
2078 which might be an inline function. */
2080 extern struct symbol *find_pc_sect_containing_function
2081 (CORE_ADDR pc, struct obj_section *section);
2083 /* Find the symbol at the given address. Returns NULL if no symbol
2084 found. Only exact matches for ADDRESS are considered. */
2086 extern struct symbol *find_symbol_at_address (CORE_ADDR);
2088 /* Finds the "function" (text symbol) that is smaller than PC but
2089 greatest of all of the potential text symbols in SECTION. Sets
2090 *NAME and/or *ADDRESS conditionally if that pointer is non-null.
2091 If ENDADDR is non-null, then set *ENDADDR to be the end of the
2092 function (exclusive). If the optional parameter BLOCK is non-null,
2093 then set *BLOCK to the address of the block corresponding to the
2094 function symbol, if such a symbol could be found during the lookup;
2095 nullptr is used as a return value for *BLOCK if no block is found.
2096 This function either succeeds or fails (not halfway succeeds). If
2097 it succeeds, it sets *NAME, *ADDRESS, and *ENDADDR to real
2098 information and returns true. If it fails, it sets *NAME, *ADDRESS
2099 and *ENDADDR to zero and returns false.
2101 If the function in question occupies non-contiguous ranges,
2102 *ADDRESS and *ENDADDR are (subject to the conditions noted above) set
2103 to the start and end of the range in which PC is found. Thus
2104 *ADDRESS <= PC < *ENDADDR with no intervening gaps (in which ranges
2105 from other functions might be found).
2107 This property allows find_pc_partial_function to be used (as it had
2108 been prior to the introduction of non-contiguous range support) by
2109 various tdep files for finding a start address and limit address
2110 for prologue analysis. This still isn't ideal, however, because we
2111 probably shouldn't be doing prologue analysis (in which
2112 instructions are scanned to determine frame size and stack layout)
2113 for any range that doesn't contain the entry pc. Moreover, a good
2114 argument can be made that prologue analysis ought to be performed
2115 starting from the entry pc even when PC is within some other range.
2116 This might suggest that *ADDRESS and *ENDADDR ought to be set to the
2117 limits of the entry pc range, but that will cause the
2118 *ADDRESS <= PC < *ENDADDR condition to be violated; many of the
2119 callers of find_pc_partial_function expect this condition to hold.
2121 Callers which require the start and/or end addresses for the range
2122 containing the entry pc should instead call
2123 find_function_entry_range_from_pc. */
2125 extern bool find_pc_partial_function (CORE_ADDR pc, const char **name,
2126 CORE_ADDR *address, CORE_ADDR *endaddr,
2127 const struct block **block = nullptr);
2129 /* Like find_pc_partial_function, above, but returns the underlying
2130 general_symbol_info (rather than the name) as an out parameter. */
2132 extern bool find_pc_partial_function_sym
2133 (CORE_ADDR pc, const general_symbol_info **sym,
2134 CORE_ADDR *address, CORE_ADDR *endaddr,
2135 const struct block **block = nullptr);
2137 /* Like find_pc_partial_function, above, but *ADDRESS and *ENDADDR are
2138 set to start and end addresses of the range containing the entry pc.
2140 Note that it is not necessarily the case that (for non-NULL ADDRESS
2141 and ENDADDR arguments) the *ADDRESS <= PC < *ENDADDR condition will
2142 hold.
2144 See comment for find_pc_partial_function, above, for further
2145 explanation. */
2147 extern bool find_function_entry_range_from_pc (CORE_ADDR pc,
2148 const char **name,
2149 CORE_ADDR *address,
2150 CORE_ADDR *endaddr);
2152 /* Return the type of a function with its first instruction exactly at
2153 the PC address. Return NULL otherwise. */
2155 extern struct type *find_function_type (CORE_ADDR pc);
2157 /* See if we can figure out the function's actual type from the type
2158 that the resolver returns. RESOLVER_FUNADDR is the address of the
2159 ifunc resolver. */
2161 extern struct type *find_gnu_ifunc_target_type (CORE_ADDR resolver_funaddr);
2163 /* Find the GNU ifunc minimal symbol that matches SYM. */
2164 extern bound_minimal_symbol find_gnu_ifunc (const symbol *sym);
2166 extern void clear_pc_function_cache (void);
2168 /* Expand symtab containing PC, SECTION if not already expanded. */
2170 extern void expand_symtab_containing_pc (CORE_ADDR, struct obj_section *);
2172 /* lookup full symbol table by address. */
2174 extern struct compunit_symtab *find_pc_compunit_symtab (CORE_ADDR);
2176 /* lookup full symbol table by address and section. */
2178 extern struct compunit_symtab *
2179 find_pc_sect_compunit_symtab (CORE_ADDR, struct obj_section *);
2181 extern bool find_pc_line_pc_range (CORE_ADDR, CORE_ADDR *, CORE_ADDR *);
2183 extern void reread_symbols (int from_tty);
2185 /* Look up a type named NAME in STRUCT_DOMAIN in the current language.
2186 The type returned must not be opaque -- i.e., must have at least one field
2187 defined. */
2189 extern struct type *lookup_transparent_type (const char *);
2191 extern struct type *basic_lookup_transparent_type (const char *);
2193 /* Macro for name of symbol to indicate a file compiled with gcc. */
2194 #ifndef GCC_COMPILED_FLAG_SYMBOL
2195 #define GCC_COMPILED_FLAG_SYMBOL "gcc_compiled."
2196 #endif
2198 /* Macro for name of symbol to indicate a file compiled with gcc2. */
2199 #ifndef GCC2_COMPILED_FLAG_SYMBOL
2200 #define GCC2_COMPILED_FLAG_SYMBOL "gcc2_compiled."
2201 #endif
2203 extern bool in_gnu_ifunc_stub (CORE_ADDR pc);
2205 /* Functions for resolving STT_GNU_IFUNC symbols which are implemented only
2206 for ELF symbol files. */
2208 struct gnu_ifunc_fns
2210 /* See elf_gnu_ifunc_resolve_addr for its real implementation. */
2211 CORE_ADDR (*gnu_ifunc_resolve_addr) (struct gdbarch *gdbarch, CORE_ADDR pc);
2213 /* See elf_gnu_ifunc_resolve_name for its real implementation. */
2214 bool (*gnu_ifunc_resolve_name) (const char *function_name,
2215 CORE_ADDR *function_address_p);
2217 /* See elf_gnu_ifunc_resolver_stop for its real implementation. */
2218 void (*gnu_ifunc_resolver_stop) (struct breakpoint *b);
2220 /* See elf_gnu_ifunc_resolver_return_stop for its real implementation. */
2221 void (*gnu_ifunc_resolver_return_stop) (struct breakpoint *b);
2224 #define gnu_ifunc_resolve_addr gnu_ifunc_fns_p->gnu_ifunc_resolve_addr
2225 #define gnu_ifunc_resolve_name gnu_ifunc_fns_p->gnu_ifunc_resolve_name
2226 #define gnu_ifunc_resolver_stop gnu_ifunc_fns_p->gnu_ifunc_resolver_stop
2227 #define gnu_ifunc_resolver_return_stop \
2228 gnu_ifunc_fns_p->gnu_ifunc_resolver_return_stop
2230 extern const struct gnu_ifunc_fns *gnu_ifunc_fns_p;
2232 extern CORE_ADDR find_solib_trampoline_target (struct frame_info *, CORE_ADDR);
2234 struct symtab_and_line
2236 /* The program space of this sal. */
2237 struct program_space *pspace = NULL;
2239 struct symtab *symtab = NULL;
2240 struct symbol *symbol = NULL;
2241 struct obj_section *section = NULL;
2242 struct minimal_symbol *msymbol = NULL;
2243 /* Line number. Line numbers start at 1 and proceed through symtab->nlines.
2244 0 is never a valid line number; it is used to indicate that line number
2245 information is not available. */
2246 int line = 0;
2248 CORE_ADDR pc = 0;
2249 CORE_ADDR end = 0;
2250 bool explicit_pc = false;
2251 bool explicit_line = false;
2253 /* If the line number information is valid, then this indicates if this
2254 line table entry had the is-stmt flag set or not. */
2255 bool is_stmt = false;
2257 /* The probe associated with this symtab_and_line. */
2258 probe *prob = NULL;
2259 /* If PROBE is not NULL, then this is the objfile in which the probe
2260 originated. */
2261 struct objfile *objfile = NULL;
2266 /* Given a pc value, return line number it is in. Second arg nonzero means
2267 if pc is on the boundary use the previous statement's line number. */
2269 extern struct symtab_and_line find_pc_line (CORE_ADDR, int);
2271 /* Same function, but specify a section as well as an address. */
2273 extern struct symtab_and_line find_pc_sect_line (CORE_ADDR,
2274 struct obj_section *, int);
2276 /* Wrapper around find_pc_line to just return the symtab. */
2278 extern struct symtab *find_pc_line_symtab (CORE_ADDR);
2280 /* Given a symtab and line number, return the pc there. */
2282 extern bool find_line_pc (struct symtab *, int, CORE_ADDR *);
2284 extern bool find_line_pc_range (struct symtab_and_line, CORE_ADDR *,
2285 CORE_ADDR *);
2287 extern void resolve_sal_pc (struct symtab_and_line *);
2289 /* solib.c */
2291 extern void clear_solib (void);
2293 /* The reason we're calling into a completion match list collector
2294 function. */
2295 enum class complete_symbol_mode
2297 /* Completing an expression. */
2298 EXPRESSION,
2300 /* Completing a linespec. */
2301 LINESPEC,
2304 extern void default_collect_symbol_completion_matches_break_on
2305 (completion_tracker &tracker,
2306 complete_symbol_mode mode,
2307 symbol_name_match_type name_match_type,
2308 const char *text, const char *word, const char *break_on,
2309 enum type_code code);
2310 extern void collect_symbol_completion_matches
2311 (completion_tracker &tracker,
2312 complete_symbol_mode mode,
2313 symbol_name_match_type name_match_type,
2314 const char *, const char *);
2315 extern void collect_symbol_completion_matches_type (completion_tracker &tracker,
2316 const char *, const char *,
2317 enum type_code);
2319 extern void collect_file_symbol_completion_matches
2320 (completion_tracker &tracker,
2321 complete_symbol_mode,
2322 symbol_name_match_type name_match_type,
2323 const char *, const char *, const char *);
2325 extern completion_list
2326 make_source_files_completion_list (const char *, const char *);
2328 /* Return whether SYM is a function/method, as opposed to a data symbol. */
2330 extern bool symbol_is_function_or_method (symbol *sym);
2332 /* Return whether MSYMBOL is a function/method, as opposed to a data
2333 symbol */
2335 extern bool symbol_is_function_or_method (minimal_symbol *msymbol);
2337 /* Return whether SYM should be skipped in completion mode MODE. In
2338 linespec mode, we're only interested in functions/methods. */
2340 template<typename Symbol>
2341 static bool
2342 completion_skip_symbol (complete_symbol_mode mode, Symbol *sym)
2344 return (mode == complete_symbol_mode::LINESPEC
2345 && !symbol_is_function_or_method (sym));
2348 /* symtab.c */
2350 bool matching_obj_sections (struct obj_section *, struct obj_section *);
2352 extern struct symtab *find_line_symtab (struct symtab *, int, int *, bool *);
2354 /* Given a function symbol SYM, find the symtab and line for the start
2355 of the function. If FUNFIRSTLINE is true, we want the first line
2356 of real code inside the function. */
2357 extern symtab_and_line find_function_start_sal (symbol *sym, bool
2358 funfirstline);
2360 /* Same, but start with a function address/section instead of a
2361 symbol. */
2362 extern symtab_and_line find_function_start_sal (CORE_ADDR func_addr,
2363 obj_section *section,
2364 bool funfirstline);
2366 extern void skip_prologue_sal (struct symtab_and_line *);
2368 /* symtab.c */
2370 extern CORE_ADDR skip_prologue_using_sal (struct gdbarch *gdbarch,
2371 CORE_ADDR func_addr);
2373 extern struct symbol *fixup_symbol_section (struct symbol *,
2374 struct objfile *);
2376 /* If MSYMBOL is an text symbol, look for a function debug symbol with
2377 the same address. Returns NULL if not found. This is necessary in
2378 case a function is an alias to some other function, because debug
2379 information is only emitted for the alias target function's
2380 definition, not for the alias. */
2381 extern symbol *find_function_alias_target (bound_minimal_symbol msymbol);
2383 /* Symbol searching */
2385 /* When using the symbol_searcher struct to search for symbols, a vector of
2386 the following structs is returned. */
2387 struct symbol_search
2389 symbol_search (int block_, struct symbol *symbol_)
2390 : block (block_),
2391 symbol (symbol_)
2393 msymbol.minsym = nullptr;
2394 msymbol.objfile = nullptr;
2397 symbol_search (int block_, struct minimal_symbol *minsym,
2398 struct objfile *objfile)
2399 : block (block_),
2400 symbol (nullptr)
2402 msymbol.minsym = minsym;
2403 msymbol.objfile = objfile;
2406 bool operator< (const symbol_search &other) const
2408 return compare_search_syms (*this, other) < 0;
2411 bool operator== (const symbol_search &other) const
2413 return compare_search_syms (*this, other) == 0;
2416 /* The block in which the match was found. Could be, for example,
2417 STATIC_BLOCK or GLOBAL_BLOCK. */
2418 int block;
2420 /* Information describing what was found.
2422 If symbol is NOT NULL, then information was found for this match. */
2423 struct symbol *symbol;
2425 /* If msymbol is non-null, then a match was made on something for
2426 which only minimal_symbols exist. */
2427 struct bound_minimal_symbol msymbol;
2429 private:
2431 static int compare_search_syms (const symbol_search &sym_a,
2432 const symbol_search &sym_b);
2435 /* In order to search for global symbols of a particular kind matching
2436 particular regular expressions, create an instance of this structure and
2437 call the SEARCH member function. */
2438 class global_symbol_searcher
2440 public:
2442 /* Constructor. */
2443 global_symbol_searcher (enum search_domain kind,
2444 const char *symbol_name_regexp)
2445 : m_kind (kind),
2446 m_symbol_name_regexp (symbol_name_regexp)
2448 /* The symbol searching is designed to only find one kind of thing. */
2449 gdb_assert (m_kind != ALL_DOMAIN);
2452 /* Set the optional regexp that matches against the symbol type. */
2453 void set_symbol_type_regexp (const char *regexp)
2455 m_symbol_type_regexp = regexp;
2458 /* Set the flag to exclude minsyms from the search results. */
2459 void set_exclude_minsyms (bool exclude_minsyms)
2461 m_exclude_minsyms = exclude_minsyms;
2464 /* Set the maximum number of search results to be returned. */
2465 void set_max_search_results (size_t max_search_results)
2467 m_max_search_results = max_search_results;
2470 /* Search the symbols from all objfiles in the current program space
2471 looking for matches as defined by the current state of this object.
2473 Within each file the results are sorted locally; each symtab's global
2474 and static blocks are separately alphabetized. Duplicate entries are
2475 removed. */
2476 std::vector<symbol_search> search () const;
2478 /* The set of source files to search in for matching symbols. This is
2479 currently public so that it can be populated after this object has
2480 been constructed. */
2481 std::vector<const char *> filenames;
2483 private:
2484 /* The kind of symbols are we searching for.
2485 VARIABLES_DOMAIN - Search all symbols, excluding functions, type
2486 names, and constants (enums).
2487 FUNCTIONS_DOMAIN - Search all functions..
2488 TYPES_DOMAIN - Search all type names.
2489 MODULES_DOMAIN - Search all Fortran modules.
2490 ALL_DOMAIN - Not valid for this function. */
2491 enum search_domain m_kind;
2493 /* Regular expression to match against the symbol name. */
2494 const char *m_symbol_name_regexp = nullptr;
2496 /* Regular expression to match against the symbol type. */
2497 const char *m_symbol_type_regexp = nullptr;
2499 /* When this flag is false then minsyms that match M_SYMBOL_REGEXP will
2500 be included in the results, otherwise they are excluded. */
2501 bool m_exclude_minsyms = false;
2503 /* Maximum number of search results. We currently impose a hard limit
2504 of SIZE_MAX, there is no "unlimited". */
2505 size_t m_max_search_results = SIZE_MAX;
2507 /* Expand symtabs in OBJFILE that match PREG, are of type M_KIND. Return
2508 true if any msymbols were seen that we should later consider adding to
2509 the results list. */
2510 bool expand_symtabs (objfile *objfile,
2511 const gdb::optional<compiled_regex> &preg) const;
2513 /* Add symbols from symtabs in OBJFILE that match PREG, and TREG, and are
2514 of type M_KIND, to the results set RESULTS_SET. Return false if we
2515 stop adding results early due to having already found too many results
2516 (based on M_MAX_SEARCH_RESULTS limit), otherwise return true.
2517 Returning true does not indicate that any results were added, just
2518 that we didn't _not_ add a result due to reaching MAX_SEARCH_RESULTS. */
2519 bool add_matching_symbols (objfile *objfile,
2520 const gdb::optional<compiled_regex> &preg,
2521 const gdb::optional<compiled_regex> &treg,
2522 std::set<symbol_search> *result_set) const;
2524 /* Add msymbols from OBJFILE that match PREG and M_KIND, to the results
2525 vector RESULTS. Return false if we stop adding results early due to
2526 having already found too many results (based on max search results
2527 limit M_MAX_SEARCH_RESULTS), otherwise return true. Returning true
2528 does not indicate that any results were added, just that we didn't
2529 _not_ add a result due to reaching MAX_SEARCH_RESULTS. */
2530 bool add_matching_msymbols (objfile *objfile,
2531 const gdb::optional<compiled_regex> &preg,
2532 std::vector<symbol_search> *results) const;
2534 /* Return true if MSYMBOL is of type KIND. */
2535 static bool is_suitable_msymbol (const enum search_domain kind,
2536 const minimal_symbol *msymbol);
2539 /* When searching for Fortran symbols within modules (functions/variables)
2540 we return a vector of this type. The first item in the pair is the
2541 module symbol, and the second item is the symbol for the function or
2542 variable we found. */
2543 typedef std::pair<symbol_search, symbol_search> module_symbol_search;
2545 /* Searches the symbols to find function and variables symbols (depending
2546 on KIND) within Fortran modules. The MODULE_REGEXP matches against the
2547 name of the module, REGEXP matches against the name of the symbol within
2548 the module, and TYPE_REGEXP matches against the type of the symbol
2549 within the module. */
2550 extern std::vector<module_symbol_search> search_module_symbols
2551 (const char *module_regexp, const char *regexp,
2552 const char *type_regexp, search_domain kind);
2554 /* Convert a global or static symbol SYM (based on BLOCK, which should be
2555 either GLOBAL_BLOCK or STATIC_BLOCK) into a string for use in 'info'
2556 type commands (e.g. 'info variables', 'info functions', etc). KIND is
2557 the type of symbol that was searched for which gave us SYM. */
2559 extern std::string symbol_to_info_string (struct symbol *sym, int block,
2560 enum search_domain kind);
2562 extern bool treg_matches_sym_type_name (const compiled_regex &treg,
2563 const struct symbol *sym);
2565 /* The name of the ``main'' function. */
2566 extern const char *main_name ();
2567 extern enum language main_language (void);
2569 /* Lookup symbol NAME from DOMAIN in MAIN_OBJFILE's global or static blocks,
2570 as specified by BLOCK_INDEX.
2571 This searches MAIN_OBJFILE as well as any associated separate debug info
2572 objfiles of MAIN_OBJFILE.
2573 BLOCK_INDEX can be GLOBAL_BLOCK or STATIC_BLOCK.
2574 Upon success fixes up the symbol's section if necessary. */
2576 extern struct block_symbol
2577 lookup_global_symbol_from_objfile (struct objfile *main_objfile,
2578 enum block_enum block_index,
2579 const char *name,
2580 const domain_enum domain);
2582 /* Return 1 if the supplied producer string matches the ARM RealView
2583 compiler (armcc). */
2584 bool producer_is_realview (const char *producer);
2586 void fixup_section (struct general_symbol_info *ginfo,
2587 CORE_ADDR addr, struct objfile *objfile);
2589 extern unsigned int symtab_create_debug;
2591 extern unsigned int symbol_lookup_debug;
2593 extern bool basenames_may_differ;
2595 bool compare_filenames_for_search (const char *filename,
2596 const char *search_name);
2598 bool compare_glob_filenames_for_search (const char *filename,
2599 const char *search_name);
2601 bool iterate_over_some_symtabs (const char *name,
2602 const char *real_path,
2603 struct compunit_symtab *first,
2604 struct compunit_symtab *after_last,
2605 gdb::function_view<bool (symtab *)> callback);
2607 void iterate_over_symtabs (const char *name,
2608 gdb::function_view<bool (symtab *)> callback);
2611 std::vector<CORE_ADDR> find_pcs_for_symtab_line
2612 (struct symtab *symtab, int line, struct linetable_entry **best_entry);
2614 /* Prototype for callbacks for LA_ITERATE_OVER_SYMBOLS. The callback
2615 is called once per matching symbol SYM. The callback should return
2616 true to indicate that LA_ITERATE_OVER_SYMBOLS should continue
2617 iterating, or false to indicate that the iteration should end. */
2619 typedef bool (symbol_found_callback_ftype) (struct block_symbol *bsym);
2621 /* Iterate over the symbols named NAME, matching DOMAIN, in BLOCK.
2623 For each symbol that matches, CALLBACK is called. The symbol is
2624 passed to the callback.
2626 If CALLBACK returns false, the iteration ends and this function
2627 returns false. Otherwise, the search continues, and the function
2628 eventually returns true. */
2630 bool iterate_over_symbols (const struct block *block,
2631 const lookup_name_info &name,
2632 const domain_enum domain,
2633 gdb::function_view<symbol_found_callback_ftype> callback);
2635 /* Like iterate_over_symbols, but if all calls to CALLBACK return
2636 true, then calls CALLBACK one additional time with a block_symbol
2637 that has a valid block but a NULL symbol. */
2639 bool iterate_over_symbols_terminated
2640 (const struct block *block,
2641 const lookup_name_info &name,
2642 const domain_enum domain,
2643 gdb::function_view<symbol_found_callback_ftype> callback);
2645 /* Storage type used by demangle_for_lookup. demangle_for_lookup
2646 either returns a const char * pointer that points to either of the
2647 fields of this type, or a pointer to the input NAME. This is done
2648 this way to avoid depending on the precise details of the storage
2649 for the string. */
2650 class demangle_result_storage
2652 public:
2654 /* Swap the malloc storage to STR, and return a pointer to the
2655 beginning of the new string. */
2656 const char *set_malloc_ptr (gdb::unique_xmalloc_ptr<char> &&str)
2658 m_malloc = std::move (str);
2659 return m_malloc.get ();
2662 /* Set the malloc storage to now point at PTR. Any previous malloc
2663 storage is released. */
2664 const char *set_malloc_ptr (char *ptr)
2666 m_malloc.reset (ptr);
2667 return ptr;
2670 private:
2672 /* The storage. */
2673 gdb::unique_xmalloc_ptr<char> m_malloc;
2676 const char *
2677 demangle_for_lookup (const char *name, enum language lang,
2678 demangle_result_storage &storage);
2680 /* Test to see if the symbol of language SYMBOL_LANGUAGE specified by
2681 SYMNAME (which is already demangled for C++ symbols) matches
2682 SYM_TEXT in the first SYM_TEXT_LEN characters. If so, add it to
2683 the current completion list and return true. Otherwise, return
2684 false. */
2685 bool completion_list_add_name (completion_tracker &tracker,
2686 language symbol_language,
2687 const char *symname,
2688 const lookup_name_info &lookup_name,
2689 const char *text, const char *word);
2691 /* A simple symbol searching class. */
2693 class symbol_searcher
2695 public:
2696 /* Returns the symbols found for the search. */
2697 const std::vector<block_symbol> &
2698 matching_symbols () const
2700 return m_symbols;
2703 /* Returns the minimal symbols found for the search. */
2704 const std::vector<bound_minimal_symbol> &
2705 matching_msymbols () const
2707 return m_minimal_symbols;
2710 /* Search for all symbols named NAME in LANGUAGE with DOMAIN, restricting
2711 search to FILE_SYMTABS and SEARCH_PSPACE, both of which may be NULL
2712 to search all symtabs and program spaces. */
2713 void find_all_symbols (const std::string &name,
2714 const struct language_defn *language,
2715 enum search_domain search_domain,
2716 std::vector<symtab *> *search_symtabs,
2717 struct program_space *search_pspace);
2719 /* Reset this object to perform another search. */
2720 void reset ()
2722 m_symbols.clear ();
2723 m_minimal_symbols.clear ();
2726 private:
2727 /* Matching debug symbols. */
2728 std::vector<block_symbol> m_symbols;
2730 /* Matching non-debug symbols. */
2731 std::vector<bound_minimal_symbol> m_minimal_symbols;
2734 /* Class used to encapsulate the filename filtering for the "info sources"
2735 command. */
2737 struct info_sources_filter
2739 /* If filename filtering is being used (see M_C_REGEXP) then which part
2740 of the filename is being filtered against? */
2741 enum class match_on
2743 /* Match against the full filename. */
2744 FULLNAME,
2746 /* Match only against the directory part of the full filename. */
2747 DIRNAME,
2749 /* Match only against the basename part of the full filename. */
2750 BASENAME
2753 /* Create a filter of MATCH_TYPE using regular expression REGEXP. If
2754 REGEXP is nullptr then all files will match the filter and MATCH_TYPE
2755 is ignored.
2757 The string pointed too by REGEXP must remain live and unchanged for
2758 this lifetime of this object as the object only retains a copy of the
2759 pointer. */
2760 info_sources_filter (match_on match_type, const char *regexp);
2762 DISABLE_COPY_AND_ASSIGN (info_sources_filter);
2764 /* Does FULLNAME match the filter defined by this object, return true if
2765 it does, otherwise, return false. If there is no filtering defined
2766 then this function will always return true. */
2767 bool matches (const char *fullname) const;
2769 private:
2771 /* The type of filtering in place. */
2772 match_on m_match_type;
2774 /* Points to the original regexp used to create this filter. */
2775 const char *m_regexp;
2777 /* A compiled version of M_REGEXP. This object is only given a value if
2778 M_REGEXP is not nullptr and is not the empty string. */
2779 gdb::optional<compiled_regex> m_c_regexp;
2782 /* Perform the core of the 'info sources' command.
2784 FILTER is used to perform regular expression based filtering on the
2785 source files that will be displayed.
2787 Output is written to UIOUT in CLI or MI style as appropriate. */
2789 extern void info_sources_worker (struct ui_out *uiout,
2790 bool group_by_objfile,
2791 const info_sources_filter &filter);
2793 #endif /* !defined(SYMTAB_H) */