gdb: Convert language_data::la_exp_desc to a method
[deliverable/binutils-gdb.git] / gdb / ada-lang.c
1 /* Ada language support routines for GDB, the GNU debugger.
2
3 Copyright (C) 1992-2020 Free Software Foundation, Inc.
4
5 This file is part of GDB.
6
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.
11
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.
16
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/>. */
19
20
21 #include "defs.h"
22 #include <ctype.h>
23 #include "gdb_regex.h"
24 #include "frame.h"
25 #include "symtab.h"
26 #include "gdbtypes.h"
27 #include "gdbcmd.h"
28 #include "expression.h"
29 #include "parser-defs.h"
30 #include "language.h"
31 #include "varobj.h"
32 #include "inferior.h"
33 #include "symfile.h"
34 #include "objfiles.h"
35 #include "breakpoint.h"
36 #include "gdbcore.h"
37 #include "hashtab.h"
38 #include "gdb_obstack.h"
39 #include "ada-lang.h"
40 #include "completer.h"
41 #include "ui-out.h"
42 #include "block.h"
43 #include "infcall.h"
44 #include "annotate.h"
45 #include "valprint.h"
46 #include "source.h"
47 #include "observable.h"
48 #include "stack.h"
49 #include "typeprint.h"
50 #include "namespace.h"
51 #include "cli/cli-style.h"
52
53 #include "value.h"
54 #include "mi/mi-common.h"
55 #include "arch-utils.h"
56 #include "cli/cli-utils.h"
57 #include "gdbsupport/function-view.h"
58 #include "gdbsupport/byte-vector.h"
59 #include <algorithm>
60
61 /* Define whether or not the C operator '/' truncates towards zero for
62 differently signed operands (truncation direction is undefined in C).
63 Copied from valarith.c. */
64
65 #ifndef TRUNCATION_TOWARDS_ZERO
66 #define TRUNCATION_TOWARDS_ZERO ((-5 / 2) == -2)
67 #endif
68
69 static struct type *desc_base_type (struct type *);
70
71 static struct type *desc_bounds_type (struct type *);
72
73 static struct value *desc_bounds (struct value *);
74
75 static int fat_pntr_bounds_bitpos (struct type *);
76
77 static int fat_pntr_bounds_bitsize (struct type *);
78
79 static struct type *desc_data_target_type (struct type *);
80
81 static struct value *desc_data (struct value *);
82
83 static int fat_pntr_data_bitpos (struct type *);
84
85 static int fat_pntr_data_bitsize (struct type *);
86
87 static struct value *desc_one_bound (struct value *, int, int);
88
89 static int desc_bound_bitpos (struct type *, int, int);
90
91 static int desc_bound_bitsize (struct type *, int, int);
92
93 static struct type *desc_index_type (struct type *, int);
94
95 static int desc_arity (struct type *);
96
97 static int ada_type_match (struct type *, struct type *, int);
98
99 static int ada_args_match (struct symbol *, struct value **, int);
100
101 static struct value *make_array_descriptor (struct type *, struct value *);
102
103 static void ada_add_block_symbols (struct obstack *,
104 const struct block *,
105 const lookup_name_info &lookup_name,
106 domain_enum, struct objfile *);
107
108 static void ada_add_all_symbols (struct obstack *, const struct block *,
109 const lookup_name_info &lookup_name,
110 domain_enum, int, int *);
111
112 static int is_nonfunction (struct block_symbol *, int);
113
114 static void add_defn_to_vec (struct obstack *, struct symbol *,
115 const struct block *);
116
117 static int num_defns_collected (struct obstack *);
118
119 static struct block_symbol *defns_collected (struct obstack *, int);
120
121 static struct value *resolve_subexp (expression_up *, int *, int,
122 struct type *, int,
123 innermost_block_tracker *);
124
125 static void replace_operator_with_call (expression_up *, int, int, int,
126 struct symbol *, const struct block *);
127
128 static int possible_user_operator_p (enum exp_opcode, struct value **);
129
130 static const char *ada_op_name (enum exp_opcode);
131
132 static const char *ada_decoded_op_name (enum exp_opcode);
133
134 static int numeric_type_p (struct type *);
135
136 static int integer_type_p (struct type *);
137
138 static int scalar_type_p (struct type *);
139
140 static int discrete_type_p (struct type *);
141
142 static struct type *ada_lookup_struct_elt_type (struct type *, const char *,
143 int, int);
144
145 static struct value *evaluate_subexp_type (struct expression *, int *);
146
147 static struct type *ada_find_parallel_type_with_name (struct type *,
148 const char *);
149
150 static int is_dynamic_field (struct type *, int);
151
152 static struct type *to_fixed_variant_branch_type (struct type *,
153 const gdb_byte *,
154 CORE_ADDR, struct value *);
155
156 static struct type *to_fixed_array_type (struct type *, struct value *, int);
157
158 static struct type *to_fixed_range_type (struct type *, struct value *);
159
160 static struct type *to_static_fixed_type (struct type *);
161 static struct type *static_unwrap_type (struct type *type);
162
163 static struct value *unwrap_value (struct value *);
164
165 static struct type *constrained_packed_array_type (struct type *, long *);
166
167 static struct type *decode_constrained_packed_array_type (struct type *);
168
169 static long decode_packed_array_bitsize (struct type *);
170
171 static struct value *decode_constrained_packed_array (struct value *);
172
173 static int ada_is_packed_array_type (struct type *);
174
175 static int ada_is_unconstrained_packed_array_type (struct type *);
176
177 static struct value *value_subscript_packed (struct value *, int,
178 struct value **);
179
180 static struct value *coerce_unspec_val_to_type (struct value *,
181 struct type *);
182
183 static int lesseq_defined_than (struct symbol *, struct symbol *);
184
185 static int equiv_types (struct type *, struct type *);
186
187 static int is_name_suffix (const char *);
188
189 static int advance_wild_match (const char **, const char *, int);
190
191 static bool wild_match (const char *name, const char *patn);
192
193 static struct value *ada_coerce_ref (struct value *);
194
195 static LONGEST pos_atr (struct value *);
196
197 static struct value *value_pos_atr (struct type *, struct value *);
198
199 static struct value *val_atr (struct type *, LONGEST);
200
201 static struct value *value_val_atr (struct type *, struct value *);
202
203 static struct symbol *standard_lookup (const char *, const struct block *,
204 domain_enum);
205
206 static struct value *ada_search_struct_field (const char *, struct value *, int,
207 struct type *);
208
209 static int find_struct_field (const char *, struct type *, int,
210 struct type **, int *, int *, int *, int *);
211
212 static int ada_resolve_function (struct block_symbol *, int,
213 struct value **, int, const char *,
214 struct type *, int);
215
216 static int ada_is_direct_array_type (struct type *);
217
218 static struct value *ada_index_struct_field (int, struct value *, int,
219 struct type *);
220
221 static struct value *assign_aggregate (struct value *, struct value *,
222 struct expression *,
223 int *, enum noside);
224
225 static void aggregate_assign_from_choices (struct value *, struct value *,
226 struct expression *,
227 int *, LONGEST *, int *,
228 int, LONGEST, LONGEST);
229
230 static void aggregate_assign_positional (struct value *, struct value *,
231 struct expression *,
232 int *, LONGEST *, int *, int,
233 LONGEST, LONGEST);
234
235
236 static void aggregate_assign_others (struct value *, struct value *,
237 struct expression *,
238 int *, LONGEST *, int, LONGEST, LONGEST);
239
240
241 static void add_component_interval (LONGEST, LONGEST, LONGEST *, int *, int);
242
243
244 static struct value *ada_evaluate_subexp (struct type *, struct expression *,
245 int *, enum noside);
246
247 static void ada_forward_operator_length (struct expression *, int, int *,
248 int *);
249
250 static struct type *ada_find_any_type (const char *name);
251
252 static symbol_name_matcher_ftype *ada_get_symbol_name_matcher
253 (const lookup_name_info &lookup_name);
254
255 \f
256
257 /* The result of a symbol lookup to be stored in our symbol cache. */
258
259 struct cache_entry
260 {
261 /* The name used to perform the lookup. */
262 const char *name;
263 /* The namespace used during the lookup. */
264 domain_enum domain;
265 /* The symbol returned by the lookup, or NULL if no matching symbol
266 was found. */
267 struct symbol *sym;
268 /* The block where the symbol was found, or NULL if no matching
269 symbol was found. */
270 const struct block *block;
271 /* A pointer to the next entry with the same hash. */
272 struct cache_entry *next;
273 };
274
275 /* The Ada symbol cache, used to store the result of Ada-mode symbol
276 lookups in the course of executing the user's commands.
277
278 The cache is implemented using a simple, fixed-sized hash.
279 The size is fixed on the grounds that there are not likely to be
280 all that many symbols looked up during any given session, regardless
281 of the size of the symbol table. If we decide to go to a resizable
282 table, let's just use the stuff from libiberty instead. */
283
284 #define HASH_SIZE 1009
285
286 struct ada_symbol_cache
287 {
288 /* An obstack used to store the entries in our cache. */
289 struct obstack cache_space;
290
291 /* The root of the hash table used to implement our symbol cache. */
292 struct cache_entry *root[HASH_SIZE];
293 };
294
295 static void ada_free_symbol_cache (struct ada_symbol_cache *sym_cache);
296
297 /* Maximum-sized dynamic type. */
298 static unsigned int varsize_limit;
299
300 static const char ada_completer_word_break_characters[] =
301 #ifdef VMS
302 " \t\n!@#%^&*()+=|~`}{[]\";:?/,-";
303 #else
304 " \t\n!@#$%^&*()+=|~`}{[]\";:?/,-";
305 #endif
306
307 /* The name of the symbol to use to get the name of the main subprogram. */
308 static const char ADA_MAIN_PROGRAM_SYMBOL_NAME[]
309 = "__gnat_ada_main_program_name";
310
311 /* Limit on the number of warnings to raise per expression evaluation. */
312 static int warning_limit = 2;
313
314 /* Number of warning messages issued; reset to 0 by cleanups after
315 expression evaluation. */
316 static int warnings_issued = 0;
317
318 static const char * const known_runtime_file_name_patterns[] = {
319 ADA_KNOWN_RUNTIME_FILE_NAME_PATTERNS NULL
320 };
321
322 static const char * const known_auxiliary_function_name_patterns[] = {
323 ADA_KNOWN_AUXILIARY_FUNCTION_NAME_PATTERNS NULL
324 };
325
326 /* Maintenance-related settings for this module. */
327
328 static struct cmd_list_element *maint_set_ada_cmdlist;
329 static struct cmd_list_element *maint_show_ada_cmdlist;
330
331 /* The "maintenance ada set/show ignore-descriptive-type" value. */
332
333 static bool ada_ignore_descriptive_types_p = false;
334
335 /* Inferior-specific data. */
336
337 /* Per-inferior data for this module. */
338
339 struct ada_inferior_data
340 {
341 /* The ada__tags__type_specific_data type, which is used when decoding
342 tagged types. With older versions of GNAT, this type was directly
343 accessible through a component ("tsd") in the object tag. But this
344 is no longer the case, so we cache it for each inferior. */
345 struct type *tsd_type = nullptr;
346
347 /* The exception_support_info data. This data is used to determine
348 how to implement support for Ada exception catchpoints in a given
349 inferior. */
350 const struct exception_support_info *exception_info = nullptr;
351 };
352
353 /* Our key to this module's inferior data. */
354 static const struct inferior_key<ada_inferior_data> ada_inferior_data;
355
356 /* Return our inferior data for the given inferior (INF).
357
358 This function always returns a valid pointer to an allocated
359 ada_inferior_data structure. If INF's inferior data has not
360 been previously set, this functions creates a new one with all
361 fields set to zero, sets INF's inferior to it, and then returns
362 a pointer to that newly allocated ada_inferior_data. */
363
364 static struct ada_inferior_data *
365 get_ada_inferior_data (struct inferior *inf)
366 {
367 struct ada_inferior_data *data;
368
369 data = ada_inferior_data.get (inf);
370 if (data == NULL)
371 data = ada_inferior_data.emplace (inf);
372
373 return data;
374 }
375
376 /* Perform all necessary cleanups regarding our module's inferior data
377 that is required after the inferior INF just exited. */
378
379 static void
380 ada_inferior_exit (struct inferior *inf)
381 {
382 ada_inferior_data.clear (inf);
383 }
384
385
386 /* program-space-specific data. */
387
388 /* This module's per-program-space data. */
389 struct ada_pspace_data
390 {
391 ~ada_pspace_data ()
392 {
393 if (sym_cache != NULL)
394 ada_free_symbol_cache (sym_cache);
395 }
396
397 /* The Ada symbol cache. */
398 struct ada_symbol_cache *sym_cache = nullptr;
399 };
400
401 /* Key to our per-program-space data. */
402 static const struct program_space_key<ada_pspace_data> ada_pspace_data_handle;
403
404 /* Return this module's data for the given program space (PSPACE).
405 If not is found, add a zero'ed one now.
406
407 This function always returns a valid object. */
408
409 static struct ada_pspace_data *
410 get_ada_pspace_data (struct program_space *pspace)
411 {
412 struct ada_pspace_data *data;
413
414 data = ada_pspace_data_handle.get (pspace);
415 if (data == NULL)
416 data = ada_pspace_data_handle.emplace (pspace);
417
418 return data;
419 }
420
421 /* Utilities */
422
423 /* If TYPE is a TYPE_CODE_TYPEDEF type, return the target type after
424 all typedef layers have been peeled. Otherwise, return TYPE.
425
426 Normally, we really expect a typedef type to only have 1 typedef layer.
427 In other words, we really expect the target type of a typedef type to be
428 a non-typedef type. This is particularly true for Ada units, because
429 the language does not have a typedef vs not-typedef distinction.
430 In that respect, the Ada compiler has been trying to eliminate as many
431 typedef definitions in the debugging information, since they generally
432 do not bring any extra information (we still use typedef under certain
433 circumstances related mostly to the GNAT encoding).
434
435 Unfortunately, we have seen situations where the debugging information
436 generated by the compiler leads to such multiple typedef layers. For
437 instance, consider the following example with stabs:
438
439 .stabs "pck__float_array___XUP:Tt(0,46)=s16P_ARRAY:(0,47)=[...]"[...]
440 .stabs "pck__float_array___XUP:t(0,36)=(0,46)",128,0,6,0
441
442 This is an error in the debugging information which causes type
443 pck__float_array___XUP to be defined twice, and the second time,
444 it is defined as a typedef of a typedef.
445
446 This is on the fringe of legality as far as debugging information is
447 concerned, and certainly unexpected. But it is easy to handle these
448 situations correctly, so we can afford to be lenient in this case. */
449
450 static struct type *
451 ada_typedef_target_type (struct type *type)
452 {
453 while (type->code () == TYPE_CODE_TYPEDEF)
454 type = TYPE_TARGET_TYPE (type);
455 return type;
456 }
457
458 /* Given DECODED_NAME a string holding a symbol name in its
459 decoded form (ie using the Ada dotted notation), returns
460 its unqualified name. */
461
462 static const char *
463 ada_unqualified_name (const char *decoded_name)
464 {
465 const char *result;
466
467 /* If the decoded name starts with '<', it means that the encoded
468 name does not follow standard naming conventions, and thus that
469 it is not your typical Ada symbol name. Trying to unqualify it
470 is therefore pointless and possibly erroneous. */
471 if (decoded_name[0] == '<')
472 return decoded_name;
473
474 result = strrchr (decoded_name, '.');
475 if (result != NULL)
476 result++; /* Skip the dot... */
477 else
478 result = decoded_name;
479
480 return result;
481 }
482
483 /* Return a string starting with '<', followed by STR, and '>'. */
484
485 static std::string
486 add_angle_brackets (const char *str)
487 {
488 return string_printf ("<%s>", str);
489 }
490
491 /* Assuming V points to an array of S objects, make sure that it contains at
492 least M objects, updating V and S as necessary. */
493
494 #define GROW_VECT(v, s, m) \
495 if ((s) < (m)) (v) = (char *) grow_vect (v, &(s), m, sizeof *(v));
496
497 /* Assuming VECT points to an array of *SIZE objects of size
498 ELEMENT_SIZE, grow it to contain at least MIN_SIZE objects,
499 updating *SIZE as necessary and returning the (new) array. */
500
501 static void *
502 grow_vect (void *vect, size_t *size, size_t min_size, int element_size)
503 {
504 if (*size < min_size)
505 {
506 *size *= 2;
507 if (*size < min_size)
508 *size = min_size;
509 vect = xrealloc (vect, *size * element_size);
510 }
511 return vect;
512 }
513
514 /* True (non-zero) iff TARGET matches FIELD_NAME up to any trailing
515 suffix of FIELD_NAME beginning "___". */
516
517 static int
518 field_name_match (const char *field_name, const char *target)
519 {
520 int len = strlen (target);
521
522 return
523 (strncmp (field_name, target, len) == 0
524 && (field_name[len] == '\0'
525 || (startswith (field_name + len, "___")
526 && strcmp (field_name + strlen (field_name) - 6,
527 "___XVN") != 0)));
528 }
529
530
531 /* Assuming TYPE is a TYPE_CODE_STRUCT or a TYPE_CODE_TYPDEF to
532 a TYPE_CODE_STRUCT, find the field whose name matches FIELD_NAME,
533 and return its index. This function also handles fields whose name
534 have ___ suffixes because the compiler sometimes alters their name
535 by adding such a suffix to represent fields with certain constraints.
536 If the field could not be found, return a negative number if
537 MAYBE_MISSING is set. Otherwise raise an error. */
538
539 int
540 ada_get_field_index (const struct type *type, const char *field_name,
541 int maybe_missing)
542 {
543 int fieldno;
544 struct type *struct_type = check_typedef ((struct type *) type);
545
546 for (fieldno = 0; fieldno < struct_type->num_fields (); fieldno++)
547 if (field_name_match (TYPE_FIELD_NAME (struct_type, fieldno), field_name))
548 return fieldno;
549
550 if (!maybe_missing)
551 error (_("Unable to find field %s in struct %s. Aborting"),
552 field_name, struct_type->name ());
553
554 return -1;
555 }
556
557 /* The length of the prefix of NAME prior to any "___" suffix. */
558
559 int
560 ada_name_prefix_len (const char *name)
561 {
562 if (name == NULL)
563 return 0;
564 else
565 {
566 const char *p = strstr (name, "___");
567
568 if (p == NULL)
569 return strlen (name);
570 else
571 return p - name;
572 }
573 }
574
575 /* Return non-zero if SUFFIX is a suffix of STR.
576 Return zero if STR is null. */
577
578 static int
579 is_suffix (const char *str, const char *suffix)
580 {
581 int len1, len2;
582
583 if (str == NULL)
584 return 0;
585 len1 = strlen (str);
586 len2 = strlen (suffix);
587 return (len1 >= len2 && strcmp (str + len1 - len2, suffix) == 0);
588 }
589
590 /* The contents of value VAL, treated as a value of type TYPE. The
591 result is an lval in memory if VAL is. */
592
593 static struct value *
594 coerce_unspec_val_to_type (struct value *val, struct type *type)
595 {
596 type = ada_check_typedef (type);
597 if (value_type (val) == type)
598 return val;
599 else
600 {
601 struct value *result;
602
603 /* Make sure that the object size is not unreasonable before
604 trying to allocate some memory for it. */
605 ada_ensure_varsize_limit (type);
606
607 if (value_lazy (val)
608 || TYPE_LENGTH (type) > TYPE_LENGTH (value_type (val)))
609 result = allocate_value_lazy (type);
610 else
611 {
612 result = allocate_value (type);
613 value_contents_copy_raw (result, 0, val, 0, TYPE_LENGTH (type));
614 }
615 set_value_component_location (result, val);
616 set_value_bitsize (result, value_bitsize (val));
617 set_value_bitpos (result, value_bitpos (val));
618 if (VALUE_LVAL (result) == lval_memory)
619 set_value_address (result, value_address (val));
620 return result;
621 }
622 }
623
624 static const gdb_byte *
625 cond_offset_host (const gdb_byte *valaddr, long offset)
626 {
627 if (valaddr == NULL)
628 return NULL;
629 else
630 return valaddr + offset;
631 }
632
633 static CORE_ADDR
634 cond_offset_target (CORE_ADDR address, long offset)
635 {
636 if (address == 0)
637 return 0;
638 else
639 return address + offset;
640 }
641
642 /* Issue a warning (as for the definition of warning in utils.c, but
643 with exactly one argument rather than ...), unless the limit on the
644 number of warnings has passed during the evaluation of the current
645 expression. */
646
647 /* FIXME: cagney/2004-10-10: This function is mimicking the behavior
648 provided by "complaint". */
649 static void lim_warning (const char *format, ...) ATTRIBUTE_PRINTF (1, 2);
650
651 static void
652 lim_warning (const char *format, ...)
653 {
654 va_list args;
655
656 va_start (args, format);
657 warnings_issued += 1;
658 if (warnings_issued <= warning_limit)
659 vwarning (format, args);
660
661 va_end (args);
662 }
663
664 /* Issue an error if the size of an object of type T is unreasonable,
665 i.e. if it would be a bad idea to allocate a value of this type in
666 GDB. */
667
668 void
669 ada_ensure_varsize_limit (const struct type *type)
670 {
671 if (TYPE_LENGTH (type) > varsize_limit)
672 error (_("object size is larger than varsize-limit"));
673 }
674
675 /* Maximum value of a SIZE-byte signed integer type. */
676 static LONGEST
677 max_of_size (int size)
678 {
679 LONGEST top_bit = (LONGEST) 1 << (size * 8 - 2);
680
681 return top_bit | (top_bit - 1);
682 }
683
684 /* Minimum value of a SIZE-byte signed integer type. */
685 static LONGEST
686 min_of_size (int size)
687 {
688 return -max_of_size (size) - 1;
689 }
690
691 /* Maximum value of a SIZE-byte unsigned integer type. */
692 static ULONGEST
693 umax_of_size (int size)
694 {
695 ULONGEST top_bit = (ULONGEST) 1 << (size * 8 - 1);
696
697 return top_bit | (top_bit - 1);
698 }
699
700 /* Maximum value of integral type T, as a signed quantity. */
701 static LONGEST
702 max_of_type (struct type *t)
703 {
704 if (t->is_unsigned ())
705 return (LONGEST) umax_of_size (TYPE_LENGTH (t));
706 else
707 return max_of_size (TYPE_LENGTH (t));
708 }
709
710 /* Minimum value of integral type T, as a signed quantity. */
711 static LONGEST
712 min_of_type (struct type *t)
713 {
714 if (t->is_unsigned ())
715 return 0;
716 else
717 return min_of_size (TYPE_LENGTH (t));
718 }
719
720 /* The largest value in the domain of TYPE, a discrete type, as an integer. */
721 LONGEST
722 ada_discrete_type_high_bound (struct type *type)
723 {
724 type = resolve_dynamic_type (type, {}, 0);
725 switch (type->code ())
726 {
727 case TYPE_CODE_RANGE:
728 {
729 const dynamic_prop &high = type->bounds ()->high;
730
731 if (high.kind () == PROP_CONST)
732 return high.const_val ();
733 else
734 {
735 gdb_assert (high.kind () == PROP_UNDEFINED);
736
737 /* This happens when trying to evaluate a type's dynamic bound
738 without a live target. There is nothing relevant for us to
739 return here, so return 0. */
740 return 0;
741 }
742 }
743 case TYPE_CODE_ENUM:
744 return TYPE_FIELD_ENUMVAL (type, type->num_fields () - 1);
745 case TYPE_CODE_BOOL:
746 return 1;
747 case TYPE_CODE_CHAR:
748 case TYPE_CODE_INT:
749 return max_of_type (type);
750 default:
751 error (_("Unexpected type in ada_discrete_type_high_bound."));
752 }
753 }
754
755 /* The smallest value in the domain of TYPE, a discrete type, as an integer. */
756 LONGEST
757 ada_discrete_type_low_bound (struct type *type)
758 {
759 type = resolve_dynamic_type (type, {}, 0);
760 switch (type->code ())
761 {
762 case TYPE_CODE_RANGE:
763 {
764 const dynamic_prop &low = type->bounds ()->low;
765
766 if (low.kind () == PROP_CONST)
767 return low.const_val ();
768 else
769 {
770 gdb_assert (low.kind () == PROP_UNDEFINED);
771
772 /* This happens when trying to evaluate a type's dynamic bound
773 without a live target. There is nothing relevant for us to
774 return here, so return 0. */
775 return 0;
776 }
777 }
778 case TYPE_CODE_ENUM:
779 return TYPE_FIELD_ENUMVAL (type, 0);
780 case TYPE_CODE_BOOL:
781 return 0;
782 case TYPE_CODE_CHAR:
783 case TYPE_CODE_INT:
784 return min_of_type (type);
785 default:
786 error (_("Unexpected type in ada_discrete_type_low_bound."));
787 }
788 }
789
790 /* The identity on non-range types. For range types, the underlying
791 non-range scalar type. */
792
793 static struct type *
794 get_base_type (struct type *type)
795 {
796 while (type != NULL && type->code () == TYPE_CODE_RANGE)
797 {
798 if (type == TYPE_TARGET_TYPE (type) || TYPE_TARGET_TYPE (type) == NULL)
799 return type;
800 type = TYPE_TARGET_TYPE (type);
801 }
802 return type;
803 }
804
805 /* Return a decoded version of the given VALUE. This means returning
806 a value whose type is obtained by applying all the GNAT-specific
807 encodings, making the resulting type a static but standard description
808 of the initial type. */
809
810 struct value *
811 ada_get_decoded_value (struct value *value)
812 {
813 struct type *type = ada_check_typedef (value_type (value));
814
815 if (ada_is_array_descriptor_type (type)
816 || (ada_is_constrained_packed_array_type (type)
817 && type->code () != TYPE_CODE_PTR))
818 {
819 if (type->code () == TYPE_CODE_TYPEDEF) /* array access type. */
820 value = ada_coerce_to_simple_array_ptr (value);
821 else
822 value = ada_coerce_to_simple_array (value);
823 }
824 else
825 value = ada_to_fixed_value (value);
826
827 return value;
828 }
829
830 /* Same as ada_get_decoded_value, but with the given TYPE.
831 Because there is no associated actual value for this type,
832 the resulting type might be a best-effort approximation in
833 the case of dynamic types. */
834
835 struct type *
836 ada_get_decoded_type (struct type *type)
837 {
838 type = to_static_fixed_type (type);
839 if (ada_is_constrained_packed_array_type (type))
840 type = ada_coerce_to_simple_array_type (type);
841 return type;
842 }
843
844 \f
845
846 /* Language Selection */
847
848 /* If the main program is in Ada, return language_ada, otherwise return LANG
849 (the main program is in Ada iif the adainit symbol is found). */
850
851 static enum language
852 ada_update_initial_language (enum language lang)
853 {
854 if (lookup_minimal_symbol ("adainit", NULL, NULL).minsym != NULL)
855 return language_ada;
856
857 return lang;
858 }
859
860 /* If the main procedure is written in Ada, then return its name.
861 The result is good until the next call. Return NULL if the main
862 procedure doesn't appear to be in Ada. */
863
864 char *
865 ada_main_name (void)
866 {
867 struct bound_minimal_symbol msym;
868 static gdb::unique_xmalloc_ptr<char> main_program_name;
869
870 /* For Ada, the name of the main procedure is stored in a specific
871 string constant, generated by the binder. Look for that symbol,
872 extract its address, and then read that string. If we didn't find
873 that string, then most probably the main procedure is not written
874 in Ada. */
875 msym = lookup_minimal_symbol (ADA_MAIN_PROGRAM_SYMBOL_NAME, NULL, NULL);
876
877 if (msym.minsym != NULL)
878 {
879 CORE_ADDR main_program_name_addr = BMSYMBOL_VALUE_ADDRESS (msym);
880 if (main_program_name_addr == 0)
881 error (_("Invalid address for Ada main program name."));
882
883 main_program_name = target_read_string (main_program_name_addr, 1024);
884 return main_program_name.get ();
885 }
886
887 /* The main procedure doesn't seem to be in Ada. */
888 return NULL;
889 }
890 \f
891 /* Symbols */
892
893 /* Table of Ada operators and their GNAT-encoded names. Last entry is pair
894 of NULLs. */
895
896 const struct ada_opname_map ada_opname_table[] = {
897 {"Oadd", "\"+\"", BINOP_ADD},
898 {"Osubtract", "\"-\"", BINOP_SUB},
899 {"Omultiply", "\"*\"", BINOP_MUL},
900 {"Odivide", "\"/\"", BINOP_DIV},
901 {"Omod", "\"mod\"", BINOP_MOD},
902 {"Orem", "\"rem\"", BINOP_REM},
903 {"Oexpon", "\"**\"", BINOP_EXP},
904 {"Olt", "\"<\"", BINOP_LESS},
905 {"Ole", "\"<=\"", BINOP_LEQ},
906 {"Ogt", "\">\"", BINOP_GTR},
907 {"Oge", "\">=\"", BINOP_GEQ},
908 {"Oeq", "\"=\"", BINOP_EQUAL},
909 {"One", "\"/=\"", BINOP_NOTEQUAL},
910 {"Oand", "\"and\"", BINOP_BITWISE_AND},
911 {"Oor", "\"or\"", BINOP_BITWISE_IOR},
912 {"Oxor", "\"xor\"", BINOP_BITWISE_XOR},
913 {"Oconcat", "\"&\"", BINOP_CONCAT},
914 {"Oabs", "\"abs\"", UNOP_ABS},
915 {"Onot", "\"not\"", UNOP_LOGICAL_NOT},
916 {"Oadd", "\"+\"", UNOP_PLUS},
917 {"Osubtract", "\"-\"", UNOP_NEG},
918 {NULL, NULL}
919 };
920
921 /* The "encoded" form of DECODED, according to GNAT conventions. The
922 result is valid until the next call to ada_encode. If
923 THROW_ERRORS, throw an error if invalid operator name is found.
924 Otherwise, return NULL in that case. */
925
926 static char *
927 ada_encode_1 (const char *decoded, bool throw_errors)
928 {
929 static char *encoding_buffer = NULL;
930 static size_t encoding_buffer_size = 0;
931 const char *p;
932 int k;
933
934 if (decoded == NULL)
935 return NULL;
936
937 GROW_VECT (encoding_buffer, encoding_buffer_size,
938 2 * strlen (decoded) + 10);
939
940 k = 0;
941 for (p = decoded; *p != '\0'; p += 1)
942 {
943 if (*p == '.')
944 {
945 encoding_buffer[k] = encoding_buffer[k + 1] = '_';
946 k += 2;
947 }
948 else if (*p == '"')
949 {
950 const struct ada_opname_map *mapping;
951
952 for (mapping = ada_opname_table;
953 mapping->encoded != NULL
954 && !startswith (p, mapping->decoded); mapping += 1)
955 ;
956 if (mapping->encoded == NULL)
957 {
958 if (throw_errors)
959 error (_("invalid Ada operator name: %s"), p);
960 else
961 return NULL;
962 }
963 strcpy (encoding_buffer + k, mapping->encoded);
964 k += strlen (mapping->encoded);
965 break;
966 }
967 else
968 {
969 encoding_buffer[k] = *p;
970 k += 1;
971 }
972 }
973
974 encoding_buffer[k] = '\0';
975 return encoding_buffer;
976 }
977
978 /* The "encoded" form of DECODED, according to GNAT conventions.
979 The result is valid until the next call to ada_encode. */
980
981 char *
982 ada_encode (const char *decoded)
983 {
984 return ada_encode_1 (decoded, true);
985 }
986
987 /* Return NAME folded to lower case, or, if surrounded by single
988 quotes, unfolded, but with the quotes stripped away. Result good
989 to next call. */
990
991 static char *
992 ada_fold_name (gdb::string_view name)
993 {
994 static char *fold_buffer = NULL;
995 static size_t fold_buffer_size = 0;
996
997 int len = name.size ();
998 GROW_VECT (fold_buffer, fold_buffer_size, len + 1);
999
1000 if (name[0] == '\'')
1001 {
1002 strncpy (fold_buffer, name.data () + 1, len - 2);
1003 fold_buffer[len - 2] = '\000';
1004 }
1005 else
1006 {
1007 int i;
1008
1009 for (i = 0; i <= len; i += 1)
1010 fold_buffer[i] = tolower (name[i]);
1011 }
1012
1013 return fold_buffer;
1014 }
1015
1016 /* Return nonzero if C is either a digit or a lowercase alphabet character. */
1017
1018 static int
1019 is_lower_alphanum (const char c)
1020 {
1021 return (isdigit (c) || (isalpha (c) && islower (c)));
1022 }
1023
1024 /* ENCODED is the linkage name of a symbol and LEN contains its length.
1025 This function saves in LEN the length of that same symbol name but
1026 without either of these suffixes:
1027 . .{DIGIT}+
1028 . ${DIGIT}+
1029 . ___{DIGIT}+
1030 . __{DIGIT}+.
1031
1032 These are suffixes introduced by the compiler for entities such as
1033 nested subprogram for instance, in order to avoid name clashes.
1034 They do not serve any purpose for the debugger. */
1035
1036 static void
1037 ada_remove_trailing_digits (const char *encoded, int *len)
1038 {
1039 if (*len > 1 && isdigit (encoded[*len - 1]))
1040 {
1041 int i = *len - 2;
1042
1043 while (i > 0 && isdigit (encoded[i]))
1044 i--;
1045 if (i >= 0 && encoded[i] == '.')
1046 *len = i;
1047 else if (i >= 0 && encoded[i] == '$')
1048 *len = i;
1049 else if (i >= 2 && startswith (encoded + i - 2, "___"))
1050 *len = i - 2;
1051 else if (i >= 1 && startswith (encoded + i - 1, "__"))
1052 *len = i - 1;
1053 }
1054 }
1055
1056 /* Remove the suffix introduced by the compiler for protected object
1057 subprograms. */
1058
1059 static void
1060 ada_remove_po_subprogram_suffix (const char *encoded, int *len)
1061 {
1062 /* Remove trailing N. */
1063
1064 /* Protected entry subprograms are broken into two
1065 separate subprograms: The first one is unprotected, and has
1066 a 'N' suffix; the second is the protected version, and has
1067 the 'P' suffix. The second calls the first one after handling
1068 the protection. Since the P subprograms are internally generated,
1069 we leave these names undecoded, giving the user a clue that this
1070 entity is internal. */
1071
1072 if (*len > 1
1073 && encoded[*len - 1] == 'N'
1074 && (isdigit (encoded[*len - 2]) || islower (encoded[*len - 2])))
1075 *len = *len - 1;
1076 }
1077
1078 /* If ENCODED follows the GNAT entity encoding conventions, then return
1079 the decoded form of ENCODED. Otherwise, return "<%s>" where "%s" is
1080 replaced by ENCODED. */
1081
1082 std::string
1083 ada_decode (const char *encoded)
1084 {
1085 int i, j;
1086 int len0;
1087 const char *p;
1088 int at_start_name;
1089 std::string decoded;
1090
1091 /* With function descriptors on PPC64, the value of a symbol named
1092 ".FN", if it exists, is the entry point of the function "FN". */
1093 if (encoded[0] == '.')
1094 encoded += 1;
1095
1096 /* The name of the Ada main procedure starts with "_ada_".
1097 This prefix is not part of the decoded name, so skip this part
1098 if we see this prefix. */
1099 if (startswith (encoded, "_ada_"))
1100 encoded += 5;
1101
1102 /* If the name starts with '_', then it is not a properly encoded
1103 name, so do not attempt to decode it. Similarly, if the name
1104 starts with '<', the name should not be decoded. */
1105 if (encoded[0] == '_' || encoded[0] == '<')
1106 goto Suppress;
1107
1108 len0 = strlen (encoded);
1109
1110 ada_remove_trailing_digits (encoded, &len0);
1111 ada_remove_po_subprogram_suffix (encoded, &len0);
1112
1113 /* Remove the ___X.* suffix if present. Do not forget to verify that
1114 the suffix is located before the current "end" of ENCODED. We want
1115 to avoid re-matching parts of ENCODED that have previously been
1116 marked as discarded (by decrementing LEN0). */
1117 p = strstr (encoded, "___");
1118 if (p != NULL && p - encoded < len0 - 3)
1119 {
1120 if (p[3] == 'X')
1121 len0 = p - encoded;
1122 else
1123 goto Suppress;
1124 }
1125
1126 /* Remove any trailing TKB suffix. It tells us that this symbol
1127 is for the body of a task, but that information does not actually
1128 appear in the decoded name. */
1129
1130 if (len0 > 3 && startswith (encoded + len0 - 3, "TKB"))
1131 len0 -= 3;
1132
1133 /* Remove any trailing TB suffix. The TB suffix is slightly different
1134 from the TKB suffix because it is used for non-anonymous task
1135 bodies. */
1136
1137 if (len0 > 2 && startswith (encoded + len0 - 2, "TB"))
1138 len0 -= 2;
1139
1140 /* Remove trailing "B" suffixes. */
1141 /* FIXME: brobecker/2006-04-19: Not sure what this are used for... */
1142
1143 if (len0 > 1 && startswith (encoded + len0 - 1, "B"))
1144 len0 -= 1;
1145
1146 /* Make decoded big enough for possible expansion by operator name. */
1147
1148 decoded.resize (2 * len0 + 1, 'X');
1149
1150 /* Remove trailing __{digit}+ or trailing ${digit}+. */
1151
1152 if (len0 > 1 && isdigit (encoded[len0 - 1]))
1153 {
1154 i = len0 - 2;
1155 while ((i >= 0 && isdigit (encoded[i]))
1156 || (i >= 1 && encoded[i] == '_' && isdigit (encoded[i - 1])))
1157 i -= 1;
1158 if (i > 1 && encoded[i] == '_' && encoded[i - 1] == '_')
1159 len0 = i - 1;
1160 else if (encoded[i] == '$')
1161 len0 = i;
1162 }
1163
1164 /* The first few characters that are not alphabetic are not part
1165 of any encoding we use, so we can copy them over verbatim. */
1166
1167 for (i = 0, j = 0; i < len0 && !isalpha (encoded[i]); i += 1, j += 1)
1168 decoded[j] = encoded[i];
1169
1170 at_start_name = 1;
1171 while (i < len0)
1172 {
1173 /* Is this a symbol function? */
1174 if (at_start_name && encoded[i] == 'O')
1175 {
1176 int k;
1177
1178 for (k = 0; ada_opname_table[k].encoded != NULL; k += 1)
1179 {
1180 int op_len = strlen (ada_opname_table[k].encoded);
1181 if ((strncmp (ada_opname_table[k].encoded + 1, encoded + i + 1,
1182 op_len - 1) == 0)
1183 && !isalnum (encoded[i + op_len]))
1184 {
1185 strcpy (&decoded.front() + j, ada_opname_table[k].decoded);
1186 at_start_name = 0;
1187 i += op_len;
1188 j += strlen (ada_opname_table[k].decoded);
1189 break;
1190 }
1191 }
1192 if (ada_opname_table[k].encoded != NULL)
1193 continue;
1194 }
1195 at_start_name = 0;
1196
1197 /* Replace "TK__" with "__", which will eventually be translated
1198 into "." (just below). */
1199
1200 if (i < len0 - 4 && startswith (encoded + i, "TK__"))
1201 i += 2;
1202
1203 /* Replace "__B_{DIGITS}+__" sequences by "__", which will eventually
1204 be translated into "." (just below). These are internal names
1205 generated for anonymous blocks inside which our symbol is nested. */
1206
1207 if (len0 - i > 5 && encoded [i] == '_' && encoded [i+1] == '_'
1208 && encoded [i+2] == 'B' && encoded [i+3] == '_'
1209 && isdigit (encoded [i+4]))
1210 {
1211 int k = i + 5;
1212
1213 while (k < len0 && isdigit (encoded[k]))
1214 k++; /* Skip any extra digit. */
1215
1216 /* Double-check that the "__B_{DIGITS}+" sequence we found
1217 is indeed followed by "__". */
1218 if (len0 - k > 2 && encoded [k] == '_' && encoded [k+1] == '_')
1219 i = k;
1220 }
1221
1222 /* Remove _E{DIGITS}+[sb] */
1223
1224 /* Just as for protected object subprograms, there are 2 categories
1225 of subprograms created by the compiler for each entry. The first
1226 one implements the actual entry code, and has a suffix following
1227 the convention above; the second one implements the barrier and
1228 uses the same convention as above, except that the 'E' is replaced
1229 by a 'B'.
1230
1231 Just as above, we do not decode the name of barrier functions
1232 to give the user a clue that the code he is debugging has been
1233 internally generated. */
1234
1235 if (len0 - i > 3 && encoded [i] == '_' && encoded[i+1] == 'E'
1236 && isdigit (encoded[i+2]))
1237 {
1238 int k = i + 3;
1239
1240 while (k < len0 && isdigit (encoded[k]))
1241 k++;
1242
1243 if (k < len0
1244 && (encoded[k] == 'b' || encoded[k] == 's'))
1245 {
1246 k++;
1247 /* Just as an extra precaution, make sure that if this
1248 suffix is followed by anything else, it is a '_'.
1249 Otherwise, we matched this sequence by accident. */
1250 if (k == len0
1251 || (k < len0 && encoded[k] == '_'))
1252 i = k;
1253 }
1254 }
1255
1256 /* Remove trailing "N" in [a-z0-9]+N__. The N is added by
1257 the GNAT front-end in protected object subprograms. */
1258
1259 if (i < len0 + 3
1260 && encoded[i] == 'N' && encoded[i+1] == '_' && encoded[i+2] == '_')
1261 {
1262 /* Backtrack a bit up until we reach either the begining of
1263 the encoded name, or "__". Make sure that we only find
1264 digits or lowercase characters. */
1265 const char *ptr = encoded + i - 1;
1266
1267 while (ptr >= encoded && is_lower_alphanum (ptr[0]))
1268 ptr--;
1269 if (ptr < encoded
1270 || (ptr > encoded && ptr[0] == '_' && ptr[-1] == '_'))
1271 i++;
1272 }
1273
1274 if (encoded[i] == 'X' && i != 0 && isalnum (encoded[i - 1]))
1275 {
1276 /* This is a X[bn]* sequence not separated from the previous
1277 part of the name with a non-alpha-numeric character (in other
1278 words, immediately following an alpha-numeric character), then
1279 verify that it is placed at the end of the encoded name. If
1280 not, then the encoding is not valid and we should abort the
1281 decoding. Otherwise, just skip it, it is used in body-nested
1282 package names. */
1283 do
1284 i += 1;
1285 while (i < len0 && (encoded[i] == 'b' || encoded[i] == 'n'));
1286 if (i < len0)
1287 goto Suppress;
1288 }
1289 else if (i < len0 - 2 && encoded[i] == '_' && encoded[i + 1] == '_')
1290 {
1291 /* Replace '__' by '.'. */
1292 decoded[j] = '.';
1293 at_start_name = 1;
1294 i += 2;
1295 j += 1;
1296 }
1297 else
1298 {
1299 /* It's a character part of the decoded name, so just copy it
1300 over. */
1301 decoded[j] = encoded[i];
1302 i += 1;
1303 j += 1;
1304 }
1305 }
1306 decoded.resize (j);
1307
1308 /* Decoded names should never contain any uppercase character.
1309 Double-check this, and abort the decoding if we find one. */
1310
1311 for (i = 0; i < decoded.length(); ++i)
1312 if (isupper (decoded[i]) || decoded[i] == ' ')
1313 goto Suppress;
1314
1315 return decoded;
1316
1317 Suppress:
1318 if (encoded[0] == '<')
1319 decoded = encoded;
1320 else
1321 decoded = '<' + std::string(encoded) + '>';
1322 return decoded;
1323
1324 }
1325
1326 /* Table for keeping permanent unique copies of decoded names. Once
1327 allocated, names in this table are never released. While this is a
1328 storage leak, it should not be significant unless there are massive
1329 changes in the set of decoded names in successive versions of a
1330 symbol table loaded during a single session. */
1331 static struct htab *decoded_names_store;
1332
1333 /* Returns the decoded name of GSYMBOL, as for ada_decode, caching it
1334 in the language-specific part of GSYMBOL, if it has not been
1335 previously computed. Tries to save the decoded name in the same
1336 obstack as GSYMBOL, if possible, and otherwise on the heap (so that,
1337 in any case, the decoded symbol has a lifetime at least that of
1338 GSYMBOL).
1339 The GSYMBOL parameter is "mutable" in the C++ sense: logically
1340 const, but nevertheless modified to a semantically equivalent form
1341 when a decoded name is cached in it. */
1342
1343 const char *
1344 ada_decode_symbol (const struct general_symbol_info *arg)
1345 {
1346 struct general_symbol_info *gsymbol = (struct general_symbol_info *) arg;
1347 const char **resultp =
1348 &gsymbol->language_specific.demangled_name;
1349
1350 if (!gsymbol->ada_mangled)
1351 {
1352 std::string decoded = ada_decode (gsymbol->linkage_name ());
1353 struct obstack *obstack = gsymbol->language_specific.obstack;
1354
1355 gsymbol->ada_mangled = 1;
1356
1357 if (obstack != NULL)
1358 *resultp = obstack_strdup (obstack, decoded.c_str ());
1359 else
1360 {
1361 /* Sometimes, we can't find a corresponding objfile, in
1362 which case, we put the result on the heap. Since we only
1363 decode when needed, we hope this usually does not cause a
1364 significant memory leak (FIXME). */
1365
1366 char **slot = (char **) htab_find_slot (decoded_names_store,
1367 decoded.c_str (), INSERT);
1368
1369 if (*slot == NULL)
1370 *slot = xstrdup (decoded.c_str ());
1371 *resultp = *slot;
1372 }
1373 }
1374
1375 return *resultp;
1376 }
1377
1378 static char *
1379 ada_la_decode (const char *encoded, int options)
1380 {
1381 return xstrdup (ada_decode (encoded).c_str ());
1382 }
1383
1384 \f
1385
1386 /* Arrays */
1387
1388 /* Assuming that INDEX_DESC_TYPE is an ___XA structure, a structure
1389 generated by the GNAT compiler to describe the index type used
1390 for each dimension of an array, check whether it follows the latest
1391 known encoding. If not, fix it up to conform to the latest encoding.
1392 Otherwise, do nothing. This function also does nothing if
1393 INDEX_DESC_TYPE is NULL.
1394
1395 The GNAT encoding used to describe the array index type evolved a bit.
1396 Initially, the information would be provided through the name of each
1397 field of the structure type only, while the type of these fields was
1398 described as unspecified and irrelevant. The debugger was then expected
1399 to perform a global type lookup using the name of that field in order
1400 to get access to the full index type description. Because these global
1401 lookups can be very expensive, the encoding was later enhanced to make
1402 the global lookup unnecessary by defining the field type as being
1403 the full index type description.
1404
1405 The purpose of this routine is to allow us to support older versions
1406 of the compiler by detecting the use of the older encoding, and by
1407 fixing up the INDEX_DESC_TYPE to follow the new one (at this point,
1408 we essentially replace each field's meaningless type by the associated
1409 index subtype). */
1410
1411 void
1412 ada_fixup_array_indexes_type (struct type *index_desc_type)
1413 {
1414 int i;
1415
1416 if (index_desc_type == NULL)
1417 return;
1418 gdb_assert (index_desc_type->num_fields () > 0);
1419
1420 /* Check if INDEX_DESC_TYPE follows the older encoding (it is sufficient
1421 to check one field only, no need to check them all). If not, return
1422 now.
1423
1424 If our INDEX_DESC_TYPE was generated using the older encoding,
1425 the field type should be a meaningless integer type whose name
1426 is not equal to the field name. */
1427 if (index_desc_type->field (0).type ()->name () != NULL
1428 && strcmp (index_desc_type->field (0).type ()->name (),
1429 TYPE_FIELD_NAME (index_desc_type, 0)) == 0)
1430 return;
1431
1432 /* Fixup each field of INDEX_DESC_TYPE. */
1433 for (i = 0; i < index_desc_type->num_fields (); i++)
1434 {
1435 const char *name = TYPE_FIELD_NAME (index_desc_type, i);
1436 struct type *raw_type = ada_check_typedef (ada_find_any_type (name));
1437
1438 if (raw_type)
1439 index_desc_type->field (i).set_type (raw_type);
1440 }
1441 }
1442
1443 /* The desc_* routines return primitive portions of array descriptors
1444 (fat pointers). */
1445
1446 /* The descriptor or array type, if any, indicated by TYPE; removes
1447 level of indirection, if needed. */
1448
1449 static struct type *
1450 desc_base_type (struct type *type)
1451 {
1452 if (type == NULL)
1453 return NULL;
1454 type = ada_check_typedef (type);
1455 if (type->code () == TYPE_CODE_TYPEDEF)
1456 type = ada_typedef_target_type (type);
1457
1458 if (type != NULL
1459 && (type->code () == TYPE_CODE_PTR
1460 || type->code () == TYPE_CODE_REF))
1461 return ada_check_typedef (TYPE_TARGET_TYPE (type));
1462 else
1463 return type;
1464 }
1465
1466 /* True iff TYPE indicates a "thin" array pointer type. */
1467
1468 static int
1469 is_thin_pntr (struct type *type)
1470 {
1471 return
1472 is_suffix (ada_type_name (desc_base_type (type)), "___XUT")
1473 || is_suffix (ada_type_name (desc_base_type (type)), "___XUT___XVE");
1474 }
1475
1476 /* The descriptor type for thin pointer type TYPE. */
1477
1478 static struct type *
1479 thin_descriptor_type (struct type *type)
1480 {
1481 struct type *base_type = desc_base_type (type);
1482
1483 if (base_type == NULL)
1484 return NULL;
1485 if (is_suffix (ada_type_name (base_type), "___XVE"))
1486 return base_type;
1487 else
1488 {
1489 struct type *alt_type = ada_find_parallel_type (base_type, "___XVE");
1490
1491 if (alt_type == NULL)
1492 return base_type;
1493 else
1494 return alt_type;
1495 }
1496 }
1497
1498 /* A pointer to the array data for thin-pointer value VAL. */
1499
1500 static struct value *
1501 thin_data_pntr (struct value *val)
1502 {
1503 struct type *type = ada_check_typedef (value_type (val));
1504 struct type *data_type = desc_data_target_type (thin_descriptor_type (type));
1505
1506 data_type = lookup_pointer_type (data_type);
1507
1508 if (type->code () == TYPE_CODE_PTR)
1509 return value_cast (data_type, value_copy (val));
1510 else
1511 return value_from_longest (data_type, value_address (val));
1512 }
1513
1514 /* True iff TYPE indicates a "thick" array pointer type. */
1515
1516 static int
1517 is_thick_pntr (struct type *type)
1518 {
1519 type = desc_base_type (type);
1520 return (type != NULL && type->code () == TYPE_CODE_STRUCT
1521 && lookup_struct_elt_type (type, "P_BOUNDS", 1) != NULL);
1522 }
1523
1524 /* If TYPE is the type of an array descriptor (fat or thin pointer) or a
1525 pointer to one, the type of its bounds data; otherwise, NULL. */
1526
1527 static struct type *
1528 desc_bounds_type (struct type *type)
1529 {
1530 struct type *r;
1531
1532 type = desc_base_type (type);
1533
1534 if (type == NULL)
1535 return NULL;
1536 else if (is_thin_pntr (type))
1537 {
1538 type = thin_descriptor_type (type);
1539 if (type == NULL)
1540 return NULL;
1541 r = lookup_struct_elt_type (type, "BOUNDS", 1);
1542 if (r != NULL)
1543 return ada_check_typedef (r);
1544 }
1545 else if (type->code () == TYPE_CODE_STRUCT)
1546 {
1547 r = lookup_struct_elt_type (type, "P_BOUNDS", 1);
1548 if (r != NULL)
1549 return ada_check_typedef (TYPE_TARGET_TYPE (ada_check_typedef (r)));
1550 }
1551 return NULL;
1552 }
1553
1554 /* If ARR is an array descriptor (fat or thin pointer), or pointer to
1555 one, a pointer to its bounds data. Otherwise NULL. */
1556
1557 static struct value *
1558 desc_bounds (struct value *arr)
1559 {
1560 struct type *type = ada_check_typedef (value_type (arr));
1561
1562 if (is_thin_pntr (type))
1563 {
1564 struct type *bounds_type =
1565 desc_bounds_type (thin_descriptor_type (type));
1566 LONGEST addr;
1567
1568 if (bounds_type == NULL)
1569 error (_("Bad GNAT array descriptor"));
1570
1571 /* NOTE: The following calculation is not really kosher, but
1572 since desc_type is an XVE-encoded type (and shouldn't be),
1573 the correct calculation is a real pain. FIXME (and fix GCC). */
1574 if (type->code () == TYPE_CODE_PTR)
1575 addr = value_as_long (arr);
1576 else
1577 addr = value_address (arr);
1578
1579 return
1580 value_from_longest (lookup_pointer_type (bounds_type),
1581 addr - TYPE_LENGTH (bounds_type));
1582 }
1583
1584 else if (is_thick_pntr (type))
1585 {
1586 struct value *p_bounds = value_struct_elt (&arr, NULL, "P_BOUNDS", NULL,
1587 _("Bad GNAT array descriptor"));
1588 struct type *p_bounds_type = value_type (p_bounds);
1589
1590 if (p_bounds_type
1591 && p_bounds_type->code () == TYPE_CODE_PTR)
1592 {
1593 struct type *target_type = TYPE_TARGET_TYPE (p_bounds_type);
1594
1595 if (target_type->is_stub ())
1596 p_bounds = value_cast (lookup_pointer_type
1597 (ada_check_typedef (target_type)),
1598 p_bounds);
1599 }
1600 else
1601 error (_("Bad GNAT array descriptor"));
1602
1603 return p_bounds;
1604 }
1605 else
1606 return NULL;
1607 }
1608
1609 /* If TYPE is the type of an array-descriptor (fat pointer), the bit
1610 position of the field containing the address of the bounds data. */
1611
1612 static int
1613 fat_pntr_bounds_bitpos (struct type *type)
1614 {
1615 return TYPE_FIELD_BITPOS (desc_base_type (type), 1);
1616 }
1617
1618 /* If TYPE is the type of an array-descriptor (fat pointer), the bit
1619 size of the field containing the address of the bounds data. */
1620
1621 static int
1622 fat_pntr_bounds_bitsize (struct type *type)
1623 {
1624 type = desc_base_type (type);
1625
1626 if (TYPE_FIELD_BITSIZE (type, 1) > 0)
1627 return TYPE_FIELD_BITSIZE (type, 1);
1628 else
1629 return 8 * TYPE_LENGTH (ada_check_typedef (type->field (1).type ()));
1630 }
1631
1632 /* If TYPE is the type of an array descriptor (fat or thin pointer) or a
1633 pointer to one, the type of its array data (a array-with-no-bounds type);
1634 otherwise, NULL. Use ada_type_of_array to get an array type with bounds
1635 data. */
1636
1637 static struct type *
1638 desc_data_target_type (struct type *type)
1639 {
1640 type = desc_base_type (type);
1641
1642 /* NOTE: The following is bogus; see comment in desc_bounds. */
1643 if (is_thin_pntr (type))
1644 return desc_base_type (thin_descriptor_type (type)->field (1).type ());
1645 else if (is_thick_pntr (type))
1646 {
1647 struct type *data_type = lookup_struct_elt_type (type, "P_ARRAY", 1);
1648
1649 if (data_type
1650 && ada_check_typedef (data_type)->code () == TYPE_CODE_PTR)
1651 return ada_check_typedef (TYPE_TARGET_TYPE (data_type));
1652 }
1653
1654 return NULL;
1655 }
1656
1657 /* If ARR is an array descriptor (fat or thin pointer), a pointer to
1658 its array data. */
1659
1660 static struct value *
1661 desc_data (struct value *arr)
1662 {
1663 struct type *type = value_type (arr);
1664
1665 if (is_thin_pntr (type))
1666 return thin_data_pntr (arr);
1667 else if (is_thick_pntr (type))
1668 return value_struct_elt (&arr, NULL, "P_ARRAY", NULL,
1669 _("Bad GNAT array descriptor"));
1670 else
1671 return NULL;
1672 }
1673
1674
1675 /* If TYPE is the type of an array-descriptor (fat pointer), the bit
1676 position of the field containing the address of the data. */
1677
1678 static int
1679 fat_pntr_data_bitpos (struct type *type)
1680 {
1681 return TYPE_FIELD_BITPOS (desc_base_type (type), 0);
1682 }
1683
1684 /* If TYPE is the type of an array-descriptor (fat pointer), the bit
1685 size of the field containing the address of the data. */
1686
1687 static int
1688 fat_pntr_data_bitsize (struct type *type)
1689 {
1690 type = desc_base_type (type);
1691
1692 if (TYPE_FIELD_BITSIZE (type, 0) > 0)
1693 return TYPE_FIELD_BITSIZE (type, 0);
1694 else
1695 return TARGET_CHAR_BIT * TYPE_LENGTH (type->field (0).type ());
1696 }
1697
1698 /* If BOUNDS is an array-bounds structure (or pointer to one), return
1699 the Ith lower bound stored in it, if WHICH is 0, and the Ith upper
1700 bound, if WHICH is 1. The first bound is I=1. */
1701
1702 static struct value *
1703 desc_one_bound (struct value *bounds, int i, int which)
1704 {
1705 char bound_name[20];
1706 xsnprintf (bound_name, sizeof (bound_name), "%cB%d",
1707 which ? 'U' : 'L', i - 1);
1708 return value_struct_elt (&bounds, NULL, bound_name, NULL,
1709 _("Bad GNAT array descriptor bounds"));
1710 }
1711
1712 /* If BOUNDS is an array-bounds structure type, return the bit position
1713 of the Ith lower bound stored in it, if WHICH is 0, and the Ith upper
1714 bound, if WHICH is 1. The first bound is I=1. */
1715
1716 static int
1717 desc_bound_bitpos (struct type *type, int i, int which)
1718 {
1719 return TYPE_FIELD_BITPOS (desc_base_type (type), 2 * i + which - 2);
1720 }
1721
1722 /* If BOUNDS is an array-bounds structure type, return the bit field size
1723 of the Ith lower bound stored in it, if WHICH is 0, and the Ith upper
1724 bound, if WHICH is 1. The first bound is I=1. */
1725
1726 static int
1727 desc_bound_bitsize (struct type *type, int i, int which)
1728 {
1729 type = desc_base_type (type);
1730
1731 if (TYPE_FIELD_BITSIZE (type, 2 * i + which - 2) > 0)
1732 return TYPE_FIELD_BITSIZE (type, 2 * i + which - 2);
1733 else
1734 return 8 * TYPE_LENGTH (type->field (2 * i + which - 2).type ());
1735 }
1736
1737 /* If TYPE is the type of an array-bounds structure, the type of its
1738 Ith bound (numbering from 1). Otherwise, NULL. */
1739
1740 static struct type *
1741 desc_index_type (struct type *type, int i)
1742 {
1743 type = desc_base_type (type);
1744
1745 if (type->code () == TYPE_CODE_STRUCT)
1746 {
1747 char bound_name[20];
1748 xsnprintf (bound_name, sizeof (bound_name), "LB%d", i - 1);
1749 return lookup_struct_elt_type (type, bound_name, 1);
1750 }
1751 else
1752 return NULL;
1753 }
1754
1755 /* The number of index positions in the array-bounds type TYPE.
1756 Return 0 if TYPE is NULL. */
1757
1758 static int
1759 desc_arity (struct type *type)
1760 {
1761 type = desc_base_type (type);
1762
1763 if (type != NULL)
1764 return type->num_fields () / 2;
1765 return 0;
1766 }
1767
1768 /* Non-zero iff TYPE is a simple array type (not a pointer to one) or
1769 an array descriptor type (representing an unconstrained array
1770 type). */
1771
1772 static int
1773 ada_is_direct_array_type (struct type *type)
1774 {
1775 if (type == NULL)
1776 return 0;
1777 type = ada_check_typedef (type);
1778 return (type->code () == TYPE_CODE_ARRAY
1779 || ada_is_array_descriptor_type (type));
1780 }
1781
1782 /* Non-zero iff TYPE represents any kind of array in Ada, or a pointer
1783 * to one. */
1784
1785 static int
1786 ada_is_array_type (struct type *type)
1787 {
1788 while (type != NULL
1789 && (type->code () == TYPE_CODE_PTR
1790 || type->code () == TYPE_CODE_REF))
1791 type = TYPE_TARGET_TYPE (type);
1792 return ada_is_direct_array_type (type);
1793 }
1794
1795 /* Non-zero iff TYPE is a simple array type or pointer to one. */
1796
1797 int
1798 ada_is_simple_array_type (struct type *type)
1799 {
1800 if (type == NULL)
1801 return 0;
1802 type = ada_check_typedef (type);
1803 return (type->code () == TYPE_CODE_ARRAY
1804 || (type->code () == TYPE_CODE_PTR
1805 && (ada_check_typedef (TYPE_TARGET_TYPE (type))->code ()
1806 == TYPE_CODE_ARRAY)));
1807 }
1808
1809 /* Non-zero iff TYPE belongs to a GNAT array descriptor. */
1810
1811 int
1812 ada_is_array_descriptor_type (struct type *type)
1813 {
1814 struct type *data_type = desc_data_target_type (type);
1815
1816 if (type == NULL)
1817 return 0;
1818 type = ada_check_typedef (type);
1819 return (data_type != NULL
1820 && data_type->code () == TYPE_CODE_ARRAY
1821 && desc_arity (desc_bounds_type (type)) > 0);
1822 }
1823
1824 /* Non-zero iff type is a partially mal-formed GNAT array
1825 descriptor. FIXME: This is to compensate for some problems with
1826 debugging output from GNAT. Re-examine periodically to see if it
1827 is still needed. */
1828
1829 int
1830 ada_is_bogus_array_descriptor (struct type *type)
1831 {
1832 return
1833 type != NULL
1834 && type->code () == TYPE_CODE_STRUCT
1835 && (lookup_struct_elt_type (type, "P_BOUNDS", 1) != NULL
1836 || lookup_struct_elt_type (type, "P_ARRAY", 1) != NULL)
1837 && !ada_is_array_descriptor_type (type);
1838 }
1839
1840
1841 /* If ARR has a record type in the form of a standard GNAT array descriptor,
1842 (fat pointer) returns the type of the array data described---specifically,
1843 a pointer-to-array type. If BOUNDS is non-zero, the bounds data are filled
1844 in from the descriptor; otherwise, they are left unspecified. If
1845 the ARR denotes a null array descriptor and BOUNDS is non-zero,
1846 returns NULL. The result is simply the type of ARR if ARR is not
1847 a descriptor. */
1848
1849 static struct type *
1850 ada_type_of_array (struct value *arr, int bounds)
1851 {
1852 if (ada_is_constrained_packed_array_type (value_type (arr)))
1853 return decode_constrained_packed_array_type (value_type (arr));
1854
1855 if (!ada_is_array_descriptor_type (value_type (arr)))
1856 return value_type (arr);
1857
1858 if (!bounds)
1859 {
1860 struct type *array_type =
1861 ada_check_typedef (desc_data_target_type (value_type (arr)));
1862
1863 if (ada_is_unconstrained_packed_array_type (value_type (arr)))
1864 TYPE_FIELD_BITSIZE (array_type, 0) =
1865 decode_packed_array_bitsize (value_type (arr));
1866
1867 return array_type;
1868 }
1869 else
1870 {
1871 struct type *elt_type;
1872 int arity;
1873 struct value *descriptor;
1874
1875 elt_type = ada_array_element_type (value_type (arr), -1);
1876 arity = ada_array_arity (value_type (arr));
1877
1878 if (elt_type == NULL || arity == 0)
1879 return ada_check_typedef (value_type (arr));
1880
1881 descriptor = desc_bounds (arr);
1882 if (value_as_long (descriptor) == 0)
1883 return NULL;
1884 while (arity > 0)
1885 {
1886 struct type *range_type = alloc_type_copy (value_type (arr));
1887 struct type *array_type = alloc_type_copy (value_type (arr));
1888 struct value *low = desc_one_bound (descriptor, arity, 0);
1889 struct value *high = desc_one_bound (descriptor, arity, 1);
1890
1891 arity -= 1;
1892 create_static_range_type (range_type, value_type (low),
1893 longest_to_int (value_as_long (low)),
1894 longest_to_int (value_as_long (high)));
1895 elt_type = create_array_type (array_type, elt_type, range_type);
1896
1897 if (ada_is_unconstrained_packed_array_type (value_type (arr)))
1898 {
1899 /* We need to store the element packed bitsize, as well as
1900 recompute the array size, because it was previously
1901 computed based on the unpacked element size. */
1902 LONGEST lo = value_as_long (low);
1903 LONGEST hi = value_as_long (high);
1904
1905 TYPE_FIELD_BITSIZE (elt_type, 0) =
1906 decode_packed_array_bitsize (value_type (arr));
1907 /* If the array has no element, then the size is already
1908 zero, and does not need to be recomputed. */
1909 if (lo < hi)
1910 {
1911 int array_bitsize =
1912 (hi - lo + 1) * TYPE_FIELD_BITSIZE (elt_type, 0);
1913
1914 TYPE_LENGTH (array_type) = (array_bitsize + 7) / 8;
1915 }
1916 }
1917 }
1918
1919 return lookup_pointer_type (elt_type);
1920 }
1921 }
1922
1923 /* If ARR does not represent an array, returns ARR unchanged.
1924 Otherwise, returns either a standard GDB array with bounds set
1925 appropriately or, if ARR is a non-null fat pointer, a pointer to a standard
1926 GDB array. Returns NULL if ARR is a null fat pointer. */
1927
1928 struct value *
1929 ada_coerce_to_simple_array_ptr (struct value *arr)
1930 {
1931 if (ada_is_array_descriptor_type (value_type (arr)))
1932 {
1933 struct type *arrType = ada_type_of_array (arr, 1);
1934
1935 if (arrType == NULL)
1936 return NULL;
1937 return value_cast (arrType, value_copy (desc_data (arr)));
1938 }
1939 else if (ada_is_constrained_packed_array_type (value_type (arr)))
1940 return decode_constrained_packed_array (arr);
1941 else
1942 return arr;
1943 }
1944
1945 /* If ARR does not represent an array, returns ARR unchanged.
1946 Otherwise, returns a standard GDB array describing ARR (which may
1947 be ARR itself if it already is in the proper form). */
1948
1949 struct value *
1950 ada_coerce_to_simple_array (struct value *arr)
1951 {
1952 if (ada_is_array_descriptor_type (value_type (arr)))
1953 {
1954 struct value *arrVal = ada_coerce_to_simple_array_ptr (arr);
1955
1956 if (arrVal == NULL)
1957 error (_("Bounds unavailable for null array pointer."));
1958 ada_ensure_varsize_limit (TYPE_TARGET_TYPE (value_type (arrVal)));
1959 return value_ind (arrVal);
1960 }
1961 else if (ada_is_constrained_packed_array_type (value_type (arr)))
1962 return decode_constrained_packed_array (arr);
1963 else
1964 return arr;
1965 }
1966
1967 /* If TYPE represents a GNAT array type, return it translated to an
1968 ordinary GDB array type (possibly with BITSIZE fields indicating
1969 packing). For other types, is the identity. */
1970
1971 struct type *
1972 ada_coerce_to_simple_array_type (struct type *type)
1973 {
1974 if (ada_is_constrained_packed_array_type (type))
1975 return decode_constrained_packed_array_type (type);
1976
1977 if (ada_is_array_descriptor_type (type))
1978 return ada_check_typedef (desc_data_target_type (type));
1979
1980 return type;
1981 }
1982
1983 /* Non-zero iff TYPE represents a standard GNAT packed-array type. */
1984
1985 static int
1986 ada_is_packed_array_type (struct type *type)
1987 {
1988 if (type == NULL)
1989 return 0;
1990 type = desc_base_type (type);
1991 type = ada_check_typedef (type);
1992 return
1993 ada_type_name (type) != NULL
1994 && strstr (ada_type_name (type), "___XP") != NULL;
1995 }
1996
1997 /* Non-zero iff TYPE represents a standard GNAT constrained
1998 packed-array type. */
1999
2000 int
2001 ada_is_constrained_packed_array_type (struct type *type)
2002 {
2003 return ada_is_packed_array_type (type)
2004 && !ada_is_array_descriptor_type (type);
2005 }
2006
2007 /* Non-zero iff TYPE represents an array descriptor for a
2008 unconstrained packed-array type. */
2009
2010 static int
2011 ada_is_unconstrained_packed_array_type (struct type *type)
2012 {
2013 return ada_is_packed_array_type (type)
2014 && ada_is_array_descriptor_type (type);
2015 }
2016
2017 /* Given that TYPE encodes a packed array type (constrained or unconstrained),
2018 return the size of its elements in bits. */
2019
2020 static long
2021 decode_packed_array_bitsize (struct type *type)
2022 {
2023 const char *raw_name;
2024 const char *tail;
2025 long bits;
2026
2027 /* Access to arrays implemented as fat pointers are encoded as a typedef
2028 of the fat pointer type. We need the name of the fat pointer type
2029 to do the decoding, so strip the typedef layer. */
2030 if (type->code () == TYPE_CODE_TYPEDEF)
2031 type = ada_typedef_target_type (type);
2032
2033 raw_name = ada_type_name (ada_check_typedef (type));
2034 if (!raw_name)
2035 raw_name = ada_type_name (desc_base_type (type));
2036
2037 if (!raw_name)
2038 return 0;
2039
2040 tail = strstr (raw_name, "___XP");
2041 gdb_assert (tail != NULL);
2042
2043 if (sscanf (tail + sizeof ("___XP") - 1, "%ld", &bits) != 1)
2044 {
2045 lim_warning
2046 (_("could not understand bit size information on packed array"));
2047 return 0;
2048 }
2049
2050 return bits;
2051 }
2052
2053 /* Given that TYPE is a standard GDB array type with all bounds filled
2054 in, and that the element size of its ultimate scalar constituents
2055 (that is, either its elements, or, if it is an array of arrays, its
2056 elements' elements, etc.) is *ELT_BITS, return an identical type,
2057 but with the bit sizes of its elements (and those of any
2058 constituent arrays) recorded in the BITSIZE components of its
2059 TYPE_FIELD_BITSIZE values, and with *ELT_BITS set to its total size
2060 in bits.
2061
2062 Note that, for arrays whose index type has an XA encoding where
2063 a bound references a record discriminant, getting that discriminant,
2064 and therefore the actual value of that bound, is not possible
2065 because none of the given parameters gives us access to the record.
2066 This function assumes that it is OK in the context where it is being
2067 used to return an array whose bounds are still dynamic and where
2068 the length is arbitrary. */
2069
2070 static struct type *
2071 constrained_packed_array_type (struct type *type, long *elt_bits)
2072 {
2073 struct type *new_elt_type;
2074 struct type *new_type;
2075 struct type *index_type_desc;
2076 struct type *index_type;
2077 LONGEST low_bound, high_bound;
2078
2079 type = ada_check_typedef (type);
2080 if (type->code () != TYPE_CODE_ARRAY)
2081 return type;
2082
2083 index_type_desc = ada_find_parallel_type (type, "___XA");
2084 if (index_type_desc)
2085 index_type = to_fixed_range_type (index_type_desc->field (0).type (),
2086 NULL);
2087 else
2088 index_type = type->index_type ();
2089
2090 new_type = alloc_type_copy (type);
2091 new_elt_type =
2092 constrained_packed_array_type (ada_check_typedef (TYPE_TARGET_TYPE (type)),
2093 elt_bits);
2094 create_array_type (new_type, new_elt_type, index_type);
2095 TYPE_FIELD_BITSIZE (new_type, 0) = *elt_bits;
2096 new_type->set_name (ada_type_name (type));
2097
2098 if ((check_typedef (index_type)->code () == TYPE_CODE_RANGE
2099 && is_dynamic_type (check_typedef (index_type)))
2100 || get_discrete_bounds (index_type, &low_bound, &high_bound) < 0)
2101 low_bound = high_bound = 0;
2102 if (high_bound < low_bound)
2103 *elt_bits = TYPE_LENGTH (new_type) = 0;
2104 else
2105 {
2106 *elt_bits *= (high_bound - low_bound + 1);
2107 TYPE_LENGTH (new_type) =
2108 (*elt_bits + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT;
2109 }
2110
2111 new_type->set_is_fixed_instance (true);
2112 return new_type;
2113 }
2114
2115 /* The array type encoded by TYPE, where
2116 ada_is_constrained_packed_array_type (TYPE). */
2117
2118 static struct type *
2119 decode_constrained_packed_array_type (struct type *type)
2120 {
2121 const char *raw_name = ada_type_name (ada_check_typedef (type));
2122 char *name;
2123 const char *tail;
2124 struct type *shadow_type;
2125 long bits;
2126
2127 if (!raw_name)
2128 raw_name = ada_type_name (desc_base_type (type));
2129
2130 if (!raw_name)
2131 return NULL;
2132
2133 name = (char *) alloca (strlen (raw_name) + 1);
2134 tail = strstr (raw_name, "___XP");
2135 type = desc_base_type (type);
2136
2137 memcpy (name, raw_name, tail - raw_name);
2138 name[tail - raw_name] = '\000';
2139
2140 shadow_type = ada_find_parallel_type_with_name (type, name);
2141
2142 if (shadow_type == NULL)
2143 {
2144 lim_warning (_("could not find bounds information on packed array"));
2145 return NULL;
2146 }
2147 shadow_type = check_typedef (shadow_type);
2148
2149 if (shadow_type->code () != TYPE_CODE_ARRAY)
2150 {
2151 lim_warning (_("could not understand bounds "
2152 "information on packed array"));
2153 return NULL;
2154 }
2155
2156 bits = decode_packed_array_bitsize (type);
2157 return constrained_packed_array_type (shadow_type, &bits);
2158 }
2159
2160 /* Given that ARR is a struct value *indicating a GNAT constrained packed
2161 array, returns a simple array that denotes that array. Its type is a
2162 standard GDB array type except that the BITSIZEs of the array
2163 target types are set to the number of bits in each element, and the
2164 type length is set appropriately. */
2165
2166 static struct value *
2167 decode_constrained_packed_array (struct value *arr)
2168 {
2169 struct type *type;
2170
2171 /* If our value is a pointer, then dereference it. Likewise if
2172 the value is a reference. Make sure that this operation does not
2173 cause the target type to be fixed, as this would indirectly cause
2174 this array to be decoded. The rest of the routine assumes that
2175 the array hasn't been decoded yet, so we use the basic "coerce_ref"
2176 and "value_ind" routines to perform the dereferencing, as opposed
2177 to using "ada_coerce_ref" or "ada_value_ind". */
2178 arr = coerce_ref (arr);
2179 if (ada_check_typedef (value_type (arr))->code () == TYPE_CODE_PTR)
2180 arr = value_ind (arr);
2181
2182 type = decode_constrained_packed_array_type (value_type (arr));
2183 if (type == NULL)
2184 {
2185 error (_("can't unpack array"));
2186 return NULL;
2187 }
2188
2189 if (type_byte_order (value_type (arr)) == BFD_ENDIAN_BIG
2190 && ada_is_modular_type (value_type (arr)))
2191 {
2192 /* This is a (right-justified) modular type representing a packed
2193 array with no wrapper. In order to interpret the value through
2194 the (left-justified) packed array type we just built, we must
2195 first left-justify it. */
2196 int bit_size, bit_pos;
2197 ULONGEST mod;
2198
2199 mod = ada_modulus (value_type (arr)) - 1;
2200 bit_size = 0;
2201 while (mod > 0)
2202 {
2203 bit_size += 1;
2204 mod >>= 1;
2205 }
2206 bit_pos = HOST_CHAR_BIT * TYPE_LENGTH (value_type (arr)) - bit_size;
2207 arr = ada_value_primitive_packed_val (arr, NULL,
2208 bit_pos / HOST_CHAR_BIT,
2209 bit_pos % HOST_CHAR_BIT,
2210 bit_size,
2211 type);
2212 }
2213
2214 return coerce_unspec_val_to_type (arr, type);
2215 }
2216
2217
2218 /* The value of the element of packed array ARR at the ARITY indices
2219 given in IND. ARR must be a simple array. */
2220
2221 static struct value *
2222 value_subscript_packed (struct value *arr, int arity, struct value **ind)
2223 {
2224 int i;
2225 int bits, elt_off, bit_off;
2226 long elt_total_bit_offset;
2227 struct type *elt_type;
2228 struct value *v;
2229
2230 bits = 0;
2231 elt_total_bit_offset = 0;
2232 elt_type = ada_check_typedef (value_type (arr));
2233 for (i = 0; i < arity; i += 1)
2234 {
2235 if (elt_type->code () != TYPE_CODE_ARRAY
2236 || TYPE_FIELD_BITSIZE (elt_type, 0) == 0)
2237 error
2238 (_("attempt to do packed indexing of "
2239 "something other than a packed array"));
2240 else
2241 {
2242 struct type *range_type = elt_type->index_type ();
2243 LONGEST lowerbound, upperbound;
2244 LONGEST idx;
2245
2246 if (get_discrete_bounds (range_type, &lowerbound, &upperbound) < 0)
2247 {
2248 lim_warning (_("don't know bounds of array"));
2249 lowerbound = upperbound = 0;
2250 }
2251
2252 idx = pos_atr (ind[i]);
2253 if (idx < lowerbound || idx > upperbound)
2254 lim_warning (_("packed array index %ld out of bounds"),
2255 (long) idx);
2256 bits = TYPE_FIELD_BITSIZE (elt_type, 0);
2257 elt_total_bit_offset += (idx - lowerbound) * bits;
2258 elt_type = ada_check_typedef (TYPE_TARGET_TYPE (elt_type));
2259 }
2260 }
2261 elt_off = elt_total_bit_offset / HOST_CHAR_BIT;
2262 bit_off = elt_total_bit_offset % HOST_CHAR_BIT;
2263
2264 v = ada_value_primitive_packed_val (arr, NULL, elt_off, bit_off,
2265 bits, elt_type);
2266 return v;
2267 }
2268
2269 /* Non-zero iff TYPE includes negative integer values. */
2270
2271 static int
2272 has_negatives (struct type *type)
2273 {
2274 switch (type->code ())
2275 {
2276 default:
2277 return 0;
2278 case TYPE_CODE_INT:
2279 return !type->is_unsigned ();
2280 case TYPE_CODE_RANGE:
2281 return type->bounds ()->low.const_val () - type->bounds ()->bias < 0;
2282 }
2283 }
2284
2285 /* With SRC being a buffer containing BIT_SIZE bits of data at BIT_OFFSET,
2286 unpack that data into UNPACKED. UNPACKED_LEN is the size in bytes of
2287 the unpacked buffer.
2288
2289 The size of the unpacked buffer (UNPACKED_LEN) is expected to be large
2290 enough to contain at least BIT_OFFSET bits. If not, an error is raised.
2291
2292 IS_BIG_ENDIAN is nonzero if the data is stored in big endian mode,
2293 zero otherwise.
2294
2295 IS_SIGNED_TYPE is nonzero if the data corresponds to a signed type.
2296
2297 IS_SCALAR is nonzero if the data corresponds to a signed type. */
2298
2299 static void
2300 ada_unpack_from_contents (const gdb_byte *src, int bit_offset, int bit_size,
2301 gdb_byte *unpacked, int unpacked_len,
2302 int is_big_endian, int is_signed_type,
2303 int is_scalar)
2304 {
2305 int src_len = (bit_size + bit_offset + HOST_CHAR_BIT - 1) / 8;
2306 int src_idx; /* Index into the source area */
2307 int src_bytes_left; /* Number of source bytes left to process. */
2308 int srcBitsLeft; /* Number of source bits left to move */
2309 int unusedLS; /* Number of bits in next significant
2310 byte of source that are unused */
2311
2312 int unpacked_idx; /* Index into the unpacked buffer */
2313 int unpacked_bytes_left; /* Number of bytes left to set in unpacked. */
2314
2315 unsigned long accum; /* Staging area for bits being transferred */
2316 int accumSize; /* Number of meaningful bits in accum */
2317 unsigned char sign;
2318
2319 /* Transmit bytes from least to most significant; delta is the direction
2320 the indices move. */
2321 int delta = is_big_endian ? -1 : 1;
2322
2323 /* Make sure that unpacked is large enough to receive the BIT_SIZE
2324 bits from SRC. .*/
2325 if ((bit_size + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT > unpacked_len)
2326 error (_("Cannot unpack %d bits into buffer of %d bytes"),
2327 bit_size, unpacked_len);
2328
2329 srcBitsLeft = bit_size;
2330 src_bytes_left = src_len;
2331 unpacked_bytes_left = unpacked_len;
2332 sign = 0;
2333
2334 if (is_big_endian)
2335 {
2336 src_idx = src_len - 1;
2337 if (is_signed_type
2338 && ((src[0] << bit_offset) & (1 << (HOST_CHAR_BIT - 1))))
2339 sign = ~0;
2340
2341 unusedLS =
2342 (HOST_CHAR_BIT - (bit_size + bit_offset) % HOST_CHAR_BIT)
2343 % HOST_CHAR_BIT;
2344
2345 if (is_scalar)
2346 {
2347 accumSize = 0;
2348 unpacked_idx = unpacked_len - 1;
2349 }
2350 else
2351 {
2352 /* Non-scalar values must be aligned at a byte boundary... */
2353 accumSize =
2354 (HOST_CHAR_BIT - bit_size % HOST_CHAR_BIT) % HOST_CHAR_BIT;
2355 /* ... And are placed at the beginning (most-significant) bytes
2356 of the target. */
2357 unpacked_idx = (bit_size + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT - 1;
2358 unpacked_bytes_left = unpacked_idx + 1;
2359 }
2360 }
2361 else
2362 {
2363 int sign_bit_offset = (bit_size + bit_offset - 1) % 8;
2364
2365 src_idx = unpacked_idx = 0;
2366 unusedLS = bit_offset;
2367 accumSize = 0;
2368
2369 if (is_signed_type && (src[src_len - 1] & (1 << sign_bit_offset)))
2370 sign = ~0;
2371 }
2372
2373 accum = 0;
2374 while (src_bytes_left > 0)
2375 {
2376 /* Mask for removing bits of the next source byte that are not
2377 part of the value. */
2378 unsigned int unusedMSMask =
2379 (1 << (srcBitsLeft >= HOST_CHAR_BIT ? HOST_CHAR_BIT : srcBitsLeft)) -
2380 1;
2381 /* Sign-extend bits for this byte. */
2382 unsigned int signMask = sign & ~unusedMSMask;
2383
2384 accum |=
2385 (((src[src_idx] >> unusedLS) & unusedMSMask) | signMask) << accumSize;
2386 accumSize += HOST_CHAR_BIT - unusedLS;
2387 if (accumSize >= HOST_CHAR_BIT)
2388 {
2389 unpacked[unpacked_idx] = accum & ~(~0UL << HOST_CHAR_BIT);
2390 accumSize -= HOST_CHAR_BIT;
2391 accum >>= HOST_CHAR_BIT;
2392 unpacked_bytes_left -= 1;
2393 unpacked_idx += delta;
2394 }
2395 srcBitsLeft -= HOST_CHAR_BIT - unusedLS;
2396 unusedLS = 0;
2397 src_bytes_left -= 1;
2398 src_idx += delta;
2399 }
2400 while (unpacked_bytes_left > 0)
2401 {
2402 accum |= sign << accumSize;
2403 unpacked[unpacked_idx] = accum & ~(~0UL << HOST_CHAR_BIT);
2404 accumSize -= HOST_CHAR_BIT;
2405 if (accumSize < 0)
2406 accumSize = 0;
2407 accum >>= HOST_CHAR_BIT;
2408 unpacked_bytes_left -= 1;
2409 unpacked_idx += delta;
2410 }
2411 }
2412
2413 /* Create a new value of type TYPE from the contents of OBJ starting
2414 at byte OFFSET, and bit offset BIT_OFFSET within that byte,
2415 proceeding for BIT_SIZE bits. If OBJ is an lval in memory, then
2416 assigning through the result will set the field fetched from.
2417 VALADDR is ignored unless OBJ is NULL, in which case,
2418 VALADDR+OFFSET must address the start of storage containing the
2419 packed value. The value returned in this case is never an lval.
2420 Assumes 0 <= BIT_OFFSET < HOST_CHAR_BIT. */
2421
2422 struct value *
2423 ada_value_primitive_packed_val (struct value *obj, const gdb_byte *valaddr,
2424 long offset, int bit_offset, int bit_size,
2425 struct type *type)
2426 {
2427 struct value *v;
2428 const gdb_byte *src; /* First byte containing data to unpack */
2429 gdb_byte *unpacked;
2430 const int is_scalar = is_scalar_type (type);
2431 const int is_big_endian = type_byte_order (type) == BFD_ENDIAN_BIG;
2432 gdb::byte_vector staging;
2433
2434 type = ada_check_typedef (type);
2435
2436 if (obj == NULL)
2437 src = valaddr + offset;
2438 else
2439 src = value_contents (obj) + offset;
2440
2441 if (is_dynamic_type (type))
2442 {
2443 /* The length of TYPE might by dynamic, so we need to resolve
2444 TYPE in order to know its actual size, which we then use
2445 to create the contents buffer of the value we return.
2446 The difficulty is that the data containing our object is
2447 packed, and therefore maybe not at a byte boundary. So, what
2448 we do, is unpack the data into a byte-aligned buffer, and then
2449 use that buffer as our object's value for resolving the type. */
2450 int staging_len = (bit_size + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT;
2451 staging.resize (staging_len);
2452
2453 ada_unpack_from_contents (src, bit_offset, bit_size,
2454 staging.data (), staging.size (),
2455 is_big_endian, has_negatives (type),
2456 is_scalar);
2457 type = resolve_dynamic_type (type, staging, 0);
2458 if (TYPE_LENGTH (type) < (bit_size + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT)
2459 {
2460 /* This happens when the length of the object is dynamic,
2461 and is actually smaller than the space reserved for it.
2462 For instance, in an array of variant records, the bit_size
2463 we're given is the array stride, which is constant and
2464 normally equal to the maximum size of its element.
2465 But, in reality, each element only actually spans a portion
2466 of that stride. */
2467 bit_size = TYPE_LENGTH (type) * HOST_CHAR_BIT;
2468 }
2469 }
2470
2471 if (obj == NULL)
2472 {
2473 v = allocate_value (type);
2474 src = valaddr + offset;
2475 }
2476 else if (VALUE_LVAL (obj) == lval_memory && value_lazy (obj))
2477 {
2478 int src_len = (bit_size + bit_offset + HOST_CHAR_BIT - 1) / 8;
2479 gdb_byte *buf;
2480
2481 v = value_at (type, value_address (obj) + offset);
2482 buf = (gdb_byte *) alloca (src_len);
2483 read_memory (value_address (v), buf, src_len);
2484 src = buf;
2485 }
2486 else
2487 {
2488 v = allocate_value (type);
2489 src = value_contents (obj) + offset;
2490 }
2491
2492 if (obj != NULL)
2493 {
2494 long new_offset = offset;
2495
2496 set_value_component_location (v, obj);
2497 set_value_bitpos (v, bit_offset + value_bitpos (obj));
2498 set_value_bitsize (v, bit_size);
2499 if (value_bitpos (v) >= HOST_CHAR_BIT)
2500 {
2501 ++new_offset;
2502 set_value_bitpos (v, value_bitpos (v) - HOST_CHAR_BIT);
2503 }
2504 set_value_offset (v, new_offset);
2505
2506 /* Also set the parent value. This is needed when trying to
2507 assign a new value (in inferior memory). */
2508 set_value_parent (v, obj);
2509 }
2510 else
2511 set_value_bitsize (v, bit_size);
2512 unpacked = value_contents_writeable (v);
2513
2514 if (bit_size == 0)
2515 {
2516 memset (unpacked, 0, TYPE_LENGTH (type));
2517 return v;
2518 }
2519
2520 if (staging.size () == TYPE_LENGTH (type))
2521 {
2522 /* Small short-cut: If we've unpacked the data into a buffer
2523 of the same size as TYPE's length, then we can reuse that,
2524 instead of doing the unpacking again. */
2525 memcpy (unpacked, staging.data (), staging.size ());
2526 }
2527 else
2528 ada_unpack_from_contents (src, bit_offset, bit_size,
2529 unpacked, TYPE_LENGTH (type),
2530 is_big_endian, has_negatives (type), is_scalar);
2531
2532 return v;
2533 }
2534
2535 /* Store the contents of FROMVAL into the location of TOVAL.
2536 Return a new value with the location of TOVAL and contents of
2537 FROMVAL. Handles assignment into packed fields that have
2538 floating-point or non-scalar types. */
2539
2540 static struct value *
2541 ada_value_assign (struct value *toval, struct value *fromval)
2542 {
2543 struct type *type = value_type (toval);
2544 int bits = value_bitsize (toval);
2545
2546 toval = ada_coerce_ref (toval);
2547 fromval = ada_coerce_ref (fromval);
2548
2549 if (ada_is_direct_array_type (value_type (toval)))
2550 toval = ada_coerce_to_simple_array (toval);
2551 if (ada_is_direct_array_type (value_type (fromval)))
2552 fromval = ada_coerce_to_simple_array (fromval);
2553
2554 if (!deprecated_value_modifiable (toval))
2555 error (_("Left operand of assignment is not a modifiable lvalue."));
2556
2557 if (VALUE_LVAL (toval) == lval_memory
2558 && bits > 0
2559 && (type->code () == TYPE_CODE_FLT
2560 || type->code () == TYPE_CODE_STRUCT))
2561 {
2562 int len = (value_bitpos (toval)
2563 + bits + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT;
2564 int from_size;
2565 gdb_byte *buffer = (gdb_byte *) alloca (len);
2566 struct value *val;
2567 CORE_ADDR to_addr = value_address (toval);
2568
2569 if (type->code () == TYPE_CODE_FLT)
2570 fromval = value_cast (type, fromval);
2571
2572 read_memory (to_addr, buffer, len);
2573 from_size = value_bitsize (fromval);
2574 if (from_size == 0)
2575 from_size = TYPE_LENGTH (value_type (fromval)) * TARGET_CHAR_BIT;
2576
2577 const int is_big_endian = type_byte_order (type) == BFD_ENDIAN_BIG;
2578 ULONGEST from_offset = 0;
2579 if (is_big_endian && is_scalar_type (value_type (fromval)))
2580 from_offset = from_size - bits;
2581 copy_bitwise (buffer, value_bitpos (toval),
2582 value_contents (fromval), from_offset,
2583 bits, is_big_endian);
2584 write_memory_with_notification (to_addr, buffer, len);
2585
2586 val = value_copy (toval);
2587 memcpy (value_contents_raw (val), value_contents (fromval),
2588 TYPE_LENGTH (type));
2589 deprecated_set_value_type (val, type);
2590
2591 return val;
2592 }
2593
2594 return value_assign (toval, fromval);
2595 }
2596
2597
2598 /* Given that COMPONENT is a memory lvalue that is part of the lvalue
2599 CONTAINER, assign the contents of VAL to COMPONENTS's place in
2600 CONTAINER. Modifies the VALUE_CONTENTS of CONTAINER only, not
2601 COMPONENT, and not the inferior's memory. The current contents
2602 of COMPONENT are ignored.
2603
2604 Although not part of the initial design, this function also works
2605 when CONTAINER and COMPONENT are not_lval's: it works as if CONTAINER
2606 had a null address, and COMPONENT had an address which is equal to
2607 its offset inside CONTAINER. */
2608
2609 static void
2610 value_assign_to_component (struct value *container, struct value *component,
2611 struct value *val)
2612 {
2613 LONGEST offset_in_container =
2614 (LONGEST) (value_address (component) - value_address (container));
2615 int bit_offset_in_container =
2616 value_bitpos (component) - value_bitpos (container);
2617 int bits;
2618
2619 val = value_cast (value_type (component), val);
2620
2621 if (value_bitsize (component) == 0)
2622 bits = TARGET_CHAR_BIT * TYPE_LENGTH (value_type (component));
2623 else
2624 bits = value_bitsize (component);
2625
2626 if (type_byte_order (value_type (container)) == BFD_ENDIAN_BIG)
2627 {
2628 int src_offset;
2629
2630 if (is_scalar_type (check_typedef (value_type (component))))
2631 src_offset
2632 = TYPE_LENGTH (value_type (component)) * TARGET_CHAR_BIT - bits;
2633 else
2634 src_offset = 0;
2635 copy_bitwise (value_contents_writeable (container) + offset_in_container,
2636 value_bitpos (container) + bit_offset_in_container,
2637 value_contents (val), src_offset, bits, 1);
2638 }
2639 else
2640 copy_bitwise (value_contents_writeable (container) + offset_in_container,
2641 value_bitpos (container) + bit_offset_in_container,
2642 value_contents (val), 0, bits, 0);
2643 }
2644
2645 /* Determine if TYPE is an access to an unconstrained array. */
2646
2647 bool
2648 ada_is_access_to_unconstrained_array (struct type *type)
2649 {
2650 return (type->code () == TYPE_CODE_TYPEDEF
2651 && is_thick_pntr (ada_typedef_target_type (type)));
2652 }
2653
2654 /* The value of the element of array ARR at the ARITY indices given in IND.
2655 ARR may be either a simple array, GNAT array descriptor, or pointer
2656 thereto. */
2657
2658 struct value *
2659 ada_value_subscript (struct value *arr, int arity, struct value **ind)
2660 {
2661 int k;
2662 struct value *elt;
2663 struct type *elt_type;
2664
2665 elt = ada_coerce_to_simple_array (arr);
2666
2667 elt_type = ada_check_typedef (value_type (elt));
2668 if (elt_type->code () == TYPE_CODE_ARRAY
2669 && TYPE_FIELD_BITSIZE (elt_type, 0) > 0)
2670 return value_subscript_packed (elt, arity, ind);
2671
2672 for (k = 0; k < arity; k += 1)
2673 {
2674 struct type *saved_elt_type = TYPE_TARGET_TYPE (elt_type);
2675
2676 if (elt_type->code () != TYPE_CODE_ARRAY)
2677 error (_("too many subscripts (%d expected)"), k);
2678
2679 elt = value_subscript (elt, pos_atr (ind[k]));
2680
2681 if (ada_is_access_to_unconstrained_array (saved_elt_type)
2682 && value_type (elt)->code () != TYPE_CODE_TYPEDEF)
2683 {
2684 /* The element is a typedef to an unconstrained array,
2685 except that the value_subscript call stripped the
2686 typedef layer. The typedef layer is GNAT's way to
2687 specify that the element is, at the source level, an
2688 access to the unconstrained array, rather than the
2689 unconstrained array. So, we need to restore that
2690 typedef layer, which we can do by forcing the element's
2691 type back to its original type. Otherwise, the returned
2692 value is going to be printed as the array, rather
2693 than as an access. Another symptom of the same issue
2694 would be that an expression trying to dereference the
2695 element would also be improperly rejected. */
2696 deprecated_set_value_type (elt, saved_elt_type);
2697 }
2698
2699 elt_type = ada_check_typedef (value_type (elt));
2700 }
2701
2702 return elt;
2703 }
2704
2705 /* Assuming ARR is a pointer to a GDB array, the value of the element
2706 of *ARR at the ARITY indices given in IND.
2707 Does not read the entire array into memory.
2708
2709 Note: Unlike what one would expect, this function is used instead of
2710 ada_value_subscript for basically all non-packed array types. The reason
2711 for this is that a side effect of doing our own pointer arithmetics instead
2712 of relying on value_subscript is that there is no implicit typedef peeling.
2713 This is important for arrays of array accesses, where it allows us to
2714 preserve the fact that the array's element is an array access, where the
2715 access part os encoded in a typedef layer. */
2716
2717 static struct value *
2718 ada_value_ptr_subscript (struct value *arr, int arity, struct value **ind)
2719 {
2720 int k;
2721 struct value *array_ind = ada_value_ind (arr);
2722 struct type *type
2723 = check_typedef (value_enclosing_type (array_ind));
2724
2725 if (type->code () == TYPE_CODE_ARRAY
2726 && TYPE_FIELD_BITSIZE (type, 0) > 0)
2727 return value_subscript_packed (array_ind, arity, ind);
2728
2729 for (k = 0; k < arity; k += 1)
2730 {
2731 LONGEST lwb, upb;
2732
2733 if (type->code () != TYPE_CODE_ARRAY)
2734 error (_("too many subscripts (%d expected)"), k);
2735 arr = value_cast (lookup_pointer_type (TYPE_TARGET_TYPE (type)),
2736 value_copy (arr));
2737 get_discrete_bounds (type->index_type (), &lwb, &upb);
2738 arr = value_ptradd (arr, pos_atr (ind[k]) - lwb);
2739 type = TYPE_TARGET_TYPE (type);
2740 }
2741
2742 return value_ind (arr);
2743 }
2744
2745 /* Given that ARRAY_PTR is a pointer or reference to an array of type TYPE (the
2746 actual type of ARRAY_PTR is ignored), returns the Ada slice of
2747 HIGH'Pos-LOW'Pos+1 elements starting at index LOW. The lower bound of
2748 this array is LOW, as per Ada rules. */
2749 static struct value *
2750 ada_value_slice_from_ptr (struct value *array_ptr, struct type *type,
2751 int low, int high)
2752 {
2753 struct type *type0 = ada_check_typedef (type);
2754 struct type *base_index_type = TYPE_TARGET_TYPE (type0->index_type ());
2755 struct type *index_type
2756 = create_static_range_type (NULL, base_index_type, low, high);
2757 struct type *slice_type = create_array_type_with_stride
2758 (NULL, TYPE_TARGET_TYPE (type0), index_type,
2759 type0->dyn_prop (DYN_PROP_BYTE_STRIDE),
2760 TYPE_FIELD_BITSIZE (type0, 0));
2761 int base_low = ada_discrete_type_low_bound (type0->index_type ());
2762 LONGEST base_low_pos, low_pos;
2763 CORE_ADDR base;
2764
2765 if (!discrete_position (base_index_type, low, &low_pos)
2766 || !discrete_position (base_index_type, base_low, &base_low_pos))
2767 {
2768 warning (_("unable to get positions in slice, use bounds instead"));
2769 low_pos = low;
2770 base_low_pos = base_low;
2771 }
2772
2773 base = value_as_address (array_ptr)
2774 + ((low_pos - base_low_pos)
2775 * TYPE_LENGTH (TYPE_TARGET_TYPE (type0)));
2776 return value_at_lazy (slice_type, base);
2777 }
2778
2779
2780 static struct value *
2781 ada_value_slice (struct value *array, int low, int high)
2782 {
2783 struct type *type = ada_check_typedef (value_type (array));
2784 struct type *base_index_type = TYPE_TARGET_TYPE (type->index_type ());
2785 struct type *index_type
2786 = create_static_range_type (NULL, type->index_type (), low, high);
2787 struct type *slice_type = create_array_type_with_stride
2788 (NULL, TYPE_TARGET_TYPE (type), index_type,
2789 type->dyn_prop (DYN_PROP_BYTE_STRIDE),
2790 TYPE_FIELD_BITSIZE (type, 0));
2791 LONGEST low_pos, high_pos;
2792
2793 if (!discrete_position (base_index_type, low, &low_pos)
2794 || !discrete_position (base_index_type, high, &high_pos))
2795 {
2796 warning (_("unable to get positions in slice, use bounds instead"));
2797 low_pos = low;
2798 high_pos = high;
2799 }
2800
2801 return value_cast (slice_type,
2802 value_slice (array, low, high_pos - low_pos + 1));
2803 }
2804
2805 /* If type is a record type in the form of a standard GNAT array
2806 descriptor, returns the number of dimensions for type. If arr is a
2807 simple array, returns the number of "array of"s that prefix its
2808 type designation. Otherwise, returns 0. */
2809
2810 int
2811 ada_array_arity (struct type *type)
2812 {
2813 int arity;
2814
2815 if (type == NULL)
2816 return 0;
2817
2818 type = desc_base_type (type);
2819
2820 arity = 0;
2821 if (type->code () == TYPE_CODE_STRUCT)
2822 return desc_arity (desc_bounds_type (type));
2823 else
2824 while (type->code () == TYPE_CODE_ARRAY)
2825 {
2826 arity += 1;
2827 type = ada_check_typedef (TYPE_TARGET_TYPE (type));
2828 }
2829
2830 return arity;
2831 }
2832
2833 /* If TYPE is a record type in the form of a standard GNAT array
2834 descriptor or a simple array type, returns the element type for
2835 TYPE after indexing by NINDICES indices, or by all indices if
2836 NINDICES is -1. Otherwise, returns NULL. */
2837
2838 struct type *
2839 ada_array_element_type (struct type *type, int nindices)
2840 {
2841 type = desc_base_type (type);
2842
2843 if (type->code () == TYPE_CODE_STRUCT)
2844 {
2845 int k;
2846 struct type *p_array_type;
2847
2848 p_array_type = desc_data_target_type (type);
2849
2850 k = ada_array_arity (type);
2851 if (k == 0)
2852 return NULL;
2853
2854 /* Initially p_array_type = elt_type(*)[]...(k times)...[]. */
2855 if (nindices >= 0 && k > nindices)
2856 k = nindices;
2857 while (k > 0 && p_array_type != NULL)
2858 {
2859 p_array_type = ada_check_typedef (TYPE_TARGET_TYPE (p_array_type));
2860 k -= 1;
2861 }
2862 return p_array_type;
2863 }
2864 else if (type->code () == TYPE_CODE_ARRAY)
2865 {
2866 while (nindices != 0 && type->code () == TYPE_CODE_ARRAY)
2867 {
2868 type = TYPE_TARGET_TYPE (type);
2869 nindices -= 1;
2870 }
2871 return type;
2872 }
2873
2874 return NULL;
2875 }
2876
2877 /* The type of nth index in arrays of given type (n numbering from 1).
2878 Does not examine memory. Throws an error if N is invalid or TYPE
2879 is not an array type. NAME is the name of the Ada attribute being
2880 evaluated ('range, 'first, 'last, or 'length); it is used in building
2881 the error message. */
2882
2883 static struct type *
2884 ada_index_type (struct type *type, int n, const char *name)
2885 {
2886 struct type *result_type;
2887
2888 type = desc_base_type (type);
2889
2890 if (n < 0 || n > ada_array_arity (type))
2891 error (_("invalid dimension number to '%s"), name);
2892
2893 if (ada_is_simple_array_type (type))
2894 {
2895 int i;
2896
2897 for (i = 1; i < n; i += 1)
2898 type = TYPE_TARGET_TYPE (type);
2899 result_type = TYPE_TARGET_TYPE (type->index_type ());
2900 /* FIXME: The stabs type r(0,0);bound;bound in an array type
2901 has a target type of TYPE_CODE_UNDEF. We compensate here, but
2902 perhaps stabsread.c would make more sense. */
2903 if (result_type && result_type->code () == TYPE_CODE_UNDEF)
2904 result_type = NULL;
2905 }
2906 else
2907 {
2908 result_type = desc_index_type (desc_bounds_type (type), n);
2909 if (result_type == NULL)
2910 error (_("attempt to take bound of something that is not an array"));
2911 }
2912
2913 return result_type;
2914 }
2915
2916 /* Given that arr is an array type, returns the lower bound of the
2917 Nth index (numbering from 1) if WHICH is 0, and the upper bound if
2918 WHICH is 1. This returns bounds 0 .. -1 if ARR_TYPE is an
2919 array-descriptor type. It works for other arrays with bounds supplied
2920 by run-time quantities other than discriminants. */
2921
2922 static LONGEST
2923 ada_array_bound_from_type (struct type *arr_type, int n, int which)
2924 {
2925 struct type *type, *index_type_desc, *index_type;
2926 int i;
2927
2928 gdb_assert (which == 0 || which == 1);
2929
2930 if (ada_is_constrained_packed_array_type (arr_type))
2931 arr_type = decode_constrained_packed_array_type (arr_type);
2932
2933 if (arr_type == NULL || !ada_is_simple_array_type (arr_type))
2934 return (LONGEST) - which;
2935
2936 if (arr_type->code () == TYPE_CODE_PTR)
2937 type = TYPE_TARGET_TYPE (arr_type);
2938 else
2939 type = arr_type;
2940
2941 if (type->is_fixed_instance ())
2942 {
2943 /* The array has already been fixed, so we do not need to
2944 check the parallel ___XA type again. That encoding has
2945 already been applied, so ignore it now. */
2946 index_type_desc = NULL;
2947 }
2948 else
2949 {
2950 index_type_desc = ada_find_parallel_type (type, "___XA");
2951 ada_fixup_array_indexes_type (index_type_desc);
2952 }
2953
2954 if (index_type_desc != NULL)
2955 index_type = to_fixed_range_type (index_type_desc->field (n - 1).type (),
2956 NULL);
2957 else
2958 {
2959 struct type *elt_type = check_typedef (type);
2960
2961 for (i = 1; i < n; i++)
2962 elt_type = check_typedef (TYPE_TARGET_TYPE (elt_type));
2963
2964 index_type = elt_type->index_type ();
2965 }
2966
2967 return
2968 (LONGEST) (which == 0
2969 ? ada_discrete_type_low_bound (index_type)
2970 : ada_discrete_type_high_bound (index_type));
2971 }
2972
2973 /* Given that arr is an array value, returns the lower bound of the
2974 nth index (numbering from 1) if WHICH is 0, and the upper bound if
2975 WHICH is 1. This routine will also work for arrays with bounds
2976 supplied by run-time quantities other than discriminants. */
2977
2978 static LONGEST
2979 ada_array_bound (struct value *arr, int n, int which)
2980 {
2981 struct type *arr_type;
2982
2983 if (check_typedef (value_type (arr))->code () == TYPE_CODE_PTR)
2984 arr = value_ind (arr);
2985 arr_type = value_enclosing_type (arr);
2986
2987 if (ada_is_constrained_packed_array_type (arr_type))
2988 return ada_array_bound (decode_constrained_packed_array (arr), n, which);
2989 else if (ada_is_simple_array_type (arr_type))
2990 return ada_array_bound_from_type (arr_type, n, which);
2991 else
2992 return value_as_long (desc_one_bound (desc_bounds (arr), n, which));
2993 }
2994
2995 /* Given that arr is an array value, returns the length of the
2996 nth index. This routine will also work for arrays with bounds
2997 supplied by run-time quantities other than discriminants.
2998 Does not work for arrays indexed by enumeration types with representation
2999 clauses at the moment. */
3000
3001 static LONGEST
3002 ada_array_length (struct value *arr, int n)
3003 {
3004 struct type *arr_type, *index_type;
3005 int low, high;
3006
3007 if (check_typedef (value_type (arr))->code () == TYPE_CODE_PTR)
3008 arr = value_ind (arr);
3009 arr_type = value_enclosing_type (arr);
3010
3011 if (ada_is_constrained_packed_array_type (arr_type))
3012 return ada_array_length (decode_constrained_packed_array (arr), n);
3013
3014 if (ada_is_simple_array_type (arr_type))
3015 {
3016 low = ada_array_bound_from_type (arr_type, n, 0);
3017 high = ada_array_bound_from_type (arr_type, n, 1);
3018 }
3019 else
3020 {
3021 low = value_as_long (desc_one_bound (desc_bounds (arr), n, 0));
3022 high = value_as_long (desc_one_bound (desc_bounds (arr), n, 1));
3023 }
3024
3025 arr_type = check_typedef (arr_type);
3026 index_type = ada_index_type (arr_type, n, "length");
3027 if (index_type != NULL)
3028 {
3029 struct type *base_type;
3030 if (index_type->code () == TYPE_CODE_RANGE)
3031 base_type = TYPE_TARGET_TYPE (index_type);
3032 else
3033 base_type = index_type;
3034
3035 low = pos_atr (value_from_longest (base_type, low));
3036 high = pos_atr (value_from_longest (base_type, high));
3037 }
3038 return high - low + 1;
3039 }
3040
3041 /* An array whose type is that of ARR_TYPE (an array type), with
3042 bounds LOW to HIGH, but whose contents are unimportant. If HIGH is
3043 less than LOW, then LOW-1 is used. */
3044
3045 static struct value *
3046 empty_array (struct type *arr_type, int low, int high)
3047 {
3048 struct type *arr_type0 = ada_check_typedef (arr_type);
3049 struct type *index_type
3050 = create_static_range_type
3051 (NULL, TYPE_TARGET_TYPE (arr_type0->index_type ()), low,
3052 high < low ? low - 1 : high);
3053 struct type *elt_type = ada_array_element_type (arr_type0, 1);
3054
3055 return allocate_value (create_array_type (NULL, elt_type, index_type));
3056 }
3057 \f
3058
3059 /* Name resolution */
3060
3061 /* The "decoded" name for the user-definable Ada operator corresponding
3062 to OP. */
3063
3064 static const char *
3065 ada_decoded_op_name (enum exp_opcode op)
3066 {
3067 int i;
3068
3069 for (i = 0; ada_opname_table[i].encoded != NULL; i += 1)
3070 {
3071 if (ada_opname_table[i].op == op)
3072 return ada_opname_table[i].decoded;
3073 }
3074 error (_("Could not find operator name for opcode"));
3075 }
3076
3077 /* Returns true (non-zero) iff decoded name N0 should appear before N1
3078 in a listing of choices during disambiguation (see sort_choices, below).
3079 The idea is that overloadings of a subprogram name from the
3080 same package should sort in their source order. We settle for ordering
3081 such symbols by their trailing number (__N or $N). */
3082
3083 static int
3084 encoded_ordered_before (const char *N0, const char *N1)
3085 {
3086 if (N1 == NULL)
3087 return 0;
3088 else if (N0 == NULL)
3089 return 1;
3090 else
3091 {
3092 int k0, k1;
3093
3094 for (k0 = strlen (N0) - 1; k0 > 0 && isdigit (N0[k0]); k0 -= 1)
3095 ;
3096 for (k1 = strlen (N1) - 1; k1 > 0 && isdigit (N1[k1]); k1 -= 1)
3097 ;
3098 if ((N0[k0] == '_' || N0[k0] == '$') && N0[k0 + 1] != '\000'
3099 && (N1[k1] == '_' || N1[k1] == '$') && N1[k1 + 1] != '\000')
3100 {
3101 int n0, n1;
3102
3103 n0 = k0;
3104 while (N0[n0] == '_' && n0 > 0 && N0[n0 - 1] == '_')
3105 n0 -= 1;
3106 n1 = k1;
3107 while (N1[n1] == '_' && n1 > 0 && N1[n1 - 1] == '_')
3108 n1 -= 1;
3109 if (n0 == n1 && strncmp (N0, N1, n0) == 0)
3110 return (atoi (N0 + k0 + 1) < atoi (N1 + k1 + 1));
3111 }
3112 return (strcmp (N0, N1) < 0);
3113 }
3114 }
3115
3116 /* Sort SYMS[0..NSYMS-1] to put the choices in a canonical order by the
3117 encoded names. */
3118
3119 static void
3120 sort_choices (struct block_symbol syms[], int nsyms)
3121 {
3122 int i;
3123
3124 for (i = 1; i < nsyms; i += 1)
3125 {
3126 struct block_symbol sym = syms[i];
3127 int j;
3128
3129 for (j = i - 1; j >= 0; j -= 1)
3130 {
3131 if (encoded_ordered_before (syms[j].symbol->linkage_name (),
3132 sym.symbol->linkage_name ()))
3133 break;
3134 syms[j + 1] = syms[j];
3135 }
3136 syms[j + 1] = sym;
3137 }
3138 }
3139
3140 /* Whether GDB should display formals and return types for functions in the
3141 overloads selection menu. */
3142 static bool print_signatures = true;
3143
3144 /* Print the signature for SYM on STREAM according to the FLAGS options. For
3145 all but functions, the signature is just the name of the symbol. For
3146 functions, this is the name of the function, the list of types for formals
3147 and the return type (if any). */
3148
3149 static void
3150 ada_print_symbol_signature (struct ui_file *stream, struct symbol *sym,
3151 const struct type_print_options *flags)
3152 {
3153 struct type *type = SYMBOL_TYPE (sym);
3154
3155 fprintf_filtered (stream, "%s", sym->print_name ());
3156 if (!print_signatures
3157 || type == NULL
3158 || type->code () != TYPE_CODE_FUNC)
3159 return;
3160
3161 if (type->num_fields () > 0)
3162 {
3163 int i;
3164
3165 fprintf_filtered (stream, " (");
3166 for (i = 0; i < type->num_fields (); ++i)
3167 {
3168 if (i > 0)
3169 fprintf_filtered (stream, "; ");
3170 ada_print_type (type->field (i).type (), NULL, stream, -1, 0,
3171 flags);
3172 }
3173 fprintf_filtered (stream, ")");
3174 }
3175 if (TYPE_TARGET_TYPE (type) != NULL
3176 && TYPE_TARGET_TYPE (type)->code () != TYPE_CODE_VOID)
3177 {
3178 fprintf_filtered (stream, " return ");
3179 ada_print_type (TYPE_TARGET_TYPE (type), NULL, stream, -1, 0, flags);
3180 }
3181 }
3182
3183 /* Read and validate a set of numeric choices from the user in the
3184 range 0 .. N_CHOICES-1. Place the results in increasing
3185 order in CHOICES[0 .. N-1], and return N.
3186
3187 The user types choices as a sequence of numbers on one line
3188 separated by blanks, encoding them as follows:
3189
3190 + A choice of 0 means to cancel the selection, throwing an error.
3191 + If IS_ALL_CHOICE, a choice of 1 selects the entire set 0 .. N_CHOICES-1.
3192 + The user chooses k by typing k+IS_ALL_CHOICE+1.
3193
3194 The user is not allowed to choose more than MAX_RESULTS values.
3195
3196 ANNOTATION_SUFFIX, if present, is used to annotate the input
3197 prompts (for use with the -f switch). */
3198
3199 static int
3200 get_selections (int *choices, int n_choices, int max_results,
3201 int is_all_choice, const char *annotation_suffix)
3202 {
3203 const char *args;
3204 const char *prompt;
3205 int n_chosen;
3206 int first_choice = is_all_choice ? 2 : 1;
3207
3208 prompt = getenv ("PS2");
3209 if (prompt == NULL)
3210 prompt = "> ";
3211
3212 args = command_line_input (prompt, annotation_suffix);
3213
3214 if (args == NULL)
3215 error_no_arg (_("one or more choice numbers"));
3216
3217 n_chosen = 0;
3218
3219 /* Set choices[0 .. n_chosen-1] to the users' choices in ascending
3220 order, as given in args. Choices are validated. */
3221 while (1)
3222 {
3223 char *args2;
3224 int choice, j;
3225
3226 args = skip_spaces (args);
3227 if (*args == '\0' && n_chosen == 0)
3228 error_no_arg (_("one or more choice numbers"));
3229 else if (*args == '\0')
3230 break;
3231
3232 choice = strtol (args, &args2, 10);
3233 if (args == args2 || choice < 0
3234 || choice > n_choices + first_choice - 1)
3235 error (_("Argument must be choice number"));
3236 args = args2;
3237
3238 if (choice == 0)
3239 error (_("cancelled"));
3240
3241 if (choice < first_choice)
3242 {
3243 n_chosen = n_choices;
3244 for (j = 0; j < n_choices; j += 1)
3245 choices[j] = j;
3246 break;
3247 }
3248 choice -= first_choice;
3249
3250 for (j = n_chosen - 1; j >= 0 && choice < choices[j]; j -= 1)
3251 {
3252 }
3253
3254 if (j < 0 || choice != choices[j])
3255 {
3256 int k;
3257
3258 for (k = n_chosen - 1; k > j; k -= 1)
3259 choices[k + 1] = choices[k];
3260 choices[j + 1] = choice;
3261 n_chosen += 1;
3262 }
3263 }
3264
3265 if (n_chosen > max_results)
3266 error (_("Select no more than %d of the above"), max_results);
3267
3268 return n_chosen;
3269 }
3270
3271 /* Given a list of NSYMS symbols in SYMS, select up to MAX_RESULTS>0
3272 by asking the user (if necessary), returning the number selected,
3273 and setting the first elements of SYMS items. Error if no symbols
3274 selected. */
3275
3276 /* NOTE: Adapted from decode_line_2 in symtab.c, with which it ought
3277 to be re-integrated one of these days. */
3278
3279 static int
3280 user_select_syms (struct block_symbol *syms, int nsyms, int max_results)
3281 {
3282 int i;
3283 int *chosen = XALLOCAVEC (int , nsyms);
3284 int n_chosen;
3285 int first_choice = (max_results == 1) ? 1 : 2;
3286 const char *select_mode = multiple_symbols_select_mode ();
3287
3288 if (max_results < 1)
3289 error (_("Request to select 0 symbols!"));
3290 if (nsyms <= 1)
3291 return nsyms;
3292
3293 if (select_mode == multiple_symbols_cancel)
3294 error (_("\
3295 canceled because the command is ambiguous\n\
3296 See set/show multiple-symbol."));
3297
3298 /* If select_mode is "all", then return all possible symbols.
3299 Only do that if more than one symbol can be selected, of course.
3300 Otherwise, display the menu as usual. */
3301 if (select_mode == multiple_symbols_all && max_results > 1)
3302 return nsyms;
3303
3304 printf_filtered (_("[0] cancel\n"));
3305 if (max_results > 1)
3306 printf_filtered (_("[1] all\n"));
3307
3308 sort_choices (syms, nsyms);
3309
3310 for (i = 0; i < nsyms; i += 1)
3311 {
3312 if (syms[i].symbol == NULL)
3313 continue;
3314
3315 if (SYMBOL_CLASS (syms[i].symbol) == LOC_BLOCK)
3316 {
3317 struct symtab_and_line sal =
3318 find_function_start_sal (syms[i].symbol, 1);
3319
3320 printf_filtered ("[%d] ", i + first_choice);
3321 ada_print_symbol_signature (gdb_stdout, syms[i].symbol,
3322 &type_print_raw_options);
3323 if (sal.symtab == NULL)
3324 printf_filtered (_(" at %p[<no source file available>%p]:%d\n"),
3325 metadata_style.style ().ptr (), nullptr, sal.line);
3326 else
3327 printf_filtered
3328 (_(" at %ps:%d\n"),
3329 styled_string (file_name_style.style (),
3330 symtab_to_filename_for_display (sal.symtab)),
3331 sal.line);
3332 continue;
3333 }
3334 else
3335 {
3336 int is_enumeral =
3337 (SYMBOL_CLASS (syms[i].symbol) == LOC_CONST
3338 && SYMBOL_TYPE (syms[i].symbol) != NULL
3339 && SYMBOL_TYPE (syms[i].symbol)->code () == TYPE_CODE_ENUM);
3340 struct symtab *symtab = NULL;
3341
3342 if (SYMBOL_OBJFILE_OWNED (syms[i].symbol))
3343 symtab = symbol_symtab (syms[i].symbol);
3344
3345 if (SYMBOL_LINE (syms[i].symbol) != 0 && symtab != NULL)
3346 {
3347 printf_filtered ("[%d] ", i + first_choice);
3348 ada_print_symbol_signature (gdb_stdout, syms[i].symbol,
3349 &type_print_raw_options);
3350 printf_filtered (_(" at %s:%d\n"),
3351 symtab_to_filename_for_display (symtab),
3352 SYMBOL_LINE (syms[i].symbol));
3353 }
3354 else if (is_enumeral
3355 && SYMBOL_TYPE (syms[i].symbol)->name () != NULL)
3356 {
3357 printf_filtered (("[%d] "), i + first_choice);
3358 ada_print_type (SYMBOL_TYPE (syms[i].symbol), NULL,
3359 gdb_stdout, -1, 0, &type_print_raw_options);
3360 printf_filtered (_("'(%s) (enumeral)\n"),
3361 syms[i].symbol->print_name ());
3362 }
3363 else
3364 {
3365 printf_filtered ("[%d] ", i + first_choice);
3366 ada_print_symbol_signature (gdb_stdout, syms[i].symbol,
3367 &type_print_raw_options);
3368
3369 if (symtab != NULL)
3370 printf_filtered (is_enumeral
3371 ? _(" in %s (enumeral)\n")
3372 : _(" at %s:?\n"),
3373 symtab_to_filename_for_display (symtab));
3374 else
3375 printf_filtered (is_enumeral
3376 ? _(" (enumeral)\n")
3377 : _(" at ?\n"));
3378 }
3379 }
3380 }
3381
3382 n_chosen = get_selections (chosen, nsyms, max_results, max_results > 1,
3383 "overload-choice");
3384
3385 for (i = 0; i < n_chosen; i += 1)
3386 syms[i] = syms[chosen[i]];
3387
3388 return n_chosen;
3389 }
3390
3391 /* Resolve the operator of the subexpression beginning at
3392 position *POS of *EXPP. "Resolving" consists of replacing
3393 the symbols that have undefined namespaces in OP_VAR_VALUE nodes
3394 with their resolutions, replacing built-in operators with
3395 function calls to user-defined operators, where appropriate, and,
3396 when DEPROCEDURE_P is non-zero, converting function-valued variables
3397 into parameterless calls. May expand *EXPP. The CONTEXT_TYPE functions
3398 are as in ada_resolve, above. */
3399
3400 static struct value *
3401 resolve_subexp (expression_up *expp, int *pos, int deprocedure_p,
3402 struct type *context_type, int parse_completion,
3403 innermost_block_tracker *tracker)
3404 {
3405 int pc = *pos;
3406 int i;
3407 struct expression *exp; /* Convenience: == *expp. */
3408 enum exp_opcode op = (*expp)->elts[pc].opcode;
3409 struct value **argvec; /* Vector of operand types (alloca'ed). */
3410 int nargs; /* Number of operands. */
3411 int oplen;
3412
3413 argvec = NULL;
3414 nargs = 0;
3415 exp = expp->get ();
3416
3417 /* Pass one: resolve operands, saving their types and updating *pos,
3418 if needed. */
3419 switch (op)
3420 {
3421 case OP_FUNCALL:
3422 if (exp->elts[pc + 3].opcode == OP_VAR_VALUE
3423 && SYMBOL_DOMAIN (exp->elts[pc + 5].symbol) == UNDEF_DOMAIN)
3424 *pos += 7;
3425 else
3426 {
3427 *pos += 3;
3428 resolve_subexp (expp, pos, 0, NULL, parse_completion, tracker);
3429 }
3430 nargs = longest_to_int (exp->elts[pc + 1].longconst);
3431 break;
3432
3433 case UNOP_ADDR:
3434 *pos += 1;
3435 resolve_subexp (expp, pos, 0, NULL, parse_completion, tracker);
3436 break;
3437
3438 case UNOP_QUAL:
3439 *pos += 3;
3440 resolve_subexp (expp, pos, 1, check_typedef (exp->elts[pc + 1].type),
3441 parse_completion, tracker);
3442 break;
3443
3444 case OP_ATR_MODULUS:
3445 case OP_ATR_SIZE:
3446 case OP_ATR_TAG:
3447 case OP_ATR_FIRST:
3448 case OP_ATR_LAST:
3449 case OP_ATR_LENGTH:
3450 case OP_ATR_POS:
3451 case OP_ATR_VAL:
3452 case OP_ATR_MIN:
3453 case OP_ATR_MAX:
3454 case TERNOP_IN_RANGE:
3455 case BINOP_IN_BOUNDS:
3456 case UNOP_IN_RANGE:
3457 case OP_AGGREGATE:
3458 case OP_OTHERS:
3459 case OP_CHOICES:
3460 case OP_POSITIONAL:
3461 case OP_DISCRETE_RANGE:
3462 case OP_NAME:
3463 ada_forward_operator_length (exp, pc, &oplen, &nargs);
3464 *pos += oplen;
3465 break;
3466
3467 case BINOP_ASSIGN:
3468 {
3469 struct value *arg1;
3470
3471 *pos += 1;
3472 arg1 = resolve_subexp (expp, pos, 0, NULL, parse_completion, tracker);
3473 if (arg1 == NULL)
3474 resolve_subexp (expp, pos, 1, NULL, parse_completion, tracker);
3475 else
3476 resolve_subexp (expp, pos, 1, value_type (arg1), parse_completion,
3477 tracker);
3478 break;
3479 }
3480
3481 case UNOP_CAST:
3482 *pos += 3;
3483 nargs = 1;
3484 break;
3485
3486 case BINOP_ADD:
3487 case BINOP_SUB:
3488 case BINOP_MUL:
3489 case BINOP_DIV:
3490 case BINOP_REM:
3491 case BINOP_MOD:
3492 case BINOP_EXP:
3493 case BINOP_CONCAT:
3494 case BINOP_LOGICAL_AND:
3495 case BINOP_LOGICAL_OR:
3496 case BINOP_BITWISE_AND:
3497 case BINOP_BITWISE_IOR:
3498 case BINOP_BITWISE_XOR:
3499
3500 case BINOP_EQUAL:
3501 case BINOP_NOTEQUAL:
3502 case BINOP_LESS:
3503 case BINOP_GTR:
3504 case BINOP_LEQ:
3505 case BINOP_GEQ:
3506
3507 case BINOP_REPEAT:
3508 case BINOP_SUBSCRIPT:
3509 case BINOP_COMMA:
3510 *pos += 1;
3511 nargs = 2;
3512 break;
3513
3514 case UNOP_NEG:
3515 case UNOP_PLUS:
3516 case UNOP_LOGICAL_NOT:
3517 case UNOP_ABS:
3518 case UNOP_IND:
3519 *pos += 1;
3520 nargs = 1;
3521 break;
3522
3523 case OP_LONG:
3524 case OP_FLOAT:
3525 case OP_VAR_VALUE:
3526 case OP_VAR_MSYM_VALUE:
3527 *pos += 4;
3528 break;
3529
3530 case OP_TYPE:
3531 case OP_BOOL:
3532 case OP_LAST:
3533 case OP_INTERNALVAR:
3534 *pos += 3;
3535 break;
3536
3537 case UNOP_MEMVAL:
3538 *pos += 3;
3539 nargs = 1;
3540 break;
3541
3542 case OP_REGISTER:
3543 *pos += 4 + BYTES_TO_EXP_ELEM (exp->elts[pc + 1].longconst + 1);
3544 break;
3545
3546 case STRUCTOP_STRUCT:
3547 *pos += 4 + BYTES_TO_EXP_ELEM (exp->elts[pc + 1].longconst + 1);
3548 nargs = 1;
3549 break;
3550
3551 case TERNOP_SLICE:
3552 *pos += 1;
3553 nargs = 3;
3554 break;
3555
3556 case OP_STRING:
3557 break;
3558
3559 default:
3560 error (_("Unexpected operator during name resolution"));
3561 }
3562
3563 argvec = XALLOCAVEC (struct value *, nargs + 1);
3564 for (i = 0; i < nargs; i += 1)
3565 argvec[i] = resolve_subexp (expp, pos, 1, NULL, parse_completion,
3566 tracker);
3567 argvec[i] = NULL;
3568 exp = expp->get ();
3569
3570 /* Pass two: perform any resolution on principal operator. */
3571 switch (op)
3572 {
3573 default:
3574 break;
3575
3576 case OP_VAR_VALUE:
3577 if (SYMBOL_DOMAIN (exp->elts[pc + 2].symbol) == UNDEF_DOMAIN)
3578 {
3579 std::vector<struct block_symbol> candidates;
3580 int n_candidates;
3581
3582 n_candidates =
3583 ada_lookup_symbol_list (exp->elts[pc + 2].symbol->linkage_name (),
3584 exp->elts[pc + 1].block, VAR_DOMAIN,
3585 &candidates);
3586
3587 if (n_candidates > 1)
3588 {
3589 /* Types tend to get re-introduced locally, so if there
3590 are any local symbols that are not types, first filter
3591 out all types. */
3592 int j;
3593 for (j = 0; j < n_candidates; j += 1)
3594 switch (SYMBOL_CLASS (candidates[j].symbol))
3595 {
3596 case LOC_REGISTER:
3597 case LOC_ARG:
3598 case LOC_REF_ARG:
3599 case LOC_REGPARM_ADDR:
3600 case LOC_LOCAL:
3601 case LOC_COMPUTED:
3602 goto FoundNonType;
3603 default:
3604 break;
3605 }
3606 FoundNonType:
3607 if (j < n_candidates)
3608 {
3609 j = 0;
3610 while (j < n_candidates)
3611 {
3612 if (SYMBOL_CLASS (candidates[j].symbol) == LOC_TYPEDEF)
3613 {
3614 candidates[j] = candidates[n_candidates - 1];
3615 n_candidates -= 1;
3616 }
3617 else
3618 j += 1;
3619 }
3620 }
3621 }
3622
3623 if (n_candidates == 0)
3624 error (_("No definition found for %s"),
3625 exp->elts[pc + 2].symbol->print_name ());
3626 else if (n_candidates == 1)
3627 i = 0;
3628 else if (deprocedure_p
3629 && !is_nonfunction (candidates.data (), n_candidates))
3630 {
3631 i = ada_resolve_function
3632 (candidates.data (), n_candidates, NULL, 0,
3633 exp->elts[pc + 2].symbol->linkage_name (),
3634 context_type, parse_completion);
3635 if (i < 0)
3636 error (_("Could not find a match for %s"),
3637 exp->elts[pc + 2].symbol->print_name ());
3638 }
3639 else
3640 {
3641 printf_filtered (_("Multiple matches for %s\n"),
3642 exp->elts[pc + 2].symbol->print_name ());
3643 user_select_syms (candidates.data (), n_candidates, 1);
3644 i = 0;
3645 }
3646
3647 exp->elts[pc + 1].block = candidates[i].block;
3648 exp->elts[pc + 2].symbol = candidates[i].symbol;
3649 tracker->update (candidates[i]);
3650 }
3651
3652 if (deprocedure_p
3653 && (SYMBOL_TYPE (exp->elts[pc + 2].symbol)->code ()
3654 == TYPE_CODE_FUNC))
3655 {
3656 replace_operator_with_call (expp, pc, 0, 4,
3657 exp->elts[pc + 2].symbol,
3658 exp->elts[pc + 1].block);
3659 exp = expp->get ();
3660 }
3661 break;
3662
3663 case OP_FUNCALL:
3664 {
3665 if (exp->elts[pc + 3].opcode == OP_VAR_VALUE
3666 && SYMBOL_DOMAIN (exp->elts[pc + 5].symbol) == UNDEF_DOMAIN)
3667 {
3668 std::vector<struct block_symbol> candidates;
3669 int n_candidates;
3670
3671 n_candidates =
3672 ada_lookup_symbol_list (exp->elts[pc + 5].symbol->linkage_name (),
3673 exp->elts[pc + 4].block, VAR_DOMAIN,
3674 &candidates);
3675
3676 if (n_candidates == 1)
3677 i = 0;
3678 else
3679 {
3680 i = ada_resolve_function
3681 (candidates.data (), n_candidates,
3682 argvec, nargs,
3683 exp->elts[pc + 5].symbol->linkage_name (),
3684 context_type, parse_completion);
3685 if (i < 0)
3686 error (_("Could not find a match for %s"),
3687 exp->elts[pc + 5].symbol->print_name ());
3688 }
3689
3690 exp->elts[pc + 4].block = candidates[i].block;
3691 exp->elts[pc + 5].symbol = candidates[i].symbol;
3692 tracker->update (candidates[i]);
3693 }
3694 }
3695 break;
3696 case BINOP_ADD:
3697 case BINOP_SUB:
3698 case BINOP_MUL:
3699 case BINOP_DIV:
3700 case BINOP_REM:
3701 case BINOP_MOD:
3702 case BINOP_CONCAT:
3703 case BINOP_BITWISE_AND:
3704 case BINOP_BITWISE_IOR:
3705 case BINOP_BITWISE_XOR:
3706 case BINOP_EQUAL:
3707 case BINOP_NOTEQUAL:
3708 case BINOP_LESS:
3709 case BINOP_GTR:
3710 case BINOP_LEQ:
3711 case BINOP_GEQ:
3712 case BINOP_EXP:
3713 case UNOP_NEG:
3714 case UNOP_PLUS:
3715 case UNOP_LOGICAL_NOT:
3716 case UNOP_ABS:
3717 if (possible_user_operator_p (op, argvec))
3718 {
3719 std::vector<struct block_symbol> candidates;
3720 int n_candidates;
3721
3722 n_candidates =
3723 ada_lookup_symbol_list (ada_decoded_op_name (op),
3724 NULL, VAR_DOMAIN,
3725 &candidates);
3726
3727 i = ada_resolve_function (candidates.data (), n_candidates, argvec,
3728 nargs, ada_decoded_op_name (op), NULL,
3729 parse_completion);
3730 if (i < 0)
3731 break;
3732
3733 replace_operator_with_call (expp, pc, nargs, 1,
3734 candidates[i].symbol,
3735 candidates[i].block);
3736 exp = expp->get ();
3737 }
3738 break;
3739
3740 case OP_TYPE:
3741 case OP_REGISTER:
3742 return NULL;
3743 }
3744
3745 *pos = pc;
3746 if (exp->elts[pc].opcode == OP_VAR_MSYM_VALUE)
3747 return evaluate_var_msym_value (EVAL_AVOID_SIDE_EFFECTS,
3748 exp->elts[pc + 1].objfile,
3749 exp->elts[pc + 2].msymbol);
3750 else
3751 return evaluate_subexp_type (exp, pos);
3752 }
3753
3754 /* Return non-zero if formal type FTYPE matches actual type ATYPE. If
3755 MAY_DEREF is non-zero, the formal may be a pointer and the actual
3756 a non-pointer. */
3757 /* The term "match" here is rather loose. The match is heuristic and
3758 liberal. */
3759
3760 static int
3761 ada_type_match (struct type *ftype, struct type *atype, int may_deref)
3762 {
3763 ftype = ada_check_typedef (ftype);
3764 atype = ada_check_typedef (atype);
3765
3766 if (ftype->code () == TYPE_CODE_REF)
3767 ftype = TYPE_TARGET_TYPE (ftype);
3768 if (atype->code () == TYPE_CODE_REF)
3769 atype = TYPE_TARGET_TYPE (atype);
3770
3771 switch (ftype->code ())
3772 {
3773 default:
3774 return ftype->code () == atype->code ();
3775 case TYPE_CODE_PTR:
3776 if (atype->code () == TYPE_CODE_PTR)
3777 return ada_type_match (TYPE_TARGET_TYPE (ftype),
3778 TYPE_TARGET_TYPE (atype), 0);
3779 else
3780 return (may_deref
3781 && ada_type_match (TYPE_TARGET_TYPE (ftype), atype, 0));
3782 case TYPE_CODE_INT:
3783 case TYPE_CODE_ENUM:
3784 case TYPE_CODE_RANGE:
3785 switch (atype->code ())
3786 {
3787 case TYPE_CODE_INT:
3788 case TYPE_CODE_ENUM:
3789 case TYPE_CODE_RANGE:
3790 return 1;
3791 default:
3792 return 0;
3793 }
3794
3795 case TYPE_CODE_ARRAY:
3796 return (atype->code () == TYPE_CODE_ARRAY
3797 || ada_is_array_descriptor_type (atype));
3798
3799 case TYPE_CODE_STRUCT:
3800 if (ada_is_array_descriptor_type (ftype))
3801 return (atype->code () == TYPE_CODE_ARRAY
3802 || ada_is_array_descriptor_type (atype));
3803 else
3804 return (atype->code () == TYPE_CODE_STRUCT
3805 && !ada_is_array_descriptor_type (atype));
3806
3807 case TYPE_CODE_UNION:
3808 case TYPE_CODE_FLT:
3809 return (atype->code () == ftype->code ());
3810 }
3811 }
3812
3813 /* Return non-zero if the formals of FUNC "sufficiently match" the
3814 vector of actual argument types ACTUALS of size N_ACTUALS. FUNC
3815 may also be an enumeral, in which case it is treated as a 0-
3816 argument function. */
3817
3818 static int
3819 ada_args_match (struct symbol *func, struct value **actuals, int n_actuals)
3820 {
3821 int i;
3822 struct type *func_type = SYMBOL_TYPE (func);
3823
3824 if (SYMBOL_CLASS (func) == LOC_CONST
3825 && func_type->code () == TYPE_CODE_ENUM)
3826 return (n_actuals == 0);
3827 else if (func_type == NULL || func_type->code () != TYPE_CODE_FUNC)
3828 return 0;
3829
3830 if (func_type->num_fields () != n_actuals)
3831 return 0;
3832
3833 for (i = 0; i < n_actuals; i += 1)
3834 {
3835 if (actuals[i] == NULL)
3836 return 0;
3837 else
3838 {
3839 struct type *ftype = ada_check_typedef (func_type->field (i).type ());
3840 struct type *atype = ada_check_typedef (value_type (actuals[i]));
3841
3842 if (!ada_type_match (ftype, atype, 1))
3843 return 0;
3844 }
3845 }
3846 return 1;
3847 }
3848
3849 /* False iff function type FUNC_TYPE definitely does not produce a value
3850 compatible with type CONTEXT_TYPE. Conservatively returns 1 if
3851 FUNC_TYPE is not a valid function type with a non-null return type
3852 or an enumerated type. A null CONTEXT_TYPE indicates any non-void type. */
3853
3854 static int
3855 return_match (struct type *func_type, struct type *context_type)
3856 {
3857 struct type *return_type;
3858
3859 if (func_type == NULL)
3860 return 1;
3861
3862 if (func_type->code () == TYPE_CODE_FUNC)
3863 return_type = get_base_type (TYPE_TARGET_TYPE (func_type));
3864 else
3865 return_type = get_base_type (func_type);
3866 if (return_type == NULL)
3867 return 1;
3868
3869 context_type = get_base_type (context_type);
3870
3871 if (return_type->code () == TYPE_CODE_ENUM)
3872 return context_type == NULL || return_type == context_type;
3873 else if (context_type == NULL)
3874 return return_type->code () != TYPE_CODE_VOID;
3875 else
3876 return return_type->code () == context_type->code ();
3877 }
3878
3879
3880 /* Returns the index in SYMS[0..NSYMS-1] that contains the symbol for the
3881 function (if any) that matches the types of the NARGS arguments in
3882 ARGS. If CONTEXT_TYPE is non-null and there is at least one match
3883 that returns that type, then eliminate matches that don't. If
3884 CONTEXT_TYPE is void and there is at least one match that does not
3885 return void, eliminate all matches that do.
3886
3887 Asks the user if there is more than one match remaining. Returns -1
3888 if there is no such symbol or none is selected. NAME is used
3889 solely for messages. May re-arrange and modify SYMS in
3890 the process; the index returned is for the modified vector. */
3891
3892 static int
3893 ada_resolve_function (struct block_symbol syms[],
3894 int nsyms, struct value **args, int nargs,
3895 const char *name, struct type *context_type,
3896 int parse_completion)
3897 {
3898 int fallback;
3899 int k;
3900 int m; /* Number of hits */
3901
3902 m = 0;
3903 /* In the first pass of the loop, we only accept functions matching
3904 context_type. If none are found, we add a second pass of the loop
3905 where every function is accepted. */
3906 for (fallback = 0; m == 0 && fallback < 2; fallback++)
3907 {
3908 for (k = 0; k < nsyms; k += 1)
3909 {
3910 struct type *type = ada_check_typedef (SYMBOL_TYPE (syms[k].symbol));
3911
3912 if (ada_args_match (syms[k].symbol, args, nargs)
3913 && (fallback || return_match (type, context_type)))
3914 {
3915 syms[m] = syms[k];
3916 m += 1;
3917 }
3918 }
3919 }
3920
3921 /* If we got multiple matches, ask the user which one to use. Don't do this
3922 interactive thing during completion, though, as the purpose of the
3923 completion is providing a list of all possible matches. Prompting the
3924 user to filter it down would be completely unexpected in this case. */
3925 if (m == 0)
3926 return -1;
3927 else if (m > 1 && !parse_completion)
3928 {
3929 printf_filtered (_("Multiple matches for %s\n"), name);
3930 user_select_syms (syms, m, 1);
3931 return 0;
3932 }
3933 return 0;
3934 }
3935
3936 /* Replace the operator of length OPLEN at position PC in *EXPP with a call
3937 on the function identified by SYM and BLOCK, and taking NARGS
3938 arguments. Update *EXPP as needed to hold more space. */
3939
3940 static void
3941 replace_operator_with_call (expression_up *expp, int pc, int nargs,
3942 int oplen, struct symbol *sym,
3943 const struct block *block)
3944 {
3945 /* A new expression, with 6 more elements (3 for funcall, 4 for function
3946 symbol, -oplen for operator being replaced). */
3947 struct expression *newexp = (struct expression *)
3948 xzalloc (sizeof (struct expression)
3949 + EXP_ELEM_TO_BYTES ((*expp)->nelts + 7 - oplen));
3950 struct expression *exp = expp->get ();
3951
3952 newexp->nelts = exp->nelts + 7 - oplen;
3953 newexp->language_defn = exp->language_defn;
3954 newexp->gdbarch = exp->gdbarch;
3955 memcpy (newexp->elts, exp->elts, EXP_ELEM_TO_BYTES (pc));
3956 memcpy (newexp->elts + pc + 7, exp->elts + pc + oplen,
3957 EXP_ELEM_TO_BYTES (exp->nelts - pc - oplen));
3958
3959 newexp->elts[pc].opcode = newexp->elts[pc + 2].opcode = OP_FUNCALL;
3960 newexp->elts[pc + 1].longconst = (LONGEST) nargs;
3961
3962 newexp->elts[pc + 3].opcode = newexp->elts[pc + 6].opcode = OP_VAR_VALUE;
3963 newexp->elts[pc + 4].block = block;
3964 newexp->elts[pc + 5].symbol = sym;
3965
3966 expp->reset (newexp);
3967 }
3968
3969 /* Type-class predicates */
3970
3971 /* True iff TYPE is numeric (i.e., an INT, RANGE (of numeric type),
3972 or FLOAT). */
3973
3974 static int
3975 numeric_type_p (struct type *type)
3976 {
3977 if (type == NULL)
3978 return 0;
3979 else
3980 {
3981 switch (type->code ())
3982 {
3983 case TYPE_CODE_INT:
3984 case TYPE_CODE_FLT:
3985 return 1;
3986 case TYPE_CODE_RANGE:
3987 return (type == TYPE_TARGET_TYPE (type)
3988 || numeric_type_p (TYPE_TARGET_TYPE (type)));
3989 default:
3990 return 0;
3991 }
3992 }
3993 }
3994
3995 /* True iff TYPE is integral (an INT or RANGE of INTs). */
3996
3997 static int
3998 integer_type_p (struct type *type)
3999 {
4000 if (type == NULL)
4001 return 0;
4002 else
4003 {
4004 switch (type->code ())
4005 {
4006 case TYPE_CODE_INT:
4007 return 1;
4008 case TYPE_CODE_RANGE:
4009 return (type == TYPE_TARGET_TYPE (type)
4010 || integer_type_p (TYPE_TARGET_TYPE (type)));
4011 default:
4012 return 0;
4013 }
4014 }
4015 }
4016
4017 /* True iff TYPE is scalar (INT, RANGE, FLOAT, ENUM). */
4018
4019 static int
4020 scalar_type_p (struct type *type)
4021 {
4022 if (type == NULL)
4023 return 0;
4024 else
4025 {
4026 switch (type->code ())
4027 {
4028 case TYPE_CODE_INT:
4029 case TYPE_CODE_RANGE:
4030 case TYPE_CODE_ENUM:
4031 case TYPE_CODE_FLT:
4032 return 1;
4033 default:
4034 return 0;
4035 }
4036 }
4037 }
4038
4039 /* True iff TYPE is discrete (INT, RANGE, ENUM). */
4040
4041 static int
4042 discrete_type_p (struct type *type)
4043 {
4044 if (type == NULL)
4045 return 0;
4046 else
4047 {
4048 switch (type->code ())
4049 {
4050 case TYPE_CODE_INT:
4051 case TYPE_CODE_RANGE:
4052 case TYPE_CODE_ENUM:
4053 case TYPE_CODE_BOOL:
4054 return 1;
4055 default:
4056 return 0;
4057 }
4058 }
4059 }
4060
4061 /* Returns non-zero if OP with operands in the vector ARGS could be
4062 a user-defined function. Errs on the side of pre-defined operators
4063 (i.e., result 0). */
4064
4065 static int
4066 possible_user_operator_p (enum exp_opcode op, struct value *args[])
4067 {
4068 struct type *type0 =
4069 (args[0] == NULL) ? NULL : ada_check_typedef (value_type (args[0]));
4070 struct type *type1 =
4071 (args[1] == NULL) ? NULL : ada_check_typedef (value_type (args[1]));
4072
4073 if (type0 == NULL)
4074 return 0;
4075
4076 switch (op)
4077 {
4078 default:
4079 return 0;
4080
4081 case BINOP_ADD:
4082 case BINOP_SUB:
4083 case BINOP_MUL:
4084 case BINOP_DIV:
4085 return (!(numeric_type_p (type0) && numeric_type_p (type1)));
4086
4087 case BINOP_REM:
4088 case BINOP_MOD:
4089 case BINOP_BITWISE_AND:
4090 case BINOP_BITWISE_IOR:
4091 case BINOP_BITWISE_XOR:
4092 return (!(integer_type_p (type0) && integer_type_p (type1)));
4093
4094 case BINOP_EQUAL:
4095 case BINOP_NOTEQUAL:
4096 case BINOP_LESS:
4097 case BINOP_GTR:
4098 case BINOP_LEQ:
4099 case BINOP_GEQ:
4100 return (!(scalar_type_p (type0) && scalar_type_p (type1)));
4101
4102 case BINOP_CONCAT:
4103 return !ada_is_array_type (type0) || !ada_is_array_type (type1);
4104
4105 case BINOP_EXP:
4106 return (!(numeric_type_p (type0) && integer_type_p (type1)));
4107
4108 case UNOP_NEG:
4109 case UNOP_PLUS:
4110 case UNOP_LOGICAL_NOT:
4111 case UNOP_ABS:
4112 return (!numeric_type_p (type0));
4113
4114 }
4115 }
4116 \f
4117 /* Renaming */
4118
4119 /* NOTES:
4120
4121 1. In the following, we assume that a renaming type's name may
4122 have an ___XD suffix. It would be nice if this went away at some
4123 point.
4124 2. We handle both the (old) purely type-based representation of
4125 renamings and the (new) variable-based encoding. At some point,
4126 it is devoutly to be hoped that the former goes away
4127 (FIXME: hilfinger-2007-07-09).
4128 3. Subprogram renamings are not implemented, although the XRS
4129 suffix is recognized (FIXME: hilfinger-2007-07-09). */
4130
4131 /* If SYM encodes a renaming,
4132
4133 <renaming> renames <renamed entity>,
4134
4135 sets *LEN to the length of the renamed entity's name,
4136 *RENAMED_ENTITY to that name (not null-terminated), and *RENAMING_EXPR to
4137 the string describing the subcomponent selected from the renamed
4138 entity. Returns ADA_NOT_RENAMING if SYM does not encode a renaming
4139 (in which case, the values of *RENAMED_ENTITY, *LEN, and *RENAMING_EXPR
4140 are undefined). Otherwise, returns a value indicating the category
4141 of entity renamed: an object (ADA_OBJECT_RENAMING), exception
4142 (ADA_EXCEPTION_RENAMING), package (ADA_PACKAGE_RENAMING), or
4143 subprogram (ADA_SUBPROGRAM_RENAMING). Does no allocation; the
4144 strings returned in *RENAMED_ENTITY and *RENAMING_EXPR should not be
4145 deallocated. The values of RENAMED_ENTITY, LEN, or RENAMING_EXPR
4146 may be NULL, in which case they are not assigned.
4147
4148 [Currently, however, GCC does not generate subprogram renamings.] */
4149
4150 enum ada_renaming_category
4151 ada_parse_renaming (struct symbol *sym,
4152 const char **renamed_entity, int *len,
4153 const char **renaming_expr)
4154 {
4155 enum ada_renaming_category kind;
4156 const char *info;
4157 const char *suffix;
4158
4159 if (sym == NULL)
4160 return ADA_NOT_RENAMING;
4161 switch (SYMBOL_CLASS (sym))
4162 {
4163 default:
4164 return ADA_NOT_RENAMING;
4165 case LOC_LOCAL:
4166 case LOC_STATIC:
4167 case LOC_COMPUTED:
4168 case LOC_OPTIMIZED_OUT:
4169 info = strstr (sym->linkage_name (), "___XR");
4170 if (info == NULL)
4171 return ADA_NOT_RENAMING;
4172 switch (info[5])
4173 {
4174 case '_':
4175 kind = ADA_OBJECT_RENAMING;
4176 info += 6;
4177 break;
4178 case 'E':
4179 kind = ADA_EXCEPTION_RENAMING;
4180 info += 7;
4181 break;
4182 case 'P':
4183 kind = ADA_PACKAGE_RENAMING;
4184 info += 7;
4185 break;
4186 case 'S':
4187 kind = ADA_SUBPROGRAM_RENAMING;
4188 info += 7;
4189 break;
4190 default:
4191 return ADA_NOT_RENAMING;
4192 }
4193 }
4194
4195 if (renamed_entity != NULL)
4196 *renamed_entity = info;
4197 suffix = strstr (info, "___XE");
4198 if (suffix == NULL || suffix == info)
4199 return ADA_NOT_RENAMING;
4200 if (len != NULL)
4201 *len = strlen (info) - strlen (suffix);
4202 suffix += 5;
4203 if (renaming_expr != NULL)
4204 *renaming_expr = suffix;
4205 return kind;
4206 }
4207
4208 /* Compute the value of the given RENAMING_SYM, which is expected to
4209 be a symbol encoding a renaming expression. BLOCK is the block
4210 used to evaluate the renaming. */
4211
4212 static struct value *
4213 ada_read_renaming_var_value (struct symbol *renaming_sym,
4214 const struct block *block)
4215 {
4216 const char *sym_name;
4217
4218 sym_name = renaming_sym->linkage_name ();
4219 expression_up expr = parse_exp_1 (&sym_name, 0, block, 0);
4220 return evaluate_expression (expr.get ());
4221 }
4222 \f
4223
4224 /* Evaluation: Function Calls */
4225
4226 /* Return an lvalue containing the value VAL. This is the identity on
4227 lvalues, and otherwise has the side-effect of allocating memory
4228 in the inferior where a copy of the value contents is copied. */
4229
4230 static struct value *
4231 ensure_lval (struct value *val)
4232 {
4233 if (VALUE_LVAL (val) == not_lval
4234 || VALUE_LVAL (val) == lval_internalvar)
4235 {
4236 int len = TYPE_LENGTH (ada_check_typedef (value_type (val)));
4237 const CORE_ADDR addr =
4238 value_as_long (value_allocate_space_in_inferior (len));
4239
4240 VALUE_LVAL (val) = lval_memory;
4241 set_value_address (val, addr);
4242 write_memory (addr, value_contents (val), len);
4243 }
4244
4245 return val;
4246 }
4247
4248 /* Given ARG, a value of type (pointer or reference to a)*
4249 structure/union, extract the component named NAME from the ultimate
4250 target structure/union and return it as a value with its
4251 appropriate type.
4252
4253 The routine searches for NAME among all members of the structure itself
4254 and (recursively) among all members of any wrapper members
4255 (e.g., '_parent').
4256
4257 If NO_ERR, then simply return NULL in case of error, rather than
4258 calling error. */
4259
4260 static struct value *
4261 ada_value_struct_elt (struct value *arg, const char *name, int no_err)
4262 {
4263 struct type *t, *t1;
4264 struct value *v;
4265 int check_tag;
4266
4267 v = NULL;
4268 t1 = t = ada_check_typedef (value_type (arg));
4269 if (t->code () == TYPE_CODE_REF)
4270 {
4271 t1 = TYPE_TARGET_TYPE (t);
4272 if (t1 == NULL)
4273 goto BadValue;
4274 t1 = ada_check_typedef (t1);
4275 if (t1->code () == TYPE_CODE_PTR)
4276 {
4277 arg = coerce_ref (arg);
4278 t = t1;
4279 }
4280 }
4281
4282 while (t->code () == TYPE_CODE_PTR)
4283 {
4284 t1 = TYPE_TARGET_TYPE (t);
4285 if (t1 == NULL)
4286 goto BadValue;
4287 t1 = ada_check_typedef (t1);
4288 if (t1->code () == TYPE_CODE_PTR)
4289 {
4290 arg = value_ind (arg);
4291 t = t1;
4292 }
4293 else
4294 break;
4295 }
4296
4297 if (t1->code () != TYPE_CODE_STRUCT && t1->code () != TYPE_CODE_UNION)
4298 goto BadValue;
4299
4300 if (t1 == t)
4301 v = ada_search_struct_field (name, arg, 0, t);
4302 else
4303 {
4304 int bit_offset, bit_size, byte_offset;
4305 struct type *field_type;
4306 CORE_ADDR address;
4307
4308 if (t->code () == TYPE_CODE_PTR)
4309 address = value_address (ada_value_ind (arg));
4310 else
4311 address = value_address (ada_coerce_ref (arg));
4312
4313 /* Check to see if this is a tagged type. We also need to handle
4314 the case where the type is a reference to a tagged type, but
4315 we have to be careful to exclude pointers to tagged types.
4316 The latter should be shown as usual (as a pointer), whereas
4317 a reference should mostly be transparent to the user. */
4318
4319 if (ada_is_tagged_type (t1, 0)
4320 || (t1->code () == TYPE_CODE_REF
4321 && ada_is_tagged_type (TYPE_TARGET_TYPE (t1), 0)))
4322 {
4323 /* We first try to find the searched field in the current type.
4324 If not found then let's look in the fixed type. */
4325
4326 if (!find_struct_field (name, t1, 0,
4327 &field_type, &byte_offset, &bit_offset,
4328 &bit_size, NULL))
4329 check_tag = 1;
4330 else
4331 check_tag = 0;
4332 }
4333 else
4334 check_tag = 0;
4335
4336 /* Convert to fixed type in all cases, so that we have proper
4337 offsets to each field in unconstrained record types. */
4338 t1 = ada_to_fixed_type (ada_get_base_type (t1), NULL,
4339 address, NULL, check_tag);
4340
4341 if (find_struct_field (name, t1, 0,
4342 &field_type, &byte_offset, &bit_offset,
4343 &bit_size, NULL))
4344 {
4345 if (bit_size != 0)
4346 {
4347 if (t->code () == TYPE_CODE_REF)
4348 arg = ada_coerce_ref (arg);
4349 else
4350 arg = ada_value_ind (arg);
4351 v = ada_value_primitive_packed_val (arg, NULL, byte_offset,
4352 bit_offset, bit_size,
4353 field_type);
4354 }
4355 else
4356 v = value_at_lazy (field_type, address + byte_offset);
4357 }
4358 }
4359
4360 if (v != NULL || no_err)
4361 return v;
4362 else
4363 error (_("There is no member named %s."), name);
4364
4365 BadValue:
4366 if (no_err)
4367 return NULL;
4368 else
4369 error (_("Attempt to extract a component of "
4370 "a value that is not a record."));
4371 }
4372
4373 /* Return the value ACTUAL, converted to be an appropriate value for a
4374 formal of type FORMAL_TYPE. Use *SP as a stack pointer for
4375 allocating any necessary descriptors (fat pointers), or copies of
4376 values not residing in memory, updating it as needed. */
4377
4378 struct value *
4379 ada_convert_actual (struct value *actual, struct type *formal_type0)
4380 {
4381 struct type *actual_type = ada_check_typedef (value_type (actual));
4382 struct type *formal_type = ada_check_typedef (formal_type0);
4383 struct type *formal_target =
4384 formal_type->code () == TYPE_CODE_PTR
4385 ? ada_check_typedef (TYPE_TARGET_TYPE (formal_type)) : formal_type;
4386 struct type *actual_target =
4387 actual_type->code () == TYPE_CODE_PTR
4388 ? ada_check_typedef (TYPE_TARGET_TYPE (actual_type)) : actual_type;
4389
4390 if (ada_is_array_descriptor_type (formal_target)
4391 && actual_target->code () == TYPE_CODE_ARRAY)
4392 return make_array_descriptor (formal_type, actual);
4393 else if (formal_type->code () == TYPE_CODE_PTR
4394 || formal_type->code () == TYPE_CODE_REF)
4395 {
4396 struct value *result;
4397
4398 if (formal_target->code () == TYPE_CODE_ARRAY
4399 && ada_is_array_descriptor_type (actual_target))
4400 result = desc_data (actual);
4401 else if (formal_type->code () != TYPE_CODE_PTR)
4402 {
4403 if (VALUE_LVAL (actual) != lval_memory)
4404 {
4405 struct value *val;
4406
4407 actual_type = ada_check_typedef (value_type (actual));
4408 val = allocate_value (actual_type);
4409 memcpy ((char *) value_contents_raw (val),
4410 (char *) value_contents (actual),
4411 TYPE_LENGTH (actual_type));
4412 actual = ensure_lval (val);
4413 }
4414 result = value_addr (actual);
4415 }
4416 else
4417 return actual;
4418 return value_cast_pointers (formal_type, result, 0);
4419 }
4420 else if (actual_type->code () == TYPE_CODE_PTR)
4421 return ada_value_ind (actual);
4422 else if (ada_is_aligner_type (formal_type))
4423 {
4424 /* We need to turn this parameter into an aligner type
4425 as well. */
4426 struct value *aligner = allocate_value (formal_type);
4427 struct value *component = ada_value_struct_elt (aligner, "F", 0);
4428
4429 value_assign_to_component (aligner, component, actual);
4430 return aligner;
4431 }
4432
4433 return actual;
4434 }
4435
4436 /* Convert VALUE (which must be an address) to a CORE_ADDR that is a pointer of
4437 type TYPE. This is usually an inefficient no-op except on some targets
4438 (such as AVR) where the representation of a pointer and an address
4439 differs. */
4440
4441 static CORE_ADDR
4442 value_pointer (struct value *value, struct type *type)
4443 {
4444 struct gdbarch *gdbarch = get_type_arch (type);
4445 unsigned len = TYPE_LENGTH (type);
4446 gdb_byte *buf = (gdb_byte *) alloca (len);
4447 CORE_ADDR addr;
4448
4449 addr = value_address (value);
4450 gdbarch_address_to_pointer (gdbarch, type, buf, addr);
4451 addr = extract_unsigned_integer (buf, len, type_byte_order (type));
4452 return addr;
4453 }
4454
4455
4456 /* Push a descriptor of type TYPE for array value ARR on the stack at
4457 *SP, updating *SP to reflect the new descriptor. Return either
4458 an lvalue representing the new descriptor, or (if TYPE is a pointer-
4459 to-descriptor type rather than a descriptor type), a struct value *
4460 representing a pointer to this descriptor. */
4461
4462 static struct value *
4463 make_array_descriptor (struct type *type, struct value *arr)
4464 {
4465 struct type *bounds_type = desc_bounds_type (type);
4466 struct type *desc_type = desc_base_type (type);
4467 struct value *descriptor = allocate_value (desc_type);
4468 struct value *bounds = allocate_value (bounds_type);
4469 int i;
4470
4471 for (i = ada_array_arity (ada_check_typedef (value_type (arr)));
4472 i > 0; i -= 1)
4473 {
4474 modify_field (value_type (bounds), value_contents_writeable (bounds),
4475 ada_array_bound (arr, i, 0),
4476 desc_bound_bitpos (bounds_type, i, 0),
4477 desc_bound_bitsize (bounds_type, i, 0));
4478 modify_field (value_type (bounds), value_contents_writeable (bounds),
4479 ada_array_bound (arr, i, 1),
4480 desc_bound_bitpos (bounds_type, i, 1),
4481 desc_bound_bitsize (bounds_type, i, 1));
4482 }
4483
4484 bounds = ensure_lval (bounds);
4485
4486 modify_field (value_type (descriptor),
4487 value_contents_writeable (descriptor),
4488 value_pointer (ensure_lval (arr),
4489 desc_type->field (0).type ()),
4490 fat_pntr_data_bitpos (desc_type),
4491 fat_pntr_data_bitsize (desc_type));
4492
4493 modify_field (value_type (descriptor),
4494 value_contents_writeable (descriptor),
4495 value_pointer (bounds,
4496 desc_type->field (1).type ()),
4497 fat_pntr_bounds_bitpos (desc_type),
4498 fat_pntr_bounds_bitsize (desc_type));
4499
4500 descriptor = ensure_lval (descriptor);
4501
4502 if (type->code () == TYPE_CODE_PTR)
4503 return value_addr (descriptor);
4504 else
4505 return descriptor;
4506 }
4507 \f
4508 /* Symbol Cache Module */
4509
4510 /* Performance measurements made as of 2010-01-15 indicate that
4511 this cache does bring some noticeable improvements. Depending
4512 on the type of entity being printed, the cache can make it as much
4513 as an order of magnitude faster than without it.
4514
4515 The descriptive type DWARF extension has significantly reduced
4516 the need for this cache, at least when DWARF is being used. However,
4517 even in this case, some expensive name-based symbol searches are still
4518 sometimes necessary - to find an XVZ variable, mostly. */
4519
4520 /* Initialize the contents of SYM_CACHE. */
4521
4522 static void
4523 ada_init_symbol_cache (struct ada_symbol_cache *sym_cache)
4524 {
4525 obstack_init (&sym_cache->cache_space);
4526 memset (sym_cache->root, '\000', sizeof (sym_cache->root));
4527 }
4528
4529 /* Free the memory used by SYM_CACHE. */
4530
4531 static void
4532 ada_free_symbol_cache (struct ada_symbol_cache *sym_cache)
4533 {
4534 obstack_free (&sym_cache->cache_space, NULL);
4535 xfree (sym_cache);
4536 }
4537
4538 /* Return the symbol cache associated to the given program space PSPACE.
4539 If not allocated for this PSPACE yet, allocate and initialize one. */
4540
4541 static struct ada_symbol_cache *
4542 ada_get_symbol_cache (struct program_space *pspace)
4543 {
4544 struct ada_pspace_data *pspace_data = get_ada_pspace_data (pspace);
4545
4546 if (pspace_data->sym_cache == NULL)
4547 {
4548 pspace_data->sym_cache = XCNEW (struct ada_symbol_cache);
4549 ada_init_symbol_cache (pspace_data->sym_cache);
4550 }
4551
4552 return pspace_data->sym_cache;
4553 }
4554
4555 /* Clear all entries from the symbol cache. */
4556
4557 static void
4558 ada_clear_symbol_cache (void)
4559 {
4560 struct ada_symbol_cache *sym_cache
4561 = ada_get_symbol_cache (current_program_space);
4562
4563 obstack_free (&sym_cache->cache_space, NULL);
4564 ada_init_symbol_cache (sym_cache);
4565 }
4566
4567 /* Search our cache for an entry matching NAME and DOMAIN.
4568 Return it if found, or NULL otherwise. */
4569
4570 static struct cache_entry **
4571 find_entry (const char *name, domain_enum domain)
4572 {
4573 struct ada_symbol_cache *sym_cache
4574 = ada_get_symbol_cache (current_program_space);
4575 int h = msymbol_hash (name) % HASH_SIZE;
4576 struct cache_entry **e;
4577
4578 for (e = &sym_cache->root[h]; *e != NULL; e = &(*e)->next)
4579 {
4580 if (domain == (*e)->domain && strcmp (name, (*e)->name) == 0)
4581 return e;
4582 }
4583 return NULL;
4584 }
4585
4586 /* Search the symbol cache for an entry matching NAME and DOMAIN.
4587 Return 1 if found, 0 otherwise.
4588
4589 If an entry was found and SYM is not NULL, set *SYM to the entry's
4590 SYM. Same principle for BLOCK if not NULL. */
4591
4592 static int
4593 lookup_cached_symbol (const char *name, domain_enum domain,
4594 struct symbol **sym, const struct block **block)
4595 {
4596 struct cache_entry **e = find_entry (name, domain);
4597
4598 if (e == NULL)
4599 return 0;
4600 if (sym != NULL)
4601 *sym = (*e)->sym;
4602 if (block != NULL)
4603 *block = (*e)->block;
4604 return 1;
4605 }
4606
4607 /* Assuming that (SYM, BLOCK) is the result of the lookup of NAME
4608 in domain DOMAIN, save this result in our symbol cache. */
4609
4610 static void
4611 cache_symbol (const char *name, domain_enum domain, struct symbol *sym,
4612 const struct block *block)
4613 {
4614 struct ada_symbol_cache *sym_cache
4615 = ada_get_symbol_cache (current_program_space);
4616 int h;
4617 struct cache_entry *e;
4618
4619 /* Symbols for builtin types don't have a block.
4620 For now don't cache such symbols. */
4621 if (sym != NULL && !SYMBOL_OBJFILE_OWNED (sym))
4622 return;
4623
4624 /* If the symbol is a local symbol, then do not cache it, as a search
4625 for that symbol depends on the context. To determine whether
4626 the symbol is local or not, we check the block where we found it
4627 against the global and static blocks of its associated symtab. */
4628 if (sym
4629 && BLOCKVECTOR_BLOCK (SYMTAB_BLOCKVECTOR (symbol_symtab (sym)),
4630 GLOBAL_BLOCK) != block
4631 && BLOCKVECTOR_BLOCK (SYMTAB_BLOCKVECTOR (symbol_symtab (sym)),
4632 STATIC_BLOCK) != block)
4633 return;
4634
4635 h = msymbol_hash (name) % HASH_SIZE;
4636 e = XOBNEW (&sym_cache->cache_space, cache_entry);
4637 e->next = sym_cache->root[h];
4638 sym_cache->root[h] = e;
4639 e->name = obstack_strdup (&sym_cache->cache_space, name);
4640 e->sym = sym;
4641 e->domain = domain;
4642 e->block = block;
4643 }
4644 \f
4645 /* Symbol Lookup */
4646
4647 /* Return the symbol name match type that should be used used when
4648 searching for all symbols matching LOOKUP_NAME.
4649
4650 LOOKUP_NAME is expected to be a symbol name after transformation
4651 for Ada lookups. */
4652
4653 static symbol_name_match_type
4654 name_match_type_from_name (const char *lookup_name)
4655 {
4656 return (strstr (lookup_name, "__") == NULL
4657 ? symbol_name_match_type::WILD
4658 : symbol_name_match_type::FULL);
4659 }
4660
4661 /* Return the result of a standard (literal, C-like) lookup of NAME in
4662 given DOMAIN, visible from lexical block BLOCK. */
4663
4664 static struct symbol *
4665 standard_lookup (const char *name, const struct block *block,
4666 domain_enum domain)
4667 {
4668 /* Initialize it just to avoid a GCC false warning. */
4669 struct block_symbol sym = {};
4670
4671 if (lookup_cached_symbol (name, domain, &sym.symbol, NULL))
4672 return sym.symbol;
4673 ada_lookup_encoded_symbol (name, block, domain, &sym);
4674 cache_symbol (name, domain, sym.symbol, sym.block);
4675 return sym.symbol;
4676 }
4677
4678
4679 /* Non-zero iff there is at least one non-function/non-enumeral symbol
4680 in the symbol fields of SYMS[0..N-1]. We treat enumerals as functions,
4681 since they contend in overloading in the same way. */
4682 static int
4683 is_nonfunction (struct block_symbol syms[], int n)
4684 {
4685 int i;
4686
4687 for (i = 0; i < n; i += 1)
4688 if (SYMBOL_TYPE (syms[i].symbol)->code () != TYPE_CODE_FUNC
4689 && (SYMBOL_TYPE (syms[i].symbol)->code () != TYPE_CODE_ENUM
4690 || SYMBOL_CLASS (syms[i].symbol) != LOC_CONST))
4691 return 1;
4692
4693 return 0;
4694 }
4695
4696 /* If true (non-zero), then TYPE0 and TYPE1 represent equivalent
4697 struct types. Otherwise, they may not. */
4698
4699 static int
4700 equiv_types (struct type *type0, struct type *type1)
4701 {
4702 if (type0 == type1)
4703 return 1;
4704 if (type0 == NULL || type1 == NULL
4705 || type0->code () != type1->code ())
4706 return 0;
4707 if ((type0->code () == TYPE_CODE_STRUCT
4708 || type0->code () == TYPE_CODE_ENUM)
4709 && ada_type_name (type0) != NULL && ada_type_name (type1) != NULL
4710 && strcmp (ada_type_name (type0), ada_type_name (type1)) == 0)
4711 return 1;
4712
4713 return 0;
4714 }
4715
4716 /* True iff SYM0 represents the same entity as SYM1, or one that is
4717 no more defined than that of SYM1. */
4718
4719 static int
4720 lesseq_defined_than (struct symbol *sym0, struct symbol *sym1)
4721 {
4722 if (sym0 == sym1)
4723 return 1;
4724 if (SYMBOL_DOMAIN (sym0) != SYMBOL_DOMAIN (sym1)
4725 || SYMBOL_CLASS (sym0) != SYMBOL_CLASS (sym1))
4726 return 0;
4727
4728 switch (SYMBOL_CLASS (sym0))
4729 {
4730 case LOC_UNDEF:
4731 return 1;
4732 case LOC_TYPEDEF:
4733 {
4734 struct type *type0 = SYMBOL_TYPE (sym0);
4735 struct type *type1 = SYMBOL_TYPE (sym1);
4736 const char *name0 = sym0->linkage_name ();
4737 const char *name1 = sym1->linkage_name ();
4738 int len0 = strlen (name0);
4739
4740 return
4741 type0->code () == type1->code ()
4742 && (equiv_types (type0, type1)
4743 || (len0 < strlen (name1) && strncmp (name0, name1, len0) == 0
4744 && startswith (name1 + len0, "___XV")));
4745 }
4746 case LOC_CONST:
4747 return SYMBOL_VALUE (sym0) == SYMBOL_VALUE (sym1)
4748 && equiv_types (SYMBOL_TYPE (sym0), SYMBOL_TYPE (sym1));
4749
4750 case LOC_STATIC:
4751 {
4752 const char *name0 = sym0->linkage_name ();
4753 const char *name1 = sym1->linkage_name ();
4754 return (strcmp (name0, name1) == 0
4755 && SYMBOL_VALUE_ADDRESS (sym0) == SYMBOL_VALUE_ADDRESS (sym1));
4756 }
4757
4758 default:
4759 return 0;
4760 }
4761 }
4762
4763 /* Append (SYM,BLOCK,SYMTAB) to the end of the array of struct block_symbol
4764 records in OBSTACKP. Do nothing if SYM is a duplicate. */
4765
4766 static void
4767 add_defn_to_vec (struct obstack *obstackp,
4768 struct symbol *sym,
4769 const struct block *block)
4770 {
4771 int i;
4772 struct block_symbol *prevDefns = defns_collected (obstackp, 0);
4773
4774 /* Do not try to complete stub types, as the debugger is probably
4775 already scanning all symbols matching a certain name at the
4776 time when this function is called. Trying to replace the stub
4777 type by its associated full type will cause us to restart a scan
4778 which may lead to an infinite recursion. Instead, the client
4779 collecting the matching symbols will end up collecting several
4780 matches, with at least one of them complete. It can then filter
4781 out the stub ones if needed. */
4782
4783 for (i = num_defns_collected (obstackp) - 1; i >= 0; i -= 1)
4784 {
4785 if (lesseq_defined_than (sym, prevDefns[i].symbol))
4786 return;
4787 else if (lesseq_defined_than (prevDefns[i].symbol, sym))
4788 {
4789 prevDefns[i].symbol = sym;
4790 prevDefns[i].block = block;
4791 return;
4792 }
4793 }
4794
4795 {
4796 struct block_symbol info;
4797
4798 info.symbol = sym;
4799 info.block = block;
4800 obstack_grow (obstackp, &info, sizeof (struct block_symbol));
4801 }
4802 }
4803
4804 /* Number of block_symbol structures currently collected in current vector in
4805 OBSTACKP. */
4806
4807 static int
4808 num_defns_collected (struct obstack *obstackp)
4809 {
4810 return obstack_object_size (obstackp) / sizeof (struct block_symbol);
4811 }
4812
4813 /* Vector of block_symbol structures currently collected in current vector in
4814 OBSTACKP. If FINISH, close off the vector and return its final address. */
4815
4816 static struct block_symbol *
4817 defns_collected (struct obstack *obstackp, int finish)
4818 {
4819 if (finish)
4820 return (struct block_symbol *) obstack_finish (obstackp);
4821 else
4822 return (struct block_symbol *) obstack_base (obstackp);
4823 }
4824
4825 /* Return a bound minimal symbol matching NAME according to Ada
4826 decoding rules. Returns an invalid symbol if there is no such
4827 minimal symbol. Names prefixed with "standard__" are handled
4828 specially: "standard__" is first stripped off, and only static and
4829 global symbols are searched. */
4830
4831 struct bound_minimal_symbol
4832 ada_lookup_simple_minsym (const char *name)
4833 {
4834 struct bound_minimal_symbol result;
4835
4836 memset (&result, 0, sizeof (result));
4837
4838 symbol_name_match_type match_type = name_match_type_from_name (name);
4839 lookup_name_info lookup_name (name, match_type);
4840
4841 symbol_name_matcher_ftype *match_name
4842 = ada_get_symbol_name_matcher (lookup_name);
4843
4844 for (objfile *objfile : current_program_space->objfiles ())
4845 {
4846 for (minimal_symbol *msymbol : objfile->msymbols ())
4847 {
4848 if (match_name (msymbol->linkage_name (), lookup_name, NULL)
4849 && MSYMBOL_TYPE (msymbol) != mst_solib_trampoline)
4850 {
4851 result.minsym = msymbol;
4852 result.objfile = objfile;
4853 break;
4854 }
4855 }
4856 }
4857
4858 return result;
4859 }
4860
4861 /* For all subprograms that statically enclose the subprogram of the
4862 selected frame, add symbols matching identifier NAME in DOMAIN
4863 and their blocks to the list of data in OBSTACKP, as for
4864 ada_add_block_symbols (q.v.). If WILD_MATCH_P, treat as NAME
4865 with a wildcard prefix. */
4866
4867 static void
4868 add_symbols_from_enclosing_procs (struct obstack *obstackp,
4869 const lookup_name_info &lookup_name,
4870 domain_enum domain)
4871 {
4872 }
4873
4874 /* True if TYPE is definitely an artificial type supplied to a symbol
4875 for which no debugging information was given in the symbol file. */
4876
4877 static int
4878 is_nondebugging_type (struct type *type)
4879 {
4880 const char *name = ada_type_name (type);
4881
4882 return (name != NULL && strcmp (name, "<variable, no debug info>") == 0);
4883 }
4884
4885 /* Return nonzero if TYPE1 and TYPE2 are two enumeration types
4886 that are deemed "identical" for practical purposes.
4887
4888 This function assumes that TYPE1 and TYPE2 are both TYPE_CODE_ENUM
4889 types and that their number of enumerals is identical (in other
4890 words, type1->num_fields () == type2->num_fields ()). */
4891
4892 static int
4893 ada_identical_enum_types_p (struct type *type1, struct type *type2)
4894 {
4895 int i;
4896
4897 /* The heuristic we use here is fairly conservative. We consider
4898 that 2 enumerate types are identical if they have the same
4899 number of enumerals and that all enumerals have the same
4900 underlying value and name. */
4901
4902 /* All enums in the type should have an identical underlying value. */
4903 for (i = 0; i < type1->num_fields (); i++)
4904 if (TYPE_FIELD_ENUMVAL (type1, i) != TYPE_FIELD_ENUMVAL (type2, i))
4905 return 0;
4906
4907 /* All enumerals should also have the same name (modulo any numerical
4908 suffix). */
4909 for (i = 0; i < type1->num_fields (); i++)
4910 {
4911 const char *name_1 = TYPE_FIELD_NAME (type1, i);
4912 const char *name_2 = TYPE_FIELD_NAME (type2, i);
4913 int len_1 = strlen (name_1);
4914 int len_2 = strlen (name_2);
4915
4916 ada_remove_trailing_digits (TYPE_FIELD_NAME (type1, i), &len_1);
4917 ada_remove_trailing_digits (TYPE_FIELD_NAME (type2, i), &len_2);
4918 if (len_1 != len_2
4919 || strncmp (TYPE_FIELD_NAME (type1, i),
4920 TYPE_FIELD_NAME (type2, i),
4921 len_1) != 0)
4922 return 0;
4923 }
4924
4925 return 1;
4926 }
4927
4928 /* Return nonzero if all the symbols in SYMS are all enumeral symbols
4929 that are deemed "identical" for practical purposes. Sometimes,
4930 enumerals are not strictly identical, but their types are so similar
4931 that they can be considered identical.
4932
4933 For instance, consider the following code:
4934
4935 type Color is (Black, Red, Green, Blue, White);
4936 type RGB_Color is new Color range Red .. Blue;
4937
4938 Type RGB_Color is a subrange of an implicit type which is a copy
4939 of type Color. If we call that implicit type RGB_ColorB ("B" is
4940 for "Base Type"), then type RGB_ColorB is a copy of type Color.
4941 As a result, when an expression references any of the enumeral
4942 by name (Eg. "print green"), the expression is technically
4943 ambiguous and the user should be asked to disambiguate. But
4944 doing so would only hinder the user, since it wouldn't matter
4945 what choice he makes, the outcome would always be the same.
4946 So, for practical purposes, we consider them as the same. */
4947
4948 static int
4949 symbols_are_identical_enums (const std::vector<struct block_symbol> &syms)
4950 {
4951 int i;
4952
4953 /* Before performing a thorough comparison check of each type,
4954 we perform a series of inexpensive checks. We expect that these
4955 checks will quickly fail in the vast majority of cases, and thus
4956 help prevent the unnecessary use of a more expensive comparison.
4957 Said comparison also expects us to make some of these checks
4958 (see ada_identical_enum_types_p). */
4959
4960 /* Quick check: All symbols should have an enum type. */
4961 for (i = 0; i < syms.size (); i++)
4962 if (SYMBOL_TYPE (syms[i].symbol)->code () != TYPE_CODE_ENUM)
4963 return 0;
4964
4965 /* Quick check: They should all have the same value. */
4966 for (i = 1; i < syms.size (); i++)
4967 if (SYMBOL_VALUE (syms[i].symbol) != SYMBOL_VALUE (syms[0].symbol))
4968 return 0;
4969
4970 /* Quick check: They should all have the same number of enumerals. */
4971 for (i = 1; i < syms.size (); i++)
4972 if (SYMBOL_TYPE (syms[i].symbol)->num_fields ()
4973 != SYMBOL_TYPE (syms[0].symbol)->num_fields ())
4974 return 0;
4975
4976 /* All the sanity checks passed, so we might have a set of
4977 identical enumeration types. Perform a more complete
4978 comparison of the type of each symbol. */
4979 for (i = 1; i < syms.size (); i++)
4980 if (!ada_identical_enum_types_p (SYMBOL_TYPE (syms[i].symbol),
4981 SYMBOL_TYPE (syms[0].symbol)))
4982 return 0;
4983
4984 return 1;
4985 }
4986
4987 /* Remove any non-debugging symbols in SYMS that definitely
4988 duplicate other symbols in the list (The only case I know of where
4989 this happens is when object files containing stabs-in-ecoff are
4990 linked with files containing ordinary ecoff debugging symbols (or no
4991 debugging symbols)). Modifies SYMS to squeeze out deleted entries.
4992 Returns the number of items in the modified list. */
4993
4994 static int
4995 remove_extra_symbols (std::vector<struct block_symbol> *syms)
4996 {
4997 int i, j;
4998
4999 /* We should never be called with less than 2 symbols, as there
5000 cannot be any extra symbol in that case. But it's easy to
5001 handle, since we have nothing to do in that case. */
5002 if (syms->size () < 2)
5003 return syms->size ();
5004
5005 i = 0;
5006 while (i < syms->size ())
5007 {
5008 int remove_p = 0;
5009
5010 /* If two symbols have the same name and one of them is a stub type,
5011 the get rid of the stub. */
5012
5013 if (SYMBOL_TYPE ((*syms)[i].symbol)->is_stub ()
5014 && (*syms)[i].symbol->linkage_name () != NULL)
5015 {
5016 for (j = 0; j < syms->size (); j++)
5017 {
5018 if (j != i
5019 && !SYMBOL_TYPE ((*syms)[j].symbol)->is_stub ()
5020 && (*syms)[j].symbol->linkage_name () != NULL
5021 && strcmp ((*syms)[i].symbol->linkage_name (),
5022 (*syms)[j].symbol->linkage_name ()) == 0)
5023 remove_p = 1;
5024 }
5025 }
5026
5027 /* Two symbols with the same name, same class and same address
5028 should be identical. */
5029
5030 else if ((*syms)[i].symbol->linkage_name () != NULL
5031 && SYMBOL_CLASS ((*syms)[i].symbol) == LOC_STATIC
5032 && is_nondebugging_type (SYMBOL_TYPE ((*syms)[i].symbol)))
5033 {
5034 for (j = 0; j < syms->size (); j += 1)
5035 {
5036 if (i != j
5037 && (*syms)[j].symbol->linkage_name () != NULL
5038 && strcmp ((*syms)[i].symbol->linkage_name (),
5039 (*syms)[j].symbol->linkage_name ()) == 0
5040 && SYMBOL_CLASS ((*syms)[i].symbol)
5041 == SYMBOL_CLASS ((*syms)[j].symbol)
5042 && SYMBOL_VALUE_ADDRESS ((*syms)[i].symbol)
5043 == SYMBOL_VALUE_ADDRESS ((*syms)[j].symbol))
5044 remove_p = 1;
5045 }
5046 }
5047
5048 if (remove_p)
5049 syms->erase (syms->begin () + i);
5050 else
5051 i += 1;
5052 }
5053
5054 /* If all the remaining symbols are identical enumerals, then
5055 just keep the first one and discard the rest.
5056
5057 Unlike what we did previously, we do not discard any entry
5058 unless they are ALL identical. This is because the symbol
5059 comparison is not a strict comparison, but rather a practical
5060 comparison. If all symbols are considered identical, then
5061 we can just go ahead and use the first one and discard the rest.
5062 But if we cannot reduce the list to a single element, we have
5063 to ask the user to disambiguate anyways. And if we have to
5064 present a multiple-choice menu, it's less confusing if the list
5065 isn't missing some choices that were identical and yet distinct. */
5066 if (symbols_are_identical_enums (*syms))
5067 syms->resize (1);
5068
5069 return syms->size ();
5070 }
5071
5072 /* Given a type that corresponds to a renaming entity, use the type name
5073 to extract the scope (package name or function name, fully qualified,
5074 and following the GNAT encoding convention) where this renaming has been
5075 defined. */
5076
5077 static std::string
5078 xget_renaming_scope (struct type *renaming_type)
5079 {
5080 /* The renaming types adhere to the following convention:
5081 <scope>__<rename>___<XR extension>.
5082 So, to extract the scope, we search for the "___XR" extension,
5083 and then backtrack until we find the first "__". */
5084
5085 const char *name = renaming_type->name ();
5086 const char *suffix = strstr (name, "___XR");
5087 const char *last;
5088
5089 /* Now, backtrack a bit until we find the first "__". Start looking
5090 at suffix - 3, as the <rename> part is at least one character long. */
5091
5092 for (last = suffix - 3; last > name; last--)
5093 if (last[0] == '_' && last[1] == '_')
5094 break;
5095
5096 /* Make a copy of scope and return it. */
5097 return std::string (name, last);
5098 }
5099
5100 /* Return nonzero if NAME corresponds to a package name. */
5101
5102 static int
5103 is_package_name (const char *name)
5104 {
5105 /* Here, We take advantage of the fact that no symbols are generated
5106 for packages, while symbols are generated for each function.
5107 So the condition for NAME represent a package becomes equivalent
5108 to NAME not existing in our list of symbols. There is only one
5109 small complication with library-level functions (see below). */
5110
5111 /* If it is a function that has not been defined at library level,
5112 then we should be able to look it up in the symbols. */
5113 if (standard_lookup (name, NULL, VAR_DOMAIN) != NULL)
5114 return 0;
5115
5116 /* Library-level function names start with "_ada_". See if function
5117 "_ada_" followed by NAME can be found. */
5118
5119 /* Do a quick check that NAME does not contain "__", since library-level
5120 functions names cannot contain "__" in them. */
5121 if (strstr (name, "__") != NULL)
5122 return 0;
5123
5124 std::string fun_name = string_printf ("_ada_%s", name);
5125
5126 return (standard_lookup (fun_name.c_str (), NULL, VAR_DOMAIN) == NULL);
5127 }
5128
5129 /* Return nonzero if SYM corresponds to a renaming entity that is
5130 not visible from FUNCTION_NAME. */
5131
5132 static int
5133 old_renaming_is_invisible (const struct symbol *sym, const char *function_name)
5134 {
5135 if (SYMBOL_CLASS (sym) != LOC_TYPEDEF)
5136 return 0;
5137
5138 std::string scope = xget_renaming_scope (SYMBOL_TYPE (sym));
5139
5140 /* If the rename has been defined in a package, then it is visible. */
5141 if (is_package_name (scope.c_str ()))
5142 return 0;
5143
5144 /* Check that the rename is in the current function scope by checking
5145 that its name starts with SCOPE. */
5146
5147 /* If the function name starts with "_ada_", it means that it is
5148 a library-level function. Strip this prefix before doing the
5149 comparison, as the encoding for the renaming does not contain
5150 this prefix. */
5151 if (startswith (function_name, "_ada_"))
5152 function_name += 5;
5153
5154 return !startswith (function_name, scope.c_str ());
5155 }
5156
5157 /* Remove entries from SYMS that corresponds to a renaming entity that
5158 is not visible from the function associated with CURRENT_BLOCK or
5159 that is superfluous due to the presence of more specific renaming
5160 information. Places surviving symbols in the initial entries of
5161 SYMS and returns the number of surviving symbols.
5162
5163 Rationale:
5164 First, in cases where an object renaming is implemented as a
5165 reference variable, GNAT may produce both the actual reference
5166 variable and the renaming encoding. In this case, we discard the
5167 latter.
5168
5169 Second, GNAT emits a type following a specified encoding for each renaming
5170 entity. Unfortunately, STABS currently does not support the definition
5171 of types that are local to a given lexical block, so all renamings types
5172 are emitted at library level. As a consequence, if an application
5173 contains two renaming entities using the same name, and a user tries to
5174 print the value of one of these entities, the result of the ada symbol
5175 lookup will also contain the wrong renaming type.
5176
5177 This function partially covers for this limitation by attempting to
5178 remove from the SYMS list renaming symbols that should be visible
5179 from CURRENT_BLOCK. However, there does not seem be a 100% reliable
5180 method with the current information available. The implementation
5181 below has a couple of limitations (FIXME: brobecker-2003-05-12):
5182
5183 - When the user tries to print a rename in a function while there
5184 is another rename entity defined in a package: Normally, the
5185 rename in the function has precedence over the rename in the
5186 package, so the latter should be removed from the list. This is
5187 currently not the case.
5188
5189 - This function will incorrectly remove valid renames if
5190 the CURRENT_BLOCK corresponds to a function which symbol name
5191 has been changed by an "Export" pragma. As a consequence,
5192 the user will be unable to print such rename entities. */
5193
5194 static int
5195 remove_irrelevant_renamings (std::vector<struct block_symbol> *syms,
5196 const struct block *current_block)
5197 {
5198 struct symbol *current_function;
5199 const char *current_function_name;
5200 int i;
5201 int is_new_style_renaming;
5202
5203 /* If there is both a renaming foo___XR... encoded as a variable and
5204 a simple variable foo in the same block, discard the latter.
5205 First, zero out such symbols, then compress. */
5206 is_new_style_renaming = 0;
5207 for (i = 0; i < syms->size (); i += 1)
5208 {
5209 struct symbol *sym = (*syms)[i].symbol;
5210 const struct block *block = (*syms)[i].block;
5211 const char *name;
5212 const char *suffix;
5213
5214 if (sym == NULL || SYMBOL_CLASS (sym) == LOC_TYPEDEF)
5215 continue;
5216 name = sym->linkage_name ();
5217 suffix = strstr (name, "___XR");
5218
5219 if (suffix != NULL)
5220 {
5221 int name_len = suffix - name;
5222 int j;
5223
5224 is_new_style_renaming = 1;
5225 for (j = 0; j < syms->size (); j += 1)
5226 if (i != j && (*syms)[j].symbol != NULL
5227 && strncmp (name, (*syms)[j].symbol->linkage_name (),
5228 name_len) == 0
5229 && block == (*syms)[j].block)
5230 (*syms)[j].symbol = NULL;
5231 }
5232 }
5233 if (is_new_style_renaming)
5234 {
5235 int j, k;
5236
5237 for (j = k = 0; j < syms->size (); j += 1)
5238 if ((*syms)[j].symbol != NULL)
5239 {
5240 (*syms)[k] = (*syms)[j];
5241 k += 1;
5242 }
5243 return k;
5244 }
5245
5246 /* Extract the function name associated to CURRENT_BLOCK.
5247 Abort if unable to do so. */
5248
5249 if (current_block == NULL)
5250 return syms->size ();
5251
5252 current_function = block_linkage_function (current_block);
5253 if (current_function == NULL)
5254 return syms->size ();
5255
5256 current_function_name = current_function->linkage_name ();
5257 if (current_function_name == NULL)
5258 return syms->size ();
5259
5260 /* Check each of the symbols, and remove it from the list if it is
5261 a type corresponding to a renaming that is out of the scope of
5262 the current block. */
5263
5264 i = 0;
5265 while (i < syms->size ())
5266 {
5267 if (ada_parse_renaming ((*syms)[i].symbol, NULL, NULL, NULL)
5268 == ADA_OBJECT_RENAMING
5269 && old_renaming_is_invisible ((*syms)[i].symbol,
5270 current_function_name))
5271 syms->erase (syms->begin () + i);
5272 else
5273 i += 1;
5274 }
5275
5276 return syms->size ();
5277 }
5278
5279 /* Add to OBSTACKP all symbols from BLOCK (and its super-blocks)
5280 whose name and domain match NAME and DOMAIN respectively.
5281 If no match was found, then extend the search to "enclosing"
5282 routines (in other words, if we're inside a nested function,
5283 search the symbols defined inside the enclosing functions).
5284 If WILD_MATCH_P is nonzero, perform the naming matching in
5285 "wild" mode (see function "wild_match" for more info).
5286
5287 Note: This function assumes that OBSTACKP has 0 (zero) element in it. */
5288
5289 static void
5290 ada_add_local_symbols (struct obstack *obstackp,
5291 const lookup_name_info &lookup_name,
5292 const struct block *block, domain_enum domain)
5293 {
5294 int block_depth = 0;
5295
5296 while (block != NULL)
5297 {
5298 block_depth += 1;
5299 ada_add_block_symbols (obstackp, block, lookup_name, domain, NULL);
5300
5301 /* If we found a non-function match, assume that's the one. */
5302 if (is_nonfunction (defns_collected (obstackp, 0),
5303 num_defns_collected (obstackp)))
5304 return;
5305
5306 block = BLOCK_SUPERBLOCK (block);
5307 }
5308
5309 /* If no luck so far, try to find NAME as a local symbol in some lexically
5310 enclosing subprogram. */
5311 if (num_defns_collected (obstackp) == 0 && block_depth > 2)
5312 add_symbols_from_enclosing_procs (obstackp, lookup_name, domain);
5313 }
5314
5315 /* An object of this type is used as the user_data argument when
5316 calling the map_matching_symbols method. */
5317
5318 struct match_data
5319 {
5320 struct objfile *objfile;
5321 struct obstack *obstackp;
5322 struct symbol *arg_sym;
5323 int found_sym;
5324 };
5325
5326 /* A callback for add_nonlocal_symbols that adds symbol, found in BSYM,
5327 to a list of symbols. DATA is a pointer to a struct match_data *
5328 containing the obstack that collects the symbol list, the file that SYM
5329 must come from, a flag indicating whether a non-argument symbol has
5330 been found in the current block, and the last argument symbol
5331 passed in SYM within the current block (if any). When SYM is null,
5332 marking the end of a block, the argument symbol is added if no
5333 other has been found. */
5334
5335 static bool
5336 aux_add_nonlocal_symbols (struct block_symbol *bsym,
5337 struct match_data *data)
5338 {
5339 const struct block *block = bsym->block;
5340 struct symbol *sym = bsym->symbol;
5341
5342 if (sym == NULL)
5343 {
5344 if (!data->found_sym && data->arg_sym != NULL)
5345 add_defn_to_vec (data->obstackp,
5346 fixup_symbol_section (data->arg_sym, data->objfile),
5347 block);
5348 data->found_sym = 0;
5349 data->arg_sym = NULL;
5350 }
5351 else
5352 {
5353 if (SYMBOL_CLASS (sym) == LOC_UNRESOLVED)
5354 return true;
5355 else if (SYMBOL_IS_ARGUMENT (sym))
5356 data->arg_sym = sym;
5357 else
5358 {
5359 data->found_sym = 1;
5360 add_defn_to_vec (data->obstackp,
5361 fixup_symbol_section (sym, data->objfile),
5362 block);
5363 }
5364 }
5365 return true;
5366 }
5367
5368 /* Helper for add_nonlocal_symbols. Find symbols in DOMAIN which are
5369 targeted by renamings matching LOOKUP_NAME in BLOCK. Add these
5370 symbols to OBSTACKP. Return whether we found such symbols. */
5371
5372 static int
5373 ada_add_block_renamings (struct obstack *obstackp,
5374 const struct block *block,
5375 const lookup_name_info &lookup_name,
5376 domain_enum domain)
5377 {
5378 struct using_direct *renaming;
5379 int defns_mark = num_defns_collected (obstackp);
5380
5381 symbol_name_matcher_ftype *name_match
5382 = ada_get_symbol_name_matcher (lookup_name);
5383
5384 for (renaming = block_using (block);
5385 renaming != NULL;
5386 renaming = renaming->next)
5387 {
5388 const char *r_name;
5389
5390 /* Avoid infinite recursions: skip this renaming if we are actually
5391 already traversing it.
5392
5393 Currently, symbol lookup in Ada don't use the namespace machinery from
5394 C++/Fortran support: skip namespace imports that use them. */
5395 if (renaming->searched
5396 || (renaming->import_src != NULL
5397 && renaming->import_src[0] != '\0')
5398 || (renaming->import_dest != NULL
5399 && renaming->import_dest[0] != '\0'))
5400 continue;
5401 renaming->searched = 1;
5402
5403 /* TODO: here, we perform another name-based symbol lookup, which can
5404 pull its own multiple overloads. In theory, we should be able to do
5405 better in this case since, in DWARF, DW_AT_import is a DIE reference,
5406 not a simple name. But in order to do this, we would need to enhance
5407 the DWARF reader to associate a symbol to this renaming, instead of a
5408 name. So, for now, we do something simpler: re-use the C++/Fortran
5409 namespace machinery. */
5410 r_name = (renaming->alias != NULL
5411 ? renaming->alias
5412 : renaming->declaration);
5413 if (name_match (r_name, lookup_name, NULL))
5414 {
5415 lookup_name_info decl_lookup_name (renaming->declaration,
5416 lookup_name.match_type ());
5417 ada_add_all_symbols (obstackp, block, decl_lookup_name, domain,
5418 1, NULL);
5419 }
5420 renaming->searched = 0;
5421 }
5422 return num_defns_collected (obstackp) != defns_mark;
5423 }
5424
5425 /* Implements compare_names, but only applying the comparision using
5426 the given CASING. */
5427
5428 static int
5429 compare_names_with_case (const char *string1, const char *string2,
5430 enum case_sensitivity casing)
5431 {
5432 while (*string1 != '\0' && *string2 != '\0')
5433 {
5434 char c1, c2;
5435
5436 if (isspace (*string1) || isspace (*string2))
5437 return strcmp_iw_ordered (string1, string2);
5438
5439 if (casing == case_sensitive_off)
5440 {
5441 c1 = tolower (*string1);
5442 c2 = tolower (*string2);
5443 }
5444 else
5445 {
5446 c1 = *string1;
5447 c2 = *string2;
5448 }
5449 if (c1 != c2)
5450 break;
5451
5452 string1 += 1;
5453 string2 += 1;
5454 }
5455
5456 switch (*string1)
5457 {
5458 case '(':
5459 return strcmp_iw_ordered (string1, string2);
5460 case '_':
5461 if (*string2 == '\0')
5462 {
5463 if (is_name_suffix (string1))
5464 return 0;
5465 else
5466 return 1;
5467 }
5468 /* FALLTHROUGH */
5469 default:
5470 if (*string2 == '(')
5471 return strcmp_iw_ordered (string1, string2);
5472 else
5473 {
5474 if (casing == case_sensitive_off)
5475 return tolower (*string1) - tolower (*string2);
5476 else
5477 return *string1 - *string2;
5478 }
5479 }
5480 }
5481
5482 /* Compare STRING1 to STRING2, with results as for strcmp.
5483 Compatible with strcmp_iw_ordered in that...
5484
5485 strcmp_iw_ordered (STRING1, STRING2) <= 0
5486
5487 ... implies...
5488
5489 compare_names (STRING1, STRING2) <= 0
5490
5491 (they may differ as to what symbols compare equal). */
5492
5493 static int
5494 compare_names (const char *string1, const char *string2)
5495 {
5496 int result;
5497
5498 /* Similar to what strcmp_iw_ordered does, we need to perform
5499 a case-insensitive comparison first, and only resort to
5500 a second, case-sensitive, comparison if the first one was
5501 not sufficient to differentiate the two strings. */
5502
5503 result = compare_names_with_case (string1, string2, case_sensitive_off);
5504 if (result == 0)
5505 result = compare_names_with_case (string1, string2, case_sensitive_on);
5506
5507 return result;
5508 }
5509
5510 /* Convenience function to get at the Ada encoded lookup name for
5511 LOOKUP_NAME, as a C string. */
5512
5513 static const char *
5514 ada_lookup_name (const lookup_name_info &lookup_name)
5515 {
5516 return lookup_name.ada ().lookup_name ().c_str ();
5517 }
5518
5519 /* Add to OBSTACKP all non-local symbols whose name and domain match
5520 LOOKUP_NAME and DOMAIN respectively. The search is performed on
5521 GLOBAL_BLOCK symbols if GLOBAL is non-zero, or on STATIC_BLOCK
5522 symbols otherwise. */
5523
5524 static void
5525 add_nonlocal_symbols (struct obstack *obstackp,
5526 const lookup_name_info &lookup_name,
5527 domain_enum domain, int global)
5528 {
5529 struct match_data data;
5530
5531 memset (&data, 0, sizeof data);
5532 data.obstackp = obstackp;
5533
5534 bool is_wild_match = lookup_name.ada ().wild_match_p ();
5535
5536 auto callback = [&] (struct block_symbol *bsym)
5537 {
5538 return aux_add_nonlocal_symbols (bsym, &data);
5539 };
5540
5541 for (objfile *objfile : current_program_space->objfiles ())
5542 {
5543 data.objfile = objfile;
5544
5545 objfile->sf->qf->map_matching_symbols (objfile, lookup_name,
5546 domain, global, callback,
5547 (is_wild_match
5548 ? NULL : compare_names));
5549
5550 for (compunit_symtab *cu : objfile->compunits ())
5551 {
5552 const struct block *global_block
5553 = BLOCKVECTOR_BLOCK (COMPUNIT_BLOCKVECTOR (cu), GLOBAL_BLOCK);
5554
5555 if (ada_add_block_renamings (obstackp, global_block, lookup_name,
5556 domain))
5557 data.found_sym = 1;
5558 }
5559 }
5560
5561 if (num_defns_collected (obstackp) == 0 && global && !is_wild_match)
5562 {
5563 const char *name = ada_lookup_name (lookup_name);
5564 std::string bracket_name = std::string ("<_ada_") + name + '>';
5565 lookup_name_info name1 (bracket_name, symbol_name_match_type::FULL);
5566
5567 for (objfile *objfile : current_program_space->objfiles ())
5568 {
5569 data.objfile = objfile;
5570 objfile->sf->qf->map_matching_symbols (objfile, name1,
5571 domain, global, callback,
5572 compare_names);
5573 }
5574 }
5575 }
5576
5577 /* Find symbols in DOMAIN matching LOOKUP_NAME, in BLOCK and, if
5578 FULL_SEARCH is non-zero, enclosing scope and in global scopes,
5579 returning the number of matches. Add these to OBSTACKP.
5580
5581 When FULL_SEARCH is non-zero, any non-function/non-enumeral
5582 symbol match within the nest of blocks whose innermost member is BLOCK,
5583 is the one match returned (no other matches in that or
5584 enclosing blocks is returned). If there are any matches in or
5585 surrounding BLOCK, then these alone are returned.
5586
5587 Names prefixed with "standard__" are handled specially:
5588 "standard__" is first stripped off (by the lookup_name
5589 constructor), and only static and global symbols are searched.
5590
5591 If MADE_GLOBAL_LOOKUP_P is non-null, set it before return to whether we had
5592 to lookup global symbols. */
5593
5594 static void
5595 ada_add_all_symbols (struct obstack *obstackp,
5596 const struct block *block,
5597 const lookup_name_info &lookup_name,
5598 domain_enum domain,
5599 int full_search,
5600 int *made_global_lookup_p)
5601 {
5602 struct symbol *sym;
5603
5604 if (made_global_lookup_p)
5605 *made_global_lookup_p = 0;
5606
5607 /* Special case: If the user specifies a symbol name inside package
5608 Standard, do a non-wild matching of the symbol name without
5609 the "standard__" prefix. This was primarily introduced in order
5610 to allow the user to specifically access the standard exceptions
5611 using, for instance, Standard.Constraint_Error when Constraint_Error
5612 is ambiguous (due to the user defining its own Constraint_Error
5613 entity inside its program). */
5614 if (lookup_name.ada ().standard_p ())
5615 block = NULL;
5616
5617 /* Check the non-global symbols. If we have ANY match, then we're done. */
5618
5619 if (block != NULL)
5620 {
5621 if (full_search)
5622 ada_add_local_symbols (obstackp, lookup_name, block, domain);
5623 else
5624 {
5625 /* In the !full_search case we're are being called by
5626 iterate_over_symbols, and we don't want to search
5627 superblocks. */
5628 ada_add_block_symbols (obstackp, block, lookup_name, domain, NULL);
5629 }
5630 if (num_defns_collected (obstackp) > 0 || !full_search)
5631 return;
5632 }
5633
5634 /* No non-global symbols found. Check our cache to see if we have
5635 already performed this search before. If we have, then return
5636 the same result. */
5637
5638 if (lookup_cached_symbol (ada_lookup_name (lookup_name),
5639 domain, &sym, &block))
5640 {
5641 if (sym != NULL)
5642 add_defn_to_vec (obstackp, sym, block);
5643 return;
5644 }
5645
5646 if (made_global_lookup_p)
5647 *made_global_lookup_p = 1;
5648
5649 /* Search symbols from all global blocks. */
5650
5651 add_nonlocal_symbols (obstackp, lookup_name, domain, 1);
5652
5653 /* Now add symbols from all per-file blocks if we've gotten no hits
5654 (not strictly correct, but perhaps better than an error). */
5655
5656 if (num_defns_collected (obstackp) == 0)
5657 add_nonlocal_symbols (obstackp, lookup_name, domain, 0);
5658 }
5659
5660 /* Find symbols in DOMAIN matching LOOKUP_NAME, in BLOCK and, if FULL_SEARCH
5661 is non-zero, enclosing scope and in global scopes, returning the number of
5662 matches.
5663 Fills *RESULTS with (SYM,BLOCK) tuples, indicating the symbols
5664 found and the blocks and symbol tables (if any) in which they were
5665 found.
5666
5667 When full_search is non-zero, any non-function/non-enumeral
5668 symbol match within the nest of blocks whose innermost member is BLOCK,
5669 is the one match returned (no other matches in that or
5670 enclosing blocks is returned). If there are any matches in or
5671 surrounding BLOCK, then these alone are returned.
5672
5673 Names prefixed with "standard__" are handled specially: "standard__"
5674 is first stripped off, and only static and global symbols are searched. */
5675
5676 static int
5677 ada_lookup_symbol_list_worker (const lookup_name_info &lookup_name,
5678 const struct block *block,
5679 domain_enum domain,
5680 std::vector<struct block_symbol> *results,
5681 int full_search)
5682 {
5683 int syms_from_global_search;
5684 int ndefns;
5685 auto_obstack obstack;
5686
5687 ada_add_all_symbols (&obstack, block, lookup_name,
5688 domain, full_search, &syms_from_global_search);
5689
5690 ndefns = num_defns_collected (&obstack);
5691
5692 struct block_symbol *base = defns_collected (&obstack, 1);
5693 for (int i = 0; i < ndefns; ++i)
5694 results->push_back (base[i]);
5695
5696 ndefns = remove_extra_symbols (results);
5697
5698 if (ndefns == 0 && full_search && syms_from_global_search)
5699 cache_symbol (ada_lookup_name (lookup_name), domain, NULL, NULL);
5700
5701 if (ndefns == 1 && full_search && syms_from_global_search)
5702 cache_symbol (ada_lookup_name (lookup_name), domain,
5703 (*results)[0].symbol, (*results)[0].block);
5704
5705 ndefns = remove_irrelevant_renamings (results, block);
5706
5707 return ndefns;
5708 }
5709
5710 /* Find symbols in DOMAIN matching NAME, in BLOCK and enclosing scope and
5711 in global scopes, returning the number of matches, and filling *RESULTS
5712 with (SYM,BLOCK) tuples.
5713
5714 See ada_lookup_symbol_list_worker for further details. */
5715
5716 int
5717 ada_lookup_symbol_list (const char *name, const struct block *block,
5718 domain_enum domain,
5719 std::vector<struct block_symbol> *results)
5720 {
5721 symbol_name_match_type name_match_type = name_match_type_from_name (name);
5722 lookup_name_info lookup_name (name, name_match_type);
5723
5724 return ada_lookup_symbol_list_worker (lookup_name, block, domain, results, 1);
5725 }
5726
5727 /* The result is as for ada_lookup_symbol_list with FULL_SEARCH set
5728 to 1, but choosing the first symbol found if there are multiple
5729 choices.
5730
5731 The result is stored in *INFO, which must be non-NULL.
5732 If no match is found, INFO->SYM is set to NULL. */
5733
5734 void
5735 ada_lookup_encoded_symbol (const char *name, const struct block *block,
5736 domain_enum domain,
5737 struct block_symbol *info)
5738 {
5739 /* Since we already have an encoded name, wrap it in '<>' to force a
5740 verbatim match. Otherwise, if the name happens to not look like
5741 an encoded name (because it doesn't include a "__"),
5742 ada_lookup_name_info would re-encode/fold it again, and that
5743 would e.g., incorrectly lowercase object renaming names like
5744 "R28b" -> "r28b". */
5745 std::string verbatim = std::string ("<") + name + '>';
5746
5747 gdb_assert (info != NULL);
5748 *info = ada_lookup_symbol (verbatim.c_str (), block, domain);
5749 }
5750
5751 /* Return a symbol in DOMAIN matching NAME, in BLOCK0 and enclosing
5752 scope and in global scopes, or NULL if none. NAME is folded and
5753 encoded first. Otherwise, the result is as for ada_lookup_symbol_list,
5754 choosing the first symbol if there are multiple choices. */
5755
5756 struct block_symbol
5757 ada_lookup_symbol (const char *name, const struct block *block0,
5758 domain_enum domain)
5759 {
5760 std::vector<struct block_symbol> candidates;
5761 int n_candidates;
5762
5763 n_candidates = ada_lookup_symbol_list (name, block0, domain, &candidates);
5764
5765 if (n_candidates == 0)
5766 return {};
5767
5768 block_symbol info = candidates[0];
5769 info.symbol = fixup_symbol_section (info.symbol, NULL);
5770 return info;
5771 }
5772
5773
5774 /* True iff STR is a possible encoded suffix of a normal Ada name
5775 that is to be ignored for matching purposes. Suffixes of parallel
5776 names (e.g., XVE) are not included here. Currently, the possible suffixes
5777 are given by any of the regular expressions:
5778
5779 [.$][0-9]+ [nested subprogram suffix, on platforms such as GNU/Linux]
5780 ___[0-9]+ [nested subprogram suffix, on platforms such as HP/UX]
5781 TKB [subprogram suffix for task bodies]
5782 _E[0-9]+[bs]$ [protected object entry suffixes]
5783 (X[nb]*)?((\$|__)[0-9](_?[0-9]+)|___(JM|LJM|X([FDBUP].*|R[^T]?)))?$
5784
5785 Also, any leading "__[0-9]+" sequence is skipped before the suffix
5786 match is performed. This sequence is used to differentiate homonyms,
5787 is an optional part of a valid name suffix. */
5788
5789 static int
5790 is_name_suffix (const char *str)
5791 {
5792 int k;
5793 const char *matching;
5794 const int len = strlen (str);
5795
5796 /* Skip optional leading __[0-9]+. */
5797
5798 if (len > 3 && str[0] == '_' && str[1] == '_' && isdigit (str[2]))
5799 {
5800 str += 3;
5801 while (isdigit (str[0]))
5802 str += 1;
5803 }
5804
5805 /* [.$][0-9]+ */
5806
5807 if (str[0] == '.' || str[0] == '$')
5808 {
5809 matching = str + 1;
5810 while (isdigit (matching[0]))
5811 matching += 1;
5812 if (matching[0] == '\0')
5813 return 1;
5814 }
5815
5816 /* ___[0-9]+ */
5817
5818 if (len > 3 && str[0] == '_' && str[1] == '_' && str[2] == '_')
5819 {
5820 matching = str + 3;
5821 while (isdigit (matching[0]))
5822 matching += 1;
5823 if (matching[0] == '\0')
5824 return 1;
5825 }
5826
5827 /* "TKB" suffixes are used for subprograms implementing task bodies. */
5828
5829 if (strcmp (str, "TKB") == 0)
5830 return 1;
5831
5832 #if 0
5833 /* FIXME: brobecker/2005-09-23: Protected Object subprograms end
5834 with a N at the end. Unfortunately, the compiler uses the same
5835 convention for other internal types it creates. So treating
5836 all entity names that end with an "N" as a name suffix causes
5837 some regressions. For instance, consider the case of an enumerated
5838 type. To support the 'Image attribute, it creates an array whose
5839 name ends with N.
5840 Having a single character like this as a suffix carrying some
5841 information is a bit risky. Perhaps we should change the encoding
5842 to be something like "_N" instead. In the meantime, do not do
5843 the following check. */
5844 /* Protected Object Subprograms */
5845 if (len == 1 && str [0] == 'N')
5846 return 1;
5847 #endif
5848
5849 /* _E[0-9]+[bs]$ */
5850 if (len > 3 && str[0] == '_' && str [1] == 'E' && isdigit (str[2]))
5851 {
5852 matching = str + 3;
5853 while (isdigit (matching[0]))
5854 matching += 1;
5855 if ((matching[0] == 'b' || matching[0] == 's')
5856 && matching [1] == '\0')
5857 return 1;
5858 }
5859
5860 /* ??? We should not modify STR directly, as we are doing below. This
5861 is fine in this case, but may become problematic later if we find
5862 that this alternative did not work, and want to try matching
5863 another one from the begining of STR. Since we modified it, we
5864 won't be able to find the begining of the string anymore! */
5865 if (str[0] == 'X')
5866 {
5867 str += 1;
5868 while (str[0] != '_' && str[0] != '\0')
5869 {
5870 if (str[0] != 'n' && str[0] != 'b')
5871 return 0;
5872 str += 1;
5873 }
5874 }
5875
5876 if (str[0] == '\000')
5877 return 1;
5878
5879 if (str[0] == '_')
5880 {
5881 if (str[1] != '_' || str[2] == '\000')
5882 return 0;
5883 if (str[2] == '_')
5884 {
5885 if (strcmp (str + 3, "JM") == 0)
5886 return 1;
5887 /* FIXME: brobecker/2004-09-30: GNAT will soon stop using
5888 the LJM suffix in favor of the JM one. But we will
5889 still accept LJM as a valid suffix for a reasonable
5890 amount of time, just to allow ourselves to debug programs
5891 compiled using an older version of GNAT. */
5892 if (strcmp (str + 3, "LJM") == 0)
5893 return 1;
5894 if (str[3] != 'X')
5895 return 0;
5896 if (str[4] == 'F' || str[4] == 'D' || str[4] == 'B'
5897 || str[4] == 'U' || str[4] == 'P')
5898 return 1;
5899 if (str[4] == 'R' && str[5] != 'T')
5900 return 1;
5901 return 0;
5902 }
5903 if (!isdigit (str[2]))
5904 return 0;
5905 for (k = 3; str[k] != '\0'; k += 1)
5906 if (!isdigit (str[k]) && str[k] != '_')
5907 return 0;
5908 return 1;
5909 }
5910 if (str[0] == '$' && isdigit (str[1]))
5911 {
5912 for (k = 2; str[k] != '\0'; k += 1)
5913 if (!isdigit (str[k]) && str[k] != '_')
5914 return 0;
5915 return 1;
5916 }
5917 return 0;
5918 }
5919
5920 /* Return non-zero if the string starting at NAME and ending before
5921 NAME_END contains no capital letters. */
5922
5923 static int
5924 is_valid_name_for_wild_match (const char *name0)
5925 {
5926 std::string decoded_name = ada_decode (name0);
5927 int i;
5928
5929 /* If the decoded name starts with an angle bracket, it means that
5930 NAME0 does not follow the GNAT encoding format. It should then
5931 not be allowed as a possible wild match. */
5932 if (decoded_name[0] == '<')
5933 return 0;
5934
5935 for (i=0; decoded_name[i] != '\0'; i++)
5936 if (isalpha (decoded_name[i]) && !islower (decoded_name[i]))
5937 return 0;
5938
5939 return 1;
5940 }
5941
5942 /* Advance *NAMEP to next occurrence of TARGET0 in the string NAME0
5943 that could start a simple name. Assumes that *NAMEP points into
5944 the string beginning at NAME0. */
5945
5946 static int
5947 advance_wild_match (const char **namep, const char *name0, int target0)
5948 {
5949 const char *name = *namep;
5950
5951 while (1)
5952 {
5953 int t0, t1;
5954
5955 t0 = *name;
5956 if (t0 == '_')
5957 {
5958 t1 = name[1];
5959 if ((t1 >= 'a' && t1 <= 'z') || (t1 >= '0' && t1 <= '9'))
5960 {
5961 name += 1;
5962 if (name == name0 + 5 && startswith (name0, "_ada"))
5963 break;
5964 else
5965 name += 1;
5966 }
5967 else if (t1 == '_' && ((name[2] >= 'a' && name[2] <= 'z')
5968 || name[2] == target0))
5969 {
5970 name += 2;
5971 break;
5972 }
5973 else
5974 return 0;
5975 }
5976 else if ((t0 >= 'a' && t0 <= 'z') || (t0 >= '0' && t0 <= '9'))
5977 name += 1;
5978 else
5979 return 0;
5980 }
5981
5982 *namep = name;
5983 return 1;
5984 }
5985
5986 /* Return true iff NAME encodes a name of the form prefix.PATN.
5987 Ignores any informational suffixes of NAME (i.e., for which
5988 is_name_suffix is true). Assumes that PATN is a lower-cased Ada
5989 simple name. */
5990
5991 static bool
5992 wild_match (const char *name, const char *patn)
5993 {
5994 const char *p;
5995 const char *name0 = name;
5996
5997 while (1)
5998 {
5999 const char *match = name;
6000
6001 if (*name == *patn)
6002 {
6003 for (name += 1, p = patn + 1; *p != '\0'; name += 1, p += 1)
6004 if (*p != *name)
6005 break;
6006 if (*p == '\0' && is_name_suffix (name))
6007 return match == name0 || is_valid_name_for_wild_match (name0);
6008
6009 if (name[-1] == '_')
6010 name -= 1;
6011 }
6012 if (!advance_wild_match (&name, name0, *patn))
6013 return false;
6014 }
6015 }
6016
6017 /* Returns true iff symbol name SYM_NAME matches SEARCH_NAME, ignoring
6018 any trailing suffixes that encode debugging information or leading
6019 _ada_ on SYM_NAME (see is_name_suffix commentary for the debugging
6020 information that is ignored). */
6021
6022 static bool
6023 full_match (const char *sym_name, const char *search_name)
6024 {
6025 size_t search_name_len = strlen (search_name);
6026
6027 if (strncmp (sym_name, search_name, search_name_len) == 0
6028 && is_name_suffix (sym_name + search_name_len))
6029 return true;
6030
6031 if (startswith (sym_name, "_ada_")
6032 && strncmp (sym_name + 5, search_name, search_name_len) == 0
6033 && is_name_suffix (sym_name + search_name_len + 5))
6034 return true;
6035
6036 return false;
6037 }
6038
6039 /* Add symbols from BLOCK matching LOOKUP_NAME in DOMAIN to vector
6040 *defn_symbols, updating the list of symbols in OBSTACKP (if
6041 necessary). OBJFILE is the section containing BLOCK. */
6042
6043 static void
6044 ada_add_block_symbols (struct obstack *obstackp,
6045 const struct block *block,
6046 const lookup_name_info &lookup_name,
6047 domain_enum domain, struct objfile *objfile)
6048 {
6049 struct block_iterator iter;
6050 /* A matching argument symbol, if any. */
6051 struct symbol *arg_sym;
6052 /* Set true when we find a matching non-argument symbol. */
6053 int found_sym;
6054 struct symbol *sym;
6055
6056 arg_sym = NULL;
6057 found_sym = 0;
6058 for (sym = block_iter_match_first (block, lookup_name, &iter);
6059 sym != NULL;
6060 sym = block_iter_match_next (lookup_name, &iter))
6061 {
6062 if (symbol_matches_domain (sym->language (), SYMBOL_DOMAIN (sym), domain))
6063 {
6064 if (SYMBOL_CLASS (sym) != LOC_UNRESOLVED)
6065 {
6066 if (SYMBOL_IS_ARGUMENT (sym))
6067 arg_sym = sym;
6068 else
6069 {
6070 found_sym = 1;
6071 add_defn_to_vec (obstackp,
6072 fixup_symbol_section (sym, objfile),
6073 block);
6074 }
6075 }
6076 }
6077 }
6078
6079 /* Handle renamings. */
6080
6081 if (ada_add_block_renamings (obstackp, block, lookup_name, domain))
6082 found_sym = 1;
6083
6084 if (!found_sym && arg_sym != NULL)
6085 {
6086 add_defn_to_vec (obstackp,
6087 fixup_symbol_section (arg_sym, objfile),
6088 block);
6089 }
6090
6091 if (!lookup_name.ada ().wild_match_p ())
6092 {
6093 arg_sym = NULL;
6094 found_sym = 0;
6095 const std::string &ada_lookup_name = lookup_name.ada ().lookup_name ();
6096 const char *name = ada_lookup_name.c_str ();
6097 size_t name_len = ada_lookup_name.size ();
6098
6099 ALL_BLOCK_SYMBOLS (block, iter, sym)
6100 {
6101 if (symbol_matches_domain (sym->language (),
6102 SYMBOL_DOMAIN (sym), domain))
6103 {
6104 int cmp;
6105
6106 cmp = (int) '_' - (int) sym->linkage_name ()[0];
6107 if (cmp == 0)
6108 {
6109 cmp = !startswith (sym->linkage_name (), "_ada_");
6110 if (cmp == 0)
6111 cmp = strncmp (name, sym->linkage_name () + 5,
6112 name_len);
6113 }
6114
6115 if (cmp == 0
6116 && is_name_suffix (sym->linkage_name () + name_len + 5))
6117 {
6118 if (SYMBOL_CLASS (sym) != LOC_UNRESOLVED)
6119 {
6120 if (SYMBOL_IS_ARGUMENT (sym))
6121 arg_sym = sym;
6122 else
6123 {
6124 found_sym = 1;
6125 add_defn_to_vec (obstackp,
6126 fixup_symbol_section (sym, objfile),
6127 block);
6128 }
6129 }
6130 }
6131 }
6132 }
6133
6134 /* NOTE: This really shouldn't be needed for _ada_ symbols.
6135 They aren't parameters, right? */
6136 if (!found_sym && arg_sym != NULL)
6137 {
6138 add_defn_to_vec (obstackp,
6139 fixup_symbol_section (arg_sym, objfile),
6140 block);
6141 }
6142 }
6143 }
6144 \f
6145
6146 /* Symbol Completion */
6147
6148 /* See symtab.h. */
6149
6150 bool
6151 ada_lookup_name_info::matches
6152 (const char *sym_name,
6153 symbol_name_match_type match_type,
6154 completion_match_result *comp_match_res) const
6155 {
6156 bool match = false;
6157 const char *text = m_encoded_name.c_str ();
6158 size_t text_len = m_encoded_name.size ();
6159
6160 /* First, test against the fully qualified name of the symbol. */
6161
6162 if (strncmp (sym_name, text, text_len) == 0)
6163 match = true;
6164
6165 std::string decoded_name = ada_decode (sym_name);
6166 if (match && !m_encoded_p)
6167 {
6168 /* One needed check before declaring a positive match is to verify
6169 that iff we are doing a verbatim match, the decoded version
6170 of the symbol name starts with '<'. Otherwise, this symbol name
6171 is not a suitable completion. */
6172
6173 bool has_angle_bracket = (decoded_name[0] == '<');
6174 match = (has_angle_bracket == m_verbatim_p);
6175 }
6176
6177 if (match && !m_verbatim_p)
6178 {
6179 /* When doing non-verbatim match, another check that needs to
6180 be done is to verify that the potentially matching symbol name
6181 does not include capital letters, because the ada-mode would
6182 not be able to understand these symbol names without the
6183 angle bracket notation. */
6184 const char *tmp;
6185
6186 for (tmp = sym_name; *tmp != '\0' && !isupper (*tmp); tmp++);
6187 if (*tmp != '\0')
6188 match = false;
6189 }
6190
6191 /* Second: Try wild matching... */
6192
6193 if (!match && m_wild_match_p)
6194 {
6195 /* Since we are doing wild matching, this means that TEXT
6196 may represent an unqualified symbol name. We therefore must
6197 also compare TEXT against the unqualified name of the symbol. */
6198 sym_name = ada_unqualified_name (decoded_name.c_str ());
6199
6200 if (strncmp (sym_name, text, text_len) == 0)
6201 match = true;
6202 }
6203
6204 /* Finally: If we found a match, prepare the result to return. */
6205
6206 if (!match)
6207 return false;
6208
6209 if (comp_match_res != NULL)
6210 {
6211 std::string &match_str = comp_match_res->match.storage ();
6212
6213 if (!m_encoded_p)
6214 match_str = ada_decode (sym_name);
6215 else
6216 {
6217 if (m_verbatim_p)
6218 match_str = add_angle_brackets (sym_name);
6219 else
6220 match_str = sym_name;
6221
6222 }
6223
6224 comp_match_res->set_match (match_str.c_str ());
6225 }
6226
6227 return true;
6228 }
6229
6230 /* Field Access */
6231
6232 /* Return non-zero if TYPE is a pointer to the GNAT dispatch table used
6233 for tagged types. */
6234
6235 static int
6236 ada_is_dispatch_table_ptr_type (struct type *type)
6237 {
6238 const char *name;
6239
6240 if (type->code () != TYPE_CODE_PTR)
6241 return 0;
6242
6243 name = TYPE_TARGET_TYPE (type)->name ();
6244 if (name == NULL)
6245 return 0;
6246
6247 return (strcmp (name, "ada__tags__dispatch_table") == 0);
6248 }
6249
6250 /* Return non-zero if TYPE is an interface tag. */
6251
6252 static int
6253 ada_is_interface_tag (struct type *type)
6254 {
6255 const char *name = type->name ();
6256
6257 if (name == NULL)
6258 return 0;
6259
6260 return (strcmp (name, "ada__tags__interface_tag") == 0);
6261 }
6262
6263 /* True if field number FIELD_NUM in struct or union type TYPE is supposed
6264 to be invisible to users. */
6265
6266 int
6267 ada_is_ignored_field (struct type *type, int field_num)
6268 {
6269 if (field_num < 0 || field_num > type->num_fields ())
6270 return 1;
6271
6272 /* Check the name of that field. */
6273 {
6274 const char *name = TYPE_FIELD_NAME (type, field_num);
6275
6276 /* Anonymous field names should not be printed.
6277 brobecker/2007-02-20: I don't think this can actually happen
6278 but we don't want to print the value of anonymous fields anyway. */
6279 if (name == NULL)
6280 return 1;
6281
6282 /* Normally, fields whose name start with an underscore ("_")
6283 are fields that have been internally generated by the compiler,
6284 and thus should not be printed. The "_parent" field is special,
6285 however: This is a field internally generated by the compiler
6286 for tagged types, and it contains the components inherited from
6287 the parent type. This field should not be printed as is, but
6288 should not be ignored either. */
6289 if (name[0] == '_' && !startswith (name, "_parent"))
6290 return 1;
6291 }
6292
6293 /* If this is the dispatch table of a tagged type or an interface tag,
6294 then ignore. */
6295 if (ada_is_tagged_type (type, 1)
6296 && (ada_is_dispatch_table_ptr_type (type->field (field_num).type ())
6297 || ada_is_interface_tag (type->field (field_num).type ())))
6298 return 1;
6299
6300 /* Not a special field, so it should not be ignored. */
6301 return 0;
6302 }
6303
6304 /* True iff TYPE has a tag field. If REFOK, then TYPE may also be a
6305 pointer or reference type whose ultimate target has a tag field. */
6306
6307 int
6308 ada_is_tagged_type (struct type *type, int refok)
6309 {
6310 return (ada_lookup_struct_elt_type (type, "_tag", refok, 1) != NULL);
6311 }
6312
6313 /* True iff TYPE represents the type of X'Tag */
6314
6315 int
6316 ada_is_tag_type (struct type *type)
6317 {
6318 type = ada_check_typedef (type);
6319
6320 if (type == NULL || type->code () != TYPE_CODE_PTR)
6321 return 0;
6322 else
6323 {
6324 const char *name = ada_type_name (TYPE_TARGET_TYPE (type));
6325
6326 return (name != NULL
6327 && strcmp (name, "ada__tags__dispatch_table") == 0);
6328 }
6329 }
6330
6331 /* The type of the tag on VAL. */
6332
6333 static struct type *
6334 ada_tag_type (struct value *val)
6335 {
6336 return ada_lookup_struct_elt_type (value_type (val), "_tag", 1, 0);
6337 }
6338
6339 /* Return 1 if TAG follows the old scheme for Ada tags (used for Ada 95,
6340 retired at Ada 05). */
6341
6342 static int
6343 is_ada95_tag (struct value *tag)
6344 {
6345 return ada_value_struct_elt (tag, "tsd", 1) != NULL;
6346 }
6347
6348 /* The value of the tag on VAL. */
6349
6350 static struct value *
6351 ada_value_tag (struct value *val)
6352 {
6353 return ada_value_struct_elt (val, "_tag", 0);
6354 }
6355
6356 /* The value of the tag on the object of type TYPE whose contents are
6357 saved at VALADDR, if it is non-null, or is at memory address
6358 ADDRESS. */
6359
6360 static struct value *
6361 value_tag_from_contents_and_address (struct type *type,
6362 const gdb_byte *valaddr,
6363 CORE_ADDR address)
6364 {
6365 int tag_byte_offset;
6366 struct type *tag_type;
6367
6368 if (find_struct_field ("_tag", type, 0, &tag_type, &tag_byte_offset,
6369 NULL, NULL, NULL))
6370 {
6371 const gdb_byte *valaddr1 = ((valaddr == NULL)
6372 ? NULL
6373 : valaddr + tag_byte_offset);
6374 CORE_ADDR address1 = (address == 0) ? 0 : address + tag_byte_offset;
6375
6376 return value_from_contents_and_address (tag_type, valaddr1, address1);
6377 }
6378 return NULL;
6379 }
6380
6381 static struct type *
6382 type_from_tag (struct value *tag)
6383 {
6384 gdb::unique_xmalloc_ptr<char> type_name = ada_tag_name (tag);
6385
6386 if (type_name != NULL)
6387 return ada_find_any_type (ada_encode (type_name.get ()));
6388 return NULL;
6389 }
6390
6391 /* Given a value OBJ of a tagged type, return a value of this
6392 type at the base address of the object. The base address, as
6393 defined in Ada.Tags, it is the address of the primary tag of
6394 the object, and therefore where the field values of its full
6395 view can be fetched. */
6396
6397 struct value *
6398 ada_tag_value_at_base_address (struct value *obj)
6399 {
6400 struct value *val;
6401 LONGEST offset_to_top = 0;
6402 struct type *ptr_type, *obj_type;
6403 struct value *tag;
6404 CORE_ADDR base_address;
6405
6406 obj_type = value_type (obj);
6407
6408 /* It is the responsability of the caller to deref pointers. */
6409
6410 if (obj_type->code () == TYPE_CODE_PTR || obj_type->code () == TYPE_CODE_REF)
6411 return obj;
6412
6413 tag = ada_value_tag (obj);
6414 if (!tag)
6415 return obj;
6416
6417 /* Base addresses only appeared with Ada 05 and multiple inheritance. */
6418
6419 if (is_ada95_tag (tag))
6420 return obj;
6421
6422 ptr_type = language_lookup_primitive_type
6423 (language_def (language_ada), target_gdbarch(), "storage_offset");
6424 ptr_type = lookup_pointer_type (ptr_type);
6425 val = value_cast (ptr_type, tag);
6426 if (!val)
6427 return obj;
6428
6429 /* It is perfectly possible that an exception be raised while
6430 trying to determine the base address, just like for the tag;
6431 see ada_tag_name for more details. We do not print the error
6432 message for the same reason. */
6433
6434 try
6435 {
6436 offset_to_top = value_as_long (value_ind (value_ptradd (val, -2)));
6437 }
6438
6439 catch (const gdb_exception_error &e)
6440 {
6441 return obj;
6442 }
6443
6444 /* If offset is null, nothing to do. */
6445
6446 if (offset_to_top == 0)
6447 return obj;
6448
6449 /* -1 is a special case in Ada.Tags; however, what should be done
6450 is not quite clear from the documentation. So do nothing for
6451 now. */
6452
6453 if (offset_to_top == -1)
6454 return obj;
6455
6456 /* OFFSET_TO_TOP used to be a positive value to be subtracted
6457 from the base address. This was however incompatible with
6458 C++ dispatch table: C++ uses a *negative* value to *add*
6459 to the base address. Ada's convention has therefore been
6460 changed in GNAT 19.0w 20171023: since then, C++ and Ada
6461 use the same convention. Here, we support both cases by
6462 checking the sign of OFFSET_TO_TOP. */
6463
6464 if (offset_to_top > 0)
6465 offset_to_top = -offset_to_top;
6466
6467 base_address = value_address (obj) + offset_to_top;
6468 tag = value_tag_from_contents_and_address (obj_type, NULL, base_address);
6469
6470 /* Make sure that we have a proper tag at the new address.
6471 Otherwise, offset_to_top is bogus (which can happen when
6472 the object is not initialized yet). */
6473
6474 if (!tag)
6475 return obj;
6476
6477 obj_type = type_from_tag (tag);
6478
6479 if (!obj_type)
6480 return obj;
6481
6482 return value_from_contents_and_address (obj_type, NULL, base_address);
6483 }
6484
6485 /* Return the "ada__tags__type_specific_data" type. */
6486
6487 static struct type *
6488 ada_get_tsd_type (struct inferior *inf)
6489 {
6490 struct ada_inferior_data *data = get_ada_inferior_data (inf);
6491
6492 if (data->tsd_type == 0)
6493 data->tsd_type = ada_find_any_type ("ada__tags__type_specific_data");
6494 return data->tsd_type;
6495 }
6496
6497 /* Return the TSD (type-specific data) associated to the given TAG.
6498 TAG is assumed to be the tag of a tagged-type entity.
6499
6500 May return NULL if we are unable to get the TSD. */
6501
6502 static struct value *
6503 ada_get_tsd_from_tag (struct value *tag)
6504 {
6505 struct value *val;
6506 struct type *type;
6507
6508 /* First option: The TSD is simply stored as a field of our TAG.
6509 Only older versions of GNAT would use this format, but we have
6510 to test it first, because there are no visible markers for
6511 the current approach except the absence of that field. */
6512
6513 val = ada_value_struct_elt (tag, "tsd", 1);
6514 if (val)
6515 return val;
6516
6517 /* Try the second representation for the dispatch table (in which
6518 there is no explicit 'tsd' field in the referent of the tag pointer,
6519 and instead the tsd pointer is stored just before the dispatch
6520 table. */
6521
6522 type = ada_get_tsd_type (current_inferior());
6523 if (type == NULL)
6524 return NULL;
6525 type = lookup_pointer_type (lookup_pointer_type (type));
6526 val = value_cast (type, tag);
6527 if (val == NULL)
6528 return NULL;
6529 return value_ind (value_ptradd (val, -1));
6530 }
6531
6532 /* Given the TSD of a tag (type-specific data), return a string
6533 containing the name of the associated type.
6534
6535 May return NULL if we are unable to determine the tag name. */
6536
6537 static gdb::unique_xmalloc_ptr<char>
6538 ada_tag_name_from_tsd (struct value *tsd)
6539 {
6540 char *p;
6541 struct value *val;
6542
6543 val = ada_value_struct_elt (tsd, "expanded_name", 1);
6544 if (val == NULL)
6545 return NULL;
6546 gdb::unique_xmalloc_ptr<char> buffer
6547 = target_read_string (value_as_address (val), INT_MAX);
6548 if (buffer == nullptr)
6549 return nullptr;
6550
6551 for (p = buffer.get (); *p != '\0'; ++p)
6552 {
6553 if (isalpha (*p))
6554 *p = tolower (*p);
6555 }
6556
6557 return buffer;
6558 }
6559
6560 /* The type name of the dynamic type denoted by the 'tag value TAG, as
6561 a C string.
6562
6563 Return NULL if the TAG is not an Ada tag, or if we were unable to
6564 determine the name of that tag. */
6565
6566 gdb::unique_xmalloc_ptr<char>
6567 ada_tag_name (struct value *tag)
6568 {
6569 gdb::unique_xmalloc_ptr<char> name;
6570
6571 if (!ada_is_tag_type (value_type (tag)))
6572 return NULL;
6573
6574 /* It is perfectly possible that an exception be raised while trying
6575 to determine the TAG's name, even under normal circumstances:
6576 The associated variable may be uninitialized or corrupted, for
6577 instance. We do not let any exception propagate past this point.
6578 instead we return NULL.
6579
6580 We also do not print the error message either (which often is very
6581 low-level (Eg: "Cannot read memory at 0x[...]"), but instead let
6582 the caller print a more meaningful message if necessary. */
6583 try
6584 {
6585 struct value *tsd = ada_get_tsd_from_tag (tag);
6586
6587 if (tsd != NULL)
6588 name = ada_tag_name_from_tsd (tsd);
6589 }
6590 catch (const gdb_exception_error &e)
6591 {
6592 }
6593
6594 return name;
6595 }
6596
6597 /* The parent type of TYPE, or NULL if none. */
6598
6599 struct type *
6600 ada_parent_type (struct type *type)
6601 {
6602 int i;
6603
6604 type = ada_check_typedef (type);
6605
6606 if (type == NULL || type->code () != TYPE_CODE_STRUCT)
6607 return NULL;
6608
6609 for (i = 0; i < type->num_fields (); i += 1)
6610 if (ada_is_parent_field (type, i))
6611 {
6612 struct type *parent_type = type->field (i).type ();
6613
6614 /* If the _parent field is a pointer, then dereference it. */
6615 if (parent_type->code () == TYPE_CODE_PTR)
6616 parent_type = TYPE_TARGET_TYPE (parent_type);
6617 /* If there is a parallel XVS type, get the actual base type. */
6618 parent_type = ada_get_base_type (parent_type);
6619
6620 return ada_check_typedef (parent_type);
6621 }
6622
6623 return NULL;
6624 }
6625
6626 /* True iff field number FIELD_NUM of structure type TYPE contains the
6627 parent-type (inherited) fields of a derived type. Assumes TYPE is
6628 a structure type with at least FIELD_NUM+1 fields. */
6629
6630 int
6631 ada_is_parent_field (struct type *type, int field_num)
6632 {
6633 const char *name = TYPE_FIELD_NAME (ada_check_typedef (type), field_num);
6634
6635 return (name != NULL
6636 && (startswith (name, "PARENT")
6637 || startswith (name, "_parent")));
6638 }
6639
6640 /* True iff field number FIELD_NUM of structure type TYPE is a
6641 transparent wrapper field (which should be silently traversed when doing
6642 field selection and flattened when printing). Assumes TYPE is a
6643 structure type with at least FIELD_NUM+1 fields. Such fields are always
6644 structures. */
6645
6646 int
6647 ada_is_wrapper_field (struct type *type, int field_num)
6648 {
6649 const char *name = TYPE_FIELD_NAME (type, field_num);
6650
6651 if (name != NULL && strcmp (name, "RETVAL") == 0)
6652 {
6653 /* This happens in functions with "out" or "in out" parameters
6654 which are passed by copy. For such functions, GNAT describes
6655 the function's return type as being a struct where the return
6656 value is in a field called RETVAL, and where the other "out"
6657 or "in out" parameters are fields of that struct. This is not
6658 a wrapper. */
6659 return 0;
6660 }
6661
6662 return (name != NULL
6663 && (startswith (name, "PARENT")
6664 || strcmp (name, "REP") == 0
6665 || startswith (name, "_parent")
6666 || name[0] == 'S' || name[0] == 'R' || name[0] == 'O'));
6667 }
6668
6669 /* True iff field number FIELD_NUM of structure or union type TYPE
6670 is a variant wrapper. Assumes TYPE is a structure type with at least
6671 FIELD_NUM+1 fields. */
6672
6673 int
6674 ada_is_variant_part (struct type *type, int field_num)
6675 {
6676 /* Only Ada types are eligible. */
6677 if (!ADA_TYPE_P (type))
6678 return 0;
6679
6680 struct type *field_type = type->field (field_num).type ();
6681
6682 return (field_type->code () == TYPE_CODE_UNION
6683 || (is_dynamic_field (type, field_num)
6684 && (TYPE_TARGET_TYPE (field_type)->code ()
6685 == TYPE_CODE_UNION)));
6686 }
6687
6688 /* Assuming that VAR_TYPE is a variant wrapper (type of the variant part)
6689 whose discriminants are contained in the record type OUTER_TYPE,
6690 returns the type of the controlling discriminant for the variant.
6691 May return NULL if the type could not be found. */
6692
6693 struct type *
6694 ada_variant_discrim_type (struct type *var_type, struct type *outer_type)
6695 {
6696 const char *name = ada_variant_discrim_name (var_type);
6697
6698 return ada_lookup_struct_elt_type (outer_type, name, 1, 1);
6699 }
6700
6701 /* Assuming that TYPE is the type of a variant wrapper, and FIELD_NUM is a
6702 valid field number within it, returns 1 iff field FIELD_NUM of TYPE
6703 represents a 'when others' clause; otherwise 0. */
6704
6705 static int
6706 ada_is_others_clause (struct type *type, int field_num)
6707 {
6708 const char *name = TYPE_FIELD_NAME (type, field_num);
6709
6710 return (name != NULL && name[0] == 'O');
6711 }
6712
6713 /* Assuming that TYPE0 is the type of the variant part of a record,
6714 returns the name of the discriminant controlling the variant.
6715 The value is valid until the next call to ada_variant_discrim_name. */
6716
6717 const char *
6718 ada_variant_discrim_name (struct type *type0)
6719 {
6720 static char *result = NULL;
6721 static size_t result_len = 0;
6722 struct type *type;
6723 const char *name;
6724 const char *discrim_end;
6725 const char *discrim_start;
6726
6727 if (type0->code () == TYPE_CODE_PTR)
6728 type = TYPE_TARGET_TYPE (type0);
6729 else
6730 type = type0;
6731
6732 name = ada_type_name (type);
6733
6734 if (name == NULL || name[0] == '\000')
6735 return "";
6736
6737 for (discrim_end = name + strlen (name) - 6; discrim_end != name;
6738 discrim_end -= 1)
6739 {
6740 if (startswith (discrim_end, "___XVN"))
6741 break;
6742 }
6743 if (discrim_end == name)
6744 return "";
6745
6746 for (discrim_start = discrim_end; discrim_start != name + 3;
6747 discrim_start -= 1)
6748 {
6749 if (discrim_start == name + 1)
6750 return "";
6751 if ((discrim_start > name + 3
6752 && startswith (discrim_start - 3, "___"))
6753 || discrim_start[-1] == '.')
6754 break;
6755 }
6756
6757 GROW_VECT (result, result_len, discrim_end - discrim_start + 1);
6758 strncpy (result, discrim_start, discrim_end - discrim_start);
6759 result[discrim_end - discrim_start] = '\0';
6760 return result;
6761 }
6762
6763 /* Scan STR for a subtype-encoded number, beginning at position K.
6764 Put the position of the character just past the number scanned in
6765 *NEW_K, if NEW_K!=NULL. Put the scanned number in *R, if R!=NULL.
6766 Return 1 if there was a valid number at the given position, and 0
6767 otherwise. A "subtype-encoded" number consists of the absolute value
6768 in decimal, followed by the letter 'm' to indicate a negative number.
6769 Assumes 0m does not occur. */
6770
6771 int
6772 ada_scan_number (const char str[], int k, LONGEST * R, int *new_k)
6773 {
6774 ULONGEST RU;
6775
6776 if (!isdigit (str[k]))
6777 return 0;
6778
6779 /* Do it the hard way so as not to make any assumption about
6780 the relationship of unsigned long (%lu scan format code) and
6781 LONGEST. */
6782 RU = 0;
6783 while (isdigit (str[k]))
6784 {
6785 RU = RU * 10 + (str[k] - '0');
6786 k += 1;
6787 }
6788
6789 if (str[k] == 'm')
6790 {
6791 if (R != NULL)
6792 *R = (-(LONGEST) (RU - 1)) - 1;
6793 k += 1;
6794 }
6795 else if (R != NULL)
6796 *R = (LONGEST) RU;
6797
6798 /* NOTE on the above: Technically, C does not say what the results of
6799 - (LONGEST) RU or (LONGEST) -RU are for RU == largest positive
6800 number representable as a LONGEST (although either would probably work
6801 in most implementations). When RU>0, the locution in the then branch
6802 above is always equivalent to the negative of RU. */
6803
6804 if (new_k != NULL)
6805 *new_k = k;
6806 return 1;
6807 }
6808
6809 /* Assuming that TYPE is a variant part wrapper type (a VARIANTS field),
6810 and FIELD_NUM is a valid field number within it, returns 1 iff VAL is
6811 in the range encoded by field FIELD_NUM of TYPE; otherwise 0. */
6812
6813 static int
6814 ada_in_variant (LONGEST val, struct type *type, int field_num)
6815 {
6816 const char *name = TYPE_FIELD_NAME (type, field_num);
6817 int p;
6818
6819 p = 0;
6820 while (1)
6821 {
6822 switch (name[p])
6823 {
6824 case '\0':
6825 return 0;
6826 case 'S':
6827 {
6828 LONGEST W;
6829
6830 if (!ada_scan_number (name, p + 1, &W, &p))
6831 return 0;
6832 if (val == W)
6833 return 1;
6834 break;
6835 }
6836 case 'R':
6837 {
6838 LONGEST L, U;
6839
6840 if (!ada_scan_number (name, p + 1, &L, &p)
6841 || name[p] != 'T' || !ada_scan_number (name, p + 1, &U, &p))
6842 return 0;
6843 if (val >= L && val <= U)
6844 return 1;
6845 break;
6846 }
6847 case 'O':
6848 return 1;
6849 default:
6850 return 0;
6851 }
6852 }
6853 }
6854
6855 /* FIXME: Lots of redundancy below. Try to consolidate. */
6856
6857 /* Given a value ARG1 (offset by OFFSET bytes) of a struct or union type
6858 ARG_TYPE, extract and return the value of one of its (non-static)
6859 fields. FIELDNO says which field. Differs from value_primitive_field
6860 only in that it can handle packed values of arbitrary type. */
6861
6862 struct value *
6863 ada_value_primitive_field (struct value *arg1, int offset, int fieldno,
6864 struct type *arg_type)
6865 {
6866 struct type *type;
6867
6868 arg_type = ada_check_typedef (arg_type);
6869 type = arg_type->field (fieldno).type ();
6870
6871 /* Handle packed fields. It might be that the field is not packed
6872 relative to its containing structure, but the structure itself is
6873 packed; in this case we must take the bit-field path. */
6874 if (TYPE_FIELD_BITSIZE (arg_type, fieldno) != 0 || value_bitpos (arg1) != 0)
6875 {
6876 int bit_pos = TYPE_FIELD_BITPOS (arg_type, fieldno);
6877 int bit_size = TYPE_FIELD_BITSIZE (arg_type, fieldno);
6878
6879 return ada_value_primitive_packed_val (arg1, value_contents (arg1),
6880 offset + bit_pos / 8,
6881 bit_pos % 8, bit_size, type);
6882 }
6883 else
6884 return value_primitive_field (arg1, offset, fieldno, arg_type);
6885 }
6886
6887 /* Find field with name NAME in object of type TYPE. If found,
6888 set the following for each argument that is non-null:
6889 - *FIELD_TYPE_P to the field's type;
6890 - *BYTE_OFFSET_P to OFFSET + the byte offset of the field within
6891 an object of that type;
6892 - *BIT_OFFSET_P to the bit offset modulo byte size of the field;
6893 - *BIT_SIZE_P to its size in bits if the field is packed, and
6894 0 otherwise;
6895 If INDEX_P is non-null, increment *INDEX_P by the number of source-visible
6896 fields up to but not including the desired field, or by the total
6897 number of fields if not found. A NULL value of NAME never
6898 matches; the function just counts visible fields in this case.
6899
6900 Notice that we need to handle when a tagged record hierarchy
6901 has some components with the same name, like in this scenario:
6902
6903 type Top_T is tagged record
6904 N : Integer := 1;
6905 U : Integer := 974;
6906 A : Integer := 48;
6907 end record;
6908
6909 type Middle_T is new Top.Top_T with record
6910 N : Character := 'a';
6911 C : Integer := 3;
6912 end record;
6913
6914 type Bottom_T is new Middle.Middle_T with record
6915 N : Float := 4.0;
6916 C : Character := '5';
6917 X : Integer := 6;
6918 A : Character := 'J';
6919 end record;
6920
6921 Let's say we now have a variable declared and initialized as follow:
6922
6923 TC : Top_A := new Bottom_T;
6924
6925 And then we use this variable to call this function
6926
6927 procedure Assign (Obj: in out Top_T; TV : Integer);
6928
6929 as follow:
6930
6931 Assign (Top_T (B), 12);
6932
6933 Now, we're in the debugger, and we're inside that procedure
6934 then and we want to print the value of obj.c:
6935
6936 Usually, the tagged record or one of the parent type owns the
6937 component to print and there's no issue but in this particular
6938 case, what does it mean to ask for Obj.C? Since the actual
6939 type for object is type Bottom_T, it could mean two things: type
6940 component C from the Middle_T view, but also component C from
6941 Bottom_T. So in that "undefined" case, when the component is
6942 not found in the non-resolved type (which includes all the
6943 components of the parent type), then resolve it and see if we
6944 get better luck once expanded.
6945
6946 In the case of homonyms in the derived tagged type, we don't
6947 guaranty anything, and pick the one that's easiest for us
6948 to program.
6949
6950 Returns 1 if found, 0 otherwise. */
6951
6952 static int
6953 find_struct_field (const char *name, struct type *type, int offset,
6954 struct type **field_type_p,
6955 int *byte_offset_p, int *bit_offset_p, int *bit_size_p,
6956 int *index_p)
6957 {
6958 int i;
6959 int parent_offset = -1;
6960
6961 type = ada_check_typedef (type);
6962
6963 if (field_type_p != NULL)
6964 *field_type_p = NULL;
6965 if (byte_offset_p != NULL)
6966 *byte_offset_p = 0;
6967 if (bit_offset_p != NULL)
6968 *bit_offset_p = 0;
6969 if (bit_size_p != NULL)
6970 *bit_size_p = 0;
6971
6972 for (i = 0; i < type->num_fields (); i += 1)
6973 {
6974 int bit_pos = TYPE_FIELD_BITPOS (type, i);
6975 int fld_offset = offset + bit_pos / 8;
6976 const char *t_field_name = TYPE_FIELD_NAME (type, i);
6977
6978 if (t_field_name == NULL)
6979 continue;
6980
6981 else if (ada_is_parent_field (type, i))
6982 {
6983 /* This is a field pointing us to the parent type of a tagged
6984 type. As hinted in this function's documentation, we give
6985 preference to fields in the current record first, so what
6986 we do here is just record the index of this field before
6987 we skip it. If it turns out we couldn't find our field
6988 in the current record, then we'll get back to it and search
6989 inside it whether the field might exist in the parent. */
6990
6991 parent_offset = i;
6992 continue;
6993 }
6994
6995 else if (name != NULL && field_name_match (t_field_name, name))
6996 {
6997 int bit_size = TYPE_FIELD_BITSIZE (type, i);
6998
6999 if (field_type_p != NULL)
7000 *field_type_p = type->field (i).type ();
7001 if (byte_offset_p != NULL)
7002 *byte_offset_p = fld_offset;
7003 if (bit_offset_p != NULL)
7004 *bit_offset_p = bit_pos % 8;
7005 if (bit_size_p != NULL)
7006 *bit_size_p = bit_size;
7007 return 1;
7008 }
7009 else if (ada_is_wrapper_field (type, i))
7010 {
7011 if (find_struct_field (name, type->field (i).type (), fld_offset,
7012 field_type_p, byte_offset_p, bit_offset_p,
7013 bit_size_p, index_p))
7014 return 1;
7015 }
7016 else if (ada_is_variant_part (type, i))
7017 {
7018 /* PNH: Wait. Do we ever execute this section, or is ARG always of
7019 fixed type?? */
7020 int j;
7021 struct type *field_type
7022 = ada_check_typedef (type->field (i).type ());
7023
7024 for (j = 0; j < field_type->num_fields (); j += 1)
7025 {
7026 if (find_struct_field (name, field_type->field (j).type (),
7027 fld_offset
7028 + TYPE_FIELD_BITPOS (field_type, j) / 8,
7029 field_type_p, byte_offset_p,
7030 bit_offset_p, bit_size_p, index_p))
7031 return 1;
7032 }
7033 }
7034 else if (index_p != NULL)
7035 *index_p += 1;
7036 }
7037
7038 /* Field not found so far. If this is a tagged type which
7039 has a parent, try finding that field in the parent now. */
7040
7041 if (parent_offset != -1)
7042 {
7043 int bit_pos = TYPE_FIELD_BITPOS (type, parent_offset);
7044 int fld_offset = offset + bit_pos / 8;
7045
7046 if (find_struct_field (name, type->field (parent_offset).type (),
7047 fld_offset, field_type_p, byte_offset_p,
7048 bit_offset_p, bit_size_p, index_p))
7049 return 1;
7050 }
7051
7052 return 0;
7053 }
7054
7055 /* Number of user-visible fields in record type TYPE. */
7056
7057 static int
7058 num_visible_fields (struct type *type)
7059 {
7060 int n;
7061
7062 n = 0;
7063 find_struct_field (NULL, type, 0, NULL, NULL, NULL, NULL, &n);
7064 return n;
7065 }
7066
7067 /* Look for a field NAME in ARG. Adjust the address of ARG by OFFSET bytes,
7068 and search in it assuming it has (class) type TYPE.
7069 If found, return value, else return NULL.
7070
7071 Searches recursively through wrapper fields (e.g., '_parent').
7072
7073 In the case of homonyms in the tagged types, please refer to the
7074 long explanation in find_struct_field's function documentation. */
7075
7076 static struct value *
7077 ada_search_struct_field (const char *name, struct value *arg, int offset,
7078 struct type *type)
7079 {
7080 int i;
7081 int parent_offset = -1;
7082
7083 type = ada_check_typedef (type);
7084 for (i = 0; i < type->num_fields (); i += 1)
7085 {
7086 const char *t_field_name = TYPE_FIELD_NAME (type, i);
7087
7088 if (t_field_name == NULL)
7089 continue;
7090
7091 else if (ada_is_parent_field (type, i))
7092 {
7093 /* This is a field pointing us to the parent type of a tagged
7094 type. As hinted in this function's documentation, we give
7095 preference to fields in the current record first, so what
7096 we do here is just record the index of this field before
7097 we skip it. If it turns out we couldn't find our field
7098 in the current record, then we'll get back to it and search
7099 inside it whether the field might exist in the parent. */
7100
7101 parent_offset = i;
7102 continue;
7103 }
7104
7105 else if (field_name_match (t_field_name, name))
7106 return ada_value_primitive_field (arg, offset, i, type);
7107
7108 else if (ada_is_wrapper_field (type, i))
7109 {
7110 struct value *v = /* Do not let indent join lines here. */
7111 ada_search_struct_field (name, arg,
7112 offset + TYPE_FIELD_BITPOS (type, i) / 8,
7113 type->field (i).type ());
7114
7115 if (v != NULL)
7116 return v;
7117 }
7118
7119 else if (ada_is_variant_part (type, i))
7120 {
7121 /* PNH: Do we ever get here? See find_struct_field. */
7122 int j;
7123 struct type *field_type = ada_check_typedef (type->field (i).type ());
7124 int var_offset = offset + TYPE_FIELD_BITPOS (type, i) / 8;
7125
7126 for (j = 0; j < field_type->num_fields (); j += 1)
7127 {
7128 struct value *v = ada_search_struct_field /* Force line
7129 break. */
7130 (name, arg,
7131 var_offset + TYPE_FIELD_BITPOS (field_type, j) / 8,
7132 field_type->field (j).type ());
7133
7134 if (v != NULL)
7135 return v;
7136 }
7137 }
7138 }
7139
7140 /* Field not found so far. If this is a tagged type which
7141 has a parent, try finding that field in the parent now. */
7142
7143 if (parent_offset != -1)
7144 {
7145 struct value *v = ada_search_struct_field (
7146 name, arg, offset + TYPE_FIELD_BITPOS (type, parent_offset) / 8,
7147 type->field (parent_offset).type ());
7148
7149 if (v != NULL)
7150 return v;
7151 }
7152
7153 return NULL;
7154 }
7155
7156 static struct value *ada_index_struct_field_1 (int *, struct value *,
7157 int, struct type *);
7158
7159
7160 /* Return field #INDEX in ARG, where the index is that returned by
7161 * find_struct_field through its INDEX_P argument. Adjust the address
7162 * of ARG by OFFSET bytes, and search in it assuming it has (class) type TYPE.
7163 * If found, return value, else return NULL. */
7164
7165 static struct value *
7166 ada_index_struct_field (int index, struct value *arg, int offset,
7167 struct type *type)
7168 {
7169 return ada_index_struct_field_1 (&index, arg, offset, type);
7170 }
7171
7172
7173 /* Auxiliary function for ada_index_struct_field. Like
7174 * ada_index_struct_field, but takes index from *INDEX_P and modifies
7175 * *INDEX_P. */
7176
7177 static struct value *
7178 ada_index_struct_field_1 (int *index_p, struct value *arg, int offset,
7179 struct type *type)
7180 {
7181 int i;
7182 type = ada_check_typedef (type);
7183
7184 for (i = 0; i < type->num_fields (); i += 1)
7185 {
7186 if (TYPE_FIELD_NAME (type, i) == NULL)
7187 continue;
7188 else if (ada_is_wrapper_field (type, i))
7189 {
7190 struct value *v = /* Do not let indent join lines here. */
7191 ada_index_struct_field_1 (index_p, arg,
7192 offset + TYPE_FIELD_BITPOS (type, i) / 8,
7193 type->field (i).type ());
7194
7195 if (v != NULL)
7196 return v;
7197 }
7198
7199 else if (ada_is_variant_part (type, i))
7200 {
7201 /* PNH: Do we ever get here? See ada_search_struct_field,
7202 find_struct_field. */
7203 error (_("Cannot assign this kind of variant record"));
7204 }
7205 else if (*index_p == 0)
7206 return ada_value_primitive_field (arg, offset, i, type);
7207 else
7208 *index_p -= 1;
7209 }
7210 return NULL;
7211 }
7212
7213 /* Return a string representation of type TYPE. */
7214
7215 static std::string
7216 type_as_string (struct type *type)
7217 {
7218 string_file tmp_stream;
7219
7220 type_print (type, "", &tmp_stream, -1);
7221
7222 return std::move (tmp_stream.string ());
7223 }
7224
7225 /* Given a type TYPE, look up the type of the component of type named NAME.
7226 If DISPP is non-null, add its byte displacement from the beginning of a
7227 structure (pointed to by a value) of type TYPE to *DISPP (does not
7228 work for packed fields).
7229
7230 Matches any field whose name has NAME as a prefix, possibly
7231 followed by "___".
7232
7233 TYPE can be either a struct or union. If REFOK, TYPE may also
7234 be a (pointer or reference)+ to a struct or union, and the
7235 ultimate target type will be searched.
7236
7237 Looks recursively into variant clauses and parent types.
7238
7239 In the case of homonyms in the tagged types, please refer to the
7240 long explanation in find_struct_field's function documentation.
7241
7242 If NOERR is nonzero, return NULL if NAME is not suitably defined or
7243 TYPE is not a type of the right kind. */
7244
7245 static struct type *
7246 ada_lookup_struct_elt_type (struct type *type, const char *name, int refok,
7247 int noerr)
7248 {
7249 int i;
7250 int parent_offset = -1;
7251
7252 if (name == NULL)
7253 goto BadName;
7254
7255 if (refok && type != NULL)
7256 while (1)
7257 {
7258 type = ada_check_typedef (type);
7259 if (type->code () != TYPE_CODE_PTR && type->code () != TYPE_CODE_REF)
7260 break;
7261 type = TYPE_TARGET_TYPE (type);
7262 }
7263
7264 if (type == NULL
7265 || (type->code () != TYPE_CODE_STRUCT
7266 && type->code () != TYPE_CODE_UNION))
7267 {
7268 if (noerr)
7269 return NULL;
7270
7271 error (_("Type %s is not a structure or union type"),
7272 type != NULL ? type_as_string (type).c_str () : _("(null)"));
7273 }
7274
7275 type = to_static_fixed_type (type);
7276
7277 for (i = 0; i < type->num_fields (); i += 1)
7278 {
7279 const char *t_field_name = TYPE_FIELD_NAME (type, i);
7280 struct type *t;
7281
7282 if (t_field_name == NULL)
7283 continue;
7284
7285 else if (ada_is_parent_field (type, i))
7286 {
7287 /* This is a field pointing us to the parent type of a tagged
7288 type. As hinted in this function's documentation, we give
7289 preference to fields in the current record first, so what
7290 we do here is just record the index of this field before
7291 we skip it. If it turns out we couldn't find our field
7292 in the current record, then we'll get back to it and search
7293 inside it whether the field might exist in the parent. */
7294
7295 parent_offset = i;
7296 continue;
7297 }
7298
7299 else if (field_name_match (t_field_name, name))
7300 return type->field (i).type ();
7301
7302 else if (ada_is_wrapper_field (type, i))
7303 {
7304 t = ada_lookup_struct_elt_type (type->field (i).type (), name,
7305 0, 1);
7306 if (t != NULL)
7307 return t;
7308 }
7309
7310 else if (ada_is_variant_part (type, i))
7311 {
7312 int j;
7313 struct type *field_type = ada_check_typedef (type->field (i).type ());
7314
7315 for (j = field_type->num_fields () - 1; j >= 0; j -= 1)
7316 {
7317 /* FIXME pnh 2008/01/26: We check for a field that is
7318 NOT wrapped in a struct, since the compiler sometimes
7319 generates these for unchecked variant types. Revisit
7320 if the compiler changes this practice. */
7321 const char *v_field_name = TYPE_FIELD_NAME (field_type, j);
7322
7323 if (v_field_name != NULL
7324 && field_name_match (v_field_name, name))
7325 t = field_type->field (j).type ();
7326 else
7327 t = ada_lookup_struct_elt_type (field_type->field (j).type (),
7328 name, 0, 1);
7329
7330 if (t != NULL)
7331 return t;
7332 }
7333 }
7334
7335 }
7336
7337 /* Field not found so far. If this is a tagged type which
7338 has a parent, try finding that field in the parent now. */
7339
7340 if (parent_offset != -1)
7341 {
7342 struct type *t;
7343
7344 t = ada_lookup_struct_elt_type (type->field (parent_offset).type (),
7345 name, 0, 1);
7346 if (t != NULL)
7347 return t;
7348 }
7349
7350 BadName:
7351 if (!noerr)
7352 {
7353 const char *name_str = name != NULL ? name : _("<null>");
7354
7355 error (_("Type %s has no component named %s"),
7356 type_as_string (type).c_str (), name_str);
7357 }
7358
7359 return NULL;
7360 }
7361
7362 /* Assuming that VAR_TYPE is the type of a variant part of a record (a union),
7363 within a value of type OUTER_TYPE, return true iff VAR_TYPE
7364 represents an unchecked union (that is, the variant part of a
7365 record that is named in an Unchecked_Union pragma). */
7366
7367 static int
7368 is_unchecked_variant (struct type *var_type, struct type *outer_type)
7369 {
7370 const char *discrim_name = ada_variant_discrim_name (var_type);
7371
7372 return (ada_lookup_struct_elt_type (outer_type, discrim_name, 0, 1) == NULL);
7373 }
7374
7375
7376 /* Assuming that VAR_TYPE is the type of a variant part of a record (a union),
7377 within OUTER, determine which variant clause (field number in VAR_TYPE,
7378 numbering from 0) is applicable. Returns -1 if none are. */
7379
7380 int
7381 ada_which_variant_applies (struct type *var_type, struct value *outer)
7382 {
7383 int others_clause;
7384 int i;
7385 const char *discrim_name = ada_variant_discrim_name (var_type);
7386 struct value *discrim;
7387 LONGEST discrim_val;
7388
7389 /* Using plain value_from_contents_and_address here causes problems
7390 because we will end up trying to resolve a type that is currently
7391 being constructed. */
7392 discrim = ada_value_struct_elt (outer, discrim_name, 1);
7393 if (discrim == NULL)
7394 return -1;
7395 discrim_val = value_as_long (discrim);
7396
7397 others_clause = -1;
7398 for (i = 0; i < var_type->num_fields (); i += 1)
7399 {
7400 if (ada_is_others_clause (var_type, i))
7401 others_clause = i;
7402 else if (ada_in_variant (discrim_val, var_type, i))
7403 return i;
7404 }
7405
7406 return others_clause;
7407 }
7408 \f
7409
7410
7411 /* Dynamic-Sized Records */
7412
7413 /* Strategy: The type ostensibly attached to a value with dynamic size
7414 (i.e., a size that is not statically recorded in the debugging
7415 data) does not accurately reflect the size or layout of the value.
7416 Our strategy is to convert these values to values with accurate,
7417 conventional types that are constructed on the fly. */
7418
7419 /* There is a subtle and tricky problem here. In general, we cannot
7420 determine the size of dynamic records without its data. However,
7421 the 'struct value' data structure, which GDB uses to represent
7422 quantities in the inferior process (the target), requires the size
7423 of the type at the time of its allocation in order to reserve space
7424 for GDB's internal copy of the data. That's why the
7425 'to_fixed_xxx_type' routines take (target) addresses as parameters,
7426 rather than struct value*s.
7427
7428 However, GDB's internal history variables ($1, $2, etc.) are
7429 struct value*s containing internal copies of the data that are not, in
7430 general, the same as the data at their corresponding addresses in
7431 the target. Fortunately, the types we give to these values are all
7432 conventional, fixed-size types (as per the strategy described
7433 above), so that we don't usually have to perform the
7434 'to_fixed_xxx_type' conversions to look at their values.
7435 Unfortunately, there is one exception: if one of the internal
7436 history variables is an array whose elements are unconstrained
7437 records, then we will need to create distinct fixed types for each
7438 element selected. */
7439
7440 /* The upshot of all of this is that many routines take a (type, host
7441 address, target address) triple as arguments to represent a value.
7442 The host address, if non-null, is supposed to contain an internal
7443 copy of the relevant data; otherwise, the program is to consult the
7444 target at the target address. */
7445
7446 /* Assuming that VAL0 represents a pointer value, the result of
7447 dereferencing it. Differs from value_ind in its treatment of
7448 dynamic-sized types. */
7449
7450 struct value *
7451 ada_value_ind (struct value *val0)
7452 {
7453 struct value *val = value_ind (val0);
7454
7455 if (ada_is_tagged_type (value_type (val), 0))
7456 val = ada_tag_value_at_base_address (val);
7457
7458 return ada_to_fixed_value (val);
7459 }
7460
7461 /* The value resulting from dereferencing any "reference to"
7462 qualifiers on VAL0. */
7463
7464 static struct value *
7465 ada_coerce_ref (struct value *val0)
7466 {
7467 if (value_type (val0)->code () == TYPE_CODE_REF)
7468 {
7469 struct value *val = val0;
7470
7471 val = coerce_ref (val);
7472
7473 if (ada_is_tagged_type (value_type (val), 0))
7474 val = ada_tag_value_at_base_address (val);
7475
7476 return ada_to_fixed_value (val);
7477 }
7478 else
7479 return val0;
7480 }
7481
7482 /* Return the bit alignment required for field #F of template type TYPE. */
7483
7484 static unsigned int
7485 field_alignment (struct type *type, int f)
7486 {
7487 const char *name = TYPE_FIELD_NAME (type, f);
7488 int len;
7489 int align_offset;
7490
7491 /* The field name should never be null, unless the debugging information
7492 is somehow malformed. In this case, we assume the field does not
7493 require any alignment. */
7494 if (name == NULL)
7495 return 1;
7496
7497 len = strlen (name);
7498
7499 if (!isdigit (name[len - 1]))
7500 return 1;
7501
7502 if (isdigit (name[len - 2]))
7503 align_offset = len - 2;
7504 else
7505 align_offset = len - 1;
7506
7507 if (align_offset < 7 || !startswith (name + align_offset - 6, "___XV"))
7508 return TARGET_CHAR_BIT;
7509
7510 return atoi (name + align_offset) * TARGET_CHAR_BIT;
7511 }
7512
7513 /* Find a typedef or tag symbol named NAME. Ignores ambiguity. */
7514
7515 static struct symbol *
7516 ada_find_any_type_symbol (const char *name)
7517 {
7518 struct symbol *sym;
7519
7520 sym = standard_lookup (name, get_selected_block (NULL), VAR_DOMAIN);
7521 if (sym != NULL && SYMBOL_CLASS (sym) == LOC_TYPEDEF)
7522 return sym;
7523
7524 sym = standard_lookup (name, NULL, STRUCT_DOMAIN);
7525 return sym;
7526 }
7527
7528 /* Find a type named NAME. Ignores ambiguity. This routine will look
7529 solely for types defined by debug info, it will not search the GDB
7530 primitive types. */
7531
7532 static struct type *
7533 ada_find_any_type (const char *name)
7534 {
7535 struct symbol *sym = ada_find_any_type_symbol (name);
7536
7537 if (sym != NULL)
7538 return SYMBOL_TYPE (sym);
7539
7540 return NULL;
7541 }
7542
7543 /* Given NAME_SYM and an associated BLOCK, find a "renaming" symbol
7544 associated with NAME_SYM's name. NAME_SYM may itself be a renaming
7545 symbol, in which case it is returned. Otherwise, this looks for
7546 symbols whose name is that of NAME_SYM suffixed with "___XR".
7547 Return symbol if found, and NULL otherwise. */
7548
7549 static bool
7550 ada_is_renaming_symbol (struct symbol *name_sym)
7551 {
7552 const char *name = name_sym->linkage_name ();
7553 return strstr (name, "___XR") != NULL;
7554 }
7555
7556 /* Because of GNAT encoding conventions, several GDB symbols may match a
7557 given type name. If the type denoted by TYPE0 is to be preferred to
7558 that of TYPE1 for purposes of type printing, return non-zero;
7559 otherwise return 0. */
7560
7561 int
7562 ada_prefer_type (struct type *type0, struct type *type1)
7563 {
7564 if (type1 == NULL)
7565 return 1;
7566 else if (type0 == NULL)
7567 return 0;
7568 else if (type1->code () == TYPE_CODE_VOID)
7569 return 1;
7570 else if (type0->code () == TYPE_CODE_VOID)
7571 return 0;
7572 else if (type1->name () == NULL && type0->name () != NULL)
7573 return 1;
7574 else if (ada_is_constrained_packed_array_type (type0))
7575 return 1;
7576 else if (ada_is_array_descriptor_type (type0)
7577 && !ada_is_array_descriptor_type (type1))
7578 return 1;
7579 else
7580 {
7581 const char *type0_name = type0->name ();
7582 const char *type1_name = type1->name ();
7583
7584 if (type0_name != NULL && strstr (type0_name, "___XR") != NULL
7585 && (type1_name == NULL || strstr (type1_name, "___XR") == NULL))
7586 return 1;
7587 }
7588 return 0;
7589 }
7590
7591 /* The name of TYPE, which is its TYPE_NAME. Null if TYPE is
7592 null. */
7593
7594 const char *
7595 ada_type_name (struct type *type)
7596 {
7597 if (type == NULL)
7598 return NULL;
7599 return type->name ();
7600 }
7601
7602 /* Search the list of "descriptive" types associated to TYPE for a type
7603 whose name is NAME. */
7604
7605 static struct type *
7606 find_parallel_type_by_descriptive_type (struct type *type, const char *name)
7607 {
7608 struct type *result, *tmp;
7609
7610 if (ada_ignore_descriptive_types_p)
7611 return NULL;
7612
7613 /* If there no descriptive-type info, then there is no parallel type
7614 to be found. */
7615 if (!HAVE_GNAT_AUX_INFO (type))
7616 return NULL;
7617
7618 result = TYPE_DESCRIPTIVE_TYPE (type);
7619 while (result != NULL)
7620 {
7621 const char *result_name = ada_type_name (result);
7622
7623 if (result_name == NULL)
7624 {
7625 warning (_("unexpected null name on descriptive type"));
7626 return NULL;
7627 }
7628
7629 /* If the names match, stop. */
7630 if (strcmp (result_name, name) == 0)
7631 break;
7632
7633 /* Otherwise, look at the next item on the list, if any. */
7634 if (HAVE_GNAT_AUX_INFO (result))
7635 tmp = TYPE_DESCRIPTIVE_TYPE (result);
7636 else
7637 tmp = NULL;
7638
7639 /* If not found either, try after having resolved the typedef. */
7640 if (tmp != NULL)
7641 result = tmp;
7642 else
7643 {
7644 result = check_typedef (result);
7645 if (HAVE_GNAT_AUX_INFO (result))
7646 result = TYPE_DESCRIPTIVE_TYPE (result);
7647 else
7648 result = NULL;
7649 }
7650 }
7651
7652 /* If we didn't find a match, see whether this is a packed array. With
7653 older compilers, the descriptive type information is either absent or
7654 irrelevant when it comes to packed arrays so the above lookup fails.
7655 Fall back to using a parallel lookup by name in this case. */
7656 if (result == NULL && ada_is_constrained_packed_array_type (type))
7657 return ada_find_any_type (name);
7658
7659 return result;
7660 }
7661
7662 /* Find a parallel type to TYPE with the specified NAME, using the
7663 descriptive type taken from the debugging information, if available,
7664 and otherwise using the (slower) name-based method. */
7665
7666 static struct type *
7667 ada_find_parallel_type_with_name (struct type *type, const char *name)
7668 {
7669 struct type *result = NULL;
7670
7671 if (HAVE_GNAT_AUX_INFO (type))
7672 result = find_parallel_type_by_descriptive_type (type, name);
7673 else
7674 result = ada_find_any_type (name);
7675
7676 return result;
7677 }
7678
7679 /* Same as above, but specify the name of the parallel type by appending
7680 SUFFIX to the name of TYPE. */
7681
7682 struct type *
7683 ada_find_parallel_type (struct type *type, const char *suffix)
7684 {
7685 char *name;
7686 const char *type_name = ada_type_name (type);
7687 int len;
7688
7689 if (type_name == NULL)
7690 return NULL;
7691
7692 len = strlen (type_name);
7693
7694 name = (char *) alloca (len + strlen (suffix) + 1);
7695
7696 strcpy (name, type_name);
7697 strcpy (name + len, suffix);
7698
7699 return ada_find_parallel_type_with_name (type, name);
7700 }
7701
7702 /* If TYPE is a variable-size record type, return the corresponding template
7703 type describing its fields. Otherwise, return NULL. */
7704
7705 static struct type *
7706 dynamic_template_type (struct type *type)
7707 {
7708 type = ada_check_typedef (type);
7709
7710 if (type == NULL || type->code () != TYPE_CODE_STRUCT
7711 || ada_type_name (type) == NULL)
7712 return NULL;
7713 else
7714 {
7715 int len = strlen (ada_type_name (type));
7716
7717 if (len > 6 && strcmp (ada_type_name (type) + len - 6, "___XVE") == 0)
7718 return type;
7719 else
7720 return ada_find_parallel_type (type, "___XVE");
7721 }
7722 }
7723
7724 /* Assuming that TEMPL_TYPE is a union or struct type, returns
7725 non-zero iff field FIELD_NUM of TEMPL_TYPE has dynamic size. */
7726
7727 static int
7728 is_dynamic_field (struct type *templ_type, int field_num)
7729 {
7730 const char *name = TYPE_FIELD_NAME (templ_type, field_num);
7731
7732 return name != NULL
7733 && templ_type->field (field_num).type ()->code () == TYPE_CODE_PTR
7734 && strstr (name, "___XVL") != NULL;
7735 }
7736
7737 /* The index of the variant field of TYPE, or -1 if TYPE does not
7738 represent a variant record type. */
7739
7740 static int
7741 variant_field_index (struct type *type)
7742 {
7743 int f;
7744
7745 if (type == NULL || type->code () != TYPE_CODE_STRUCT)
7746 return -1;
7747
7748 for (f = 0; f < type->num_fields (); f += 1)
7749 {
7750 if (ada_is_variant_part (type, f))
7751 return f;
7752 }
7753 return -1;
7754 }
7755
7756 /* A record type with no fields. */
7757
7758 static struct type *
7759 empty_record (struct type *templ)
7760 {
7761 struct type *type = alloc_type_copy (templ);
7762
7763 type->set_code (TYPE_CODE_STRUCT);
7764 INIT_NONE_SPECIFIC (type);
7765 type->set_name ("<empty>");
7766 TYPE_LENGTH (type) = 0;
7767 return type;
7768 }
7769
7770 /* An ordinary record type (with fixed-length fields) that describes
7771 the value of type TYPE at VALADDR or ADDRESS (see comments at
7772 the beginning of this section) VAL according to GNAT conventions.
7773 DVAL0 should describe the (portion of a) record that contains any
7774 necessary discriminants. It should be NULL if value_type (VAL) is
7775 an outer-level type (i.e., as opposed to a branch of a variant.) A
7776 variant field (unless unchecked) is replaced by a particular branch
7777 of the variant.
7778
7779 If not KEEP_DYNAMIC_FIELDS, then all fields whose position or
7780 length are not statically known are discarded. As a consequence,
7781 VALADDR, ADDRESS and DVAL0 are ignored.
7782
7783 NOTE: Limitations: For now, we assume that dynamic fields and
7784 variants occupy whole numbers of bytes. However, they need not be
7785 byte-aligned. */
7786
7787 struct type *
7788 ada_template_to_fixed_record_type_1 (struct type *type,
7789 const gdb_byte *valaddr,
7790 CORE_ADDR address, struct value *dval0,
7791 int keep_dynamic_fields)
7792 {
7793 struct value *mark = value_mark ();
7794 struct value *dval;
7795 struct type *rtype;
7796 int nfields, bit_len;
7797 int variant_field;
7798 long off;
7799 int fld_bit_len;
7800 int f;
7801
7802 /* Compute the number of fields in this record type that are going
7803 to be processed: unless keep_dynamic_fields, this includes only
7804 fields whose position and length are static will be processed. */
7805 if (keep_dynamic_fields)
7806 nfields = type->num_fields ();
7807 else
7808 {
7809 nfields = 0;
7810 while (nfields < type->num_fields ()
7811 && !ada_is_variant_part (type, nfields)
7812 && !is_dynamic_field (type, nfields))
7813 nfields++;
7814 }
7815
7816 rtype = alloc_type_copy (type);
7817 rtype->set_code (TYPE_CODE_STRUCT);
7818 INIT_NONE_SPECIFIC (rtype);
7819 rtype->set_num_fields (nfields);
7820 rtype->set_fields
7821 ((struct field *) TYPE_ZALLOC (rtype, nfields * sizeof (struct field)));
7822 rtype->set_name (ada_type_name (type));
7823 rtype->set_is_fixed_instance (true);
7824
7825 off = 0;
7826 bit_len = 0;
7827 variant_field = -1;
7828
7829 for (f = 0; f < nfields; f += 1)
7830 {
7831 off = align_up (off, field_alignment (type, f))
7832 + TYPE_FIELD_BITPOS (type, f);
7833 SET_FIELD_BITPOS (rtype->field (f), off);
7834 TYPE_FIELD_BITSIZE (rtype, f) = 0;
7835
7836 if (ada_is_variant_part (type, f))
7837 {
7838 variant_field = f;
7839 fld_bit_len = 0;
7840 }
7841 else if (is_dynamic_field (type, f))
7842 {
7843 const gdb_byte *field_valaddr = valaddr;
7844 CORE_ADDR field_address = address;
7845 struct type *field_type =
7846 TYPE_TARGET_TYPE (type->field (f).type ());
7847
7848 if (dval0 == NULL)
7849 {
7850 /* rtype's length is computed based on the run-time
7851 value of discriminants. If the discriminants are not
7852 initialized, the type size may be completely bogus and
7853 GDB may fail to allocate a value for it. So check the
7854 size first before creating the value. */
7855 ada_ensure_varsize_limit (rtype);
7856 /* Using plain value_from_contents_and_address here
7857 causes problems because we will end up trying to
7858 resolve a type that is currently being
7859 constructed. */
7860 dval = value_from_contents_and_address_unresolved (rtype,
7861 valaddr,
7862 address);
7863 rtype = value_type (dval);
7864 }
7865 else
7866 dval = dval0;
7867
7868 /* If the type referenced by this field is an aligner type, we need
7869 to unwrap that aligner type, because its size might not be set.
7870 Keeping the aligner type would cause us to compute the wrong
7871 size for this field, impacting the offset of the all the fields
7872 that follow this one. */
7873 if (ada_is_aligner_type (field_type))
7874 {
7875 long field_offset = TYPE_FIELD_BITPOS (field_type, f);
7876
7877 field_valaddr = cond_offset_host (field_valaddr, field_offset);
7878 field_address = cond_offset_target (field_address, field_offset);
7879 field_type = ada_aligned_type (field_type);
7880 }
7881
7882 field_valaddr = cond_offset_host (field_valaddr,
7883 off / TARGET_CHAR_BIT);
7884 field_address = cond_offset_target (field_address,
7885 off / TARGET_CHAR_BIT);
7886
7887 /* Get the fixed type of the field. Note that, in this case,
7888 we do not want to get the real type out of the tag: if
7889 the current field is the parent part of a tagged record,
7890 we will get the tag of the object. Clearly wrong: the real
7891 type of the parent is not the real type of the child. We
7892 would end up in an infinite loop. */
7893 field_type = ada_get_base_type (field_type);
7894 field_type = ada_to_fixed_type (field_type, field_valaddr,
7895 field_address, dval, 0);
7896 /* If the field size is already larger than the maximum
7897 object size, then the record itself will necessarily
7898 be larger than the maximum object size. We need to make
7899 this check now, because the size might be so ridiculously
7900 large (due to an uninitialized variable in the inferior)
7901 that it would cause an overflow when adding it to the
7902 record size. */
7903 ada_ensure_varsize_limit (field_type);
7904
7905 rtype->field (f).set_type (field_type);
7906 TYPE_FIELD_NAME (rtype, f) = TYPE_FIELD_NAME (type, f);
7907 /* The multiplication can potentially overflow. But because
7908 the field length has been size-checked just above, and
7909 assuming that the maximum size is a reasonable value,
7910 an overflow should not happen in practice. So rather than
7911 adding overflow recovery code to this already complex code,
7912 we just assume that it's not going to happen. */
7913 fld_bit_len =
7914 TYPE_LENGTH (rtype->field (f).type ()) * TARGET_CHAR_BIT;
7915 }
7916 else
7917 {
7918 /* Note: If this field's type is a typedef, it is important
7919 to preserve the typedef layer.
7920
7921 Otherwise, we might be transforming a typedef to a fat
7922 pointer (encoding a pointer to an unconstrained array),
7923 into a basic fat pointer (encoding an unconstrained
7924 array). As both types are implemented using the same
7925 structure, the typedef is the only clue which allows us
7926 to distinguish between the two options. Stripping it
7927 would prevent us from printing this field appropriately. */
7928 rtype->field (f).set_type (type->field (f).type ());
7929 TYPE_FIELD_NAME (rtype, f) = TYPE_FIELD_NAME (type, f);
7930 if (TYPE_FIELD_BITSIZE (type, f) > 0)
7931 fld_bit_len =
7932 TYPE_FIELD_BITSIZE (rtype, f) = TYPE_FIELD_BITSIZE (type, f);
7933 else
7934 {
7935 struct type *field_type = type->field (f).type ();
7936
7937 /* We need to be careful of typedefs when computing
7938 the length of our field. If this is a typedef,
7939 get the length of the target type, not the length
7940 of the typedef. */
7941 if (field_type->code () == TYPE_CODE_TYPEDEF)
7942 field_type = ada_typedef_target_type (field_type);
7943
7944 fld_bit_len =
7945 TYPE_LENGTH (ada_check_typedef (field_type)) * TARGET_CHAR_BIT;
7946 }
7947 }
7948 if (off + fld_bit_len > bit_len)
7949 bit_len = off + fld_bit_len;
7950 off += fld_bit_len;
7951 TYPE_LENGTH (rtype) =
7952 align_up (bit_len, TARGET_CHAR_BIT) / TARGET_CHAR_BIT;
7953 }
7954
7955 /* We handle the variant part, if any, at the end because of certain
7956 odd cases in which it is re-ordered so as NOT to be the last field of
7957 the record. This can happen in the presence of representation
7958 clauses. */
7959 if (variant_field >= 0)
7960 {
7961 struct type *branch_type;
7962
7963 off = TYPE_FIELD_BITPOS (rtype, variant_field);
7964
7965 if (dval0 == NULL)
7966 {
7967 /* Using plain value_from_contents_and_address here causes
7968 problems because we will end up trying to resolve a type
7969 that is currently being constructed. */
7970 dval = value_from_contents_and_address_unresolved (rtype, valaddr,
7971 address);
7972 rtype = value_type (dval);
7973 }
7974 else
7975 dval = dval0;
7976
7977 branch_type =
7978 to_fixed_variant_branch_type
7979 (type->field (variant_field).type (),
7980 cond_offset_host (valaddr, off / TARGET_CHAR_BIT),
7981 cond_offset_target (address, off / TARGET_CHAR_BIT), dval);
7982 if (branch_type == NULL)
7983 {
7984 for (f = variant_field + 1; f < rtype->num_fields (); f += 1)
7985 rtype->field (f - 1) = rtype->field (f);
7986 rtype->set_num_fields (rtype->num_fields () - 1);
7987 }
7988 else
7989 {
7990 rtype->field (variant_field).set_type (branch_type);
7991 TYPE_FIELD_NAME (rtype, variant_field) = "S";
7992 fld_bit_len =
7993 TYPE_LENGTH (rtype->field (variant_field).type ()) *
7994 TARGET_CHAR_BIT;
7995 if (off + fld_bit_len > bit_len)
7996 bit_len = off + fld_bit_len;
7997 TYPE_LENGTH (rtype) =
7998 align_up (bit_len, TARGET_CHAR_BIT) / TARGET_CHAR_BIT;
7999 }
8000 }
8001
8002 /* According to exp_dbug.ads, the size of TYPE for variable-size records
8003 should contain the alignment of that record, which should be a strictly
8004 positive value. If null or negative, then something is wrong, most
8005 probably in the debug info. In that case, we don't round up the size
8006 of the resulting type. If this record is not part of another structure,
8007 the current RTYPE length might be good enough for our purposes. */
8008 if (TYPE_LENGTH (type) <= 0)
8009 {
8010 if (rtype->name ())
8011 warning (_("Invalid type size for `%s' detected: %s."),
8012 rtype->name (), pulongest (TYPE_LENGTH (type)));
8013 else
8014 warning (_("Invalid type size for <unnamed> detected: %s."),
8015 pulongest (TYPE_LENGTH (type)));
8016 }
8017 else
8018 {
8019 TYPE_LENGTH (rtype) = align_up (TYPE_LENGTH (rtype),
8020 TYPE_LENGTH (type));
8021 }
8022
8023 value_free_to_mark (mark);
8024 if (TYPE_LENGTH (rtype) > varsize_limit)
8025 error (_("record type with dynamic size is larger than varsize-limit"));
8026 return rtype;
8027 }
8028
8029 /* As for ada_template_to_fixed_record_type_1 with KEEP_DYNAMIC_FIELDS
8030 of 1. */
8031
8032 static struct type *
8033 template_to_fixed_record_type (struct type *type, const gdb_byte *valaddr,
8034 CORE_ADDR address, struct value *dval0)
8035 {
8036 return ada_template_to_fixed_record_type_1 (type, valaddr,
8037 address, dval0, 1);
8038 }
8039
8040 /* An ordinary record type in which ___XVL-convention fields and
8041 ___XVU- and ___XVN-convention field types in TYPE0 are replaced with
8042 static approximations, containing all possible fields. Uses
8043 no runtime values. Useless for use in values, but that's OK,
8044 since the results are used only for type determinations. Works on both
8045 structs and unions. Representation note: to save space, we memorize
8046 the result of this function in the TYPE_TARGET_TYPE of the
8047 template type. */
8048
8049 static struct type *
8050 template_to_static_fixed_type (struct type *type0)
8051 {
8052 struct type *type;
8053 int nfields;
8054 int f;
8055
8056 /* No need no do anything if the input type is already fixed. */
8057 if (type0->is_fixed_instance ())
8058 return type0;
8059
8060 /* Likewise if we already have computed the static approximation. */
8061 if (TYPE_TARGET_TYPE (type0) != NULL)
8062 return TYPE_TARGET_TYPE (type0);
8063
8064 /* Don't clone TYPE0 until we are sure we are going to need a copy. */
8065 type = type0;
8066 nfields = type0->num_fields ();
8067
8068 /* Whether or not we cloned TYPE0, cache the result so that we don't do
8069 recompute all over next time. */
8070 TYPE_TARGET_TYPE (type0) = type;
8071
8072 for (f = 0; f < nfields; f += 1)
8073 {
8074 struct type *field_type = type0->field (f).type ();
8075 struct type *new_type;
8076
8077 if (is_dynamic_field (type0, f))
8078 {
8079 field_type = ada_check_typedef (field_type);
8080 new_type = to_static_fixed_type (TYPE_TARGET_TYPE (field_type));
8081 }
8082 else
8083 new_type = static_unwrap_type (field_type);
8084
8085 if (new_type != field_type)
8086 {
8087 /* Clone TYPE0 only the first time we get a new field type. */
8088 if (type == type0)
8089 {
8090 TYPE_TARGET_TYPE (type0) = type = alloc_type_copy (type0);
8091 type->set_code (type0->code ());
8092 INIT_NONE_SPECIFIC (type);
8093 type->set_num_fields (nfields);
8094
8095 field *fields =
8096 ((struct field *)
8097 TYPE_ALLOC (type, nfields * sizeof (struct field)));
8098 memcpy (fields, type0->fields (),
8099 sizeof (struct field) * nfields);
8100 type->set_fields (fields);
8101
8102 type->set_name (ada_type_name (type0));
8103 type->set_is_fixed_instance (true);
8104 TYPE_LENGTH (type) = 0;
8105 }
8106 type->field (f).set_type (new_type);
8107 TYPE_FIELD_NAME (type, f) = TYPE_FIELD_NAME (type0, f);
8108 }
8109 }
8110
8111 return type;
8112 }
8113
8114 /* Given an object of type TYPE whose contents are at VALADDR and
8115 whose address in memory is ADDRESS, returns a revision of TYPE,
8116 which should be a non-dynamic-sized record, in which the variant
8117 part, if any, is replaced with the appropriate branch. Looks
8118 for discriminant values in DVAL0, which can be NULL if the record
8119 contains the necessary discriminant values. */
8120
8121 static struct type *
8122 to_record_with_fixed_variant_part (struct type *type, const gdb_byte *valaddr,
8123 CORE_ADDR address, struct value *dval0)
8124 {
8125 struct value *mark = value_mark ();
8126 struct value *dval;
8127 struct type *rtype;
8128 struct type *branch_type;
8129 int nfields = type->num_fields ();
8130 int variant_field = variant_field_index (type);
8131
8132 if (variant_field == -1)
8133 return type;
8134
8135 if (dval0 == NULL)
8136 {
8137 dval = value_from_contents_and_address (type, valaddr, address);
8138 type = value_type (dval);
8139 }
8140 else
8141 dval = dval0;
8142
8143 rtype = alloc_type_copy (type);
8144 rtype->set_code (TYPE_CODE_STRUCT);
8145 INIT_NONE_SPECIFIC (rtype);
8146 rtype->set_num_fields (nfields);
8147
8148 field *fields =
8149 (struct field *) TYPE_ALLOC (rtype, nfields * sizeof (struct field));
8150 memcpy (fields, type->fields (), sizeof (struct field) * nfields);
8151 rtype->set_fields (fields);
8152
8153 rtype->set_name (ada_type_name (type));
8154 rtype->set_is_fixed_instance (true);
8155 TYPE_LENGTH (rtype) = TYPE_LENGTH (type);
8156
8157 branch_type = to_fixed_variant_branch_type
8158 (type->field (variant_field).type (),
8159 cond_offset_host (valaddr,
8160 TYPE_FIELD_BITPOS (type, variant_field)
8161 / TARGET_CHAR_BIT),
8162 cond_offset_target (address,
8163 TYPE_FIELD_BITPOS (type, variant_field)
8164 / TARGET_CHAR_BIT), dval);
8165 if (branch_type == NULL)
8166 {
8167 int f;
8168
8169 for (f = variant_field + 1; f < nfields; f += 1)
8170 rtype->field (f - 1) = rtype->field (f);
8171 rtype->set_num_fields (rtype->num_fields () - 1);
8172 }
8173 else
8174 {
8175 rtype->field (variant_field).set_type (branch_type);
8176 TYPE_FIELD_NAME (rtype, variant_field) = "S";
8177 TYPE_FIELD_BITSIZE (rtype, variant_field) = 0;
8178 TYPE_LENGTH (rtype) += TYPE_LENGTH (branch_type);
8179 }
8180 TYPE_LENGTH (rtype) -= TYPE_LENGTH (type->field (variant_field).type ());
8181
8182 value_free_to_mark (mark);
8183 return rtype;
8184 }
8185
8186 /* An ordinary record type (with fixed-length fields) that describes
8187 the value at (TYPE0, VALADDR, ADDRESS) [see explanation at
8188 beginning of this section]. Any necessary discriminants' values
8189 should be in DVAL, a record value; it may be NULL if the object
8190 at ADDR itself contains any necessary discriminant values.
8191 Additionally, VALADDR and ADDRESS may also be NULL if no discriminant
8192 values from the record are needed. Except in the case that DVAL,
8193 VALADDR, and ADDRESS are all 0 or NULL, a variant field (unless
8194 unchecked) is replaced by a particular branch of the variant.
8195
8196 NOTE: the case in which DVAL and VALADDR are NULL and ADDRESS is 0
8197 is questionable and may be removed. It can arise during the
8198 processing of an unconstrained-array-of-record type where all the
8199 variant branches have exactly the same size. This is because in
8200 such cases, the compiler does not bother to use the XVS convention
8201 when encoding the record. I am currently dubious of this
8202 shortcut and suspect the compiler should be altered. FIXME. */
8203
8204 static struct type *
8205 to_fixed_record_type (struct type *type0, const gdb_byte *valaddr,
8206 CORE_ADDR address, struct value *dval)
8207 {
8208 struct type *templ_type;
8209
8210 if (type0->is_fixed_instance ())
8211 return type0;
8212
8213 templ_type = dynamic_template_type (type0);
8214
8215 if (templ_type != NULL)
8216 return template_to_fixed_record_type (templ_type, valaddr, address, dval);
8217 else if (variant_field_index (type0) >= 0)
8218 {
8219 if (dval == NULL && valaddr == NULL && address == 0)
8220 return type0;
8221 return to_record_with_fixed_variant_part (type0, valaddr, address,
8222 dval);
8223 }
8224 else
8225 {
8226 type0->set_is_fixed_instance (true);
8227 return type0;
8228 }
8229
8230 }
8231
8232 /* An ordinary record type (with fixed-length fields) that describes
8233 the value at (VAR_TYPE0, VALADDR, ADDRESS), where VAR_TYPE0 is a
8234 union type. Any necessary discriminants' values should be in DVAL,
8235 a record value. That is, this routine selects the appropriate
8236 branch of the union at ADDR according to the discriminant value
8237 indicated in the union's type name. Returns VAR_TYPE0 itself if
8238 it represents a variant subject to a pragma Unchecked_Union. */
8239
8240 static struct type *
8241 to_fixed_variant_branch_type (struct type *var_type0, const gdb_byte *valaddr,
8242 CORE_ADDR address, struct value *dval)
8243 {
8244 int which;
8245 struct type *templ_type;
8246 struct type *var_type;
8247
8248 if (var_type0->code () == TYPE_CODE_PTR)
8249 var_type = TYPE_TARGET_TYPE (var_type0);
8250 else
8251 var_type = var_type0;
8252
8253 templ_type = ada_find_parallel_type (var_type, "___XVU");
8254
8255 if (templ_type != NULL)
8256 var_type = templ_type;
8257
8258 if (is_unchecked_variant (var_type, value_type (dval)))
8259 return var_type0;
8260 which = ada_which_variant_applies (var_type, dval);
8261
8262 if (which < 0)
8263 return empty_record (var_type);
8264 else if (is_dynamic_field (var_type, which))
8265 return to_fixed_record_type
8266 (TYPE_TARGET_TYPE (var_type->field (which).type ()),
8267 valaddr, address, dval);
8268 else if (variant_field_index (var_type->field (which).type ()) >= 0)
8269 return
8270 to_fixed_record_type
8271 (var_type->field (which).type (), valaddr, address, dval);
8272 else
8273 return var_type->field (which).type ();
8274 }
8275
8276 /* Assuming RANGE_TYPE is a TYPE_CODE_RANGE, return nonzero if
8277 ENCODING_TYPE, a type following the GNAT conventions for discrete
8278 type encodings, only carries redundant information. */
8279
8280 static int
8281 ada_is_redundant_range_encoding (struct type *range_type,
8282 struct type *encoding_type)
8283 {
8284 const char *bounds_str;
8285 int n;
8286 LONGEST lo, hi;
8287
8288 gdb_assert (range_type->code () == TYPE_CODE_RANGE);
8289
8290 if (get_base_type (range_type)->code ()
8291 != get_base_type (encoding_type)->code ())
8292 {
8293 /* The compiler probably used a simple base type to describe
8294 the range type instead of the range's actual base type,
8295 expecting us to get the real base type from the encoding
8296 anyway. In this situation, the encoding cannot be ignored
8297 as redundant. */
8298 return 0;
8299 }
8300
8301 if (is_dynamic_type (range_type))
8302 return 0;
8303
8304 if (encoding_type->name () == NULL)
8305 return 0;
8306
8307 bounds_str = strstr (encoding_type->name (), "___XDLU_");
8308 if (bounds_str == NULL)
8309 return 0;
8310
8311 n = 8; /* Skip "___XDLU_". */
8312 if (!ada_scan_number (bounds_str, n, &lo, &n))
8313 return 0;
8314 if (range_type->bounds ()->low.const_val () != lo)
8315 return 0;
8316
8317 n += 2; /* Skip the "__" separator between the two bounds. */
8318 if (!ada_scan_number (bounds_str, n, &hi, &n))
8319 return 0;
8320 if (range_type->bounds ()->high.const_val () != hi)
8321 return 0;
8322
8323 return 1;
8324 }
8325
8326 /* Given the array type ARRAY_TYPE, return nonzero if DESC_TYPE,
8327 a type following the GNAT encoding for describing array type
8328 indices, only carries redundant information. */
8329
8330 static int
8331 ada_is_redundant_index_type_desc (struct type *array_type,
8332 struct type *desc_type)
8333 {
8334 struct type *this_layer = check_typedef (array_type);
8335 int i;
8336
8337 for (i = 0; i < desc_type->num_fields (); i++)
8338 {
8339 if (!ada_is_redundant_range_encoding (this_layer->index_type (),
8340 desc_type->field (i).type ()))
8341 return 0;
8342 this_layer = check_typedef (TYPE_TARGET_TYPE (this_layer));
8343 }
8344
8345 return 1;
8346 }
8347
8348 /* Assuming that TYPE0 is an array type describing the type of a value
8349 at ADDR, and that DVAL describes a record containing any
8350 discriminants used in TYPE0, returns a type for the value that
8351 contains no dynamic components (that is, no components whose sizes
8352 are determined by run-time quantities). Unless IGNORE_TOO_BIG is
8353 true, gives an error message if the resulting type's size is over
8354 varsize_limit. */
8355
8356 static struct type *
8357 to_fixed_array_type (struct type *type0, struct value *dval,
8358 int ignore_too_big)
8359 {
8360 struct type *index_type_desc;
8361 struct type *result;
8362 int constrained_packed_array_p;
8363 static const char *xa_suffix = "___XA";
8364
8365 type0 = ada_check_typedef (type0);
8366 if (type0->is_fixed_instance ())
8367 return type0;
8368
8369 constrained_packed_array_p = ada_is_constrained_packed_array_type (type0);
8370 if (constrained_packed_array_p)
8371 type0 = decode_constrained_packed_array_type (type0);
8372
8373 index_type_desc = ada_find_parallel_type (type0, xa_suffix);
8374
8375 /* As mentioned in exp_dbug.ads, for non bit-packed arrays an
8376 encoding suffixed with 'P' may still be generated. If so,
8377 it should be used to find the XA type. */
8378
8379 if (index_type_desc == NULL)
8380 {
8381 const char *type_name = ada_type_name (type0);
8382
8383 if (type_name != NULL)
8384 {
8385 const int len = strlen (type_name);
8386 char *name = (char *) alloca (len + strlen (xa_suffix));
8387
8388 if (type_name[len - 1] == 'P')
8389 {
8390 strcpy (name, type_name);
8391 strcpy (name + len - 1, xa_suffix);
8392 index_type_desc = ada_find_parallel_type_with_name (type0, name);
8393 }
8394 }
8395 }
8396
8397 ada_fixup_array_indexes_type (index_type_desc);
8398 if (index_type_desc != NULL
8399 && ada_is_redundant_index_type_desc (type0, index_type_desc))
8400 {
8401 /* Ignore this ___XA parallel type, as it does not bring any
8402 useful information. This allows us to avoid creating fixed
8403 versions of the array's index types, which would be identical
8404 to the original ones. This, in turn, can also help avoid
8405 the creation of fixed versions of the array itself. */
8406 index_type_desc = NULL;
8407 }
8408
8409 if (index_type_desc == NULL)
8410 {
8411 struct type *elt_type0 = ada_check_typedef (TYPE_TARGET_TYPE (type0));
8412
8413 /* NOTE: elt_type---the fixed version of elt_type0---should never
8414 depend on the contents of the array in properly constructed
8415 debugging data. */
8416 /* Create a fixed version of the array element type.
8417 We're not providing the address of an element here,
8418 and thus the actual object value cannot be inspected to do
8419 the conversion. This should not be a problem, since arrays of
8420 unconstrained objects are not allowed. In particular, all
8421 the elements of an array of a tagged type should all be of
8422 the same type specified in the debugging info. No need to
8423 consult the object tag. */
8424 struct type *elt_type = ada_to_fixed_type (elt_type0, 0, 0, dval, 1);
8425
8426 /* Make sure we always create a new array type when dealing with
8427 packed array types, since we're going to fix-up the array
8428 type length and element bitsize a little further down. */
8429 if (elt_type0 == elt_type && !constrained_packed_array_p)
8430 result = type0;
8431 else
8432 result = create_array_type (alloc_type_copy (type0),
8433 elt_type, type0->index_type ());
8434 }
8435 else
8436 {
8437 int i;
8438 struct type *elt_type0;
8439
8440 elt_type0 = type0;
8441 for (i = index_type_desc->num_fields (); i > 0; i -= 1)
8442 elt_type0 = TYPE_TARGET_TYPE (elt_type0);
8443
8444 /* NOTE: result---the fixed version of elt_type0---should never
8445 depend on the contents of the array in properly constructed
8446 debugging data. */
8447 /* Create a fixed version of the array element type.
8448 We're not providing the address of an element here,
8449 and thus the actual object value cannot be inspected to do
8450 the conversion. This should not be a problem, since arrays of
8451 unconstrained objects are not allowed. In particular, all
8452 the elements of an array of a tagged type should all be of
8453 the same type specified in the debugging info. No need to
8454 consult the object tag. */
8455 result =
8456 ada_to_fixed_type (ada_check_typedef (elt_type0), 0, 0, dval, 1);
8457
8458 elt_type0 = type0;
8459 for (i = index_type_desc->num_fields () - 1; i >= 0; i -= 1)
8460 {
8461 struct type *range_type =
8462 to_fixed_range_type (index_type_desc->field (i).type (), dval);
8463
8464 result = create_array_type (alloc_type_copy (elt_type0),
8465 result, range_type);
8466 elt_type0 = TYPE_TARGET_TYPE (elt_type0);
8467 }
8468 if (!ignore_too_big && TYPE_LENGTH (result) > varsize_limit)
8469 error (_("array type with dynamic size is larger than varsize-limit"));
8470 }
8471
8472 /* We want to preserve the type name. This can be useful when
8473 trying to get the type name of a value that has already been
8474 printed (for instance, if the user did "print VAR; whatis $". */
8475 result->set_name (type0->name ());
8476
8477 if (constrained_packed_array_p)
8478 {
8479 /* So far, the resulting type has been created as if the original
8480 type was a regular (non-packed) array type. As a result, the
8481 bitsize of the array elements needs to be set again, and the array
8482 length needs to be recomputed based on that bitsize. */
8483 int len = TYPE_LENGTH (result) / TYPE_LENGTH (TYPE_TARGET_TYPE (result));
8484 int elt_bitsize = TYPE_FIELD_BITSIZE (type0, 0);
8485
8486 TYPE_FIELD_BITSIZE (result, 0) = TYPE_FIELD_BITSIZE (type0, 0);
8487 TYPE_LENGTH (result) = len * elt_bitsize / HOST_CHAR_BIT;
8488 if (TYPE_LENGTH (result) * HOST_CHAR_BIT < len * elt_bitsize)
8489 TYPE_LENGTH (result)++;
8490 }
8491
8492 result->set_is_fixed_instance (true);
8493 return result;
8494 }
8495
8496
8497 /* A standard type (containing no dynamically sized components)
8498 corresponding to TYPE for the value (TYPE, VALADDR, ADDRESS)
8499 DVAL describes a record containing any discriminants used in TYPE0,
8500 and may be NULL if there are none, or if the object of type TYPE at
8501 ADDRESS or in VALADDR contains these discriminants.
8502
8503 If CHECK_TAG is not null, in the case of tagged types, this function
8504 attempts to locate the object's tag and use it to compute the actual
8505 type. However, when ADDRESS is null, we cannot use it to determine the
8506 location of the tag, and therefore compute the tagged type's actual type.
8507 So we return the tagged type without consulting the tag. */
8508
8509 static struct type *
8510 ada_to_fixed_type_1 (struct type *type, const gdb_byte *valaddr,
8511 CORE_ADDR address, struct value *dval, int check_tag)
8512 {
8513 type = ada_check_typedef (type);
8514
8515 /* Only un-fixed types need to be handled here. */
8516 if (!HAVE_GNAT_AUX_INFO (type))
8517 return type;
8518
8519 switch (type->code ())
8520 {
8521 default:
8522 return type;
8523 case TYPE_CODE_STRUCT:
8524 {
8525 struct type *static_type = to_static_fixed_type (type);
8526 struct type *fixed_record_type =
8527 to_fixed_record_type (type, valaddr, address, NULL);
8528
8529 /* If STATIC_TYPE is a tagged type and we know the object's address,
8530 then we can determine its tag, and compute the object's actual
8531 type from there. Note that we have to use the fixed record
8532 type (the parent part of the record may have dynamic fields
8533 and the way the location of _tag is expressed may depend on
8534 them). */
8535
8536 if (check_tag && address != 0 && ada_is_tagged_type (static_type, 0))
8537 {
8538 struct value *tag =
8539 value_tag_from_contents_and_address
8540 (fixed_record_type,
8541 valaddr,
8542 address);
8543 struct type *real_type = type_from_tag (tag);
8544 struct value *obj =
8545 value_from_contents_and_address (fixed_record_type,
8546 valaddr,
8547 address);
8548 fixed_record_type = value_type (obj);
8549 if (real_type != NULL)
8550 return to_fixed_record_type
8551 (real_type, NULL,
8552 value_address (ada_tag_value_at_base_address (obj)), NULL);
8553 }
8554
8555 /* Check to see if there is a parallel ___XVZ variable.
8556 If there is, then it provides the actual size of our type. */
8557 else if (ada_type_name (fixed_record_type) != NULL)
8558 {
8559 const char *name = ada_type_name (fixed_record_type);
8560 char *xvz_name
8561 = (char *) alloca (strlen (name) + 7 /* "___XVZ\0" */);
8562 bool xvz_found = false;
8563 LONGEST size;
8564
8565 xsnprintf (xvz_name, strlen (name) + 7, "%s___XVZ", name);
8566 try
8567 {
8568 xvz_found = get_int_var_value (xvz_name, size);
8569 }
8570 catch (const gdb_exception_error &except)
8571 {
8572 /* We found the variable, but somehow failed to read
8573 its value. Rethrow the same error, but with a little
8574 bit more information, to help the user understand
8575 what went wrong (Eg: the variable might have been
8576 optimized out). */
8577 throw_error (except.error,
8578 _("unable to read value of %s (%s)"),
8579 xvz_name, except.what ());
8580 }
8581
8582 if (xvz_found && TYPE_LENGTH (fixed_record_type) != size)
8583 {
8584 fixed_record_type = copy_type (fixed_record_type);
8585 TYPE_LENGTH (fixed_record_type) = size;
8586
8587 /* The FIXED_RECORD_TYPE may have be a stub. We have
8588 observed this when the debugging info is STABS, and
8589 apparently it is something that is hard to fix.
8590
8591 In practice, we don't need the actual type definition
8592 at all, because the presence of the XVZ variable allows us
8593 to assume that there must be a XVS type as well, which we
8594 should be able to use later, when we need the actual type
8595 definition.
8596
8597 In the meantime, pretend that the "fixed" type we are
8598 returning is NOT a stub, because this can cause trouble
8599 when using this type to create new types targeting it.
8600 Indeed, the associated creation routines often check
8601 whether the target type is a stub and will try to replace
8602 it, thus using a type with the wrong size. This, in turn,
8603 might cause the new type to have the wrong size too.
8604 Consider the case of an array, for instance, where the size
8605 of the array is computed from the number of elements in
8606 our array multiplied by the size of its element. */
8607 fixed_record_type->set_is_stub (false);
8608 }
8609 }
8610 return fixed_record_type;
8611 }
8612 case TYPE_CODE_ARRAY:
8613 return to_fixed_array_type (type, dval, 1);
8614 case TYPE_CODE_UNION:
8615 if (dval == NULL)
8616 return type;
8617 else
8618 return to_fixed_variant_branch_type (type, valaddr, address, dval);
8619 }
8620 }
8621
8622 /* The same as ada_to_fixed_type_1, except that it preserves the type
8623 if it is a TYPE_CODE_TYPEDEF of a type that is already fixed.
8624
8625 The typedef layer needs be preserved in order to differentiate between
8626 arrays and array pointers when both types are implemented using the same
8627 fat pointer. In the array pointer case, the pointer is encoded as
8628 a typedef of the pointer type. For instance, considering:
8629
8630 type String_Access is access String;
8631 S1 : String_Access := null;
8632
8633 To the debugger, S1 is defined as a typedef of type String. But
8634 to the user, it is a pointer. So if the user tries to print S1,
8635 we should not dereference the array, but print the array address
8636 instead.
8637
8638 If we didn't preserve the typedef layer, we would lose the fact that
8639 the type is to be presented as a pointer (needs de-reference before
8640 being printed). And we would also use the source-level type name. */
8641
8642 struct type *
8643 ada_to_fixed_type (struct type *type, const gdb_byte *valaddr,
8644 CORE_ADDR address, struct value *dval, int check_tag)
8645
8646 {
8647 struct type *fixed_type =
8648 ada_to_fixed_type_1 (type, valaddr, address, dval, check_tag);
8649
8650 /* If TYPE is a typedef and its target type is the same as the FIXED_TYPE,
8651 then preserve the typedef layer.
8652
8653 Implementation note: We can only check the main-type portion of
8654 the TYPE and FIXED_TYPE, because eliminating the typedef layer
8655 from TYPE now returns a type that has the same instance flags
8656 as TYPE. For instance, if TYPE is a "typedef const", and its
8657 target type is a "struct", then the typedef elimination will return
8658 a "const" version of the target type. See check_typedef for more
8659 details about how the typedef layer elimination is done.
8660
8661 brobecker/2010-11-19: It seems to me that the only case where it is
8662 useful to preserve the typedef layer is when dealing with fat pointers.
8663 Perhaps, we could add a check for that and preserve the typedef layer
8664 only in that situation. But this seems unnecessary so far, probably
8665 because we call check_typedef/ada_check_typedef pretty much everywhere.
8666 */
8667 if (type->code () == TYPE_CODE_TYPEDEF
8668 && (TYPE_MAIN_TYPE (ada_typedef_target_type (type))
8669 == TYPE_MAIN_TYPE (fixed_type)))
8670 return type;
8671
8672 return fixed_type;
8673 }
8674
8675 /* A standard (static-sized) type corresponding as well as possible to
8676 TYPE0, but based on no runtime data. */
8677
8678 static struct type *
8679 to_static_fixed_type (struct type *type0)
8680 {
8681 struct type *type;
8682
8683 if (type0 == NULL)
8684 return NULL;
8685
8686 if (type0->is_fixed_instance ())
8687 return type0;
8688
8689 type0 = ada_check_typedef (type0);
8690
8691 switch (type0->code ())
8692 {
8693 default:
8694 return type0;
8695 case TYPE_CODE_STRUCT:
8696 type = dynamic_template_type (type0);
8697 if (type != NULL)
8698 return template_to_static_fixed_type (type);
8699 else
8700 return template_to_static_fixed_type (type0);
8701 case TYPE_CODE_UNION:
8702 type = ada_find_parallel_type (type0, "___XVU");
8703 if (type != NULL)
8704 return template_to_static_fixed_type (type);
8705 else
8706 return template_to_static_fixed_type (type0);
8707 }
8708 }
8709
8710 /* A static approximation of TYPE with all type wrappers removed. */
8711
8712 static struct type *
8713 static_unwrap_type (struct type *type)
8714 {
8715 if (ada_is_aligner_type (type))
8716 {
8717 struct type *type1 = ada_check_typedef (type)->field (0).type ();
8718 if (ada_type_name (type1) == NULL)
8719 type1->set_name (ada_type_name (type));
8720
8721 return static_unwrap_type (type1);
8722 }
8723 else
8724 {
8725 struct type *raw_real_type = ada_get_base_type (type);
8726
8727 if (raw_real_type == type)
8728 return type;
8729 else
8730 return to_static_fixed_type (raw_real_type);
8731 }
8732 }
8733
8734 /* In some cases, incomplete and private types require
8735 cross-references that are not resolved as records (for example,
8736 type Foo;
8737 type FooP is access Foo;
8738 V: FooP;
8739 type Foo is array ...;
8740 ). In these cases, since there is no mechanism for producing
8741 cross-references to such types, we instead substitute for FooP a
8742 stub enumeration type that is nowhere resolved, and whose tag is
8743 the name of the actual type. Call these types "non-record stubs". */
8744
8745 /* A type equivalent to TYPE that is not a non-record stub, if one
8746 exists, otherwise TYPE. */
8747
8748 struct type *
8749 ada_check_typedef (struct type *type)
8750 {
8751 if (type == NULL)
8752 return NULL;
8753
8754 /* If our type is an access to an unconstrained array, which is encoded
8755 as a TYPE_CODE_TYPEDEF of a fat pointer, then we're done.
8756 We don't want to strip the TYPE_CODE_TYPDEF layer, because this is
8757 what allows us to distinguish between fat pointers that represent
8758 array types, and fat pointers that represent array access types
8759 (in both cases, the compiler implements them as fat pointers). */
8760 if (ada_is_access_to_unconstrained_array (type))
8761 return type;
8762
8763 type = check_typedef (type);
8764 if (type == NULL || type->code () != TYPE_CODE_ENUM
8765 || !type->is_stub ()
8766 || type->name () == NULL)
8767 return type;
8768 else
8769 {
8770 const char *name = type->name ();
8771 struct type *type1 = ada_find_any_type (name);
8772
8773 if (type1 == NULL)
8774 return type;
8775
8776 /* TYPE1 might itself be a TYPE_CODE_TYPEDEF (this can happen with
8777 stubs pointing to arrays, as we don't create symbols for array
8778 types, only for the typedef-to-array types). If that's the case,
8779 strip the typedef layer. */
8780 if (type1->code () == TYPE_CODE_TYPEDEF)
8781 type1 = ada_check_typedef (type1);
8782
8783 return type1;
8784 }
8785 }
8786
8787 /* A value representing the data at VALADDR/ADDRESS as described by
8788 type TYPE0, but with a standard (static-sized) type that correctly
8789 describes it. If VAL0 is not NULL and TYPE0 already is a standard
8790 type, then return VAL0 [this feature is simply to avoid redundant
8791 creation of struct values]. */
8792
8793 static struct value *
8794 ada_to_fixed_value_create (struct type *type0, CORE_ADDR address,
8795 struct value *val0)
8796 {
8797 struct type *type = ada_to_fixed_type (type0, 0, address, NULL, 1);
8798
8799 if (type == type0 && val0 != NULL)
8800 return val0;
8801
8802 if (VALUE_LVAL (val0) != lval_memory)
8803 {
8804 /* Our value does not live in memory; it could be a convenience
8805 variable, for instance. Create a not_lval value using val0's
8806 contents. */
8807 return value_from_contents (type, value_contents (val0));
8808 }
8809
8810 return value_from_contents_and_address (type, 0, address);
8811 }
8812
8813 /* A value representing VAL, but with a standard (static-sized) type
8814 that correctly describes it. Does not necessarily create a new
8815 value. */
8816
8817 struct value *
8818 ada_to_fixed_value (struct value *val)
8819 {
8820 val = unwrap_value (val);
8821 val = ada_to_fixed_value_create (value_type (val), value_address (val), val);
8822 return val;
8823 }
8824 \f
8825
8826 /* Attributes */
8827
8828 /* Table mapping attribute numbers to names.
8829 NOTE: Keep up to date with enum ada_attribute definition in ada-lang.h. */
8830
8831 static const char * const attribute_names[] = {
8832 "<?>",
8833
8834 "first",
8835 "last",
8836 "length",
8837 "image",
8838 "max",
8839 "min",
8840 "modulus",
8841 "pos",
8842 "size",
8843 "tag",
8844 "val",
8845 0
8846 };
8847
8848 static const char *
8849 ada_attribute_name (enum exp_opcode n)
8850 {
8851 if (n >= OP_ATR_FIRST && n <= (int) OP_ATR_VAL)
8852 return attribute_names[n - OP_ATR_FIRST + 1];
8853 else
8854 return attribute_names[0];
8855 }
8856
8857 /* Evaluate the 'POS attribute applied to ARG. */
8858
8859 static LONGEST
8860 pos_atr (struct value *arg)
8861 {
8862 struct value *val = coerce_ref (arg);
8863 struct type *type = value_type (val);
8864 LONGEST result;
8865
8866 if (!discrete_type_p (type))
8867 error (_("'POS only defined on discrete types"));
8868
8869 if (!discrete_position (type, value_as_long (val), &result))
8870 error (_("enumeration value is invalid: can't find 'POS"));
8871
8872 return result;
8873 }
8874
8875 static struct value *
8876 value_pos_atr (struct type *type, struct value *arg)
8877 {
8878 return value_from_longest (type, pos_atr (arg));
8879 }
8880
8881 /* Evaluate the TYPE'VAL attribute applied to ARG. */
8882
8883 static struct value *
8884 val_atr (struct type *type, LONGEST val)
8885 {
8886 gdb_assert (discrete_type_p (type));
8887 if (type->code () == TYPE_CODE_RANGE)
8888 type = TYPE_TARGET_TYPE (type);
8889 if (type->code () == TYPE_CODE_ENUM)
8890 {
8891 if (val < 0 || val >= type->num_fields ())
8892 error (_("argument to 'VAL out of range"));
8893 val = TYPE_FIELD_ENUMVAL (type, val);
8894 }
8895 return value_from_longest (type, val);
8896 }
8897
8898 static struct value *
8899 value_val_atr (struct type *type, struct value *arg)
8900 {
8901 if (!discrete_type_p (type))
8902 error (_("'VAL only defined on discrete types"));
8903 if (!integer_type_p (value_type (arg)))
8904 error (_("'VAL requires integral argument"));
8905
8906 return val_atr (type, value_as_long (arg));
8907 }
8908 \f
8909
8910 /* Evaluation */
8911
8912 /* True if TYPE appears to be an Ada character type.
8913 [At the moment, this is true only for Character and Wide_Character;
8914 It is a heuristic test that could stand improvement]. */
8915
8916 bool
8917 ada_is_character_type (struct type *type)
8918 {
8919 const char *name;
8920
8921 /* If the type code says it's a character, then assume it really is,
8922 and don't check any further. */
8923 if (type->code () == TYPE_CODE_CHAR)
8924 return true;
8925
8926 /* Otherwise, assume it's a character type iff it is a discrete type
8927 with a known character type name. */
8928 name = ada_type_name (type);
8929 return (name != NULL
8930 && (type->code () == TYPE_CODE_INT
8931 || type->code () == TYPE_CODE_RANGE)
8932 && (strcmp (name, "character") == 0
8933 || strcmp (name, "wide_character") == 0
8934 || strcmp (name, "wide_wide_character") == 0
8935 || strcmp (name, "unsigned char") == 0));
8936 }
8937
8938 /* True if TYPE appears to be an Ada string type. */
8939
8940 bool
8941 ada_is_string_type (struct type *type)
8942 {
8943 type = ada_check_typedef (type);
8944 if (type != NULL
8945 && type->code () != TYPE_CODE_PTR
8946 && (ada_is_simple_array_type (type)
8947 || ada_is_array_descriptor_type (type))
8948 && ada_array_arity (type) == 1)
8949 {
8950 struct type *elttype = ada_array_element_type (type, 1);
8951
8952 return ada_is_character_type (elttype);
8953 }
8954 else
8955 return false;
8956 }
8957
8958 /* The compiler sometimes provides a parallel XVS type for a given
8959 PAD type. Normally, it is safe to follow the PAD type directly,
8960 but older versions of the compiler have a bug that causes the offset
8961 of its "F" field to be wrong. Following that field in that case
8962 would lead to incorrect results, but this can be worked around
8963 by ignoring the PAD type and using the associated XVS type instead.
8964
8965 Set to True if the debugger should trust the contents of PAD types.
8966 Otherwise, ignore the PAD type if there is a parallel XVS type. */
8967 static bool trust_pad_over_xvs = true;
8968
8969 /* True if TYPE is a struct type introduced by the compiler to force the
8970 alignment of a value. Such types have a single field with a
8971 distinctive name. */
8972
8973 int
8974 ada_is_aligner_type (struct type *type)
8975 {
8976 type = ada_check_typedef (type);
8977
8978 if (!trust_pad_over_xvs && ada_find_parallel_type (type, "___XVS") != NULL)
8979 return 0;
8980
8981 return (type->code () == TYPE_CODE_STRUCT
8982 && type->num_fields () == 1
8983 && strcmp (TYPE_FIELD_NAME (type, 0), "F") == 0);
8984 }
8985
8986 /* If there is an ___XVS-convention type parallel to SUBTYPE, return
8987 the parallel type. */
8988
8989 struct type *
8990 ada_get_base_type (struct type *raw_type)
8991 {
8992 struct type *real_type_namer;
8993 struct type *raw_real_type;
8994
8995 if (raw_type == NULL || raw_type->code () != TYPE_CODE_STRUCT)
8996 return raw_type;
8997
8998 if (ada_is_aligner_type (raw_type))
8999 /* The encoding specifies that we should always use the aligner type.
9000 So, even if this aligner type has an associated XVS type, we should
9001 simply ignore it.
9002
9003 According to the compiler gurus, an XVS type parallel to an aligner
9004 type may exist because of a stabs limitation. In stabs, aligner
9005 types are empty because the field has a variable-sized type, and
9006 thus cannot actually be used as an aligner type. As a result,
9007 we need the associated parallel XVS type to decode the type.
9008 Since the policy in the compiler is to not change the internal
9009 representation based on the debugging info format, we sometimes
9010 end up having a redundant XVS type parallel to the aligner type. */
9011 return raw_type;
9012
9013 real_type_namer = ada_find_parallel_type (raw_type, "___XVS");
9014 if (real_type_namer == NULL
9015 || real_type_namer->code () != TYPE_CODE_STRUCT
9016 || real_type_namer->num_fields () != 1)
9017 return raw_type;
9018
9019 if (real_type_namer->field (0).type ()->code () != TYPE_CODE_REF)
9020 {
9021 /* This is an older encoding form where the base type needs to be
9022 looked up by name. We prefer the newer encoding because it is
9023 more efficient. */
9024 raw_real_type = ada_find_any_type (TYPE_FIELD_NAME (real_type_namer, 0));
9025 if (raw_real_type == NULL)
9026 return raw_type;
9027 else
9028 return raw_real_type;
9029 }
9030
9031 /* The field in our XVS type is a reference to the base type. */
9032 return TYPE_TARGET_TYPE (real_type_namer->field (0).type ());
9033 }
9034
9035 /* The type of value designated by TYPE, with all aligners removed. */
9036
9037 struct type *
9038 ada_aligned_type (struct type *type)
9039 {
9040 if (ada_is_aligner_type (type))
9041 return ada_aligned_type (type->field (0).type ());
9042 else
9043 return ada_get_base_type (type);
9044 }
9045
9046
9047 /* The address of the aligned value in an object at address VALADDR
9048 having type TYPE. Assumes ada_is_aligner_type (TYPE). */
9049
9050 const gdb_byte *
9051 ada_aligned_value_addr (struct type *type, const gdb_byte *valaddr)
9052 {
9053 if (ada_is_aligner_type (type))
9054 return ada_aligned_value_addr (type->field (0).type (),
9055 valaddr +
9056 TYPE_FIELD_BITPOS (type,
9057 0) / TARGET_CHAR_BIT);
9058 else
9059 return valaddr;
9060 }
9061
9062
9063
9064 /* The printed representation of an enumeration literal with encoded
9065 name NAME. The value is good to the next call of ada_enum_name. */
9066 const char *
9067 ada_enum_name (const char *name)
9068 {
9069 static char *result;
9070 static size_t result_len = 0;
9071 const char *tmp;
9072
9073 /* First, unqualify the enumeration name:
9074 1. Search for the last '.' character. If we find one, then skip
9075 all the preceding characters, the unqualified name starts
9076 right after that dot.
9077 2. Otherwise, we may be debugging on a target where the compiler
9078 translates dots into "__". Search forward for double underscores,
9079 but stop searching when we hit an overloading suffix, which is
9080 of the form "__" followed by digits. */
9081
9082 tmp = strrchr (name, '.');
9083 if (tmp != NULL)
9084 name = tmp + 1;
9085 else
9086 {
9087 while ((tmp = strstr (name, "__")) != NULL)
9088 {
9089 if (isdigit (tmp[2]))
9090 break;
9091 else
9092 name = tmp + 2;
9093 }
9094 }
9095
9096 if (name[0] == 'Q')
9097 {
9098 int v;
9099
9100 if (name[1] == 'U' || name[1] == 'W')
9101 {
9102 if (sscanf (name + 2, "%x", &v) != 1)
9103 return name;
9104 }
9105 else if (((name[1] >= '0' && name[1] <= '9')
9106 || (name[1] >= 'a' && name[1] <= 'z'))
9107 && name[2] == '\0')
9108 {
9109 GROW_VECT (result, result_len, 4);
9110 xsnprintf (result, result_len, "'%c'", name[1]);
9111 return result;
9112 }
9113 else
9114 return name;
9115
9116 GROW_VECT (result, result_len, 16);
9117 if (isascii (v) && isprint (v))
9118 xsnprintf (result, result_len, "'%c'", v);
9119 else if (name[1] == 'U')
9120 xsnprintf (result, result_len, "[\"%02x\"]", v);
9121 else
9122 xsnprintf (result, result_len, "[\"%04x\"]", v);
9123
9124 return result;
9125 }
9126 else
9127 {
9128 tmp = strstr (name, "__");
9129 if (tmp == NULL)
9130 tmp = strstr (name, "$");
9131 if (tmp != NULL)
9132 {
9133 GROW_VECT (result, result_len, tmp - name + 1);
9134 strncpy (result, name, tmp - name);
9135 result[tmp - name] = '\0';
9136 return result;
9137 }
9138
9139 return name;
9140 }
9141 }
9142
9143 /* Evaluate the subexpression of EXP starting at *POS as for
9144 evaluate_type, updating *POS to point just past the evaluated
9145 expression. */
9146
9147 static struct value *
9148 evaluate_subexp_type (struct expression *exp, int *pos)
9149 {
9150 return evaluate_subexp (nullptr, exp, pos, EVAL_AVOID_SIDE_EFFECTS);
9151 }
9152
9153 /* If VAL is wrapped in an aligner or subtype wrapper, return the
9154 value it wraps. */
9155
9156 static struct value *
9157 unwrap_value (struct value *val)
9158 {
9159 struct type *type = ada_check_typedef (value_type (val));
9160
9161 if (ada_is_aligner_type (type))
9162 {
9163 struct value *v = ada_value_struct_elt (val, "F", 0);
9164 struct type *val_type = ada_check_typedef (value_type (v));
9165
9166 if (ada_type_name (val_type) == NULL)
9167 val_type->set_name (ada_type_name (type));
9168
9169 return unwrap_value (v);
9170 }
9171 else
9172 {
9173 struct type *raw_real_type =
9174 ada_check_typedef (ada_get_base_type (type));
9175
9176 /* If there is no parallel XVS or XVE type, then the value is
9177 already unwrapped. Return it without further modification. */
9178 if ((type == raw_real_type)
9179 && ada_find_parallel_type (type, "___XVE") == NULL)
9180 return val;
9181
9182 return
9183 coerce_unspec_val_to_type
9184 (val, ada_to_fixed_type (raw_real_type, 0,
9185 value_address (val),
9186 NULL, 1));
9187 }
9188 }
9189
9190 static struct value *
9191 cast_from_fixed (struct type *type, struct value *arg)
9192 {
9193 struct value *scale = ada_scaling_factor (value_type (arg));
9194 arg = value_cast (value_type (scale), arg);
9195
9196 arg = value_binop (arg, scale, BINOP_MUL);
9197 return value_cast (type, arg);
9198 }
9199
9200 static struct value *
9201 cast_to_fixed (struct type *type, struct value *arg)
9202 {
9203 if (type == value_type (arg))
9204 return arg;
9205
9206 struct value *scale = ada_scaling_factor (type);
9207 if (ada_is_gnat_encoded_fixed_point_type (value_type (arg)))
9208 arg = cast_from_fixed (value_type (scale), arg);
9209 else
9210 arg = value_cast (value_type (scale), arg);
9211
9212 arg = value_binop (arg, scale, BINOP_DIV);
9213 return value_cast (type, arg);
9214 }
9215
9216 /* Given two array types T1 and T2, return nonzero iff both arrays
9217 contain the same number of elements. */
9218
9219 static int
9220 ada_same_array_size_p (struct type *t1, struct type *t2)
9221 {
9222 LONGEST lo1, hi1, lo2, hi2;
9223
9224 /* Get the array bounds in order to verify that the size of
9225 the two arrays match. */
9226 if (!get_array_bounds (t1, &lo1, &hi1)
9227 || !get_array_bounds (t2, &lo2, &hi2))
9228 error (_("unable to determine array bounds"));
9229
9230 /* To make things easier for size comparison, normalize a bit
9231 the case of empty arrays by making sure that the difference
9232 between upper bound and lower bound is always -1. */
9233 if (lo1 > hi1)
9234 hi1 = lo1 - 1;
9235 if (lo2 > hi2)
9236 hi2 = lo2 - 1;
9237
9238 return (hi1 - lo1 == hi2 - lo2);
9239 }
9240
9241 /* Assuming that VAL is an array of integrals, and TYPE represents
9242 an array with the same number of elements, but with wider integral
9243 elements, return an array "casted" to TYPE. In practice, this
9244 means that the returned array is built by casting each element
9245 of the original array into TYPE's (wider) element type. */
9246
9247 static struct value *
9248 ada_promote_array_of_integrals (struct type *type, struct value *val)
9249 {
9250 struct type *elt_type = TYPE_TARGET_TYPE (type);
9251 LONGEST lo, hi;
9252 struct value *res;
9253 LONGEST i;
9254
9255 /* Verify that both val and type are arrays of scalars, and
9256 that the size of val's elements is smaller than the size
9257 of type's element. */
9258 gdb_assert (type->code () == TYPE_CODE_ARRAY);
9259 gdb_assert (is_integral_type (TYPE_TARGET_TYPE (type)));
9260 gdb_assert (value_type (val)->code () == TYPE_CODE_ARRAY);
9261 gdb_assert (is_integral_type (TYPE_TARGET_TYPE (value_type (val))));
9262 gdb_assert (TYPE_LENGTH (TYPE_TARGET_TYPE (type))
9263 > TYPE_LENGTH (TYPE_TARGET_TYPE (value_type (val))));
9264
9265 if (!get_array_bounds (type, &lo, &hi))
9266 error (_("unable to determine array bounds"));
9267
9268 res = allocate_value (type);
9269
9270 /* Promote each array element. */
9271 for (i = 0; i < hi - lo + 1; i++)
9272 {
9273 struct value *elt = value_cast (elt_type, value_subscript (val, lo + i));
9274
9275 memcpy (value_contents_writeable (res) + (i * TYPE_LENGTH (elt_type)),
9276 value_contents_all (elt), TYPE_LENGTH (elt_type));
9277 }
9278
9279 return res;
9280 }
9281
9282 /* Coerce VAL as necessary for assignment to an lval of type TYPE, and
9283 return the converted value. */
9284
9285 static struct value *
9286 coerce_for_assign (struct type *type, struct value *val)
9287 {
9288 struct type *type2 = value_type (val);
9289
9290 if (type == type2)
9291 return val;
9292
9293 type2 = ada_check_typedef (type2);
9294 type = ada_check_typedef (type);
9295
9296 if (type2->code () == TYPE_CODE_PTR
9297 && type->code () == TYPE_CODE_ARRAY)
9298 {
9299 val = ada_value_ind (val);
9300 type2 = value_type (val);
9301 }
9302
9303 if (type2->code () == TYPE_CODE_ARRAY
9304 && type->code () == TYPE_CODE_ARRAY)
9305 {
9306 if (!ada_same_array_size_p (type, type2))
9307 error (_("cannot assign arrays of different length"));
9308
9309 if (is_integral_type (TYPE_TARGET_TYPE (type))
9310 && is_integral_type (TYPE_TARGET_TYPE (type2))
9311 && TYPE_LENGTH (TYPE_TARGET_TYPE (type2))
9312 < TYPE_LENGTH (TYPE_TARGET_TYPE (type)))
9313 {
9314 /* Allow implicit promotion of the array elements to
9315 a wider type. */
9316 return ada_promote_array_of_integrals (type, val);
9317 }
9318
9319 if (TYPE_LENGTH (TYPE_TARGET_TYPE (type2))
9320 != TYPE_LENGTH (TYPE_TARGET_TYPE (type)))
9321 error (_("Incompatible types in assignment"));
9322 deprecated_set_value_type (val, type);
9323 }
9324 return val;
9325 }
9326
9327 static struct value *
9328 ada_value_binop (struct value *arg1, struct value *arg2, enum exp_opcode op)
9329 {
9330 struct value *val;
9331 struct type *type1, *type2;
9332 LONGEST v, v1, v2;
9333
9334 arg1 = coerce_ref (arg1);
9335 arg2 = coerce_ref (arg2);
9336 type1 = get_base_type (ada_check_typedef (value_type (arg1)));
9337 type2 = get_base_type (ada_check_typedef (value_type (arg2)));
9338
9339 if (type1->code () != TYPE_CODE_INT
9340 || type2->code () != TYPE_CODE_INT)
9341 return value_binop (arg1, arg2, op);
9342
9343 switch (op)
9344 {
9345 case BINOP_MOD:
9346 case BINOP_DIV:
9347 case BINOP_REM:
9348 break;
9349 default:
9350 return value_binop (arg1, arg2, op);
9351 }
9352
9353 v2 = value_as_long (arg2);
9354 if (v2 == 0)
9355 error (_("second operand of %s must not be zero."), op_string (op));
9356
9357 if (type1->is_unsigned () || op == BINOP_MOD)
9358 return value_binop (arg1, arg2, op);
9359
9360 v1 = value_as_long (arg1);
9361 switch (op)
9362 {
9363 case BINOP_DIV:
9364 v = v1 / v2;
9365 if (!TRUNCATION_TOWARDS_ZERO && v1 * (v1 % v2) < 0)
9366 v += v > 0 ? -1 : 1;
9367 break;
9368 case BINOP_REM:
9369 v = v1 % v2;
9370 if (v * v1 < 0)
9371 v -= v2;
9372 break;
9373 default:
9374 /* Should not reach this point. */
9375 v = 0;
9376 }
9377
9378 val = allocate_value (type1);
9379 store_unsigned_integer (value_contents_raw (val),
9380 TYPE_LENGTH (value_type (val)),
9381 type_byte_order (type1), v);
9382 return val;
9383 }
9384
9385 static int
9386 ada_value_equal (struct value *arg1, struct value *arg2)
9387 {
9388 if (ada_is_direct_array_type (value_type (arg1))
9389 || ada_is_direct_array_type (value_type (arg2)))
9390 {
9391 struct type *arg1_type, *arg2_type;
9392
9393 /* Automatically dereference any array reference before
9394 we attempt to perform the comparison. */
9395 arg1 = ada_coerce_ref (arg1);
9396 arg2 = ada_coerce_ref (arg2);
9397
9398 arg1 = ada_coerce_to_simple_array (arg1);
9399 arg2 = ada_coerce_to_simple_array (arg2);
9400
9401 arg1_type = ada_check_typedef (value_type (arg1));
9402 arg2_type = ada_check_typedef (value_type (arg2));
9403
9404 if (arg1_type->code () != TYPE_CODE_ARRAY
9405 || arg2_type->code () != TYPE_CODE_ARRAY)
9406 error (_("Attempt to compare array with non-array"));
9407 /* FIXME: The following works only for types whose
9408 representations use all bits (no padding or undefined bits)
9409 and do not have user-defined equality. */
9410 return (TYPE_LENGTH (arg1_type) == TYPE_LENGTH (arg2_type)
9411 && memcmp (value_contents (arg1), value_contents (arg2),
9412 TYPE_LENGTH (arg1_type)) == 0);
9413 }
9414 return value_equal (arg1, arg2);
9415 }
9416
9417 /* Total number of component associations in the aggregate starting at
9418 index PC in EXP. Assumes that index PC is the start of an
9419 OP_AGGREGATE. */
9420
9421 static int
9422 num_component_specs (struct expression *exp, int pc)
9423 {
9424 int n, m, i;
9425
9426 m = exp->elts[pc + 1].longconst;
9427 pc += 3;
9428 n = 0;
9429 for (i = 0; i < m; i += 1)
9430 {
9431 switch (exp->elts[pc].opcode)
9432 {
9433 default:
9434 n += 1;
9435 break;
9436 case OP_CHOICES:
9437 n += exp->elts[pc + 1].longconst;
9438 break;
9439 }
9440 ada_evaluate_subexp (NULL, exp, &pc, EVAL_SKIP);
9441 }
9442 return n;
9443 }
9444
9445 /* Assign the result of evaluating EXP starting at *POS to the INDEXth
9446 component of LHS (a simple array or a record), updating *POS past
9447 the expression, assuming that LHS is contained in CONTAINER. Does
9448 not modify the inferior's memory, nor does it modify LHS (unless
9449 LHS == CONTAINER). */
9450
9451 static void
9452 assign_component (struct value *container, struct value *lhs, LONGEST index,
9453 struct expression *exp, int *pos)
9454 {
9455 struct value *mark = value_mark ();
9456 struct value *elt;
9457 struct type *lhs_type = check_typedef (value_type (lhs));
9458
9459 if (lhs_type->code () == TYPE_CODE_ARRAY)
9460 {
9461 struct type *index_type = builtin_type (exp->gdbarch)->builtin_int;
9462 struct value *index_val = value_from_longest (index_type, index);
9463
9464 elt = unwrap_value (ada_value_subscript (lhs, 1, &index_val));
9465 }
9466 else
9467 {
9468 elt = ada_index_struct_field (index, lhs, 0, value_type (lhs));
9469 elt = ada_to_fixed_value (elt);
9470 }
9471
9472 if (exp->elts[*pos].opcode == OP_AGGREGATE)
9473 assign_aggregate (container, elt, exp, pos, EVAL_NORMAL);
9474 else
9475 value_assign_to_component (container, elt,
9476 ada_evaluate_subexp (NULL, exp, pos,
9477 EVAL_NORMAL));
9478
9479 value_free_to_mark (mark);
9480 }
9481
9482 /* Assuming that LHS represents an lvalue having a record or array
9483 type, and EXP->ELTS[*POS] is an OP_AGGREGATE, evaluate an assignment
9484 of that aggregate's value to LHS, advancing *POS past the
9485 aggregate. NOSIDE is as for evaluate_subexp. CONTAINER is an
9486 lvalue containing LHS (possibly LHS itself). Does not modify
9487 the inferior's memory, nor does it modify the contents of
9488 LHS (unless == CONTAINER). Returns the modified CONTAINER. */
9489
9490 static struct value *
9491 assign_aggregate (struct value *container,
9492 struct value *lhs, struct expression *exp,
9493 int *pos, enum noside noside)
9494 {
9495 struct type *lhs_type;
9496 int n = exp->elts[*pos+1].longconst;
9497 LONGEST low_index, high_index;
9498 int num_specs;
9499 LONGEST *indices;
9500 int max_indices, num_indices;
9501 int i;
9502
9503 *pos += 3;
9504 if (noside != EVAL_NORMAL)
9505 {
9506 for (i = 0; i < n; i += 1)
9507 ada_evaluate_subexp (NULL, exp, pos, noside);
9508 return container;
9509 }
9510
9511 container = ada_coerce_ref (container);
9512 if (ada_is_direct_array_type (value_type (container)))
9513 container = ada_coerce_to_simple_array (container);
9514 lhs = ada_coerce_ref (lhs);
9515 if (!deprecated_value_modifiable (lhs))
9516 error (_("Left operand of assignment is not a modifiable lvalue."));
9517
9518 lhs_type = check_typedef (value_type (lhs));
9519 if (ada_is_direct_array_type (lhs_type))
9520 {
9521 lhs = ada_coerce_to_simple_array (lhs);
9522 lhs_type = check_typedef (value_type (lhs));
9523 low_index = lhs_type->bounds ()->low.const_val ();
9524 high_index = lhs_type->bounds ()->high.const_val ();
9525 }
9526 else if (lhs_type->code () == TYPE_CODE_STRUCT)
9527 {
9528 low_index = 0;
9529 high_index = num_visible_fields (lhs_type) - 1;
9530 }
9531 else
9532 error (_("Left-hand side must be array or record."));
9533
9534 num_specs = num_component_specs (exp, *pos - 3);
9535 max_indices = 4 * num_specs + 4;
9536 indices = XALLOCAVEC (LONGEST, max_indices);
9537 indices[0] = indices[1] = low_index - 1;
9538 indices[2] = indices[3] = high_index + 1;
9539 num_indices = 4;
9540
9541 for (i = 0; i < n; i += 1)
9542 {
9543 switch (exp->elts[*pos].opcode)
9544 {
9545 case OP_CHOICES:
9546 aggregate_assign_from_choices (container, lhs, exp, pos, indices,
9547 &num_indices, max_indices,
9548 low_index, high_index);
9549 break;
9550 case OP_POSITIONAL:
9551 aggregate_assign_positional (container, lhs, exp, pos, indices,
9552 &num_indices, max_indices,
9553 low_index, high_index);
9554 break;
9555 case OP_OTHERS:
9556 if (i != n-1)
9557 error (_("Misplaced 'others' clause"));
9558 aggregate_assign_others (container, lhs, exp, pos, indices,
9559 num_indices, low_index, high_index);
9560 break;
9561 default:
9562 error (_("Internal error: bad aggregate clause"));
9563 }
9564 }
9565
9566 return container;
9567 }
9568
9569 /* Assign into the component of LHS indexed by the OP_POSITIONAL
9570 construct at *POS, updating *POS past the construct, given that
9571 the positions are relative to lower bound LOW, where HIGH is the
9572 upper bound. Record the position in INDICES[0 .. MAX_INDICES-1]
9573 updating *NUM_INDICES as needed. CONTAINER is as for
9574 assign_aggregate. */
9575 static void
9576 aggregate_assign_positional (struct value *container,
9577 struct value *lhs, struct expression *exp,
9578 int *pos, LONGEST *indices, int *num_indices,
9579 int max_indices, LONGEST low, LONGEST high)
9580 {
9581 LONGEST ind = longest_to_int (exp->elts[*pos + 1].longconst) + low;
9582
9583 if (ind - 1 == high)
9584 warning (_("Extra components in aggregate ignored."));
9585 if (ind <= high)
9586 {
9587 add_component_interval (ind, ind, indices, num_indices, max_indices);
9588 *pos += 3;
9589 assign_component (container, lhs, ind, exp, pos);
9590 }
9591 else
9592 ada_evaluate_subexp (NULL, exp, pos, EVAL_SKIP);
9593 }
9594
9595 /* Assign into the components of LHS indexed by the OP_CHOICES
9596 construct at *POS, updating *POS past the construct, given that
9597 the allowable indices are LOW..HIGH. Record the indices assigned
9598 to in INDICES[0 .. MAX_INDICES-1], updating *NUM_INDICES as
9599 needed. CONTAINER is as for assign_aggregate. */
9600 static void
9601 aggregate_assign_from_choices (struct value *container,
9602 struct value *lhs, struct expression *exp,
9603 int *pos, LONGEST *indices, int *num_indices,
9604 int max_indices, LONGEST low, LONGEST high)
9605 {
9606 int j;
9607 int n_choices = longest_to_int (exp->elts[*pos+1].longconst);
9608 int choice_pos, expr_pc;
9609 int is_array = ada_is_direct_array_type (value_type (lhs));
9610
9611 choice_pos = *pos += 3;
9612
9613 for (j = 0; j < n_choices; j += 1)
9614 ada_evaluate_subexp (NULL, exp, pos, EVAL_SKIP);
9615 expr_pc = *pos;
9616 ada_evaluate_subexp (NULL, exp, pos, EVAL_SKIP);
9617
9618 for (j = 0; j < n_choices; j += 1)
9619 {
9620 LONGEST lower, upper;
9621 enum exp_opcode op = exp->elts[choice_pos].opcode;
9622
9623 if (op == OP_DISCRETE_RANGE)
9624 {
9625 choice_pos += 1;
9626 lower = value_as_long (ada_evaluate_subexp (NULL, exp, pos,
9627 EVAL_NORMAL));
9628 upper = value_as_long (ada_evaluate_subexp (NULL, exp, pos,
9629 EVAL_NORMAL));
9630 }
9631 else if (is_array)
9632 {
9633 lower = value_as_long (ada_evaluate_subexp (NULL, exp, &choice_pos,
9634 EVAL_NORMAL));
9635 upper = lower;
9636 }
9637 else
9638 {
9639 int ind;
9640 const char *name;
9641
9642 switch (op)
9643 {
9644 case OP_NAME:
9645 name = &exp->elts[choice_pos + 2].string;
9646 break;
9647 case OP_VAR_VALUE:
9648 name = exp->elts[choice_pos + 2].symbol->natural_name ();
9649 break;
9650 default:
9651 error (_("Invalid record component association."));
9652 }
9653 ada_evaluate_subexp (NULL, exp, &choice_pos, EVAL_SKIP);
9654 ind = 0;
9655 if (! find_struct_field (name, value_type (lhs), 0,
9656 NULL, NULL, NULL, NULL, &ind))
9657 error (_("Unknown component name: %s."), name);
9658 lower = upper = ind;
9659 }
9660
9661 if (lower <= upper && (lower < low || upper > high))
9662 error (_("Index in component association out of bounds."));
9663
9664 add_component_interval (lower, upper, indices, num_indices,
9665 max_indices);
9666 while (lower <= upper)
9667 {
9668 int pos1;
9669
9670 pos1 = expr_pc;
9671 assign_component (container, lhs, lower, exp, &pos1);
9672 lower += 1;
9673 }
9674 }
9675 }
9676
9677 /* Assign the value of the expression in the OP_OTHERS construct in
9678 EXP at *POS into the components of LHS indexed from LOW .. HIGH that
9679 have not been previously assigned. The index intervals already assigned
9680 are in INDICES[0 .. NUM_INDICES-1]. Updates *POS to after the
9681 OP_OTHERS clause. CONTAINER is as for assign_aggregate. */
9682 static void
9683 aggregate_assign_others (struct value *container,
9684 struct value *lhs, struct expression *exp,
9685 int *pos, LONGEST *indices, int num_indices,
9686 LONGEST low, LONGEST high)
9687 {
9688 int i;
9689 int expr_pc = *pos + 1;
9690
9691 for (i = 0; i < num_indices - 2; i += 2)
9692 {
9693 LONGEST ind;
9694
9695 for (ind = indices[i + 1] + 1; ind < indices[i + 2]; ind += 1)
9696 {
9697 int localpos;
9698
9699 localpos = expr_pc;
9700 assign_component (container, lhs, ind, exp, &localpos);
9701 }
9702 }
9703 ada_evaluate_subexp (NULL, exp, pos, EVAL_SKIP);
9704 }
9705
9706 /* Add the interval [LOW .. HIGH] to the sorted set of intervals
9707 [ INDICES[0] .. INDICES[1] ],..., [ INDICES[*SIZE-2] .. INDICES[*SIZE-1] ],
9708 modifying *SIZE as needed. It is an error if *SIZE exceeds
9709 MAX_SIZE. The resulting intervals do not overlap. */
9710 static void
9711 add_component_interval (LONGEST low, LONGEST high,
9712 LONGEST* indices, int *size, int max_size)
9713 {
9714 int i, j;
9715
9716 for (i = 0; i < *size; i += 2) {
9717 if (high >= indices[i] && low <= indices[i + 1])
9718 {
9719 int kh;
9720
9721 for (kh = i + 2; kh < *size; kh += 2)
9722 if (high < indices[kh])
9723 break;
9724 if (low < indices[i])
9725 indices[i] = low;
9726 indices[i + 1] = indices[kh - 1];
9727 if (high > indices[i + 1])
9728 indices[i + 1] = high;
9729 memcpy (indices + i + 2, indices + kh, *size - kh);
9730 *size -= kh - i - 2;
9731 return;
9732 }
9733 else if (high < indices[i])
9734 break;
9735 }
9736
9737 if (*size == max_size)
9738 error (_("Internal error: miscounted aggregate components."));
9739 *size += 2;
9740 for (j = *size-1; j >= i+2; j -= 1)
9741 indices[j] = indices[j - 2];
9742 indices[i] = low;
9743 indices[i + 1] = high;
9744 }
9745
9746 /* Perform and Ada cast of ARG2 to type TYPE if the type of ARG2
9747 is different. */
9748
9749 static struct value *
9750 ada_value_cast (struct type *type, struct value *arg2)
9751 {
9752 if (type == ada_check_typedef (value_type (arg2)))
9753 return arg2;
9754
9755 if (ada_is_gnat_encoded_fixed_point_type (type))
9756 return cast_to_fixed (type, arg2);
9757
9758 if (ada_is_gnat_encoded_fixed_point_type (value_type (arg2)))
9759 return cast_from_fixed (type, arg2);
9760
9761 return value_cast (type, arg2);
9762 }
9763
9764 /* Evaluating Ada expressions, and printing their result.
9765 ------------------------------------------------------
9766
9767 1. Introduction:
9768 ----------------
9769
9770 We usually evaluate an Ada expression in order to print its value.
9771 We also evaluate an expression in order to print its type, which
9772 happens during the EVAL_AVOID_SIDE_EFFECTS phase of the evaluation,
9773 but we'll focus mostly on the EVAL_NORMAL phase. In practice, the
9774 EVAL_AVOID_SIDE_EFFECTS phase allows us to simplify certain aspects of
9775 the evaluation compared to the EVAL_NORMAL, but is otherwise very
9776 similar.
9777
9778 Evaluating expressions is a little more complicated for Ada entities
9779 than it is for entities in languages such as C. The main reason for
9780 this is that Ada provides types whose definition might be dynamic.
9781 One example of such types is variant records. Or another example
9782 would be an array whose bounds can only be known at run time.
9783
9784 The following description is a general guide as to what should be
9785 done (and what should NOT be done) in order to evaluate an expression
9786 involving such types, and when. This does not cover how the semantic
9787 information is encoded by GNAT as this is covered separatly. For the
9788 document used as the reference for the GNAT encoding, see exp_dbug.ads
9789 in the GNAT sources.
9790
9791 Ideally, we should embed each part of this description next to its
9792 associated code. Unfortunately, the amount of code is so vast right
9793 now that it's hard to see whether the code handling a particular
9794 situation might be duplicated or not. One day, when the code is
9795 cleaned up, this guide might become redundant with the comments
9796 inserted in the code, and we might want to remove it.
9797
9798 2. ``Fixing'' an Entity, the Simple Case:
9799 -----------------------------------------
9800
9801 When evaluating Ada expressions, the tricky issue is that they may
9802 reference entities whose type contents and size are not statically
9803 known. Consider for instance a variant record:
9804
9805 type Rec (Empty : Boolean := True) is record
9806 case Empty is
9807 when True => null;
9808 when False => Value : Integer;
9809 end case;
9810 end record;
9811 Yes : Rec := (Empty => False, Value => 1);
9812 No : Rec := (empty => True);
9813
9814 The size and contents of that record depends on the value of the
9815 descriminant (Rec.Empty). At this point, neither the debugging
9816 information nor the associated type structure in GDB are able to
9817 express such dynamic types. So what the debugger does is to create
9818 "fixed" versions of the type that applies to the specific object.
9819 We also informally refer to this operation as "fixing" an object,
9820 which means creating its associated fixed type.
9821
9822 Example: when printing the value of variable "Yes" above, its fixed
9823 type would look like this:
9824
9825 type Rec is record
9826 Empty : Boolean;
9827 Value : Integer;
9828 end record;
9829
9830 On the other hand, if we printed the value of "No", its fixed type
9831 would become:
9832
9833 type Rec is record
9834 Empty : Boolean;
9835 end record;
9836
9837 Things become a little more complicated when trying to fix an entity
9838 with a dynamic type that directly contains another dynamic type,
9839 such as an array of variant records, for instance. There are
9840 two possible cases: Arrays, and records.
9841
9842 3. ``Fixing'' Arrays:
9843 ---------------------
9844
9845 The type structure in GDB describes an array in terms of its bounds,
9846 and the type of its elements. By design, all elements in the array
9847 have the same type and we cannot represent an array of variant elements
9848 using the current type structure in GDB. When fixing an array,
9849 we cannot fix the array element, as we would potentially need one
9850 fixed type per element of the array. As a result, the best we can do
9851 when fixing an array is to produce an array whose bounds and size
9852 are correct (allowing us to read it from memory), but without having
9853 touched its element type. Fixing each element will be done later,
9854 when (if) necessary.
9855
9856 Arrays are a little simpler to handle than records, because the same
9857 amount of memory is allocated for each element of the array, even if
9858 the amount of space actually used by each element differs from element
9859 to element. Consider for instance the following array of type Rec:
9860
9861 type Rec_Array is array (1 .. 2) of Rec;
9862
9863 The actual amount of memory occupied by each element might be different
9864 from element to element, depending on the value of their discriminant.
9865 But the amount of space reserved for each element in the array remains
9866 fixed regardless. So we simply need to compute that size using
9867 the debugging information available, from which we can then determine
9868 the array size (we multiply the number of elements of the array by
9869 the size of each element).
9870
9871 The simplest case is when we have an array of a constrained element
9872 type. For instance, consider the following type declarations:
9873
9874 type Bounded_String (Max_Size : Integer) is
9875 Length : Integer;
9876 Buffer : String (1 .. Max_Size);
9877 end record;
9878 type Bounded_String_Array is array (1 ..2) of Bounded_String (80);
9879
9880 In this case, the compiler describes the array as an array of
9881 variable-size elements (identified by its XVS suffix) for which
9882 the size can be read in the parallel XVZ variable.
9883
9884 In the case of an array of an unconstrained element type, the compiler
9885 wraps the array element inside a private PAD type. This type should not
9886 be shown to the user, and must be "unwrap"'ed before printing. Note
9887 that we also use the adjective "aligner" in our code to designate
9888 these wrapper types.
9889
9890 In some cases, the size allocated for each element is statically
9891 known. In that case, the PAD type already has the correct size,
9892 and the array element should remain unfixed.
9893
9894 But there are cases when this size is not statically known.
9895 For instance, assuming that "Five" is an integer variable:
9896
9897 type Dynamic is array (1 .. Five) of Integer;
9898 type Wrapper (Has_Length : Boolean := False) is record
9899 Data : Dynamic;
9900 case Has_Length is
9901 when True => Length : Integer;
9902 when False => null;
9903 end case;
9904 end record;
9905 type Wrapper_Array is array (1 .. 2) of Wrapper;
9906
9907 Hello : Wrapper_Array := (others => (Has_Length => True,
9908 Data => (others => 17),
9909 Length => 1));
9910
9911
9912 The debugging info would describe variable Hello as being an
9913 array of a PAD type. The size of that PAD type is not statically
9914 known, but can be determined using a parallel XVZ variable.
9915 In that case, a copy of the PAD type with the correct size should
9916 be used for the fixed array.
9917
9918 3. ``Fixing'' record type objects:
9919 ----------------------------------
9920
9921 Things are slightly different from arrays in the case of dynamic
9922 record types. In this case, in order to compute the associated
9923 fixed type, we need to determine the size and offset of each of
9924 its components. This, in turn, requires us to compute the fixed
9925 type of each of these components.
9926
9927 Consider for instance the example:
9928
9929 type Bounded_String (Max_Size : Natural) is record
9930 Str : String (1 .. Max_Size);
9931 Length : Natural;
9932 end record;
9933 My_String : Bounded_String (Max_Size => 10);
9934
9935 In that case, the position of field "Length" depends on the size
9936 of field Str, which itself depends on the value of the Max_Size
9937 discriminant. In order to fix the type of variable My_String,
9938 we need to fix the type of field Str. Therefore, fixing a variant
9939 record requires us to fix each of its components.
9940
9941 However, if a component does not have a dynamic size, the component
9942 should not be fixed. In particular, fields that use a PAD type
9943 should not fixed. Here is an example where this might happen
9944 (assuming type Rec above):
9945
9946 type Container (Big : Boolean) is record
9947 First : Rec;
9948 After : Integer;
9949 case Big is
9950 when True => Another : Integer;
9951 when False => null;
9952 end case;
9953 end record;
9954 My_Container : Container := (Big => False,
9955 First => (Empty => True),
9956 After => 42);
9957
9958 In that example, the compiler creates a PAD type for component First,
9959 whose size is constant, and then positions the component After just
9960 right after it. The offset of component After is therefore constant
9961 in this case.
9962
9963 The debugger computes the position of each field based on an algorithm
9964 that uses, among other things, the actual position and size of the field
9965 preceding it. Let's now imagine that the user is trying to print
9966 the value of My_Container. If the type fixing was recursive, we would
9967 end up computing the offset of field After based on the size of the
9968 fixed version of field First. And since in our example First has
9969 only one actual field, the size of the fixed type is actually smaller
9970 than the amount of space allocated to that field, and thus we would
9971 compute the wrong offset of field After.
9972
9973 To make things more complicated, we need to watch out for dynamic
9974 components of variant records (identified by the ___XVL suffix in
9975 the component name). Even if the target type is a PAD type, the size
9976 of that type might not be statically known. So the PAD type needs
9977 to be unwrapped and the resulting type needs to be fixed. Otherwise,
9978 we might end up with the wrong size for our component. This can be
9979 observed with the following type declarations:
9980
9981 type Octal is new Integer range 0 .. 7;
9982 type Octal_Array is array (Positive range <>) of Octal;
9983 pragma Pack (Octal_Array);
9984
9985 type Octal_Buffer (Size : Positive) is record
9986 Buffer : Octal_Array (1 .. Size);
9987 Length : Integer;
9988 end record;
9989
9990 In that case, Buffer is a PAD type whose size is unset and needs
9991 to be computed by fixing the unwrapped type.
9992
9993 4. When to ``Fix'' un-``Fixed'' sub-elements of an entity:
9994 ----------------------------------------------------------
9995
9996 Lastly, when should the sub-elements of an entity that remained unfixed
9997 thus far, be actually fixed?
9998
9999 The answer is: Only when referencing that element. For instance
10000 when selecting one component of a record, this specific component
10001 should be fixed at that point in time. Or when printing the value
10002 of a record, each component should be fixed before its value gets
10003 printed. Similarly for arrays, the element of the array should be
10004 fixed when printing each element of the array, or when extracting
10005 one element out of that array. On the other hand, fixing should
10006 not be performed on the elements when taking a slice of an array!
10007
10008 Note that one of the side effects of miscomputing the offset and
10009 size of each field is that we end up also miscomputing the size
10010 of the containing type. This can have adverse results when computing
10011 the value of an entity. GDB fetches the value of an entity based
10012 on the size of its type, and thus a wrong size causes GDB to fetch
10013 the wrong amount of memory. In the case where the computed size is
10014 too small, GDB fetches too little data to print the value of our
10015 entity. Results in this case are unpredictable, as we usually read
10016 past the buffer containing the data =:-o. */
10017
10018 /* Evaluate a subexpression of EXP, at index *POS, and return a value
10019 for that subexpression cast to TO_TYPE. Advance *POS over the
10020 subexpression. */
10021
10022 static value *
10023 ada_evaluate_subexp_for_cast (expression *exp, int *pos,
10024 enum noside noside, struct type *to_type)
10025 {
10026 int pc = *pos;
10027
10028 if (exp->elts[pc].opcode == OP_VAR_MSYM_VALUE
10029 || exp->elts[pc].opcode == OP_VAR_VALUE)
10030 {
10031 (*pos) += 4;
10032
10033 value *val;
10034 if (exp->elts[pc].opcode == OP_VAR_MSYM_VALUE)
10035 {
10036 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10037 return value_zero (to_type, not_lval);
10038
10039 val = evaluate_var_msym_value (noside,
10040 exp->elts[pc + 1].objfile,
10041 exp->elts[pc + 2].msymbol);
10042 }
10043 else
10044 val = evaluate_var_value (noside,
10045 exp->elts[pc + 1].block,
10046 exp->elts[pc + 2].symbol);
10047
10048 if (noside == EVAL_SKIP)
10049 return eval_skip_value (exp);
10050
10051 val = ada_value_cast (to_type, val);
10052
10053 /* Follow the Ada language semantics that do not allow taking
10054 an address of the result of a cast (view conversion in Ada). */
10055 if (VALUE_LVAL (val) == lval_memory)
10056 {
10057 if (value_lazy (val))
10058 value_fetch_lazy (val);
10059 VALUE_LVAL (val) = not_lval;
10060 }
10061 return val;
10062 }
10063
10064 value *val = evaluate_subexp (to_type, exp, pos, noside);
10065 if (noside == EVAL_SKIP)
10066 return eval_skip_value (exp);
10067 return ada_value_cast (to_type, val);
10068 }
10069
10070 /* Implement the evaluate_exp routine in the exp_descriptor structure
10071 for the Ada language. */
10072
10073 static struct value *
10074 ada_evaluate_subexp (struct type *expect_type, struct expression *exp,
10075 int *pos, enum noside noside)
10076 {
10077 enum exp_opcode op;
10078 int tem;
10079 int pc;
10080 int preeval_pos;
10081 struct value *arg1 = NULL, *arg2 = NULL, *arg3;
10082 struct type *type;
10083 int nargs, oplen;
10084 struct value **argvec;
10085
10086 pc = *pos;
10087 *pos += 1;
10088 op = exp->elts[pc].opcode;
10089
10090 switch (op)
10091 {
10092 default:
10093 *pos -= 1;
10094 arg1 = evaluate_subexp_standard (expect_type, exp, pos, noside);
10095
10096 if (noside == EVAL_NORMAL)
10097 arg1 = unwrap_value (arg1);
10098
10099 /* If evaluating an OP_FLOAT and an EXPECT_TYPE was provided,
10100 then we need to perform the conversion manually, because
10101 evaluate_subexp_standard doesn't do it. This conversion is
10102 necessary in Ada because the different kinds of float/fixed
10103 types in Ada have different representations.
10104
10105 Similarly, we need to perform the conversion from OP_LONG
10106 ourselves. */
10107 if ((op == OP_FLOAT || op == OP_LONG) && expect_type != NULL)
10108 arg1 = ada_value_cast (expect_type, arg1);
10109
10110 return arg1;
10111
10112 case OP_STRING:
10113 {
10114 struct value *result;
10115
10116 *pos -= 1;
10117 result = evaluate_subexp_standard (expect_type, exp, pos, noside);
10118 /* The result type will have code OP_STRING, bashed there from
10119 OP_ARRAY. Bash it back. */
10120 if (value_type (result)->code () == TYPE_CODE_STRING)
10121 value_type (result)->set_code (TYPE_CODE_ARRAY);
10122 return result;
10123 }
10124
10125 case UNOP_CAST:
10126 (*pos) += 2;
10127 type = exp->elts[pc + 1].type;
10128 return ada_evaluate_subexp_for_cast (exp, pos, noside, type);
10129
10130 case UNOP_QUAL:
10131 (*pos) += 2;
10132 type = exp->elts[pc + 1].type;
10133 return ada_evaluate_subexp (type, exp, pos, noside);
10134
10135 case BINOP_ASSIGN:
10136 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10137 if (exp->elts[*pos].opcode == OP_AGGREGATE)
10138 {
10139 arg1 = assign_aggregate (arg1, arg1, exp, pos, noside);
10140 if (noside == EVAL_SKIP || noside == EVAL_AVOID_SIDE_EFFECTS)
10141 return arg1;
10142 return ada_value_assign (arg1, arg1);
10143 }
10144 /* Force the evaluation of the rhs ARG2 to the type of the lhs ARG1,
10145 except if the lhs of our assignment is a convenience variable.
10146 In the case of assigning to a convenience variable, the lhs
10147 should be exactly the result of the evaluation of the rhs. */
10148 type = value_type (arg1);
10149 if (VALUE_LVAL (arg1) == lval_internalvar)
10150 type = NULL;
10151 arg2 = evaluate_subexp (type, exp, pos, noside);
10152 if (noside == EVAL_SKIP || noside == EVAL_AVOID_SIDE_EFFECTS)
10153 return arg1;
10154 if (VALUE_LVAL (arg1) == lval_internalvar)
10155 {
10156 /* Nothing. */
10157 }
10158 else if (ada_is_gnat_encoded_fixed_point_type (value_type (arg1)))
10159 arg2 = cast_to_fixed (value_type (arg1), arg2);
10160 else if (ada_is_gnat_encoded_fixed_point_type (value_type (arg2)))
10161 error
10162 (_("Fixed-point values must be assigned to fixed-point variables"));
10163 else
10164 arg2 = coerce_for_assign (value_type (arg1), arg2);
10165 return ada_value_assign (arg1, arg2);
10166
10167 case BINOP_ADD:
10168 arg1 = evaluate_subexp_with_coercion (exp, pos, noside);
10169 arg2 = evaluate_subexp_with_coercion (exp, pos, noside);
10170 if (noside == EVAL_SKIP)
10171 goto nosideret;
10172 if (value_type (arg1)->code () == TYPE_CODE_PTR)
10173 return (value_from_longest
10174 (value_type (arg1),
10175 value_as_long (arg1) + value_as_long (arg2)));
10176 if (value_type (arg2)->code () == TYPE_CODE_PTR)
10177 return (value_from_longest
10178 (value_type (arg2),
10179 value_as_long (arg1) + value_as_long (arg2)));
10180 if ((ada_is_gnat_encoded_fixed_point_type (value_type (arg1))
10181 || ada_is_gnat_encoded_fixed_point_type (value_type (arg2)))
10182 && value_type (arg1) != value_type (arg2))
10183 error (_("Operands of fixed-point addition must have the same type"));
10184 /* Do the addition, and cast the result to the type of the first
10185 argument. We cannot cast the result to a reference type, so if
10186 ARG1 is a reference type, find its underlying type. */
10187 type = value_type (arg1);
10188 while (type->code () == TYPE_CODE_REF)
10189 type = TYPE_TARGET_TYPE (type);
10190 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10191 return value_cast (type, value_binop (arg1, arg2, BINOP_ADD));
10192
10193 case BINOP_SUB:
10194 arg1 = evaluate_subexp_with_coercion (exp, pos, noside);
10195 arg2 = evaluate_subexp_with_coercion (exp, pos, noside);
10196 if (noside == EVAL_SKIP)
10197 goto nosideret;
10198 if (value_type (arg1)->code () == TYPE_CODE_PTR)
10199 return (value_from_longest
10200 (value_type (arg1),
10201 value_as_long (arg1) - value_as_long (arg2)));
10202 if (value_type (arg2)->code () == TYPE_CODE_PTR)
10203 return (value_from_longest
10204 (value_type (arg2),
10205 value_as_long (arg1) - value_as_long (arg2)));
10206 if ((ada_is_gnat_encoded_fixed_point_type (value_type (arg1))
10207 || ada_is_gnat_encoded_fixed_point_type (value_type (arg2)))
10208 && value_type (arg1) != value_type (arg2))
10209 error (_("Operands of fixed-point subtraction "
10210 "must have the same type"));
10211 /* Do the substraction, and cast the result to the type of the first
10212 argument. We cannot cast the result to a reference type, so if
10213 ARG1 is a reference type, find its underlying type. */
10214 type = value_type (arg1);
10215 while (type->code () == TYPE_CODE_REF)
10216 type = TYPE_TARGET_TYPE (type);
10217 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10218 return value_cast (type, value_binop (arg1, arg2, BINOP_SUB));
10219
10220 case BINOP_MUL:
10221 case BINOP_DIV:
10222 case BINOP_REM:
10223 case BINOP_MOD:
10224 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10225 arg2 = evaluate_subexp (nullptr, exp, pos, noside);
10226 if (noside == EVAL_SKIP)
10227 goto nosideret;
10228 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10229 {
10230 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10231 return value_zero (value_type (arg1), not_lval);
10232 }
10233 else
10234 {
10235 type = builtin_type (exp->gdbarch)->builtin_double;
10236 if (ada_is_gnat_encoded_fixed_point_type (value_type (arg1)))
10237 arg1 = cast_from_fixed (type, arg1);
10238 if (ada_is_gnat_encoded_fixed_point_type (value_type (arg2)))
10239 arg2 = cast_from_fixed (type, arg2);
10240 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10241 return ada_value_binop (arg1, arg2, op);
10242 }
10243
10244 case BINOP_EQUAL:
10245 case BINOP_NOTEQUAL:
10246 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10247 arg2 = evaluate_subexp (value_type (arg1), exp, pos, noside);
10248 if (noside == EVAL_SKIP)
10249 goto nosideret;
10250 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10251 tem = 0;
10252 else
10253 {
10254 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10255 tem = ada_value_equal (arg1, arg2);
10256 }
10257 if (op == BINOP_NOTEQUAL)
10258 tem = !tem;
10259 type = language_bool_type (exp->language_defn, exp->gdbarch);
10260 return value_from_longest (type, (LONGEST) tem);
10261
10262 case UNOP_NEG:
10263 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10264 if (noside == EVAL_SKIP)
10265 goto nosideret;
10266 else if (ada_is_gnat_encoded_fixed_point_type (value_type (arg1)))
10267 return value_cast (value_type (arg1), value_neg (arg1));
10268 else
10269 {
10270 unop_promote (exp->language_defn, exp->gdbarch, &arg1);
10271 return value_neg (arg1);
10272 }
10273
10274 case BINOP_LOGICAL_AND:
10275 case BINOP_LOGICAL_OR:
10276 case UNOP_LOGICAL_NOT:
10277 {
10278 struct value *val;
10279
10280 *pos -= 1;
10281 val = evaluate_subexp_standard (expect_type, exp, pos, noside);
10282 type = language_bool_type (exp->language_defn, exp->gdbarch);
10283 return value_cast (type, val);
10284 }
10285
10286 case BINOP_BITWISE_AND:
10287 case BINOP_BITWISE_IOR:
10288 case BINOP_BITWISE_XOR:
10289 {
10290 struct value *val;
10291
10292 arg1 = evaluate_subexp (nullptr, exp, pos, EVAL_AVOID_SIDE_EFFECTS);
10293 *pos = pc;
10294 val = evaluate_subexp_standard (expect_type, exp, pos, noside);
10295
10296 return value_cast (value_type (arg1), val);
10297 }
10298
10299 case OP_VAR_VALUE:
10300 *pos -= 1;
10301
10302 if (noside == EVAL_SKIP)
10303 {
10304 *pos += 4;
10305 goto nosideret;
10306 }
10307
10308 if (SYMBOL_DOMAIN (exp->elts[pc + 2].symbol) == UNDEF_DOMAIN)
10309 /* Only encountered when an unresolved symbol occurs in a
10310 context other than a function call, in which case, it is
10311 invalid. */
10312 error (_("Unexpected unresolved symbol, %s, during evaluation"),
10313 exp->elts[pc + 2].symbol->print_name ());
10314
10315 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10316 {
10317 type = static_unwrap_type (SYMBOL_TYPE (exp->elts[pc + 2].symbol));
10318 /* Check to see if this is a tagged type. We also need to handle
10319 the case where the type is a reference to a tagged type, but
10320 we have to be careful to exclude pointers to tagged types.
10321 The latter should be shown as usual (as a pointer), whereas
10322 a reference should mostly be transparent to the user. */
10323 if (ada_is_tagged_type (type, 0)
10324 || (type->code () == TYPE_CODE_REF
10325 && ada_is_tagged_type (TYPE_TARGET_TYPE (type), 0)))
10326 {
10327 /* Tagged types are a little special in the fact that the real
10328 type is dynamic and can only be determined by inspecting the
10329 object's tag. This means that we need to get the object's
10330 value first (EVAL_NORMAL) and then extract the actual object
10331 type from its tag.
10332
10333 Note that we cannot skip the final step where we extract
10334 the object type from its tag, because the EVAL_NORMAL phase
10335 results in dynamic components being resolved into fixed ones.
10336 This can cause problems when trying to print the type
10337 description of tagged types whose parent has a dynamic size:
10338 We use the type name of the "_parent" component in order
10339 to print the name of the ancestor type in the type description.
10340 If that component had a dynamic size, the resolution into
10341 a fixed type would result in the loss of that type name,
10342 thus preventing us from printing the name of the ancestor
10343 type in the type description. */
10344 arg1 = evaluate_subexp (nullptr, exp, pos, EVAL_NORMAL);
10345
10346 if (type->code () != TYPE_CODE_REF)
10347 {
10348 struct type *actual_type;
10349
10350 actual_type = type_from_tag (ada_value_tag (arg1));
10351 if (actual_type == NULL)
10352 /* If, for some reason, we were unable to determine
10353 the actual type from the tag, then use the static
10354 approximation that we just computed as a fallback.
10355 This can happen if the debugging information is
10356 incomplete, for instance. */
10357 actual_type = type;
10358 return value_zero (actual_type, not_lval);
10359 }
10360 else
10361 {
10362 /* In the case of a ref, ada_coerce_ref takes care
10363 of determining the actual type. But the evaluation
10364 should return a ref as it should be valid to ask
10365 for its address; so rebuild a ref after coerce. */
10366 arg1 = ada_coerce_ref (arg1);
10367 return value_ref (arg1, TYPE_CODE_REF);
10368 }
10369 }
10370
10371 /* Records and unions for which GNAT encodings have been
10372 generated need to be statically fixed as well.
10373 Otherwise, non-static fixing produces a type where
10374 all dynamic properties are removed, which prevents "ptype"
10375 from being able to completely describe the type.
10376 For instance, a case statement in a variant record would be
10377 replaced by the relevant components based on the actual
10378 value of the discriminants. */
10379 if ((type->code () == TYPE_CODE_STRUCT
10380 && dynamic_template_type (type) != NULL)
10381 || (type->code () == TYPE_CODE_UNION
10382 && ada_find_parallel_type (type, "___XVU") != NULL))
10383 {
10384 *pos += 4;
10385 return value_zero (to_static_fixed_type (type), not_lval);
10386 }
10387 }
10388
10389 arg1 = evaluate_subexp_standard (expect_type, exp, pos, noside);
10390 return ada_to_fixed_value (arg1);
10391
10392 case OP_FUNCALL:
10393 (*pos) += 2;
10394
10395 /* Allocate arg vector, including space for the function to be
10396 called in argvec[0] and a terminating NULL. */
10397 nargs = longest_to_int (exp->elts[pc + 1].longconst);
10398 argvec = XALLOCAVEC (struct value *, nargs + 2);
10399
10400 if (exp->elts[*pos].opcode == OP_VAR_VALUE
10401 && SYMBOL_DOMAIN (exp->elts[pc + 5].symbol) == UNDEF_DOMAIN)
10402 error (_("Unexpected unresolved symbol, %s, during evaluation"),
10403 exp->elts[pc + 5].symbol->print_name ());
10404 else
10405 {
10406 for (tem = 0; tem <= nargs; tem += 1)
10407 argvec[tem] = evaluate_subexp (nullptr, exp, pos, noside);
10408 argvec[tem] = 0;
10409
10410 if (noside == EVAL_SKIP)
10411 goto nosideret;
10412 }
10413
10414 if (ada_is_constrained_packed_array_type
10415 (desc_base_type (value_type (argvec[0]))))
10416 argvec[0] = ada_coerce_to_simple_array (argvec[0]);
10417 else if (value_type (argvec[0])->code () == TYPE_CODE_ARRAY
10418 && TYPE_FIELD_BITSIZE (value_type (argvec[0]), 0) != 0)
10419 /* This is a packed array that has already been fixed, and
10420 therefore already coerced to a simple array. Nothing further
10421 to do. */
10422 ;
10423 else if (value_type (argvec[0])->code () == TYPE_CODE_REF)
10424 {
10425 /* Make sure we dereference references so that all the code below
10426 feels like it's really handling the referenced value. Wrapping
10427 types (for alignment) may be there, so make sure we strip them as
10428 well. */
10429 argvec[0] = ada_to_fixed_value (coerce_ref (argvec[0]));
10430 }
10431 else if (value_type (argvec[0])->code () == TYPE_CODE_ARRAY
10432 && VALUE_LVAL (argvec[0]) == lval_memory)
10433 argvec[0] = value_addr (argvec[0]);
10434
10435 type = ada_check_typedef (value_type (argvec[0]));
10436
10437 /* Ada allows us to implicitly dereference arrays when subscripting
10438 them. So, if this is an array typedef (encoding use for array
10439 access types encoded as fat pointers), strip it now. */
10440 if (type->code () == TYPE_CODE_TYPEDEF)
10441 type = ada_typedef_target_type (type);
10442
10443 if (type->code () == TYPE_CODE_PTR)
10444 {
10445 switch (ada_check_typedef (TYPE_TARGET_TYPE (type))->code ())
10446 {
10447 case TYPE_CODE_FUNC:
10448 type = ada_check_typedef (TYPE_TARGET_TYPE (type));
10449 break;
10450 case TYPE_CODE_ARRAY:
10451 break;
10452 case TYPE_CODE_STRUCT:
10453 if (noside != EVAL_AVOID_SIDE_EFFECTS)
10454 argvec[0] = ada_value_ind (argvec[0]);
10455 type = ada_check_typedef (TYPE_TARGET_TYPE (type));
10456 break;
10457 default:
10458 error (_("cannot subscript or call something of type `%s'"),
10459 ada_type_name (value_type (argvec[0])));
10460 break;
10461 }
10462 }
10463
10464 switch (type->code ())
10465 {
10466 case TYPE_CODE_FUNC:
10467 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10468 {
10469 if (TYPE_TARGET_TYPE (type) == NULL)
10470 error_call_unknown_return_type (NULL);
10471 return allocate_value (TYPE_TARGET_TYPE (type));
10472 }
10473 return call_function_by_hand (argvec[0], NULL,
10474 gdb::make_array_view (argvec + 1,
10475 nargs));
10476 case TYPE_CODE_INTERNAL_FUNCTION:
10477 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10478 /* We don't know anything about what the internal
10479 function might return, but we have to return
10480 something. */
10481 return value_zero (builtin_type (exp->gdbarch)->builtin_int,
10482 not_lval);
10483 else
10484 return call_internal_function (exp->gdbarch, exp->language_defn,
10485 argvec[0], nargs, argvec + 1);
10486
10487 case TYPE_CODE_STRUCT:
10488 {
10489 int arity;
10490
10491 arity = ada_array_arity (type);
10492 type = ada_array_element_type (type, nargs);
10493 if (type == NULL)
10494 error (_("cannot subscript or call a record"));
10495 if (arity != nargs)
10496 error (_("wrong number of subscripts; expecting %d"), arity);
10497 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10498 return value_zero (ada_aligned_type (type), lval_memory);
10499 return
10500 unwrap_value (ada_value_subscript
10501 (argvec[0], nargs, argvec + 1));
10502 }
10503 case TYPE_CODE_ARRAY:
10504 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10505 {
10506 type = ada_array_element_type (type, nargs);
10507 if (type == NULL)
10508 error (_("element type of array unknown"));
10509 else
10510 return value_zero (ada_aligned_type (type), lval_memory);
10511 }
10512 return
10513 unwrap_value (ada_value_subscript
10514 (ada_coerce_to_simple_array (argvec[0]),
10515 nargs, argvec + 1));
10516 case TYPE_CODE_PTR: /* Pointer to array */
10517 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10518 {
10519 type = to_fixed_array_type (TYPE_TARGET_TYPE (type), NULL, 1);
10520 type = ada_array_element_type (type, nargs);
10521 if (type == NULL)
10522 error (_("element type of array unknown"));
10523 else
10524 return value_zero (ada_aligned_type (type), lval_memory);
10525 }
10526 return
10527 unwrap_value (ada_value_ptr_subscript (argvec[0],
10528 nargs, argvec + 1));
10529
10530 default:
10531 error (_("Attempt to index or call something other than an "
10532 "array or function"));
10533 }
10534
10535 case TERNOP_SLICE:
10536 {
10537 struct value *array = evaluate_subexp (nullptr, exp, pos, noside);
10538 struct value *low_bound_val
10539 = evaluate_subexp (nullptr, exp, pos, noside);
10540 struct value *high_bound_val
10541 = evaluate_subexp (nullptr, exp, pos, noside);
10542 LONGEST low_bound;
10543 LONGEST high_bound;
10544
10545 low_bound_val = coerce_ref (low_bound_val);
10546 high_bound_val = coerce_ref (high_bound_val);
10547 low_bound = value_as_long (low_bound_val);
10548 high_bound = value_as_long (high_bound_val);
10549
10550 if (noside == EVAL_SKIP)
10551 goto nosideret;
10552
10553 /* If this is a reference to an aligner type, then remove all
10554 the aligners. */
10555 if (value_type (array)->code () == TYPE_CODE_REF
10556 && ada_is_aligner_type (TYPE_TARGET_TYPE (value_type (array))))
10557 TYPE_TARGET_TYPE (value_type (array)) =
10558 ada_aligned_type (TYPE_TARGET_TYPE (value_type (array)));
10559
10560 if (ada_is_constrained_packed_array_type (value_type (array)))
10561 error (_("cannot slice a packed array"));
10562
10563 /* If this is a reference to an array or an array lvalue,
10564 convert to a pointer. */
10565 if (value_type (array)->code () == TYPE_CODE_REF
10566 || (value_type (array)->code () == TYPE_CODE_ARRAY
10567 && VALUE_LVAL (array) == lval_memory))
10568 array = value_addr (array);
10569
10570 if (noside == EVAL_AVOID_SIDE_EFFECTS
10571 && ada_is_array_descriptor_type (ada_check_typedef
10572 (value_type (array))))
10573 return empty_array (ada_type_of_array (array, 0), low_bound,
10574 high_bound);
10575
10576 array = ada_coerce_to_simple_array_ptr (array);
10577
10578 /* If we have more than one level of pointer indirection,
10579 dereference the value until we get only one level. */
10580 while (value_type (array)->code () == TYPE_CODE_PTR
10581 && (TYPE_TARGET_TYPE (value_type (array))->code ()
10582 == TYPE_CODE_PTR))
10583 array = value_ind (array);
10584
10585 /* Make sure we really do have an array type before going further,
10586 to avoid a SEGV when trying to get the index type or the target
10587 type later down the road if the debug info generated by
10588 the compiler is incorrect or incomplete. */
10589 if (!ada_is_simple_array_type (value_type (array)))
10590 error (_("cannot take slice of non-array"));
10591
10592 if (ada_check_typedef (value_type (array))->code ()
10593 == TYPE_CODE_PTR)
10594 {
10595 struct type *type0 = ada_check_typedef (value_type (array));
10596
10597 if (high_bound < low_bound || noside == EVAL_AVOID_SIDE_EFFECTS)
10598 return empty_array (TYPE_TARGET_TYPE (type0), low_bound, high_bound);
10599 else
10600 {
10601 struct type *arr_type0 =
10602 to_fixed_array_type (TYPE_TARGET_TYPE (type0), NULL, 1);
10603
10604 return ada_value_slice_from_ptr (array, arr_type0,
10605 longest_to_int (low_bound),
10606 longest_to_int (high_bound));
10607 }
10608 }
10609 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10610 return array;
10611 else if (high_bound < low_bound)
10612 return empty_array (value_type (array), low_bound, high_bound);
10613 else
10614 return ada_value_slice (array, longest_to_int (low_bound),
10615 longest_to_int (high_bound));
10616 }
10617
10618 case UNOP_IN_RANGE:
10619 (*pos) += 2;
10620 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10621 type = check_typedef (exp->elts[pc + 1].type);
10622
10623 if (noside == EVAL_SKIP)
10624 goto nosideret;
10625
10626 switch (type->code ())
10627 {
10628 default:
10629 lim_warning (_("Membership test incompletely implemented; "
10630 "always returns true"));
10631 type = language_bool_type (exp->language_defn, exp->gdbarch);
10632 return value_from_longest (type, (LONGEST) 1);
10633
10634 case TYPE_CODE_RANGE:
10635 arg2 = value_from_longest (type,
10636 type->bounds ()->low.const_val ());
10637 arg3 = value_from_longest (type,
10638 type->bounds ()->high.const_val ());
10639 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10640 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg3);
10641 type = language_bool_type (exp->language_defn, exp->gdbarch);
10642 return
10643 value_from_longest (type,
10644 (value_less (arg1, arg3)
10645 || value_equal (arg1, arg3))
10646 && (value_less (arg2, arg1)
10647 || value_equal (arg2, arg1)));
10648 }
10649
10650 case BINOP_IN_BOUNDS:
10651 (*pos) += 2;
10652 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10653 arg2 = evaluate_subexp (nullptr, exp, pos, noside);
10654
10655 if (noside == EVAL_SKIP)
10656 goto nosideret;
10657
10658 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10659 {
10660 type = language_bool_type (exp->language_defn, exp->gdbarch);
10661 return value_zero (type, not_lval);
10662 }
10663
10664 tem = longest_to_int (exp->elts[pc + 1].longconst);
10665
10666 type = ada_index_type (value_type (arg2), tem, "range");
10667 if (!type)
10668 type = value_type (arg1);
10669
10670 arg3 = value_from_longest (type, ada_array_bound (arg2, tem, 1));
10671 arg2 = value_from_longest (type, ada_array_bound (arg2, tem, 0));
10672
10673 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10674 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg3);
10675 type = language_bool_type (exp->language_defn, exp->gdbarch);
10676 return
10677 value_from_longest (type,
10678 (value_less (arg1, arg3)
10679 || value_equal (arg1, arg3))
10680 && (value_less (arg2, arg1)
10681 || value_equal (arg2, arg1)));
10682
10683 case TERNOP_IN_RANGE:
10684 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10685 arg2 = evaluate_subexp (nullptr, exp, pos, noside);
10686 arg3 = evaluate_subexp (nullptr, exp, pos, noside);
10687
10688 if (noside == EVAL_SKIP)
10689 goto nosideret;
10690
10691 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10692 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg3);
10693 type = language_bool_type (exp->language_defn, exp->gdbarch);
10694 return
10695 value_from_longest (type,
10696 (value_less (arg1, arg3)
10697 || value_equal (arg1, arg3))
10698 && (value_less (arg2, arg1)
10699 || value_equal (arg2, arg1)));
10700
10701 case OP_ATR_FIRST:
10702 case OP_ATR_LAST:
10703 case OP_ATR_LENGTH:
10704 {
10705 struct type *type_arg;
10706
10707 if (exp->elts[*pos].opcode == OP_TYPE)
10708 {
10709 evaluate_subexp (nullptr, exp, pos, EVAL_SKIP);
10710 arg1 = NULL;
10711 type_arg = check_typedef (exp->elts[pc + 2].type);
10712 }
10713 else
10714 {
10715 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10716 type_arg = NULL;
10717 }
10718
10719 if (exp->elts[*pos].opcode != OP_LONG)
10720 error (_("Invalid operand to '%s"), ada_attribute_name (op));
10721 tem = longest_to_int (exp->elts[*pos + 2].longconst);
10722 *pos += 4;
10723
10724 if (noside == EVAL_SKIP)
10725 goto nosideret;
10726 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10727 {
10728 if (type_arg == NULL)
10729 type_arg = value_type (arg1);
10730
10731 if (ada_is_constrained_packed_array_type (type_arg))
10732 type_arg = decode_constrained_packed_array_type (type_arg);
10733
10734 if (!discrete_type_p (type_arg))
10735 {
10736 switch (op)
10737 {
10738 default: /* Should never happen. */
10739 error (_("unexpected attribute encountered"));
10740 case OP_ATR_FIRST:
10741 case OP_ATR_LAST:
10742 type_arg = ada_index_type (type_arg, tem,
10743 ada_attribute_name (op));
10744 break;
10745 case OP_ATR_LENGTH:
10746 type_arg = builtin_type (exp->gdbarch)->builtin_int;
10747 break;
10748 }
10749 }
10750
10751 return value_zero (type_arg, not_lval);
10752 }
10753 else if (type_arg == NULL)
10754 {
10755 arg1 = ada_coerce_ref (arg1);
10756
10757 if (ada_is_constrained_packed_array_type (value_type (arg1)))
10758 arg1 = ada_coerce_to_simple_array (arg1);
10759
10760 if (op == OP_ATR_LENGTH)
10761 type = builtin_type (exp->gdbarch)->builtin_int;
10762 else
10763 {
10764 type = ada_index_type (value_type (arg1), tem,
10765 ada_attribute_name (op));
10766 if (type == NULL)
10767 type = builtin_type (exp->gdbarch)->builtin_int;
10768 }
10769
10770 switch (op)
10771 {
10772 default: /* Should never happen. */
10773 error (_("unexpected attribute encountered"));
10774 case OP_ATR_FIRST:
10775 return value_from_longest
10776 (type, ada_array_bound (arg1, tem, 0));
10777 case OP_ATR_LAST:
10778 return value_from_longest
10779 (type, ada_array_bound (arg1, tem, 1));
10780 case OP_ATR_LENGTH:
10781 return value_from_longest
10782 (type, ada_array_length (arg1, tem));
10783 }
10784 }
10785 else if (discrete_type_p (type_arg))
10786 {
10787 struct type *range_type;
10788 const char *name = ada_type_name (type_arg);
10789
10790 range_type = NULL;
10791 if (name != NULL && type_arg->code () != TYPE_CODE_ENUM)
10792 range_type = to_fixed_range_type (type_arg, NULL);
10793 if (range_type == NULL)
10794 range_type = type_arg;
10795 switch (op)
10796 {
10797 default:
10798 error (_("unexpected attribute encountered"));
10799 case OP_ATR_FIRST:
10800 return value_from_longest
10801 (range_type, ada_discrete_type_low_bound (range_type));
10802 case OP_ATR_LAST:
10803 return value_from_longest
10804 (range_type, ada_discrete_type_high_bound (range_type));
10805 case OP_ATR_LENGTH:
10806 error (_("the 'length attribute applies only to array types"));
10807 }
10808 }
10809 else if (type_arg->code () == TYPE_CODE_FLT)
10810 error (_("unimplemented type attribute"));
10811 else
10812 {
10813 LONGEST low, high;
10814
10815 if (ada_is_constrained_packed_array_type (type_arg))
10816 type_arg = decode_constrained_packed_array_type (type_arg);
10817
10818 if (op == OP_ATR_LENGTH)
10819 type = builtin_type (exp->gdbarch)->builtin_int;
10820 else
10821 {
10822 type = ada_index_type (type_arg, tem, ada_attribute_name (op));
10823 if (type == NULL)
10824 type = builtin_type (exp->gdbarch)->builtin_int;
10825 }
10826
10827 switch (op)
10828 {
10829 default:
10830 error (_("unexpected attribute encountered"));
10831 case OP_ATR_FIRST:
10832 low = ada_array_bound_from_type (type_arg, tem, 0);
10833 return value_from_longest (type, low);
10834 case OP_ATR_LAST:
10835 high = ada_array_bound_from_type (type_arg, tem, 1);
10836 return value_from_longest (type, high);
10837 case OP_ATR_LENGTH:
10838 low = ada_array_bound_from_type (type_arg, tem, 0);
10839 high = ada_array_bound_from_type (type_arg, tem, 1);
10840 return value_from_longest (type, high - low + 1);
10841 }
10842 }
10843 }
10844
10845 case OP_ATR_TAG:
10846 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10847 if (noside == EVAL_SKIP)
10848 goto nosideret;
10849
10850 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10851 return value_zero (ada_tag_type (arg1), not_lval);
10852
10853 return ada_value_tag (arg1);
10854
10855 case OP_ATR_MIN:
10856 case OP_ATR_MAX:
10857 evaluate_subexp (nullptr, exp, pos, EVAL_SKIP);
10858 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10859 arg2 = evaluate_subexp (nullptr, exp, pos, noside);
10860 if (noside == EVAL_SKIP)
10861 goto nosideret;
10862 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10863 return value_zero (value_type (arg1), not_lval);
10864 else
10865 {
10866 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10867 return value_binop (arg1, arg2,
10868 op == OP_ATR_MIN ? BINOP_MIN : BINOP_MAX);
10869 }
10870
10871 case OP_ATR_MODULUS:
10872 {
10873 struct type *type_arg = check_typedef (exp->elts[pc + 2].type);
10874
10875 evaluate_subexp (nullptr, exp, pos, EVAL_SKIP);
10876 if (noside == EVAL_SKIP)
10877 goto nosideret;
10878
10879 if (!ada_is_modular_type (type_arg))
10880 error (_("'modulus must be applied to modular type"));
10881
10882 return value_from_longest (TYPE_TARGET_TYPE (type_arg),
10883 ada_modulus (type_arg));
10884 }
10885
10886
10887 case OP_ATR_POS:
10888 evaluate_subexp (nullptr, exp, pos, EVAL_SKIP);
10889 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10890 if (noside == EVAL_SKIP)
10891 goto nosideret;
10892 type = builtin_type (exp->gdbarch)->builtin_int;
10893 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10894 return value_zero (type, not_lval);
10895 else
10896 return value_pos_atr (type, arg1);
10897
10898 case OP_ATR_SIZE:
10899 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10900 type = value_type (arg1);
10901
10902 /* If the argument is a reference, then dereference its type, since
10903 the user is really asking for the size of the actual object,
10904 not the size of the pointer. */
10905 if (type->code () == TYPE_CODE_REF)
10906 type = TYPE_TARGET_TYPE (type);
10907
10908 if (noside == EVAL_SKIP)
10909 goto nosideret;
10910 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10911 return value_zero (builtin_type (exp->gdbarch)->builtin_int, not_lval);
10912 else
10913 return value_from_longest (builtin_type (exp->gdbarch)->builtin_int,
10914 TARGET_CHAR_BIT * TYPE_LENGTH (type));
10915
10916 case OP_ATR_VAL:
10917 evaluate_subexp (nullptr, exp, pos, EVAL_SKIP);
10918 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10919 type = exp->elts[pc + 2].type;
10920 if (noside == EVAL_SKIP)
10921 goto nosideret;
10922 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10923 return value_zero (type, not_lval);
10924 else
10925 return value_val_atr (type, arg1);
10926
10927 case BINOP_EXP:
10928 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10929 arg2 = evaluate_subexp (nullptr, exp, pos, noside);
10930 if (noside == EVAL_SKIP)
10931 goto nosideret;
10932 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
10933 return value_zero (value_type (arg1), not_lval);
10934 else
10935 {
10936 /* For integer exponentiation operations,
10937 only promote the first argument. */
10938 if (is_integral_type (value_type (arg2)))
10939 unop_promote (exp->language_defn, exp->gdbarch, &arg1);
10940 else
10941 binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2);
10942
10943 return value_binop (arg1, arg2, op);
10944 }
10945
10946 case UNOP_PLUS:
10947 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10948 if (noside == EVAL_SKIP)
10949 goto nosideret;
10950 else
10951 return arg1;
10952
10953 case UNOP_ABS:
10954 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10955 if (noside == EVAL_SKIP)
10956 goto nosideret;
10957 unop_promote (exp->language_defn, exp->gdbarch, &arg1);
10958 if (value_less (arg1, value_zero (value_type (arg1), not_lval)))
10959 return value_neg (arg1);
10960 else
10961 return arg1;
10962
10963 case UNOP_IND:
10964 preeval_pos = *pos;
10965 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
10966 if (noside == EVAL_SKIP)
10967 goto nosideret;
10968 type = ada_check_typedef (value_type (arg1));
10969 if (noside == EVAL_AVOID_SIDE_EFFECTS)
10970 {
10971 if (ada_is_array_descriptor_type (type))
10972 /* GDB allows dereferencing GNAT array descriptors. */
10973 {
10974 struct type *arrType = ada_type_of_array (arg1, 0);
10975
10976 if (arrType == NULL)
10977 error (_("Attempt to dereference null array pointer."));
10978 return value_at_lazy (arrType, 0);
10979 }
10980 else if (type->code () == TYPE_CODE_PTR
10981 || type->code () == TYPE_CODE_REF
10982 /* In C you can dereference an array to get the 1st elt. */
10983 || type->code () == TYPE_CODE_ARRAY)
10984 {
10985 /* As mentioned in the OP_VAR_VALUE case, tagged types can
10986 only be determined by inspecting the object's tag.
10987 This means that we need to evaluate completely the
10988 expression in order to get its type. */
10989
10990 if ((type->code () == TYPE_CODE_REF
10991 || type->code () == TYPE_CODE_PTR)
10992 && ada_is_tagged_type (TYPE_TARGET_TYPE (type), 0))
10993 {
10994 arg1
10995 = evaluate_subexp (nullptr, exp, &preeval_pos, EVAL_NORMAL);
10996 type = value_type (ada_value_ind (arg1));
10997 }
10998 else
10999 {
11000 type = to_static_fixed_type
11001 (ada_aligned_type
11002 (ada_check_typedef (TYPE_TARGET_TYPE (type))));
11003 }
11004 ada_ensure_varsize_limit (type);
11005 return value_zero (type, lval_memory);
11006 }
11007 else if (type->code () == TYPE_CODE_INT)
11008 {
11009 /* GDB allows dereferencing an int. */
11010 if (expect_type == NULL)
11011 return value_zero (builtin_type (exp->gdbarch)->builtin_int,
11012 lval_memory);
11013 else
11014 {
11015 expect_type =
11016 to_static_fixed_type (ada_aligned_type (expect_type));
11017 return value_zero (expect_type, lval_memory);
11018 }
11019 }
11020 else
11021 error (_("Attempt to take contents of a non-pointer value."));
11022 }
11023 arg1 = ada_coerce_ref (arg1); /* FIXME: What is this for?? */
11024 type = ada_check_typedef (value_type (arg1));
11025
11026 if (type->code () == TYPE_CODE_INT)
11027 /* GDB allows dereferencing an int. If we were given
11028 the expect_type, then use that as the target type.
11029 Otherwise, assume that the target type is an int. */
11030 {
11031 if (expect_type != NULL)
11032 return ada_value_ind (value_cast (lookup_pointer_type (expect_type),
11033 arg1));
11034 else
11035 return value_at_lazy (builtin_type (exp->gdbarch)->builtin_int,
11036 (CORE_ADDR) value_as_address (arg1));
11037 }
11038
11039 if (ada_is_array_descriptor_type (type))
11040 /* GDB allows dereferencing GNAT array descriptors. */
11041 return ada_coerce_to_simple_array (arg1);
11042 else
11043 return ada_value_ind (arg1);
11044
11045 case STRUCTOP_STRUCT:
11046 tem = longest_to_int (exp->elts[pc + 1].longconst);
11047 (*pos) += 3 + BYTES_TO_EXP_ELEM (tem + 1);
11048 preeval_pos = *pos;
11049 arg1 = evaluate_subexp (nullptr, exp, pos, noside);
11050 if (noside == EVAL_SKIP)
11051 goto nosideret;
11052 if (noside == EVAL_AVOID_SIDE_EFFECTS)
11053 {
11054 struct type *type1 = value_type (arg1);
11055
11056 if (ada_is_tagged_type (type1, 1))
11057 {
11058 type = ada_lookup_struct_elt_type (type1,
11059 &exp->elts[pc + 2].string,
11060 1, 1);
11061
11062 /* If the field is not found, check if it exists in the
11063 extension of this object's type. This means that we
11064 need to evaluate completely the expression. */
11065
11066 if (type == NULL)
11067 {
11068 arg1
11069 = evaluate_subexp (nullptr, exp, &preeval_pos, EVAL_NORMAL);
11070 arg1 = ada_value_struct_elt (arg1,
11071 &exp->elts[pc + 2].string,
11072 0);
11073 arg1 = unwrap_value (arg1);
11074 type = value_type (ada_to_fixed_value (arg1));
11075 }
11076 }
11077 else
11078 type =
11079 ada_lookup_struct_elt_type (type1, &exp->elts[pc + 2].string, 1,
11080 0);
11081
11082 return value_zero (ada_aligned_type (type), lval_memory);
11083 }
11084 else
11085 {
11086 arg1 = ada_value_struct_elt (arg1, &exp->elts[pc + 2].string, 0);
11087 arg1 = unwrap_value (arg1);
11088 return ada_to_fixed_value (arg1);
11089 }
11090
11091 case OP_TYPE:
11092 /* The value is not supposed to be used. This is here to make it
11093 easier to accommodate expressions that contain types. */
11094 (*pos) += 2;
11095 if (noside == EVAL_SKIP)
11096 goto nosideret;
11097 else if (noside == EVAL_AVOID_SIDE_EFFECTS)
11098 return allocate_value (exp->elts[pc + 1].type);
11099 else
11100 error (_("Attempt to use a type name as an expression"));
11101
11102 case OP_AGGREGATE:
11103 case OP_CHOICES:
11104 case OP_OTHERS:
11105 case OP_DISCRETE_RANGE:
11106 case OP_POSITIONAL:
11107 case OP_NAME:
11108 if (noside == EVAL_NORMAL)
11109 switch (op)
11110 {
11111 case OP_NAME:
11112 error (_("Undefined name, ambiguous name, or renaming used in "
11113 "component association: %s."), &exp->elts[pc+2].string);
11114 case OP_AGGREGATE:
11115 error (_("Aggregates only allowed on the right of an assignment"));
11116 default:
11117 internal_error (__FILE__, __LINE__,
11118 _("aggregate apparently mangled"));
11119 }
11120
11121 ada_forward_operator_length (exp, pc, &oplen, &nargs);
11122 *pos += oplen - 1;
11123 for (tem = 0; tem < nargs; tem += 1)
11124 ada_evaluate_subexp (NULL, exp, pos, noside);
11125 goto nosideret;
11126 }
11127
11128 nosideret:
11129 return eval_skip_value (exp);
11130 }
11131 \f
11132
11133 /* Fixed point */
11134
11135 /* If TYPE encodes an Ada fixed-point type, return the suffix of the
11136 type name that encodes the 'small and 'delta information.
11137 Otherwise, return NULL. */
11138
11139 static const char *
11140 gnat_encoded_fixed_type_info (struct type *type)
11141 {
11142 const char *name = ada_type_name (type);
11143 enum type_code code = (type == NULL) ? TYPE_CODE_UNDEF : type->code ();
11144
11145 if ((code == TYPE_CODE_INT || code == TYPE_CODE_RANGE) && name != NULL)
11146 {
11147 const char *tail = strstr (name, "___XF_");
11148
11149 if (tail == NULL)
11150 return NULL;
11151 else
11152 return tail + 5;
11153 }
11154 else if (code == TYPE_CODE_RANGE && TYPE_TARGET_TYPE (type) != type)
11155 return gnat_encoded_fixed_type_info (TYPE_TARGET_TYPE (type));
11156 else
11157 return NULL;
11158 }
11159
11160 /* Returns non-zero iff TYPE represents an Ada fixed-point type. */
11161
11162 int
11163 ada_is_gnat_encoded_fixed_point_type (struct type *type)
11164 {
11165 return gnat_encoded_fixed_type_info (type) != NULL;
11166 }
11167
11168 /* Return non-zero iff TYPE represents a System.Address type. */
11169
11170 int
11171 ada_is_system_address_type (struct type *type)
11172 {
11173 return (type->name () && strcmp (type->name (), "system__address") == 0);
11174 }
11175
11176 /* Assuming that TYPE is the representation of an Ada fixed-point
11177 type, return the target floating-point type to be used to represent
11178 of this type during internal computation. */
11179
11180 static struct type *
11181 ada_scaling_type (struct type *type)
11182 {
11183 return builtin_type (get_type_arch (type))->builtin_long_double;
11184 }
11185
11186 /* Assuming that TYPE is the representation of an Ada fixed-point
11187 type, return its delta, or NULL if the type is malformed and the
11188 delta cannot be determined. */
11189
11190 struct value *
11191 gnat_encoded_fixed_point_delta (struct type *type)
11192 {
11193 const char *encoding = gnat_encoded_fixed_type_info (type);
11194 struct type *scale_type = ada_scaling_type (type);
11195
11196 long long num, den;
11197
11198 if (sscanf (encoding, "_%lld_%lld", &num, &den) < 2)
11199 return nullptr;
11200 else
11201 return value_binop (value_from_longest (scale_type, num),
11202 value_from_longest (scale_type, den), BINOP_DIV);
11203 }
11204
11205 /* Assuming that ada_is_gnat_encoded_fixed_point_type (TYPE), return
11206 the scaling factor ('SMALL value) associated with the type. */
11207
11208 struct value *
11209 ada_scaling_factor (struct type *type)
11210 {
11211 const char *encoding = gnat_encoded_fixed_type_info (type);
11212 struct type *scale_type = ada_scaling_type (type);
11213
11214 long long num0, den0, num1, den1;
11215 int n;
11216
11217 n = sscanf (encoding, "_%lld_%lld_%lld_%lld",
11218 &num0, &den0, &num1, &den1);
11219
11220 if (n < 2)
11221 return value_from_longest (scale_type, 1);
11222 else if (n == 4)
11223 return value_binop (value_from_longest (scale_type, num1),
11224 value_from_longest (scale_type, den1), BINOP_DIV);
11225 else
11226 return value_binop (value_from_longest (scale_type, num0),
11227 value_from_longest (scale_type, den0), BINOP_DIV);
11228 }
11229
11230 \f
11231
11232 /* Range types */
11233
11234 /* Scan STR beginning at position K for a discriminant name, and
11235 return the value of that discriminant field of DVAL in *PX. If
11236 PNEW_K is not null, put the position of the character beyond the
11237 name scanned in *PNEW_K. Return 1 if successful; return 0 and do
11238 not alter *PX and *PNEW_K if unsuccessful. */
11239
11240 static int
11241 scan_discrim_bound (const char *str, int k, struct value *dval, LONGEST * px,
11242 int *pnew_k)
11243 {
11244 static char *bound_buffer = NULL;
11245 static size_t bound_buffer_len = 0;
11246 const char *pstart, *pend, *bound;
11247 struct value *bound_val;
11248
11249 if (dval == NULL || str == NULL || str[k] == '\0')
11250 return 0;
11251
11252 pstart = str + k;
11253 pend = strstr (pstart, "__");
11254 if (pend == NULL)
11255 {
11256 bound = pstart;
11257 k += strlen (bound);
11258 }
11259 else
11260 {
11261 int len = pend - pstart;
11262
11263 /* Strip __ and beyond. */
11264 GROW_VECT (bound_buffer, bound_buffer_len, len + 1);
11265 strncpy (bound_buffer, pstart, len);
11266 bound_buffer[len] = '\0';
11267
11268 bound = bound_buffer;
11269 k = pend - str;
11270 }
11271
11272 bound_val = ada_search_struct_field (bound, dval, 0, value_type (dval));
11273 if (bound_val == NULL)
11274 return 0;
11275
11276 *px = value_as_long (bound_val);
11277 if (pnew_k != NULL)
11278 *pnew_k = k;
11279 return 1;
11280 }
11281
11282 /* Value of variable named NAME in the current environment. If
11283 no such variable found, then if ERR_MSG is null, returns 0, and
11284 otherwise causes an error with message ERR_MSG. */
11285
11286 static struct value *
11287 get_var_value (const char *name, const char *err_msg)
11288 {
11289 lookup_name_info lookup_name (name, symbol_name_match_type::FULL);
11290
11291 std::vector<struct block_symbol> syms;
11292 int nsyms = ada_lookup_symbol_list_worker (lookup_name,
11293 get_selected_block (0),
11294 VAR_DOMAIN, &syms, 1);
11295
11296 if (nsyms != 1)
11297 {
11298 if (err_msg == NULL)
11299 return 0;
11300 else
11301 error (("%s"), err_msg);
11302 }
11303
11304 return value_of_variable (syms[0].symbol, syms[0].block);
11305 }
11306
11307 /* Value of integer variable named NAME in the current environment.
11308 If no such variable is found, returns false. Otherwise, sets VALUE
11309 to the variable's value and returns true. */
11310
11311 bool
11312 get_int_var_value (const char *name, LONGEST &value)
11313 {
11314 struct value *var_val = get_var_value (name, 0);
11315
11316 if (var_val == 0)
11317 return false;
11318
11319 value = value_as_long (var_val);
11320 return true;
11321 }
11322
11323
11324 /* Return a range type whose base type is that of the range type named
11325 NAME in the current environment, and whose bounds are calculated
11326 from NAME according to the GNAT range encoding conventions.
11327 Extract discriminant values, if needed, from DVAL. ORIG_TYPE is the
11328 corresponding range type from debug information; fall back to using it
11329 if symbol lookup fails. If a new type must be created, allocate it
11330 like ORIG_TYPE was. The bounds information, in general, is encoded
11331 in NAME, the base type given in the named range type. */
11332
11333 static struct type *
11334 to_fixed_range_type (struct type *raw_type, struct value *dval)
11335 {
11336 const char *name;
11337 struct type *base_type;
11338 const char *subtype_info;
11339
11340 gdb_assert (raw_type != NULL);
11341 gdb_assert (raw_type->name () != NULL);
11342
11343 if (raw_type->code () == TYPE_CODE_RANGE)
11344 base_type = TYPE_TARGET_TYPE (raw_type);
11345 else
11346 base_type = raw_type;
11347
11348 name = raw_type->name ();
11349 subtype_info = strstr (name, "___XD");
11350 if (subtype_info == NULL)
11351 {
11352 LONGEST L = ada_discrete_type_low_bound (raw_type);
11353 LONGEST U = ada_discrete_type_high_bound (raw_type);
11354
11355 if (L < INT_MIN || U > INT_MAX)
11356 return raw_type;
11357 else
11358 return create_static_range_type (alloc_type_copy (raw_type), raw_type,
11359 L, U);
11360 }
11361 else
11362 {
11363 static char *name_buf = NULL;
11364 static size_t name_len = 0;
11365 int prefix_len = subtype_info - name;
11366 LONGEST L, U;
11367 struct type *type;
11368 const char *bounds_str;
11369 int n;
11370
11371 GROW_VECT (name_buf, name_len, prefix_len + 5);
11372 strncpy (name_buf, name, prefix_len);
11373 name_buf[prefix_len] = '\0';
11374
11375 subtype_info += 5;
11376 bounds_str = strchr (subtype_info, '_');
11377 n = 1;
11378
11379 if (*subtype_info == 'L')
11380 {
11381 if (!ada_scan_number (bounds_str, n, &L, &n)
11382 && !scan_discrim_bound (bounds_str, n, dval, &L, &n))
11383 return raw_type;
11384 if (bounds_str[n] == '_')
11385 n += 2;
11386 else if (bounds_str[n] == '.') /* FIXME? SGI Workshop kludge. */
11387 n += 1;
11388 subtype_info += 1;
11389 }
11390 else
11391 {
11392 strcpy (name_buf + prefix_len, "___L");
11393 if (!get_int_var_value (name_buf, L))
11394 {
11395 lim_warning (_("Unknown lower bound, using 1."));
11396 L = 1;
11397 }
11398 }
11399
11400 if (*subtype_info == 'U')
11401 {
11402 if (!ada_scan_number (bounds_str, n, &U, &n)
11403 && !scan_discrim_bound (bounds_str, n, dval, &U, &n))
11404 return raw_type;
11405 }
11406 else
11407 {
11408 strcpy (name_buf + prefix_len, "___U");
11409 if (!get_int_var_value (name_buf, U))
11410 {
11411 lim_warning (_("Unknown upper bound, using %ld."), (long) L);
11412 U = L;
11413 }
11414 }
11415
11416 type = create_static_range_type (alloc_type_copy (raw_type),
11417 base_type, L, U);
11418 /* create_static_range_type alters the resulting type's length
11419 to match the size of the base_type, which is not what we want.
11420 Set it back to the original range type's length. */
11421 TYPE_LENGTH (type) = TYPE_LENGTH (raw_type);
11422 type->set_name (name);
11423 return type;
11424 }
11425 }
11426
11427 /* True iff NAME is the name of a range type. */
11428
11429 int
11430 ada_is_range_type_name (const char *name)
11431 {
11432 return (name != NULL && strstr (name, "___XD"));
11433 }
11434 \f
11435
11436 /* Modular types */
11437
11438 /* True iff TYPE is an Ada modular type. */
11439
11440 int
11441 ada_is_modular_type (struct type *type)
11442 {
11443 struct type *subranged_type = get_base_type (type);
11444
11445 return (subranged_type != NULL && type->code () == TYPE_CODE_RANGE
11446 && subranged_type->code () == TYPE_CODE_INT
11447 && subranged_type->is_unsigned ());
11448 }
11449
11450 /* Assuming ada_is_modular_type (TYPE), the modulus of TYPE. */
11451
11452 ULONGEST
11453 ada_modulus (struct type *type)
11454 {
11455 const dynamic_prop &high = type->bounds ()->high;
11456
11457 if (high.kind () == PROP_CONST)
11458 return (ULONGEST) high.const_val () + 1;
11459
11460 /* If TYPE is unresolved, the high bound might be a location list. Return
11461 0, for lack of a better value to return. */
11462 return 0;
11463 }
11464 \f
11465
11466 /* Ada exception catchpoint support:
11467 ---------------------------------
11468
11469 We support 3 kinds of exception catchpoints:
11470 . catchpoints on Ada exceptions
11471 . catchpoints on unhandled Ada exceptions
11472 . catchpoints on failed assertions
11473
11474 Exceptions raised during failed assertions, or unhandled exceptions
11475 could perfectly be caught with the general catchpoint on Ada exceptions.
11476 However, we can easily differentiate these two special cases, and having
11477 the option to distinguish these two cases from the rest can be useful
11478 to zero-in on certain situations.
11479
11480 Exception catchpoints are a specialized form of breakpoint,
11481 since they rely on inserting breakpoints inside known routines
11482 of the GNAT runtime. The implementation therefore uses a standard
11483 breakpoint structure of the BP_BREAKPOINT type, but with its own set
11484 of breakpoint_ops.
11485
11486 Support in the runtime for exception catchpoints have been changed
11487 a few times already, and these changes affect the implementation
11488 of these catchpoints. In order to be able to support several
11489 variants of the runtime, we use a sniffer that will determine
11490 the runtime variant used by the program being debugged. */
11491
11492 /* Ada's standard exceptions.
11493
11494 The Ada 83 standard also defined Numeric_Error. But there so many
11495 situations where it was unclear from the Ada 83 Reference Manual
11496 (RM) whether Constraint_Error or Numeric_Error should be raised,
11497 that the ARG (Ada Rapporteur Group) eventually issued a Binding
11498 Interpretation saying that anytime the RM says that Numeric_Error
11499 should be raised, the implementation may raise Constraint_Error.
11500 Ada 95 went one step further and pretty much removed Numeric_Error
11501 from the list of standard exceptions (it made it a renaming of
11502 Constraint_Error, to help preserve compatibility when compiling
11503 an Ada83 compiler). As such, we do not include Numeric_Error from
11504 this list of standard exceptions. */
11505
11506 static const char * const standard_exc[] = {
11507 "constraint_error",
11508 "program_error",
11509 "storage_error",
11510 "tasking_error"
11511 };
11512
11513 typedef CORE_ADDR (ada_unhandled_exception_name_addr_ftype) (void);
11514
11515 /* A structure that describes how to support exception catchpoints
11516 for a given executable. */
11517
11518 struct exception_support_info
11519 {
11520 /* The name of the symbol to break on in order to insert
11521 a catchpoint on exceptions. */
11522 const char *catch_exception_sym;
11523
11524 /* The name of the symbol to break on in order to insert
11525 a catchpoint on unhandled exceptions. */
11526 const char *catch_exception_unhandled_sym;
11527
11528 /* The name of the symbol to break on in order to insert
11529 a catchpoint on failed assertions. */
11530 const char *catch_assert_sym;
11531
11532 /* The name of the symbol to break on in order to insert
11533 a catchpoint on exception handling. */
11534 const char *catch_handlers_sym;
11535
11536 /* Assuming that the inferior just triggered an unhandled exception
11537 catchpoint, this function is responsible for returning the address
11538 in inferior memory where the name of that exception is stored.
11539 Return zero if the address could not be computed. */
11540 ada_unhandled_exception_name_addr_ftype *unhandled_exception_name_addr;
11541 };
11542
11543 static CORE_ADDR ada_unhandled_exception_name_addr (void);
11544 static CORE_ADDR ada_unhandled_exception_name_addr_from_raise (void);
11545
11546 /* The following exception support info structure describes how to
11547 implement exception catchpoints with the latest version of the
11548 Ada runtime (as of 2019-08-??). */
11549
11550 static const struct exception_support_info default_exception_support_info =
11551 {
11552 "__gnat_debug_raise_exception", /* catch_exception_sym */
11553 "__gnat_unhandled_exception", /* catch_exception_unhandled_sym */
11554 "__gnat_debug_raise_assert_failure", /* catch_assert_sym */
11555 "__gnat_begin_handler_v1", /* catch_handlers_sym */
11556 ada_unhandled_exception_name_addr
11557 };
11558
11559 /* The following exception support info structure describes how to
11560 implement exception catchpoints with an earlier version of the
11561 Ada runtime (as of 2007-03-06) using v0 of the EH ABI. */
11562
11563 static const struct exception_support_info exception_support_info_v0 =
11564 {
11565 "__gnat_debug_raise_exception", /* catch_exception_sym */
11566 "__gnat_unhandled_exception", /* catch_exception_unhandled_sym */
11567 "__gnat_debug_raise_assert_failure", /* catch_assert_sym */
11568 "__gnat_begin_handler", /* catch_handlers_sym */
11569 ada_unhandled_exception_name_addr
11570 };
11571
11572 /* The following exception support info structure describes how to
11573 implement exception catchpoints with a slightly older version
11574 of the Ada runtime. */
11575
11576 static const struct exception_support_info exception_support_info_fallback =
11577 {
11578 "__gnat_raise_nodefer_with_msg", /* catch_exception_sym */
11579 "__gnat_unhandled_exception", /* catch_exception_unhandled_sym */
11580 "system__assertions__raise_assert_failure", /* catch_assert_sym */
11581 "__gnat_begin_handler", /* catch_handlers_sym */
11582 ada_unhandled_exception_name_addr_from_raise
11583 };
11584
11585 /* Return nonzero if we can detect the exception support routines
11586 described in EINFO.
11587
11588 This function errors out if an abnormal situation is detected
11589 (for instance, if we find the exception support routines, but
11590 that support is found to be incomplete). */
11591
11592 static int
11593 ada_has_this_exception_support (const struct exception_support_info *einfo)
11594 {
11595 struct symbol *sym;
11596
11597 /* The symbol we're looking up is provided by a unit in the GNAT runtime
11598 that should be compiled with debugging information. As a result, we
11599 expect to find that symbol in the symtabs. */
11600
11601 sym = standard_lookup (einfo->catch_exception_sym, NULL, VAR_DOMAIN);
11602 if (sym == NULL)
11603 {
11604 /* Perhaps we did not find our symbol because the Ada runtime was
11605 compiled without debugging info, or simply stripped of it.
11606 It happens on some GNU/Linux distributions for instance, where
11607 users have to install a separate debug package in order to get
11608 the runtime's debugging info. In that situation, let the user
11609 know why we cannot insert an Ada exception catchpoint.
11610
11611 Note: Just for the purpose of inserting our Ada exception
11612 catchpoint, we could rely purely on the associated minimal symbol.
11613 But we would be operating in degraded mode anyway, since we are
11614 still lacking the debugging info needed later on to extract
11615 the name of the exception being raised (this name is printed in
11616 the catchpoint message, and is also used when trying to catch
11617 a specific exception). We do not handle this case for now. */
11618 struct bound_minimal_symbol msym
11619 = lookup_minimal_symbol (einfo->catch_exception_sym, NULL, NULL);
11620
11621 if (msym.minsym && MSYMBOL_TYPE (msym.minsym) != mst_solib_trampoline)
11622 error (_("Your Ada runtime appears to be missing some debugging "
11623 "information.\nCannot insert Ada exception catchpoint "
11624 "in this configuration."));
11625
11626 return 0;
11627 }
11628
11629 /* Make sure that the symbol we found corresponds to a function. */
11630
11631 if (SYMBOL_CLASS (sym) != LOC_BLOCK)
11632 {
11633 error (_("Symbol \"%s\" is not a function (class = %d)"),
11634 sym->linkage_name (), SYMBOL_CLASS (sym));
11635 return 0;
11636 }
11637
11638 sym = standard_lookup (einfo->catch_handlers_sym, NULL, VAR_DOMAIN);
11639 if (sym == NULL)
11640 {
11641 struct bound_minimal_symbol msym
11642 = lookup_minimal_symbol (einfo->catch_handlers_sym, NULL, NULL);
11643
11644 if (msym.minsym && MSYMBOL_TYPE (msym.minsym) != mst_solib_trampoline)
11645 error (_("Your Ada runtime appears to be missing some debugging "
11646 "information.\nCannot insert Ada exception catchpoint "
11647 "in this configuration."));
11648
11649 return 0;
11650 }
11651
11652 /* Make sure that the symbol we found corresponds to a function. */
11653
11654 if (SYMBOL_CLASS (sym) != LOC_BLOCK)
11655 {
11656 error (_("Symbol \"%s\" is not a function (class = %d)"),
11657 sym->linkage_name (), SYMBOL_CLASS (sym));
11658 return 0;
11659 }
11660
11661 return 1;
11662 }
11663
11664 /* Inspect the Ada runtime and determine which exception info structure
11665 should be used to provide support for exception catchpoints.
11666
11667 This function will always set the per-inferior exception_info,
11668 or raise an error. */
11669
11670 static void
11671 ada_exception_support_info_sniffer (void)
11672 {
11673 struct ada_inferior_data *data = get_ada_inferior_data (current_inferior ());
11674
11675 /* If the exception info is already known, then no need to recompute it. */
11676 if (data->exception_info != NULL)
11677 return;
11678
11679 /* Check the latest (default) exception support info. */
11680 if (ada_has_this_exception_support (&default_exception_support_info))
11681 {
11682 data->exception_info = &default_exception_support_info;
11683 return;
11684 }
11685
11686 /* Try the v0 exception suport info. */
11687 if (ada_has_this_exception_support (&exception_support_info_v0))
11688 {
11689 data->exception_info = &exception_support_info_v0;
11690 return;
11691 }
11692
11693 /* Try our fallback exception suport info. */
11694 if (ada_has_this_exception_support (&exception_support_info_fallback))
11695 {
11696 data->exception_info = &exception_support_info_fallback;
11697 return;
11698 }
11699
11700 /* Sometimes, it is normal for us to not be able to find the routine
11701 we are looking for. This happens when the program is linked with
11702 the shared version of the GNAT runtime, and the program has not been
11703 started yet. Inform the user of these two possible causes if
11704 applicable. */
11705
11706 if (ada_update_initial_language (language_unknown) != language_ada)
11707 error (_("Unable to insert catchpoint. Is this an Ada main program?"));
11708
11709 /* If the symbol does not exist, then check that the program is
11710 already started, to make sure that shared libraries have been
11711 loaded. If it is not started, this may mean that the symbol is
11712 in a shared library. */
11713
11714 if (inferior_ptid.pid () == 0)
11715 error (_("Unable to insert catchpoint. Try to start the program first."));
11716
11717 /* At this point, we know that we are debugging an Ada program and
11718 that the inferior has been started, but we still are not able to
11719 find the run-time symbols. That can mean that we are in
11720 configurable run time mode, or that a-except as been optimized
11721 out by the linker... In any case, at this point it is not worth
11722 supporting this feature. */
11723
11724 error (_("Cannot insert Ada exception catchpoints in this configuration."));
11725 }
11726
11727 /* True iff FRAME is very likely to be that of a function that is
11728 part of the runtime system. This is all very heuristic, but is
11729 intended to be used as advice as to what frames are uninteresting
11730 to most users. */
11731
11732 static int
11733 is_known_support_routine (struct frame_info *frame)
11734 {
11735 enum language func_lang;
11736 int i;
11737 const char *fullname;
11738
11739 /* If this code does not have any debugging information (no symtab),
11740 This cannot be any user code. */
11741
11742 symtab_and_line sal = find_frame_sal (frame);
11743 if (sal.symtab == NULL)
11744 return 1;
11745
11746 /* If there is a symtab, but the associated source file cannot be
11747 located, then assume this is not user code: Selecting a frame
11748 for which we cannot display the code would not be very helpful
11749 for the user. This should also take care of case such as VxWorks
11750 where the kernel has some debugging info provided for a few units. */
11751
11752 fullname = symtab_to_fullname (sal.symtab);
11753 if (access (fullname, R_OK) != 0)
11754 return 1;
11755
11756 /* Check the unit filename against the Ada runtime file naming.
11757 We also check the name of the objfile against the name of some
11758 known system libraries that sometimes come with debugging info
11759 too. */
11760
11761 for (i = 0; known_runtime_file_name_patterns[i] != NULL; i += 1)
11762 {
11763 re_comp (known_runtime_file_name_patterns[i]);
11764 if (re_exec (lbasename (sal.symtab->filename)))
11765 return 1;
11766 if (SYMTAB_OBJFILE (sal.symtab) != NULL
11767 && re_exec (objfile_name (SYMTAB_OBJFILE (sal.symtab))))
11768 return 1;
11769 }
11770
11771 /* Check whether the function is a GNAT-generated entity. */
11772
11773 gdb::unique_xmalloc_ptr<char> func_name
11774 = find_frame_funname (frame, &func_lang, NULL);
11775 if (func_name == NULL)
11776 return 1;
11777
11778 for (i = 0; known_auxiliary_function_name_patterns[i] != NULL; i += 1)
11779 {
11780 re_comp (known_auxiliary_function_name_patterns[i]);
11781 if (re_exec (func_name.get ()))
11782 return 1;
11783 }
11784
11785 return 0;
11786 }
11787
11788 /* Find the first frame that contains debugging information and that is not
11789 part of the Ada run-time, starting from FI and moving upward. */
11790
11791 void
11792 ada_find_printable_frame (struct frame_info *fi)
11793 {
11794 for (; fi != NULL; fi = get_prev_frame (fi))
11795 {
11796 if (!is_known_support_routine (fi))
11797 {
11798 select_frame (fi);
11799 break;
11800 }
11801 }
11802
11803 }
11804
11805 /* Assuming that the inferior just triggered an unhandled exception
11806 catchpoint, return the address in inferior memory where the name
11807 of the exception is stored.
11808
11809 Return zero if the address could not be computed. */
11810
11811 static CORE_ADDR
11812 ada_unhandled_exception_name_addr (void)
11813 {
11814 return parse_and_eval_address ("e.full_name");
11815 }
11816
11817 /* Same as ada_unhandled_exception_name_addr, except that this function
11818 should be used when the inferior uses an older version of the runtime,
11819 where the exception name needs to be extracted from a specific frame
11820 several frames up in the callstack. */
11821
11822 static CORE_ADDR
11823 ada_unhandled_exception_name_addr_from_raise (void)
11824 {
11825 int frame_level;
11826 struct frame_info *fi;
11827 struct ada_inferior_data *data = get_ada_inferior_data (current_inferior ());
11828
11829 /* To determine the name of this exception, we need to select
11830 the frame corresponding to RAISE_SYM_NAME. This frame is
11831 at least 3 levels up, so we simply skip the first 3 frames
11832 without checking the name of their associated function. */
11833 fi = get_current_frame ();
11834 for (frame_level = 0; frame_level < 3; frame_level += 1)
11835 if (fi != NULL)
11836 fi = get_prev_frame (fi);
11837
11838 while (fi != NULL)
11839 {
11840 enum language func_lang;
11841
11842 gdb::unique_xmalloc_ptr<char> func_name
11843 = find_frame_funname (fi, &func_lang, NULL);
11844 if (func_name != NULL)
11845 {
11846 if (strcmp (func_name.get (),
11847 data->exception_info->catch_exception_sym) == 0)
11848 break; /* We found the frame we were looking for... */
11849 }
11850 fi = get_prev_frame (fi);
11851 }
11852
11853 if (fi == NULL)
11854 return 0;
11855
11856 select_frame (fi);
11857 return parse_and_eval_address ("id.full_name");
11858 }
11859
11860 /* Assuming the inferior just triggered an Ada exception catchpoint
11861 (of any type), return the address in inferior memory where the name
11862 of the exception is stored, if applicable.
11863
11864 Assumes the selected frame is the current frame.
11865
11866 Return zero if the address could not be computed, or if not relevant. */
11867
11868 static CORE_ADDR
11869 ada_exception_name_addr_1 (enum ada_exception_catchpoint_kind ex,
11870 struct breakpoint *b)
11871 {
11872 struct ada_inferior_data *data = get_ada_inferior_data (current_inferior ());
11873
11874 switch (ex)
11875 {
11876 case ada_catch_exception:
11877 return (parse_and_eval_address ("e.full_name"));
11878 break;
11879
11880 case ada_catch_exception_unhandled:
11881 return data->exception_info->unhandled_exception_name_addr ();
11882 break;
11883
11884 case ada_catch_handlers:
11885 return 0; /* The runtimes does not provide access to the exception
11886 name. */
11887 break;
11888
11889 case ada_catch_assert:
11890 return 0; /* Exception name is not relevant in this case. */
11891 break;
11892
11893 default:
11894 internal_error (__FILE__, __LINE__, _("unexpected catchpoint type"));
11895 break;
11896 }
11897
11898 return 0; /* Should never be reached. */
11899 }
11900
11901 /* Assuming the inferior is stopped at an exception catchpoint,
11902 return the message which was associated to the exception, if
11903 available. Return NULL if the message could not be retrieved.
11904
11905 Note: The exception message can be associated to an exception
11906 either through the use of the Raise_Exception function, or
11907 more simply (Ada 2005 and later), via:
11908
11909 raise Exception_Name with "exception message";
11910
11911 */
11912
11913 static gdb::unique_xmalloc_ptr<char>
11914 ada_exception_message_1 (void)
11915 {
11916 struct value *e_msg_val;
11917 int e_msg_len;
11918
11919 /* For runtimes that support this feature, the exception message
11920 is passed as an unbounded string argument called "message". */
11921 e_msg_val = parse_and_eval ("message");
11922 if (e_msg_val == NULL)
11923 return NULL; /* Exception message not supported. */
11924
11925 e_msg_val = ada_coerce_to_simple_array (e_msg_val);
11926 gdb_assert (e_msg_val != NULL);
11927 e_msg_len = TYPE_LENGTH (value_type (e_msg_val));
11928
11929 /* If the message string is empty, then treat it as if there was
11930 no exception message. */
11931 if (e_msg_len <= 0)
11932 return NULL;
11933
11934 gdb::unique_xmalloc_ptr<char> e_msg ((char *) xmalloc (e_msg_len + 1));
11935 read_memory (value_address (e_msg_val), (gdb_byte *) e_msg.get (),
11936 e_msg_len);
11937 e_msg.get ()[e_msg_len] = '\0';
11938
11939 return e_msg;
11940 }
11941
11942 /* Same as ada_exception_message_1, except that all exceptions are
11943 contained here (returning NULL instead). */
11944
11945 static gdb::unique_xmalloc_ptr<char>
11946 ada_exception_message (void)
11947 {
11948 gdb::unique_xmalloc_ptr<char> e_msg;
11949
11950 try
11951 {
11952 e_msg = ada_exception_message_1 ();
11953 }
11954 catch (const gdb_exception_error &e)
11955 {
11956 e_msg.reset (nullptr);
11957 }
11958
11959 return e_msg;
11960 }
11961
11962 /* Same as ada_exception_name_addr_1, except that it intercepts and contains
11963 any error that ada_exception_name_addr_1 might cause to be thrown.
11964 When an error is intercepted, a warning with the error message is printed,
11965 and zero is returned. */
11966
11967 static CORE_ADDR
11968 ada_exception_name_addr (enum ada_exception_catchpoint_kind ex,
11969 struct breakpoint *b)
11970 {
11971 CORE_ADDR result = 0;
11972
11973 try
11974 {
11975 result = ada_exception_name_addr_1 (ex, b);
11976 }
11977
11978 catch (const gdb_exception_error &e)
11979 {
11980 warning (_("failed to get exception name: %s"), e.what ());
11981 return 0;
11982 }
11983
11984 return result;
11985 }
11986
11987 static std::string ada_exception_catchpoint_cond_string
11988 (const char *excep_string,
11989 enum ada_exception_catchpoint_kind ex);
11990
11991 /* Ada catchpoints.
11992
11993 In the case of catchpoints on Ada exceptions, the catchpoint will
11994 stop the target on every exception the program throws. When a user
11995 specifies the name of a specific exception, we translate this
11996 request into a condition expression (in text form), and then parse
11997 it into an expression stored in each of the catchpoint's locations.
11998 We then use this condition to check whether the exception that was
11999 raised is the one the user is interested in. If not, then the
12000 target is resumed again. We store the name of the requested
12001 exception, in order to be able to re-set the condition expression
12002 when symbols change. */
12003
12004 /* An instance of this type is used to represent an Ada catchpoint
12005 breakpoint location. */
12006
12007 class ada_catchpoint_location : public bp_location
12008 {
12009 public:
12010 ada_catchpoint_location (breakpoint *owner)
12011 : bp_location (owner, bp_loc_software_breakpoint)
12012 {}
12013
12014 /* The condition that checks whether the exception that was raised
12015 is the specific exception the user specified on catchpoint
12016 creation. */
12017 expression_up excep_cond_expr;
12018 };
12019
12020 /* An instance of this type is used to represent an Ada catchpoint. */
12021
12022 struct ada_catchpoint : public breakpoint
12023 {
12024 explicit ada_catchpoint (enum ada_exception_catchpoint_kind kind)
12025 : m_kind (kind)
12026 {
12027 }
12028
12029 /* The name of the specific exception the user specified. */
12030 std::string excep_string;
12031
12032 /* What kind of catchpoint this is. */
12033 enum ada_exception_catchpoint_kind m_kind;
12034 };
12035
12036 /* Parse the exception condition string in the context of each of the
12037 catchpoint's locations, and store them for later evaluation. */
12038
12039 static void
12040 create_excep_cond_exprs (struct ada_catchpoint *c,
12041 enum ada_exception_catchpoint_kind ex)
12042 {
12043 struct bp_location *bl;
12044
12045 /* Nothing to do if there's no specific exception to catch. */
12046 if (c->excep_string.empty ())
12047 return;
12048
12049 /* Same if there are no locations... */
12050 if (c->loc == NULL)
12051 return;
12052
12053 /* Compute the condition expression in text form, from the specific
12054 expection we want to catch. */
12055 std::string cond_string
12056 = ada_exception_catchpoint_cond_string (c->excep_string.c_str (), ex);
12057
12058 /* Iterate over all the catchpoint's locations, and parse an
12059 expression for each. */
12060 for (bl = c->loc; bl != NULL; bl = bl->next)
12061 {
12062 struct ada_catchpoint_location *ada_loc
12063 = (struct ada_catchpoint_location *) bl;
12064 expression_up exp;
12065
12066 if (!bl->shlib_disabled)
12067 {
12068 const char *s;
12069
12070 s = cond_string.c_str ();
12071 try
12072 {
12073 exp = parse_exp_1 (&s, bl->address,
12074 block_for_pc (bl->address),
12075 0);
12076 }
12077 catch (const gdb_exception_error &e)
12078 {
12079 warning (_("failed to reevaluate internal exception condition "
12080 "for catchpoint %d: %s"),
12081 c->number, e.what ());
12082 }
12083 }
12084
12085 ada_loc->excep_cond_expr = std::move (exp);
12086 }
12087 }
12088
12089 /* Implement the ALLOCATE_LOCATION method in the breakpoint_ops
12090 structure for all exception catchpoint kinds. */
12091
12092 static struct bp_location *
12093 allocate_location_exception (struct breakpoint *self)
12094 {
12095 return new ada_catchpoint_location (self);
12096 }
12097
12098 /* Implement the RE_SET method in the breakpoint_ops structure for all
12099 exception catchpoint kinds. */
12100
12101 static void
12102 re_set_exception (struct breakpoint *b)
12103 {
12104 struct ada_catchpoint *c = (struct ada_catchpoint *) b;
12105
12106 /* Call the base class's method. This updates the catchpoint's
12107 locations. */
12108 bkpt_breakpoint_ops.re_set (b);
12109
12110 /* Reparse the exception conditional expressions. One for each
12111 location. */
12112 create_excep_cond_exprs (c, c->m_kind);
12113 }
12114
12115 /* Returns true if we should stop for this breakpoint hit. If the
12116 user specified a specific exception, we only want to cause a stop
12117 if the program thrown that exception. */
12118
12119 static int
12120 should_stop_exception (const struct bp_location *bl)
12121 {
12122 struct ada_catchpoint *c = (struct ada_catchpoint *) bl->owner;
12123 const struct ada_catchpoint_location *ada_loc
12124 = (const struct ada_catchpoint_location *) bl;
12125 int stop;
12126
12127 struct internalvar *var = lookup_internalvar ("_ada_exception");
12128 if (c->m_kind == ada_catch_assert)
12129 clear_internalvar (var);
12130 else
12131 {
12132 try
12133 {
12134 const char *expr;
12135
12136 if (c->m_kind == ada_catch_handlers)
12137 expr = ("GNAT_GCC_exception_Access(gcc_exception)"
12138 ".all.occurrence.id");
12139 else
12140 expr = "e";
12141
12142 struct value *exc = parse_and_eval (expr);
12143 set_internalvar (var, exc);
12144 }
12145 catch (const gdb_exception_error &ex)
12146 {
12147 clear_internalvar (var);
12148 }
12149 }
12150
12151 /* With no specific exception, should always stop. */
12152 if (c->excep_string.empty ())
12153 return 1;
12154
12155 if (ada_loc->excep_cond_expr == NULL)
12156 {
12157 /* We will have a NULL expression if back when we were creating
12158 the expressions, this location's had failed to parse. */
12159 return 1;
12160 }
12161
12162 stop = 1;
12163 try
12164 {
12165 struct value *mark;
12166
12167 mark = value_mark ();
12168 stop = value_true (evaluate_expression (ada_loc->excep_cond_expr.get ()));
12169 value_free_to_mark (mark);
12170 }
12171 catch (const gdb_exception &ex)
12172 {
12173 exception_fprintf (gdb_stderr, ex,
12174 _("Error in testing exception condition:\n"));
12175 }
12176
12177 return stop;
12178 }
12179
12180 /* Implement the CHECK_STATUS method in the breakpoint_ops structure
12181 for all exception catchpoint kinds. */
12182
12183 static void
12184 check_status_exception (bpstat bs)
12185 {
12186 bs->stop = should_stop_exception (bs->bp_location_at);
12187 }
12188
12189 /* Implement the PRINT_IT method in the breakpoint_ops structure
12190 for all exception catchpoint kinds. */
12191
12192 static enum print_stop_action
12193 print_it_exception (bpstat bs)
12194 {
12195 struct ui_out *uiout = current_uiout;
12196 struct breakpoint *b = bs->breakpoint_at;
12197
12198 annotate_catchpoint (b->number);
12199
12200 if (uiout->is_mi_like_p ())
12201 {
12202 uiout->field_string ("reason",
12203 async_reason_lookup (EXEC_ASYNC_BREAKPOINT_HIT));
12204 uiout->field_string ("disp", bpdisp_text (b->disposition));
12205 }
12206
12207 uiout->text (b->disposition == disp_del
12208 ? "\nTemporary catchpoint " : "\nCatchpoint ");
12209 uiout->field_signed ("bkptno", b->number);
12210 uiout->text (", ");
12211
12212 /* ada_exception_name_addr relies on the selected frame being the
12213 current frame. Need to do this here because this function may be
12214 called more than once when printing a stop, and below, we'll
12215 select the first frame past the Ada run-time (see
12216 ada_find_printable_frame). */
12217 select_frame (get_current_frame ());
12218
12219 struct ada_catchpoint *c = (struct ada_catchpoint *) b;
12220 switch (c->m_kind)
12221 {
12222 case ada_catch_exception:
12223 case ada_catch_exception_unhandled:
12224 case ada_catch_handlers:
12225 {
12226 const CORE_ADDR addr = ada_exception_name_addr (c->m_kind, b);
12227 char exception_name[256];
12228
12229 if (addr != 0)
12230 {
12231 read_memory (addr, (gdb_byte *) exception_name,
12232 sizeof (exception_name) - 1);
12233 exception_name [sizeof (exception_name) - 1] = '\0';
12234 }
12235 else
12236 {
12237 /* For some reason, we were unable to read the exception
12238 name. This could happen if the Runtime was compiled
12239 without debugging info, for instance. In that case,
12240 just replace the exception name by the generic string
12241 "exception" - it will read as "an exception" in the
12242 notification we are about to print. */
12243 memcpy (exception_name, "exception", sizeof ("exception"));
12244 }
12245 /* In the case of unhandled exception breakpoints, we print
12246 the exception name as "unhandled EXCEPTION_NAME", to make
12247 it clearer to the user which kind of catchpoint just got
12248 hit. We used ui_out_text to make sure that this extra
12249 info does not pollute the exception name in the MI case. */
12250 if (c->m_kind == ada_catch_exception_unhandled)
12251 uiout->text ("unhandled ");
12252 uiout->field_string ("exception-name", exception_name);
12253 }
12254 break;
12255 case ada_catch_assert:
12256 /* In this case, the name of the exception is not really
12257 important. Just print "failed assertion" to make it clearer
12258 that his program just hit an assertion-failure catchpoint.
12259 We used ui_out_text because this info does not belong in
12260 the MI output. */
12261 uiout->text ("failed assertion");
12262 break;
12263 }
12264
12265 gdb::unique_xmalloc_ptr<char> exception_message = ada_exception_message ();
12266 if (exception_message != NULL)
12267 {
12268 uiout->text (" (");
12269 uiout->field_string ("exception-message", exception_message.get ());
12270 uiout->text (")");
12271 }
12272
12273 uiout->text (" at ");
12274 ada_find_printable_frame (get_current_frame ());
12275
12276 return PRINT_SRC_AND_LOC;
12277 }
12278
12279 /* Implement the PRINT_ONE method in the breakpoint_ops structure
12280 for all exception catchpoint kinds. */
12281
12282 static void
12283 print_one_exception (struct breakpoint *b, struct bp_location **last_loc)
12284 {
12285 struct ui_out *uiout = current_uiout;
12286 struct ada_catchpoint *c = (struct ada_catchpoint *) b;
12287 struct value_print_options opts;
12288
12289 get_user_print_options (&opts);
12290
12291 if (opts.addressprint)
12292 uiout->field_skip ("addr");
12293
12294 annotate_field (5);
12295 switch (c->m_kind)
12296 {
12297 case ada_catch_exception:
12298 if (!c->excep_string.empty ())
12299 {
12300 std::string msg = string_printf (_("`%s' Ada exception"),
12301 c->excep_string.c_str ());
12302
12303 uiout->field_string ("what", msg);
12304 }
12305 else
12306 uiout->field_string ("what", "all Ada exceptions");
12307
12308 break;
12309
12310 case ada_catch_exception_unhandled:
12311 uiout->field_string ("what", "unhandled Ada exceptions");
12312 break;
12313
12314 case ada_catch_handlers:
12315 if (!c->excep_string.empty ())
12316 {
12317 uiout->field_fmt ("what",
12318 _("`%s' Ada exception handlers"),
12319 c->excep_string.c_str ());
12320 }
12321 else
12322 uiout->field_string ("what", "all Ada exceptions handlers");
12323 break;
12324
12325 case ada_catch_assert:
12326 uiout->field_string ("what", "failed Ada assertions");
12327 break;
12328
12329 default:
12330 internal_error (__FILE__, __LINE__, _("unexpected catchpoint type"));
12331 break;
12332 }
12333 }
12334
12335 /* Implement the PRINT_MENTION method in the breakpoint_ops structure
12336 for all exception catchpoint kinds. */
12337
12338 static void
12339 print_mention_exception (struct breakpoint *b)
12340 {
12341 struct ada_catchpoint *c = (struct ada_catchpoint *) b;
12342 struct ui_out *uiout = current_uiout;
12343
12344 uiout->text (b->disposition == disp_del ? _("Temporary catchpoint ")
12345 : _("Catchpoint "));
12346 uiout->field_signed ("bkptno", b->number);
12347 uiout->text (": ");
12348
12349 switch (c->m_kind)
12350 {
12351 case ada_catch_exception:
12352 if (!c->excep_string.empty ())
12353 {
12354 std::string info = string_printf (_("`%s' Ada exception"),
12355 c->excep_string.c_str ());
12356 uiout->text (info.c_str ());
12357 }
12358 else
12359 uiout->text (_("all Ada exceptions"));
12360 break;
12361
12362 case ada_catch_exception_unhandled:
12363 uiout->text (_("unhandled Ada exceptions"));
12364 break;
12365
12366 case ada_catch_handlers:
12367 if (!c->excep_string.empty ())
12368 {
12369 std::string info
12370 = string_printf (_("`%s' Ada exception handlers"),
12371 c->excep_string.c_str ());
12372 uiout->text (info.c_str ());
12373 }
12374 else
12375 uiout->text (_("all Ada exceptions handlers"));
12376 break;
12377
12378 case ada_catch_assert:
12379 uiout->text (_("failed Ada assertions"));
12380 break;
12381
12382 default:
12383 internal_error (__FILE__, __LINE__, _("unexpected catchpoint type"));
12384 break;
12385 }
12386 }
12387
12388 /* Implement the PRINT_RECREATE method in the breakpoint_ops structure
12389 for all exception catchpoint kinds. */
12390
12391 static void
12392 print_recreate_exception (struct breakpoint *b, struct ui_file *fp)
12393 {
12394 struct ada_catchpoint *c = (struct ada_catchpoint *) b;
12395
12396 switch (c->m_kind)
12397 {
12398 case ada_catch_exception:
12399 fprintf_filtered (fp, "catch exception");
12400 if (!c->excep_string.empty ())
12401 fprintf_filtered (fp, " %s", c->excep_string.c_str ());
12402 break;
12403
12404 case ada_catch_exception_unhandled:
12405 fprintf_filtered (fp, "catch exception unhandled");
12406 break;
12407
12408 case ada_catch_handlers:
12409 fprintf_filtered (fp, "catch handlers");
12410 break;
12411
12412 case ada_catch_assert:
12413 fprintf_filtered (fp, "catch assert");
12414 break;
12415
12416 default:
12417 internal_error (__FILE__, __LINE__, _("unexpected catchpoint type"));
12418 }
12419 print_recreate_thread (b, fp);
12420 }
12421
12422 /* Virtual tables for various breakpoint types. */
12423 static struct breakpoint_ops catch_exception_breakpoint_ops;
12424 static struct breakpoint_ops catch_exception_unhandled_breakpoint_ops;
12425 static struct breakpoint_ops catch_assert_breakpoint_ops;
12426 static struct breakpoint_ops catch_handlers_breakpoint_ops;
12427
12428 /* See ada-lang.h. */
12429
12430 bool
12431 is_ada_exception_catchpoint (breakpoint *bp)
12432 {
12433 return (bp->ops == &catch_exception_breakpoint_ops
12434 || bp->ops == &catch_exception_unhandled_breakpoint_ops
12435 || bp->ops == &catch_assert_breakpoint_ops
12436 || bp->ops == &catch_handlers_breakpoint_ops);
12437 }
12438
12439 /* Split the arguments specified in a "catch exception" command.
12440 Set EX to the appropriate catchpoint type.
12441 Set EXCEP_STRING to the name of the specific exception if
12442 specified by the user.
12443 IS_CATCH_HANDLERS_CMD: True if the arguments are for a
12444 "catch handlers" command. False otherwise.
12445 If a condition is found at the end of the arguments, the condition
12446 expression is stored in COND_STRING (memory must be deallocated
12447 after use). Otherwise COND_STRING is set to NULL. */
12448
12449 static void
12450 catch_ada_exception_command_split (const char *args,
12451 bool is_catch_handlers_cmd,
12452 enum ada_exception_catchpoint_kind *ex,
12453 std::string *excep_string,
12454 std::string *cond_string)
12455 {
12456 std::string exception_name;
12457
12458 exception_name = extract_arg (&args);
12459 if (exception_name == "if")
12460 {
12461 /* This is not an exception name; this is the start of a condition
12462 expression for a catchpoint on all exceptions. So, "un-get"
12463 this token, and set exception_name to NULL. */
12464 exception_name.clear ();
12465 args -= 2;
12466 }
12467
12468 /* Check to see if we have a condition. */
12469
12470 args = skip_spaces (args);
12471 if (startswith (args, "if")
12472 && (isspace (args[2]) || args[2] == '\0'))
12473 {
12474 args += 2;
12475 args = skip_spaces (args);
12476
12477 if (args[0] == '\0')
12478 error (_("Condition missing after `if' keyword"));
12479 *cond_string = args;
12480
12481 args += strlen (args);
12482 }
12483
12484 /* Check that we do not have any more arguments. Anything else
12485 is unexpected. */
12486
12487 if (args[0] != '\0')
12488 error (_("Junk at end of expression"));
12489
12490 if (is_catch_handlers_cmd)
12491 {
12492 /* Catch handling of exceptions. */
12493 *ex = ada_catch_handlers;
12494 *excep_string = exception_name;
12495 }
12496 else if (exception_name.empty ())
12497 {
12498 /* Catch all exceptions. */
12499 *ex = ada_catch_exception;
12500 excep_string->clear ();
12501 }
12502 else if (exception_name == "unhandled")
12503 {
12504 /* Catch unhandled exceptions. */
12505 *ex = ada_catch_exception_unhandled;
12506 excep_string->clear ();
12507 }
12508 else
12509 {
12510 /* Catch a specific exception. */
12511 *ex = ada_catch_exception;
12512 *excep_string = exception_name;
12513 }
12514 }
12515
12516 /* Return the name of the symbol on which we should break in order to
12517 implement a catchpoint of the EX kind. */
12518
12519 static const char *
12520 ada_exception_sym_name (enum ada_exception_catchpoint_kind ex)
12521 {
12522 struct ada_inferior_data *data = get_ada_inferior_data (current_inferior ());
12523
12524 gdb_assert (data->exception_info != NULL);
12525
12526 switch (ex)
12527 {
12528 case ada_catch_exception:
12529 return (data->exception_info->catch_exception_sym);
12530 break;
12531 case ada_catch_exception_unhandled:
12532 return (data->exception_info->catch_exception_unhandled_sym);
12533 break;
12534 case ada_catch_assert:
12535 return (data->exception_info->catch_assert_sym);
12536 break;
12537 case ada_catch_handlers:
12538 return (data->exception_info->catch_handlers_sym);
12539 break;
12540 default:
12541 internal_error (__FILE__, __LINE__,
12542 _("unexpected catchpoint kind (%d)"), ex);
12543 }
12544 }
12545
12546 /* Return the breakpoint ops "virtual table" used for catchpoints
12547 of the EX kind. */
12548
12549 static const struct breakpoint_ops *
12550 ada_exception_breakpoint_ops (enum ada_exception_catchpoint_kind ex)
12551 {
12552 switch (ex)
12553 {
12554 case ada_catch_exception:
12555 return (&catch_exception_breakpoint_ops);
12556 break;
12557 case ada_catch_exception_unhandled:
12558 return (&catch_exception_unhandled_breakpoint_ops);
12559 break;
12560 case ada_catch_assert:
12561 return (&catch_assert_breakpoint_ops);
12562 break;
12563 case ada_catch_handlers:
12564 return (&catch_handlers_breakpoint_ops);
12565 break;
12566 default:
12567 internal_error (__FILE__, __LINE__,
12568 _("unexpected catchpoint kind (%d)"), ex);
12569 }
12570 }
12571
12572 /* Return the condition that will be used to match the current exception
12573 being raised with the exception that the user wants to catch. This
12574 assumes that this condition is used when the inferior just triggered
12575 an exception catchpoint.
12576 EX: the type of catchpoints used for catching Ada exceptions. */
12577
12578 static std::string
12579 ada_exception_catchpoint_cond_string (const char *excep_string,
12580 enum ada_exception_catchpoint_kind ex)
12581 {
12582 int i;
12583 bool is_standard_exc = false;
12584 std::string result;
12585
12586 if (ex == ada_catch_handlers)
12587 {
12588 /* For exception handlers catchpoints, the condition string does
12589 not use the same parameter as for the other exceptions. */
12590 result = ("long_integer (GNAT_GCC_exception_Access"
12591 "(gcc_exception).all.occurrence.id)");
12592 }
12593 else
12594 result = "long_integer (e)";
12595
12596 /* The standard exceptions are a special case. They are defined in
12597 runtime units that have been compiled without debugging info; if
12598 EXCEP_STRING is the not-fully-qualified name of a standard
12599 exception (e.g. "constraint_error") then, during the evaluation
12600 of the condition expression, the symbol lookup on this name would
12601 *not* return this standard exception. The catchpoint condition
12602 may then be set only on user-defined exceptions which have the
12603 same not-fully-qualified name (e.g. my_package.constraint_error).
12604
12605 To avoid this unexcepted behavior, these standard exceptions are
12606 systematically prefixed by "standard". This means that "catch
12607 exception constraint_error" is rewritten into "catch exception
12608 standard.constraint_error".
12609
12610 If an exception named constraint_error is defined in another package of
12611 the inferior program, then the only way to specify this exception as a
12612 breakpoint condition is to use its fully-qualified named:
12613 e.g. my_package.constraint_error. */
12614
12615 for (i = 0; i < sizeof (standard_exc) / sizeof (char *); i++)
12616 {
12617 if (strcmp (standard_exc [i], excep_string) == 0)
12618 {
12619 is_standard_exc = true;
12620 break;
12621 }
12622 }
12623
12624 result += " = ";
12625
12626 if (is_standard_exc)
12627 string_appendf (result, "long_integer (&standard.%s)", excep_string);
12628 else
12629 string_appendf (result, "long_integer (&%s)", excep_string);
12630
12631 return result;
12632 }
12633
12634 /* Return the symtab_and_line that should be used to insert an exception
12635 catchpoint of the TYPE kind.
12636
12637 ADDR_STRING returns the name of the function where the real
12638 breakpoint that implements the catchpoints is set, depending on the
12639 type of catchpoint we need to create. */
12640
12641 static struct symtab_and_line
12642 ada_exception_sal (enum ada_exception_catchpoint_kind ex,
12643 std::string *addr_string, const struct breakpoint_ops **ops)
12644 {
12645 const char *sym_name;
12646 struct symbol *sym;
12647
12648 /* First, find out which exception support info to use. */
12649 ada_exception_support_info_sniffer ();
12650
12651 /* Then lookup the function on which we will break in order to catch
12652 the Ada exceptions requested by the user. */
12653 sym_name = ada_exception_sym_name (ex);
12654 sym = standard_lookup (sym_name, NULL, VAR_DOMAIN);
12655
12656 if (sym == NULL)
12657 error (_("Catchpoint symbol not found: %s"), sym_name);
12658
12659 if (SYMBOL_CLASS (sym) != LOC_BLOCK)
12660 error (_("Unable to insert catchpoint. %s is not a function."), sym_name);
12661
12662 /* Set ADDR_STRING. */
12663 *addr_string = sym_name;
12664
12665 /* Set OPS. */
12666 *ops = ada_exception_breakpoint_ops (ex);
12667
12668 return find_function_start_sal (sym, 1);
12669 }
12670
12671 /* Create an Ada exception catchpoint.
12672
12673 EX_KIND is the kind of exception catchpoint to be created.
12674
12675 If EXCEPT_STRING is empty, this catchpoint is expected to trigger
12676 for all exceptions. Otherwise, EXCEPT_STRING indicates the name
12677 of the exception to which this catchpoint applies.
12678
12679 COND_STRING, if not empty, is the catchpoint condition.
12680
12681 TEMPFLAG, if nonzero, means that the underlying breakpoint
12682 should be temporary.
12683
12684 FROM_TTY is the usual argument passed to all commands implementations. */
12685
12686 void
12687 create_ada_exception_catchpoint (struct gdbarch *gdbarch,
12688 enum ada_exception_catchpoint_kind ex_kind,
12689 const std::string &excep_string,
12690 const std::string &cond_string,
12691 int tempflag,
12692 int disabled,
12693 int from_tty)
12694 {
12695 std::string addr_string;
12696 const struct breakpoint_ops *ops = NULL;
12697 struct symtab_and_line sal = ada_exception_sal (ex_kind, &addr_string, &ops);
12698
12699 std::unique_ptr<ada_catchpoint> c (new ada_catchpoint (ex_kind));
12700 init_ada_exception_breakpoint (c.get (), gdbarch, sal, addr_string.c_str (),
12701 ops, tempflag, disabled, from_tty);
12702 c->excep_string = excep_string;
12703 create_excep_cond_exprs (c.get (), ex_kind);
12704 if (!cond_string.empty ())
12705 set_breakpoint_condition (c.get (), cond_string.c_str (), from_tty);
12706 install_breakpoint (0, std::move (c), 1);
12707 }
12708
12709 /* Implement the "catch exception" command. */
12710
12711 static void
12712 catch_ada_exception_command (const char *arg_entry, int from_tty,
12713 struct cmd_list_element *command)
12714 {
12715 const char *arg = arg_entry;
12716 struct gdbarch *gdbarch = get_current_arch ();
12717 int tempflag;
12718 enum ada_exception_catchpoint_kind ex_kind;
12719 std::string excep_string;
12720 std::string cond_string;
12721
12722 tempflag = get_cmd_context (command) == CATCH_TEMPORARY;
12723
12724 if (!arg)
12725 arg = "";
12726 catch_ada_exception_command_split (arg, false, &ex_kind, &excep_string,
12727 &cond_string);
12728 create_ada_exception_catchpoint (gdbarch, ex_kind,
12729 excep_string, cond_string,
12730 tempflag, 1 /* enabled */,
12731 from_tty);
12732 }
12733
12734 /* Implement the "catch handlers" command. */
12735
12736 static void
12737 catch_ada_handlers_command (const char *arg_entry, int from_tty,
12738 struct cmd_list_element *command)
12739 {
12740 const char *arg = arg_entry;
12741 struct gdbarch *gdbarch = get_current_arch ();
12742 int tempflag;
12743 enum ada_exception_catchpoint_kind ex_kind;
12744 std::string excep_string;
12745 std::string cond_string;
12746
12747 tempflag = get_cmd_context (command) == CATCH_TEMPORARY;
12748
12749 if (!arg)
12750 arg = "";
12751 catch_ada_exception_command_split (arg, true, &ex_kind, &excep_string,
12752 &cond_string);
12753 create_ada_exception_catchpoint (gdbarch, ex_kind,
12754 excep_string, cond_string,
12755 tempflag, 1 /* enabled */,
12756 from_tty);
12757 }
12758
12759 /* Completion function for the Ada "catch" commands. */
12760
12761 static void
12762 catch_ada_completer (struct cmd_list_element *cmd, completion_tracker &tracker,
12763 const char *text, const char *word)
12764 {
12765 std::vector<ada_exc_info> exceptions = ada_exceptions_list (NULL);
12766
12767 for (const ada_exc_info &info : exceptions)
12768 {
12769 if (startswith (info.name, word))
12770 tracker.add_completion (make_unique_xstrdup (info.name));
12771 }
12772 }
12773
12774 /* Split the arguments specified in a "catch assert" command.
12775
12776 ARGS contains the command's arguments (or the empty string if
12777 no arguments were passed).
12778
12779 If ARGS contains a condition, set COND_STRING to that condition
12780 (the memory needs to be deallocated after use). */
12781
12782 static void
12783 catch_ada_assert_command_split (const char *args, std::string &cond_string)
12784 {
12785 args = skip_spaces (args);
12786
12787 /* Check whether a condition was provided. */
12788 if (startswith (args, "if")
12789 && (isspace (args[2]) || args[2] == '\0'))
12790 {
12791 args += 2;
12792 args = skip_spaces (args);
12793 if (args[0] == '\0')
12794 error (_("condition missing after `if' keyword"));
12795 cond_string.assign (args);
12796 }
12797
12798 /* Otherwise, there should be no other argument at the end of
12799 the command. */
12800 else if (args[0] != '\0')
12801 error (_("Junk at end of arguments."));
12802 }
12803
12804 /* Implement the "catch assert" command. */
12805
12806 static void
12807 catch_assert_command (const char *arg_entry, int from_tty,
12808 struct cmd_list_element *command)
12809 {
12810 const char *arg = arg_entry;
12811 struct gdbarch *gdbarch = get_current_arch ();
12812 int tempflag;
12813 std::string cond_string;
12814
12815 tempflag = get_cmd_context (command) == CATCH_TEMPORARY;
12816
12817 if (!arg)
12818 arg = "";
12819 catch_ada_assert_command_split (arg, cond_string);
12820 create_ada_exception_catchpoint (gdbarch, ada_catch_assert,
12821 "", cond_string,
12822 tempflag, 1 /* enabled */,
12823 from_tty);
12824 }
12825
12826 /* Return non-zero if the symbol SYM is an Ada exception object. */
12827
12828 static int
12829 ada_is_exception_sym (struct symbol *sym)
12830 {
12831 const char *type_name = SYMBOL_TYPE (sym)->name ();
12832
12833 return (SYMBOL_CLASS (sym) != LOC_TYPEDEF
12834 && SYMBOL_CLASS (sym) != LOC_BLOCK
12835 && SYMBOL_CLASS (sym) != LOC_CONST
12836 && SYMBOL_CLASS (sym) != LOC_UNRESOLVED
12837 && type_name != NULL && strcmp (type_name, "exception") == 0);
12838 }
12839
12840 /* Given a global symbol SYM, return non-zero iff SYM is a non-standard
12841 Ada exception object. This matches all exceptions except the ones
12842 defined by the Ada language. */
12843
12844 static int
12845 ada_is_non_standard_exception_sym (struct symbol *sym)
12846 {
12847 int i;
12848
12849 if (!ada_is_exception_sym (sym))
12850 return 0;
12851
12852 for (i = 0; i < ARRAY_SIZE (standard_exc); i++)
12853 if (strcmp (sym->linkage_name (), standard_exc[i]) == 0)
12854 return 0; /* A standard exception. */
12855
12856 /* Numeric_Error is also a standard exception, so exclude it.
12857 See the STANDARD_EXC description for more details as to why
12858 this exception is not listed in that array. */
12859 if (strcmp (sym->linkage_name (), "numeric_error") == 0)
12860 return 0;
12861
12862 return 1;
12863 }
12864
12865 /* A helper function for std::sort, comparing two struct ada_exc_info
12866 objects.
12867
12868 The comparison is determined first by exception name, and then
12869 by exception address. */
12870
12871 bool
12872 ada_exc_info::operator< (const ada_exc_info &other) const
12873 {
12874 int result;
12875
12876 result = strcmp (name, other.name);
12877 if (result < 0)
12878 return true;
12879 if (result == 0 && addr < other.addr)
12880 return true;
12881 return false;
12882 }
12883
12884 bool
12885 ada_exc_info::operator== (const ada_exc_info &other) const
12886 {
12887 return addr == other.addr && strcmp (name, other.name) == 0;
12888 }
12889
12890 /* Sort EXCEPTIONS using compare_ada_exception_info as the comparison
12891 routine, but keeping the first SKIP elements untouched.
12892
12893 All duplicates are also removed. */
12894
12895 static void
12896 sort_remove_dups_ada_exceptions_list (std::vector<ada_exc_info> *exceptions,
12897 int skip)
12898 {
12899 std::sort (exceptions->begin () + skip, exceptions->end ());
12900 exceptions->erase (std::unique (exceptions->begin () + skip, exceptions->end ()),
12901 exceptions->end ());
12902 }
12903
12904 /* Add all exceptions defined by the Ada standard whose name match
12905 a regular expression.
12906
12907 If PREG is not NULL, then this regexp_t object is used to
12908 perform the symbol name matching. Otherwise, no name-based
12909 filtering is performed.
12910
12911 EXCEPTIONS is a vector of exceptions to which matching exceptions
12912 gets pushed. */
12913
12914 static void
12915 ada_add_standard_exceptions (compiled_regex *preg,
12916 std::vector<ada_exc_info> *exceptions)
12917 {
12918 int i;
12919
12920 for (i = 0; i < ARRAY_SIZE (standard_exc); i++)
12921 {
12922 if (preg == NULL
12923 || preg->exec (standard_exc[i], 0, NULL, 0) == 0)
12924 {
12925 struct bound_minimal_symbol msymbol
12926 = ada_lookup_simple_minsym (standard_exc[i]);
12927
12928 if (msymbol.minsym != NULL)
12929 {
12930 struct ada_exc_info info
12931 = {standard_exc[i], BMSYMBOL_VALUE_ADDRESS (msymbol)};
12932
12933 exceptions->push_back (info);
12934 }
12935 }
12936 }
12937 }
12938
12939 /* Add all Ada exceptions defined locally and accessible from the given
12940 FRAME.
12941
12942 If PREG is not NULL, then this regexp_t object is used to
12943 perform the symbol name matching. Otherwise, no name-based
12944 filtering is performed.
12945
12946 EXCEPTIONS is a vector of exceptions to which matching exceptions
12947 gets pushed. */
12948
12949 static void
12950 ada_add_exceptions_from_frame (compiled_regex *preg,
12951 struct frame_info *frame,
12952 std::vector<ada_exc_info> *exceptions)
12953 {
12954 const struct block *block = get_frame_block (frame, 0);
12955
12956 while (block != 0)
12957 {
12958 struct block_iterator iter;
12959 struct symbol *sym;
12960
12961 ALL_BLOCK_SYMBOLS (block, iter, sym)
12962 {
12963 switch (SYMBOL_CLASS (sym))
12964 {
12965 case LOC_TYPEDEF:
12966 case LOC_BLOCK:
12967 case LOC_CONST:
12968 break;
12969 default:
12970 if (ada_is_exception_sym (sym))
12971 {
12972 struct ada_exc_info info = {sym->print_name (),
12973 SYMBOL_VALUE_ADDRESS (sym)};
12974
12975 exceptions->push_back (info);
12976 }
12977 }
12978 }
12979 if (BLOCK_FUNCTION (block) != NULL)
12980 break;
12981 block = BLOCK_SUPERBLOCK (block);
12982 }
12983 }
12984
12985 /* Return true if NAME matches PREG or if PREG is NULL. */
12986
12987 static bool
12988 name_matches_regex (const char *name, compiled_regex *preg)
12989 {
12990 return (preg == NULL
12991 || preg->exec (ada_decode (name).c_str (), 0, NULL, 0) == 0);
12992 }
12993
12994 /* Add all exceptions defined globally whose name name match
12995 a regular expression, excluding standard exceptions.
12996
12997 The reason we exclude standard exceptions is that they need
12998 to be handled separately: Standard exceptions are defined inside
12999 a runtime unit which is normally not compiled with debugging info,
13000 and thus usually do not show up in our symbol search. However,
13001 if the unit was in fact built with debugging info, we need to
13002 exclude them because they would duplicate the entry we found
13003 during the special loop that specifically searches for those
13004 standard exceptions.
13005
13006 If PREG is not NULL, then this regexp_t object is used to
13007 perform the symbol name matching. Otherwise, no name-based
13008 filtering is performed.
13009
13010 EXCEPTIONS is a vector of exceptions to which matching exceptions
13011 gets pushed. */
13012
13013 static void
13014 ada_add_global_exceptions (compiled_regex *preg,
13015 std::vector<ada_exc_info> *exceptions)
13016 {
13017 /* In Ada, the symbol "search name" is a linkage name, whereas the
13018 regular expression used to do the matching refers to the natural
13019 name. So match against the decoded name. */
13020 expand_symtabs_matching (NULL,
13021 lookup_name_info::match_any (),
13022 [&] (const char *search_name)
13023 {
13024 std::string decoded = ada_decode (search_name);
13025 return name_matches_regex (decoded.c_str (), preg);
13026 },
13027 NULL,
13028 VARIABLES_DOMAIN);
13029
13030 for (objfile *objfile : current_program_space->objfiles ())
13031 {
13032 for (compunit_symtab *s : objfile->compunits ())
13033 {
13034 const struct blockvector *bv = COMPUNIT_BLOCKVECTOR (s);
13035 int i;
13036
13037 for (i = GLOBAL_BLOCK; i <= STATIC_BLOCK; i++)
13038 {
13039 const struct block *b = BLOCKVECTOR_BLOCK (bv, i);
13040 struct block_iterator iter;
13041 struct symbol *sym;
13042
13043 ALL_BLOCK_SYMBOLS (b, iter, sym)
13044 if (ada_is_non_standard_exception_sym (sym)
13045 && name_matches_regex (sym->natural_name (), preg))
13046 {
13047 struct ada_exc_info info
13048 = {sym->print_name (), SYMBOL_VALUE_ADDRESS (sym)};
13049
13050 exceptions->push_back (info);
13051 }
13052 }
13053 }
13054 }
13055 }
13056
13057 /* Implements ada_exceptions_list with the regular expression passed
13058 as a regex_t, rather than a string.
13059
13060 If not NULL, PREG is used to filter out exceptions whose names
13061 do not match. Otherwise, all exceptions are listed. */
13062
13063 static std::vector<ada_exc_info>
13064 ada_exceptions_list_1 (compiled_regex *preg)
13065 {
13066 std::vector<ada_exc_info> result;
13067 int prev_len;
13068
13069 /* First, list the known standard exceptions. These exceptions
13070 need to be handled separately, as they are usually defined in
13071 runtime units that have been compiled without debugging info. */
13072
13073 ada_add_standard_exceptions (preg, &result);
13074
13075 /* Next, find all exceptions whose scope is local and accessible
13076 from the currently selected frame. */
13077
13078 if (has_stack_frames ())
13079 {
13080 prev_len = result.size ();
13081 ada_add_exceptions_from_frame (preg, get_selected_frame (NULL),
13082 &result);
13083 if (result.size () > prev_len)
13084 sort_remove_dups_ada_exceptions_list (&result, prev_len);
13085 }
13086
13087 /* Add all exceptions whose scope is global. */
13088
13089 prev_len = result.size ();
13090 ada_add_global_exceptions (preg, &result);
13091 if (result.size () > prev_len)
13092 sort_remove_dups_ada_exceptions_list (&result, prev_len);
13093
13094 return result;
13095 }
13096
13097 /* Return a vector of ada_exc_info.
13098
13099 If REGEXP is NULL, all exceptions are included in the result.
13100 Otherwise, it should contain a valid regular expression,
13101 and only the exceptions whose names match that regular expression
13102 are included in the result.
13103
13104 The exceptions are sorted in the following order:
13105 - Standard exceptions (defined by the Ada language), in
13106 alphabetical order;
13107 - Exceptions only visible from the current frame, in
13108 alphabetical order;
13109 - Exceptions whose scope is global, in alphabetical order. */
13110
13111 std::vector<ada_exc_info>
13112 ada_exceptions_list (const char *regexp)
13113 {
13114 if (regexp == NULL)
13115 return ada_exceptions_list_1 (NULL);
13116
13117 compiled_regex reg (regexp, REG_NOSUB, _("invalid regular expression"));
13118 return ada_exceptions_list_1 (&reg);
13119 }
13120
13121 /* Implement the "info exceptions" command. */
13122
13123 static void
13124 info_exceptions_command (const char *regexp, int from_tty)
13125 {
13126 struct gdbarch *gdbarch = get_current_arch ();
13127
13128 std::vector<ada_exc_info> exceptions = ada_exceptions_list (regexp);
13129
13130 if (regexp != NULL)
13131 printf_filtered
13132 (_("All Ada exceptions matching regular expression \"%s\":\n"), regexp);
13133 else
13134 printf_filtered (_("All defined Ada exceptions:\n"));
13135
13136 for (const ada_exc_info &info : exceptions)
13137 printf_filtered ("%s: %s\n", info.name, paddress (gdbarch, info.addr));
13138 }
13139
13140 /* Operators */
13141 /* Information about operators given special treatment in functions
13142 below. */
13143 /* Format: OP_DEFN (<operator>, <operator length>, <# args>, <binop>). */
13144
13145 #define ADA_OPERATORS \
13146 OP_DEFN (OP_VAR_VALUE, 4, 0, 0) \
13147 OP_DEFN (BINOP_IN_BOUNDS, 3, 2, 0) \
13148 OP_DEFN (TERNOP_IN_RANGE, 1, 3, 0) \
13149 OP_DEFN (OP_ATR_FIRST, 1, 2, 0) \
13150 OP_DEFN (OP_ATR_LAST, 1, 2, 0) \
13151 OP_DEFN (OP_ATR_LENGTH, 1, 2, 0) \
13152 OP_DEFN (OP_ATR_IMAGE, 1, 2, 0) \
13153 OP_DEFN (OP_ATR_MAX, 1, 3, 0) \
13154 OP_DEFN (OP_ATR_MIN, 1, 3, 0) \
13155 OP_DEFN (OP_ATR_MODULUS, 1, 1, 0) \
13156 OP_DEFN (OP_ATR_POS, 1, 2, 0) \
13157 OP_DEFN (OP_ATR_SIZE, 1, 1, 0) \
13158 OP_DEFN (OP_ATR_TAG, 1, 1, 0) \
13159 OP_DEFN (OP_ATR_VAL, 1, 2, 0) \
13160 OP_DEFN (UNOP_QUAL, 3, 1, 0) \
13161 OP_DEFN (UNOP_IN_RANGE, 3, 1, 0) \
13162 OP_DEFN (OP_OTHERS, 1, 1, 0) \
13163 OP_DEFN (OP_POSITIONAL, 3, 1, 0) \
13164 OP_DEFN (OP_DISCRETE_RANGE, 1, 2, 0)
13165
13166 static void
13167 ada_operator_length (const struct expression *exp, int pc, int *oplenp,
13168 int *argsp)
13169 {
13170 switch (exp->elts[pc - 1].opcode)
13171 {
13172 default:
13173 operator_length_standard (exp, pc, oplenp, argsp);
13174 break;
13175
13176 #define OP_DEFN(op, len, args, binop) \
13177 case op: *oplenp = len; *argsp = args; break;
13178 ADA_OPERATORS;
13179 #undef OP_DEFN
13180
13181 case OP_AGGREGATE:
13182 *oplenp = 3;
13183 *argsp = longest_to_int (exp->elts[pc - 2].longconst);
13184 break;
13185
13186 case OP_CHOICES:
13187 *oplenp = 3;
13188 *argsp = longest_to_int (exp->elts[pc - 2].longconst) + 1;
13189 break;
13190 }
13191 }
13192
13193 /* Implementation of the exp_descriptor method operator_check. */
13194
13195 static int
13196 ada_operator_check (struct expression *exp, int pos,
13197 int (*objfile_func) (struct objfile *objfile, void *data),
13198 void *data)
13199 {
13200 const union exp_element *const elts = exp->elts;
13201 struct type *type = NULL;
13202
13203 switch (elts[pos].opcode)
13204 {
13205 case UNOP_IN_RANGE:
13206 case UNOP_QUAL:
13207 type = elts[pos + 1].type;
13208 break;
13209
13210 default:
13211 return operator_check_standard (exp, pos, objfile_func, data);
13212 }
13213
13214 /* Invoke callbacks for TYPE and OBJFILE if they were set as non-NULL. */
13215
13216 if (type && TYPE_OBJFILE (type)
13217 && (*objfile_func) (TYPE_OBJFILE (type), data))
13218 return 1;
13219
13220 return 0;
13221 }
13222
13223 static const char *
13224 ada_op_name (enum exp_opcode opcode)
13225 {
13226 switch (opcode)
13227 {
13228 default:
13229 return op_name_standard (opcode);
13230
13231 #define OP_DEFN(op, len, args, binop) case op: return #op;
13232 ADA_OPERATORS;
13233 #undef OP_DEFN
13234
13235 case OP_AGGREGATE:
13236 return "OP_AGGREGATE";
13237 case OP_CHOICES:
13238 return "OP_CHOICES";
13239 case OP_NAME:
13240 return "OP_NAME";
13241 }
13242 }
13243
13244 /* As for operator_length, but assumes PC is pointing at the first
13245 element of the operator, and gives meaningful results only for the
13246 Ada-specific operators, returning 0 for *OPLENP and *ARGSP otherwise. */
13247
13248 static void
13249 ada_forward_operator_length (struct expression *exp, int pc,
13250 int *oplenp, int *argsp)
13251 {
13252 switch (exp->elts[pc].opcode)
13253 {
13254 default:
13255 *oplenp = *argsp = 0;
13256 break;
13257
13258 #define OP_DEFN(op, len, args, binop) \
13259 case op: *oplenp = len; *argsp = args; break;
13260 ADA_OPERATORS;
13261 #undef OP_DEFN
13262
13263 case OP_AGGREGATE:
13264 *oplenp = 3;
13265 *argsp = longest_to_int (exp->elts[pc + 1].longconst);
13266 break;
13267
13268 case OP_CHOICES:
13269 *oplenp = 3;
13270 *argsp = longest_to_int (exp->elts[pc + 1].longconst) + 1;
13271 break;
13272
13273 case OP_STRING:
13274 case OP_NAME:
13275 {
13276 int len = longest_to_int (exp->elts[pc + 1].longconst);
13277
13278 *oplenp = 4 + BYTES_TO_EXP_ELEM (len + 1);
13279 *argsp = 0;
13280 break;
13281 }
13282 }
13283 }
13284
13285 static int
13286 ada_dump_subexp_body (struct expression *exp, struct ui_file *stream, int elt)
13287 {
13288 enum exp_opcode op = exp->elts[elt].opcode;
13289 int oplen, nargs;
13290 int pc = elt;
13291 int i;
13292
13293 ada_forward_operator_length (exp, elt, &oplen, &nargs);
13294
13295 switch (op)
13296 {
13297 /* Ada attributes ('Foo). */
13298 case OP_ATR_FIRST:
13299 case OP_ATR_LAST:
13300 case OP_ATR_LENGTH:
13301 case OP_ATR_IMAGE:
13302 case OP_ATR_MAX:
13303 case OP_ATR_MIN:
13304 case OP_ATR_MODULUS:
13305 case OP_ATR_POS:
13306 case OP_ATR_SIZE:
13307 case OP_ATR_TAG:
13308 case OP_ATR_VAL:
13309 break;
13310
13311 case UNOP_IN_RANGE:
13312 case UNOP_QUAL:
13313 /* XXX: gdb_sprint_host_address, type_sprint */
13314 fprintf_filtered (stream, _("Type @"));
13315 gdb_print_host_address (exp->elts[pc + 1].type, stream);
13316 fprintf_filtered (stream, " (");
13317 type_print (exp->elts[pc + 1].type, NULL, stream, 0);
13318 fprintf_filtered (stream, ")");
13319 break;
13320 case BINOP_IN_BOUNDS:
13321 fprintf_filtered (stream, " (%d)",
13322 longest_to_int (exp->elts[pc + 2].longconst));
13323 break;
13324 case TERNOP_IN_RANGE:
13325 break;
13326
13327 case OP_AGGREGATE:
13328 case OP_OTHERS:
13329 case OP_DISCRETE_RANGE:
13330 case OP_POSITIONAL:
13331 case OP_CHOICES:
13332 break;
13333
13334 case OP_NAME:
13335 case OP_STRING:
13336 {
13337 char *name = &exp->elts[elt + 2].string;
13338 int len = longest_to_int (exp->elts[elt + 1].longconst);
13339
13340 fprintf_filtered (stream, "Text: `%.*s'", len, name);
13341 break;
13342 }
13343
13344 default:
13345 return dump_subexp_body_standard (exp, stream, elt);
13346 }
13347
13348 elt += oplen;
13349 for (i = 0; i < nargs; i += 1)
13350 elt = dump_subexp (exp, stream, elt);
13351
13352 return elt;
13353 }
13354
13355 /* The Ada extension of print_subexp (q.v.). */
13356
13357 static void
13358 ada_print_subexp (struct expression *exp, int *pos,
13359 struct ui_file *stream, enum precedence prec)
13360 {
13361 int oplen, nargs, i;
13362 int pc = *pos;
13363 enum exp_opcode op = exp->elts[pc].opcode;
13364
13365 ada_forward_operator_length (exp, pc, &oplen, &nargs);
13366
13367 *pos += oplen;
13368 switch (op)
13369 {
13370 default:
13371 *pos -= oplen;
13372 print_subexp_standard (exp, pos, stream, prec);
13373 return;
13374
13375 case OP_VAR_VALUE:
13376 fputs_filtered (exp->elts[pc + 2].symbol->natural_name (), stream);
13377 return;
13378
13379 case BINOP_IN_BOUNDS:
13380 /* XXX: sprint_subexp */
13381 print_subexp (exp, pos, stream, PREC_SUFFIX);
13382 fputs_filtered (" in ", stream);
13383 print_subexp (exp, pos, stream, PREC_SUFFIX);
13384 fputs_filtered ("'range", stream);
13385 if (exp->elts[pc + 1].longconst > 1)
13386 fprintf_filtered (stream, "(%ld)",
13387 (long) exp->elts[pc + 1].longconst);
13388 return;
13389
13390 case TERNOP_IN_RANGE:
13391 if (prec >= PREC_EQUAL)
13392 fputs_filtered ("(", stream);
13393 /* XXX: sprint_subexp */
13394 print_subexp (exp, pos, stream, PREC_SUFFIX);
13395 fputs_filtered (" in ", stream);
13396 print_subexp (exp, pos, stream, PREC_EQUAL);
13397 fputs_filtered (" .. ", stream);
13398 print_subexp (exp, pos, stream, PREC_EQUAL);
13399 if (prec >= PREC_EQUAL)
13400 fputs_filtered (")", stream);
13401 return;
13402
13403 case OP_ATR_FIRST:
13404 case OP_ATR_LAST:
13405 case OP_ATR_LENGTH:
13406 case OP_ATR_IMAGE:
13407 case OP_ATR_MAX:
13408 case OP_ATR_MIN:
13409 case OP_ATR_MODULUS:
13410 case OP_ATR_POS:
13411 case OP_ATR_SIZE:
13412 case OP_ATR_TAG:
13413 case OP_ATR_VAL:
13414 if (exp->elts[*pos].opcode == OP_TYPE)
13415 {
13416 if (exp->elts[*pos + 1].type->code () != TYPE_CODE_VOID)
13417 LA_PRINT_TYPE (exp->elts[*pos + 1].type, "", stream, 0, 0,
13418 &type_print_raw_options);
13419 *pos += 3;
13420 }
13421 else
13422 print_subexp (exp, pos, stream, PREC_SUFFIX);
13423 fprintf_filtered (stream, "'%s", ada_attribute_name (op));
13424 if (nargs > 1)
13425 {
13426 int tem;
13427
13428 for (tem = 1; tem < nargs; tem += 1)
13429 {
13430 fputs_filtered ((tem == 1) ? " (" : ", ", stream);
13431 print_subexp (exp, pos, stream, PREC_ABOVE_COMMA);
13432 }
13433 fputs_filtered (")", stream);
13434 }
13435 return;
13436
13437 case UNOP_QUAL:
13438 type_print (exp->elts[pc + 1].type, "", stream, 0);
13439 fputs_filtered ("'(", stream);
13440 print_subexp (exp, pos, stream, PREC_PREFIX);
13441 fputs_filtered (")", stream);
13442 return;
13443
13444 case UNOP_IN_RANGE:
13445 /* XXX: sprint_subexp */
13446 print_subexp (exp, pos, stream, PREC_SUFFIX);
13447 fputs_filtered (" in ", stream);
13448 LA_PRINT_TYPE (exp->elts[pc + 1].type, "", stream, 1, 0,
13449 &type_print_raw_options);
13450 return;
13451
13452 case OP_DISCRETE_RANGE:
13453 print_subexp (exp, pos, stream, PREC_SUFFIX);
13454 fputs_filtered ("..", stream);
13455 print_subexp (exp, pos, stream, PREC_SUFFIX);
13456 return;
13457
13458 case OP_OTHERS:
13459 fputs_filtered ("others => ", stream);
13460 print_subexp (exp, pos, stream, PREC_SUFFIX);
13461 return;
13462
13463 case OP_CHOICES:
13464 for (i = 0; i < nargs-1; i += 1)
13465 {
13466 if (i > 0)
13467 fputs_filtered ("|", stream);
13468 print_subexp (exp, pos, stream, PREC_SUFFIX);
13469 }
13470 fputs_filtered (" => ", stream);
13471 print_subexp (exp, pos, stream, PREC_SUFFIX);
13472 return;
13473
13474 case OP_POSITIONAL:
13475 print_subexp (exp, pos, stream, PREC_SUFFIX);
13476 return;
13477
13478 case OP_AGGREGATE:
13479 fputs_filtered ("(", stream);
13480 for (i = 0; i < nargs; i += 1)
13481 {
13482 if (i > 0)
13483 fputs_filtered (", ", stream);
13484 print_subexp (exp, pos, stream, PREC_SUFFIX);
13485 }
13486 fputs_filtered (")", stream);
13487 return;
13488 }
13489 }
13490
13491 /* Table mapping opcodes into strings for printing operators
13492 and precedences of the operators. */
13493
13494 static const struct op_print ada_op_print_tab[] = {
13495 {":=", BINOP_ASSIGN, PREC_ASSIGN, 1},
13496 {"or else", BINOP_LOGICAL_OR, PREC_LOGICAL_OR, 0},
13497 {"and then", BINOP_LOGICAL_AND, PREC_LOGICAL_AND, 0},
13498 {"or", BINOP_BITWISE_IOR, PREC_BITWISE_IOR, 0},
13499 {"xor", BINOP_BITWISE_XOR, PREC_BITWISE_XOR, 0},
13500 {"and", BINOP_BITWISE_AND, PREC_BITWISE_AND, 0},
13501 {"=", BINOP_EQUAL, PREC_EQUAL, 0},
13502 {"/=", BINOP_NOTEQUAL, PREC_EQUAL, 0},
13503 {"<=", BINOP_LEQ, PREC_ORDER, 0},
13504 {">=", BINOP_GEQ, PREC_ORDER, 0},
13505 {">", BINOP_GTR, PREC_ORDER, 0},
13506 {"<", BINOP_LESS, PREC_ORDER, 0},
13507 {">>", BINOP_RSH, PREC_SHIFT, 0},
13508 {"<<", BINOP_LSH, PREC_SHIFT, 0},
13509 {"+", BINOP_ADD, PREC_ADD, 0},
13510 {"-", BINOP_SUB, PREC_ADD, 0},
13511 {"&", BINOP_CONCAT, PREC_ADD, 0},
13512 {"*", BINOP_MUL, PREC_MUL, 0},
13513 {"/", BINOP_DIV, PREC_MUL, 0},
13514 {"rem", BINOP_REM, PREC_MUL, 0},
13515 {"mod", BINOP_MOD, PREC_MUL, 0},
13516 {"**", BINOP_EXP, PREC_REPEAT, 0},
13517 {"@", BINOP_REPEAT, PREC_REPEAT, 0},
13518 {"-", UNOP_NEG, PREC_PREFIX, 0},
13519 {"+", UNOP_PLUS, PREC_PREFIX, 0},
13520 {"not ", UNOP_LOGICAL_NOT, PREC_PREFIX, 0},
13521 {"not ", UNOP_COMPLEMENT, PREC_PREFIX, 0},
13522 {"abs ", UNOP_ABS, PREC_PREFIX, 0},
13523 {".all", UNOP_IND, PREC_SUFFIX, 1},
13524 {"'access", UNOP_ADDR, PREC_SUFFIX, 1},
13525 {"'size", OP_ATR_SIZE, PREC_SUFFIX, 1},
13526 {NULL, OP_NULL, PREC_SUFFIX, 0}
13527 };
13528 \f
13529 enum ada_primitive_types {
13530 ada_primitive_type_int,
13531 ada_primitive_type_long,
13532 ada_primitive_type_short,
13533 ada_primitive_type_char,
13534 ada_primitive_type_float,
13535 ada_primitive_type_double,
13536 ada_primitive_type_void,
13537 ada_primitive_type_long_long,
13538 ada_primitive_type_long_double,
13539 ada_primitive_type_natural,
13540 ada_primitive_type_positive,
13541 ada_primitive_type_system_address,
13542 ada_primitive_type_storage_offset,
13543 nr_ada_primitive_types
13544 };
13545
13546 \f
13547 /* Language vector */
13548
13549 static const struct exp_descriptor ada_exp_descriptor = {
13550 ada_print_subexp,
13551 ada_operator_length,
13552 ada_operator_check,
13553 ada_op_name,
13554 ada_dump_subexp_body,
13555 ada_evaluate_subexp
13556 };
13557
13558 /* symbol_name_matcher_ftype adapter for wild_match. */
13559
13560 static bool
13561 do_wild_match (const char *symbol_search_name,
13562 const lookup_name_info &lookup_name,
13563 completion_match_result *comp_match_res)
13564 {
13565 return wild_match (symbol_search_name, ada_lookup_name (lookup_name));
13566 }
13567
13568 /* symbol_name_matcher_ftype adapter for full_match. */
13569
13570 static bool
13571 do_full_match (const char *symbol_search_name,
13572 const lookup_name_info &lookup_name,
13573 completion_match_result *comp_match_res)
13574 {
13575 return full_match (symbol_search_name, ada_lookup_name (lookup_name));
13576 }
13577
13578 /* symbol_name_matcher_ftype for exact (verbatim) matches. */
13579
13580 static bool
13581 do_exact_match (const char *symbol_search_name,
13582 const lookup_name_info &lookup_name,
13583 completion_match_result *comp_match_res)
13584 {
13585 return strcmp (symbol_search_name, ada_lookup_name (lookup_name)) == 0;
13586 }
13587
13588 /* Build the Ada lookup name for LOOKUP_NAME. */
13589
13590 ada_lookup_name_info::ada_lookup_name_info (const lookup_name_info &lookup_name)
13591 {
13592 gdb::string_view user_name = lookup_name.name ();
13593
13594 if (user_name[0] == '<')
13595 {
13596 if (user_name.back () == '>')
13597 m_encoded_name
13598 = gdb::to_string (user_name.substr (1, user_name.size () - 2));
13599 else
13600 m_encoded_name
13601 = gdb::to_string (user_name.substr (1, user_name.size () - 1));
13602 m_encoded_p = true;
13603 m_verbatim_p = true;
13604 m_wild_match_p = false;
13605 m_standard_p = false;
13606 }
13607 else
13608 {
13609 m_verbatim_p = false;
13610
13611 m_encoded_p = user_name.find ("__") != gdb::string_view::npos;
13612
13613 if (!m_encoded_p)
13614 {
13615 const char *folded = ada_fold_name (user_name);
13616 const char *encoded = ada_encode_1 (folded, false);
13617 if (encoded != NULL)
13618 m_encoded_name = encoded;
13619 else
13620 m_encoded_name = gdb::to_string (user_name);
13621 }
13622 else
13623 m_encoded_name = gdb::to_string (user_name);
13624
13625 /* Handle the 'package Standard' special case. See description
13626 of m_standard_p. */
13627 if (startswith (m_encoded_name.c_str (), "standard__"))
13628 {
13629 m_encoded_name = m_encoded_name.substr (sizeof ("standard__") - 1);
13630 m_standard_p = true;
13631 }
13632 else
13633 m_standard_p = false;
13634
13635 /* If the name contains a ".", then the user is entering a fully
13636 qualified entity name, and the match must not be done in wild
13637 mode. Similarly, if the user wants to complete what looks
13638 like an encoded name, the match must not be done in wild
13639 mode. Also, in the standard__ special case always do
13640 non-wild matching. */
13641 m_wild_match_p
13642 = (lookup_name.match_type () != symbol_name_match_type::FULL
13643 && !m_encoded_p
13644 && !m_standard_p
13645 && user_name.find ('.') == std::string::npos);
13646 }
13647 }
13648
13649 /* symbol_name_matcher_ftype method for Ada. This only handles
13650 completion mode. */
13651
13652 static bool
13653 ada_symbol_name_matches (const char *symbol_search_name,
13654 const lookup_name_info &lookup_name,
13655 completion_match_result *comp_match_res)
13656 {
13657 return lookup_name.ada ().matches (symbol_search_name,
13658 lookup_name.match_type (),
13659 comp_match_res);
13660 }
13661
13662 /* A name matcher that matches the symbol name exactly, with
13663 strcmp. */
13664
13665 static bool
13666 literal_symbol_name_matcher (const char *symbol_search_name,
13667 const lookup_name_info &lookup_name,
13668 completion_match_result *comp_match_res)
13669 {
13670 gdb::string_view name_view = lookup_name.name ();
13671
13672 if (lookup_name.completion_mode ()
13673 ? (strncmp (symbol_search_name, name_view.data (),
13674 name_view.size ()) == 0)
13675 : symbol_search_name == name_view)
13676 {
13677 if (comp_match_res != NULL)
13678 comp_match_res->set_match (symbol_search_name);
13679 return true;
13680 }
13681 else
13682 return false;
13683 }
13684
13685 /* Implement the "get_symbol_name_matcher" language_defn method for
13686 Ada. */
13687
13688 static symbol_name_matcher_ftype *
13689 ada_get_symbol_name_matcher (const lookup_name_info &lookup_name)
13690 {
13691 if (lookup_name.match_type () == symbol_name_match_type::SEARCH_NAME)
13692 return literal_symbol_name_matcher;
13693
13694 if (lookup_name.completion_mode ())
13695 return ada_symbol_name_matches;
13696 else
13697 {
13698 if (lookup_name.ada ().wild_match_p ())
13699 return do_wild_match;
13700 else if (lookup_name.ada ().verbatim_p ())
13701 return do_exact_match;
13702 else
13703 return do_full_match;
13704 }
13705 }
13706
13707 /* Constant data that describes the Ada language. */
13708
13709 extern const struct language_data ada_language_data =
13710 {
13711 ada_op_print_tab, /* expression operators for printing */
13712 };
13713
13714 /* Class representing the Ada language. */
13715
13716 class ada_language : public language_defn
13717 {
13718 public:
13719 ada_language ()
13720 : language_defn (language_ada, ada_language_data)
13721 { /* Nothing. */ }
13722
13723 /* See language.h. */
13724
13725 const char *name () const override
13726 { return "ada"; }
13727
13728 /* See language.h. */
13729
13730 const char *natural_name () const override
13731 { return "Ada"; }
13732
13733 /* See language.h. */
13734
13735 const std::vector<const char *> &filename_extensions () const override
13736 {
13737 static const std::vector<const char *> extensions
13738 = { ".adb", ".ads", ".a", ".ada", ".dg" };
13739 return extensions;
13740 }
13741
13742 /* Print an array element index using the Ada syntax. */
13743
13744 void print_array_index (struct type *index_type,
13745 LONGEST index,
13746 struct ui_file *stream,
13747 const value_print_options *options) const override
13748 {
13749 struct value *index_value = val_atr (index_type, index);
13750
13751 LA_VALUE_PRINT (index_value, stream, options);
13752 fprintf_filtered (stream, " => ");
13753 }
13754
13755 /* Implement the "read_var_value" language_defn method for Ada. */
13756
13757 struct value *read_var_value (struct symbol *var,
13758 const struct block *var_block,
13759 struct frame_info *frame) const override
13760 {
13761 /* The only case where default_read_var_value is not sufficient
13762 is when VAR is a renaming... */
13763 if (frame != nullptr)
13764 {
13765 const struct block *frame_block = get_frame_block (frame, NULL);
13766 if (frame_block != nullptr && ada_is_renaming_symbol (var))
13767 return ada_read_renaming_var_value (var, frame_block);
13768 }
13769
13770 /* This is a typical case where we expect the default_read_var_value
13771 function to work. */
13772 return language_defn::read_var_value (var, var_block, frame);
13773 }
13774
13775 /* See language.h. */
13776 void language_arch_info (struct gdbarch *gdbarch,
13777 struct language_arch_info *lai) const override
13778 {
13779 const struct builtin_type *builtin = builtin_type (gdbarch);
13780
13781 lai->primitive_type_vector
13782 = GDBARCH_OBSTACK_CALLOC (gdbarch, nr_ada_primitive_types + 1,
13783 struct type *);
13784
13785 lai->primitive_type_vector [ada_primitive_type_int]
13786 = arch_integer_type (gdbarch, gdbarch_int_bit (gdbarch),
13787 0, "integer");
13788 lai->primitive_type_vector [ada_primitive_type_long]
13789 = arch_integer_type (gdbarch, gdbarch_long_bit (gdbarch),
13790 0, "long_integer");
13791 lai->primitive_type_vector [ada_primitive_type_short]
13792 = arch_integer_type (gdbarch, gdbarch_short_bit (gdbarch),
13793 0, "short_integer");
13794 lai->string_char_type
13795 = lai->primitive_type_vector [ada_primitive_type_char]
13796 = arch_character_type (gdbarch, TARGET_CHAR_BIT, 0, "character");
13797 lai->primitive_type_vector [ada_primitive_type_float]
13798 = arch_float_type (gdbarch, gdbarch_float_bit (gdbarch),
13799 "float", gdbarch_float_format (gdbarch));
13800 lai->primitive_type_vector [ada_primitive_type_double]
13801 = arch_float_type (gdbarch, gdbarch_double_bit (gdbarch),
13802 "long_float", gdbarch_double_format (gdbarch));
13803 lai->primitive_type_vector [ada_primitive_type_long_long]
13804 = arch_integer_type (gdbarch, gdbarch_long_long_bit (gdbarch),
13805 0, "long_long_integer");
13806 lai->primitive_type_vector [ada_primitive_type_long_double]
13807 = arch_float_type (gdbarch, gdbarch_long_double_bit (gdbarch),
13808 "long_long_float", gdbarch_long_double_format (gdbarch));
13809 lai->primitive_type_vector [ada_primitive_type_natural]
13810 = arch_integer_type (gdbarch, gdbarch_int_bit (gdbarch),
13811 0, "natural");
13812 lai->primitive_type_vector [ada_primitive_type_positive]
13813 = arch_integer_type (gdbarch, gdbarch_int_bit (gdbarch),
13814 0, "positive");
13815 lai->primitive_type_vector [ada_primitive_type_void]
13816 = builtin->builtin_void;
13817
13818 lai->primitive_type_vector [ada_primitive_type_system_address]
13819 = lookup_pointer_type (arch_type (gdbarch, TYPE_CODE_VOID, TARGET_CHAR_BIT,
13820 "void"));
13821 lai->primitive_type_vector [ada_primitive_type_system_address]
13822 ->set_name ("system__address");
13823
13824 /* Create the equivalent of the System.Storage_Elements.Storage_Offset
13825 type. This is a signed integral type whose size is the same as
13826 the size of addresses. */
13827 {
13828 unsigned int addr_length = TYPE_LENGTH
13829 (lai->primitive_type_vector [ada_primitive_type_system_address]);
13830
13831 lai->primitive_type_vector [ada_primitive_type_storage_offset]
13832 = arch_integer_type (gdbarch, addr_length * HOST_CHAR_BIT, 0,
13833 "storage_offset");
13834 }
13835
13836 lai->bool_type_symbol = NULL;
13837 lai->bool_type_default = builtin->builtin_bool;
13838 }
13839
13840 /* See language.h. */
13841
13842 bool iterate_over_symbols
13843 (const struct block *block, const lookup_name_info &name,
13844 domain_enum domain,
13845 gdb::function_view<symbol_found_callback_ftype> callback) const override
13846 {
13847 std::vector<struct block_symbol> results;
13848
13849 ada_lookup_symbol_list_worker (name, block, domain, &results, 0);
13850 for (block_symbol &sym : results)
13851 {
13852 if (!callback (&sym))
13853 return false;
13854 }
13855
13856 return true;
13857 }
13858
13859 /* See language.h. */
13860 bool sniff_from_mangled_name (const char *mangled,
13861 char **out) const override
13862 {
13863 std::string demangled = ada_decode (mangled);
13864
13865 *out = NULL;
13866
13867 if (demangled != mangled && demangled[0] != '<')
13868 {
13869 /* Set the gsymbol language to Ada, but still return 0.
13870 Two reasons for that:
13871
13872 1. For Ada, we prefer computing the symbol's decoded name
13873 on the fly rather than pre-compute it, in order to save
13874 memory (Ada projects are typically very large).
13875
13876 2. There are some areas in the definition of the GNAT
13877 encoding where, with a bit of bad luck, we might be able
13878 to decode a non-Ada symbol, generating an incorrect
13879 demangled name (Eg: names ending with "TB" for instance
13880 are identified as task bodies and so stripped from
13881 the decoded name returned).
13882
13883 Returning true, here, but not setting *DEMANGLED, helps us get
13884 a little bit of the best of both worlds. Because we're last,
13885 we should not affect any of the other languages that were
13886 able to demangle the symbol before us; we get to correctly
13887 tag Ada symbols as such; and even if we incorrectly tagged a
13888 non-Ada symbol, which should be rare, any routing through the
13889 Ada language should be transparent (Ada tries to behave much
13890 like C/C++ with non-Ada symbols). */
13891 return true;
13892 }
13893
13894 return false;
13895 }
13896
13897 /* See language.h. */
13898
13899 char *demangle (const char *mangled, int options) const override
13900 {
13901 return ada_la_decode (mangled, options);
13902 }
13903
13904 /* See language.h. */
13905
13906 void print_type (struct type *type, const char *varstring,
13907 struct ui_file *stream, int show, int level,
13908 const struct type_print_options *flags) const override
13909 {
13910 ada_print_type (type, varstring, stream, show, level, flags);
13911 }
13912
13913 /* See language.h. */
13914
13915 const char *word_break_characters (void) const override
13916 {
13917 return ada_completer_word_break_characters;
13918 }
13919
13920 /* See language.h. */
13921
13922 void collect_symbol_completion_matches (completion_tracker &tracker,
13923 complete_symbol_mode mode,
13924 symbol_name_match_type name_match_type,
13925 const char *text, const char *word,
13926 enum type_code code) const override
13927 {
13928 struct symbol *sym;
13929 const struct block *b, *surrounding_static_block = 0;
13930 struct block_iterator iter;
13931
13932 gdb_assert (code == TYPE_CODE_UNDEF);
13933
13934 lookup_name_info lookup_name (text, name_match_type, true);
13935
13936 /* First, look at the partial symtab symbols. */
13937 expand_symtabs_matching (NULL,
13938 lookup_name,
13939 NULL,
13940 NULL,
13941 ALL_DOMAIN);
13942
13943 /* At this point scan through the misc symbol vectors and add each
13944 symbol you find to the list. Eventually we want to ignore
13945 anything that isn't a text symbol (everything else will be
13946 handled by the psymtab code above). */
13947
13948 for (objfile *objfile : current_program_space->objfiles ())
13949 {
13950 for (minimal_symbol *msymbol : objfile->msymbols ())
13951 {
13952 QUIT;
13953
13954 if (completion_skip_symbol (mode, msymbol))
13955 continue;
13956
13957 language symbol_language = msymbol->language ();
13958
13959 /* Ada minimal symbols won't have their language set to Ada. If
13960 we let completion_list_add_name compare using the
13961 default/C-like matcher, then when completing e.g., symbols in a
13962 package named "pck", we'd match internal Ada symbols like
13963 "pckS", which are invalid in an Ada expression, unless you wrap
13964 them in '<' '>' to request a verbatim match.
13965
13966 Unfortunately, some Ada encoded names successfully demangle as
13967 C++ symbols (using an old mangling scheme), such as "name__2Xn"
13968 -> "Xn::name(void)" and thus some Ada minimal symbols end up
13969 with the wrong language set. Paper over that issue here. */
13970 if (symbol_language == language_auto
13971 || symbol_language == language_cplus)
13972 symbol_language = language_ada;
13973
13974 completion_list_add_name (tracker,
13975 symbol_language,
13976 msymbol->linkage_name (),
13977 lookup_name, text, word);
13978 }
13979 }
13980
13981 /* Search upwards from currently selected frame (so that we can
13982 complete on local vars. */
13983
13984 for (b = get_selected_block (0); b != NULL; b = BLOCK_SUPERBLOCK (b))
13985 {
13986 if (!BLOCK_SUPERBLOCK (b))
13987 surrounding_static_block = b; /* For elmin of dups */
13988
13989 ALL_BLOCK_SYMBOLS (b, iter, sym)
13990 {
13991 if (completion_skip_symbol (mode, sym))
13992 continue;
13993
13994 completion_list_add_name (tracker,
13995 sym->language (),
13996 sym->linkage_name (),
13997 lookup_name, text, word);
13998 }
13999 }
14000
14001 /* Go through the symtabs and check the externs and statics for
14002 symbols which match. */
14003
14004 for (objfile *objfile : current_program_space->objfiles ())
14005 {
14006 for (compunit_symtab *s : objfile->compunits ())
14007 {
14008 QUIT;
14009 b = BLOCKVECTOR_BLOCK (COMPUNIT_BLOCKVECTOR (s), GLOBAL_BLOCK);
14010 ALL_BLOCK_SYMBOLS (b, iter, sym)
14011 {
14012 if (completion_skip_symbol (mode, sym))
14013 continue;
14014
14015 completion_list_add_name (tracker,
14016 sym->language (),
14017 sym->linkage_name (),
14018 lookup_name, text, word);
14019 }
14020 }
14021 }
14022
14023 for (objfile *objfile : current_program_space->objfiles ())
14024 {
14025 for (compunit_symtab *s : objfile->compunits ())
14026 {
14027 QUIT;
14028 b = BLOCKVECTOR_BLOCK (COMPUNIT_BLOCKVECTOR (s), STATIC_BLOCK);
14029 /* Don't do this block twice. */
14030 if (b == surrounding_static_block)
14031 continue;
14032 ALL_BLOCK_SYMBOLS (b, iter, sym)
14033 {
14034 if (completion_skip_symbol (mode, sym))
14035 continue;
14036
14037 completion_list_add_name (tracker,
14038 sym->language (),
14039 sym->linkage_name (),
14040 lookup_name, text, word);
14041 }
14042 }
14043 }
14044 }
14045
14046 /* See language.h. */
14047
14048 gdb::unique_xmalloc_ptr<char> watch_location_expression
14049 (struct type *type, CORE_ADDR addr) const override
14050 {
14051 type = check_typedef (TYPE_TARGET_TYPE (check_typedef (type)));
14052 std::string name = type_to_string (type);
14053 return gdb::unique_xmalloc_ptr<char>
14054 (xstrprintf ("{%s} %s", name.c_str (), core_addr_to_string (addr)));
14055 }
14056
14057 /* See language.h. */
14058
14059 void value_print (struct value *val, struct ui_file *stream,
14060 const struct value_print_options *options) const override
14061 {
14062 return ada_value_print (val, stream, options);
14063 }
14064
14065 /* See language.h. */
14066
14067 void value_print_inner
14068 (struct value *val, struct ui_file *stream, int recurse,
14069 const struct value_print_options *options) const override
14070 {
14071 return ada_value_print_inner (val, stream, recurse, options);
14072 }
14073
14074 /* See language.h. */
14075
14076 struct block_symbol lookup_symbol_nonlocal
14077 (const char *name, const struct block *block,
14078 const domain_enum domain) const override
14079 {
14080 struct block_symbol sym;
14081
14082 sym = ada_lookup_symbol (name, block_static_block (block), domain);
14083 if (sym.symbol != NULL)
14084 return sym;
14085
14086 /* If we haven't found a match at this point, try the primitive
14087 types. In other languages, this search is performed before
14088 searching for global symbols in order to short-circuit that
14089 global-symbol search if it happens that the name corresponds
14090 to a primitive type. But we cannot do the same in Ada, because
14091 it is perfectly legitimate for a program to declare a type which
14092 has the same name as a standard type. If looking up a type in
14093 that situation, we have traditionally ignored the primitive type
14094 in favor of user-defined types. This is why, unlike most other
14095 languages, we search the primitive types this late and only after
14096 having searched the global symbols without success. */
14097
14098 if (domain == VAR_DOMAIN)
14099 {
14100 struct gdbarch *gdbarch;
14101
14102 if (block == NULL)
14103 gdbarch = target_gdbarch ();
14104 else
14105 gdbarch = block_gdbarch (block);
14106 sym.symbol
14107 = language_lookup_primitive_type_as_symbol (this, gdbarch, name);
14108 if (sym.symbol != NULL)
14109 return sym;
14110 }
14111
14112 return {};
14113 }
14114
14115 /* See language.h. */
14116
14117 int parser (struct parser_state *ps) const override
14118 {
14119 warnings_issued = 0;
14120 return ada_parse (ps);
14121 }
14122
14123 /* See language.h.
14124
14125 Same as evaluate_type (*EXP), but resolves ambiguous symbol references
14126 (marked by OP_VAR_VALUE nodes in which the symbol has an undefined
14127 namespace) and converts operators that are user-defined into
14128 appropriate function calls. If CONTEXT_TYPE is non-null, it provides
14129 a preferred result type [at the moment, only type void has any
14130 effect---causing procedures to be preferred over functions in calls].
14131 A null CONTEXT_TYPE indicates that a non-void return type is
14132 preferred. May change (expand) *EXP. */
14133
14134 void post_parser (expression_up *expp, int void_context_p, int completing,
14135 innermost_block_tracker *tracker) const override
14136 {
14137 struct type *context_type = NULL;
14138 int pc = 0;
14139
14140 if (void_context_p)
14141 context_type = builtin_type ((*expp)->gdbarch)->builtin_void;
14142
14143 resolve_subexp (expp, &pc, 1, context_type, completing, tracker);
14144 }
14145
14146 /* See language.h. */
14147
14148 void emitchar (int ch, struct type *chtype,
14149 struct ui_file *stream, int quoter) const override
14150 {
14151 ada_emit_char (ch, chtype, stream, quoter, 1);
14152 }
14153
14154 /* See language.h. */
14155
14156 void printchar (int ch, struct type *chtype,
14157 struct ui_file *stream) const override
14158 {
14159 ada_printchar (ch, chtype, stream);
14160 }
14161
14162 /* See language.h. */
14163
14164 void printstr (struct ui_file *stream, struct type *elttype,
14165 const gdb_byte *string, unsigned int length,
14166 const char *encoding, int force_ellipses,
14167 const struct value_print_options *options) const override
14168 {
14169 ada_printstr (stream, elttype, string, length, encoding,
14170 force_ellipses, options);
14171 }
14172
14173 /* See language.h. */
14174
14175 void print_typedef (struct type *type, struct symbol *new_symbol,
14176 struct ui_file *stream) const override
14177 {
14178 ada_print_typedef (type, new_symbol, stream);
14179 }
14180
14181 /* See language.h. */
14182
14183 bool is_string_type_p (struct type *type) const override
14184 {
14185 return ada_is_string_type (type);
14186 }
14187
14188 /* See language.h. */
14189
14190 const char *struct_too_deep_ellipsis () const override
14191 { return "(...)"; }
14192
14193 /* See language.h. */
14194
14195 bool c_style_arrays_p () const override
14196 { return false; }
14197
14198 /* See language.h. */
14199
14200 bool store_sym_names_in_linkage_form_p () const override
14201 { return true; }
14202
14203 /* See language.h. */
14204
14205 const struct lang_varobj_ops *varobj_ops () const override
14206 { return &ada_varobj_ops; }
14207
14208 /* See language.h. */
14209
14210 const struct exp_descriptor *expression_ops () const override
14211 { return &ada_exp_descriptor; }
14212
14213 protected:
14214 /* See language.h. */
14215
14216 symbol_name_matcher_ftype *get_symbol_name_matcher_inner
14217 (const lookup_name_info &lookup_name) const override
14218 {
14219 return ada_get_symbol_name_matcher (lookup_name);
14220 }
14221 };
14222
14223 /* Single instance of the Ada language class. */
14224
14225 static ada_language ada_language_defn;
14226
14227 /* Command-list for the "set/show ada" prefix command. */
14228 static struct cmd_list_element *set_ada_list;
14229 static struct cmd_list_element *show_ada_list;
14230
14231 static void
14232 initialize_ada_catchpoint_ops (void)
14233 {
14234 struct breakpoint_ops *ops;
14235
14236 initialize_breakpoint_ops ();
14237
14238 ops = &catch_exception_breakpoint_ops;
14239 *ops = bkpt_breakpoint_ops;
14240 ops->allocate_location = allocate_location_exception;
14241 ops->re_set = re_set_exception;
14242 ops->check_status = check_status_exception;
14243 ops->print_it = print_it_exception;
14244 ops->print_one = print_one_exception;
14245 ops->print_mention = print_mention_exception;
14246 ops->print_recreate = print_recreate_exception;
14247
14248 ops = &catch_exception_unhandled_breakpoint_ops;
14249 *ops = bkpt_breakpoint_ops;
14250 ops->allocate_location = allocate_location_exception;
14251 ops->re_set = re_set_exception;
14252 ops->check_status = check_status_exception;
14253 ops->print_it = print_it_exception;
14254 ops->print_one = print_one_exception;
14255 ops->print_mention = print_mention_exception;
14256 ops->print_recreate = print_recreate_exception;
14257
14258 ops = &catch_assert_breakpoint_ops;
14259 *ops = bkpt_breakpoint_ops;
14260 ops->allocate_location = allocate_location_exception;
14261 ops->re_set = re_set_exception;
14262 ops->check_status = check_status_exception;
14263 ops->print_it = print_it_exception;
14264 ops->print_one = print_one_exception;
14265 ops->print_mention = print_mention_exception;
14266 ops->print_recreate = print_recreate_exception;
14267
14268 ops = &catch_handlers_breakpoint_ops;
14269 *ops = bkpt_breakpoint_ops;
14270 ops->allocate_location = allocate_location_exception;
14271 ops->re_set = re_set_exception;
14272 ops->check_status = check_status_exception;
14273 ops->print_it = print_it_exception;
14274 ops->print_one = print_one_exception;
14275 ops->print_mention = print_mention_exception;
14276 ops->print_recreate = print_recreate_exception;
14277 }
14278
14279 /* This module's 'new_objfile' observer. */
14280
14281 static void
14282 ada_new_objfile_observer (struct objfile *objfile)
14283 {
14284 ada_clear_symbol_cache ();
14285 }
14286
14287 /* This module's 'free_objfile' observer. */
14288
14289 static void
14290 ada_free_objfile_observer (struct objfile *objfile)
14291 {
14292 ada_clear_symbol_cache ();
14293 }
14294
14295 void _initialize_ada_language ();
14296 void
14297 _initialize_ada_language ()
14298 {
14299 initialize_ada_catchpoint_ops ();
14300
14301 add_basic_prefix_cmd ("ada", no_class,
14302 _("Prefix command for changing Ada-specific settings."),
14303 &set_ada_list, "set ada ", 0, &setlist);
14304
14305 add_show_prefix_cmd ("ada", no_class,
14306 _("Generic command for showing Ada-specific settings."),
14307 &show_ada_list, "show ada ", 0, &showlist);
14308
14309 add_setshow_boolean_cmd ("trust-PAD-over-XVS", class_obscure,
14310 &trust_pad_over_xvs, _("\
14311 Enable or disable an optimization trusting PAD types over XVS types."), _("\
14312 Show whether an optimization trusting PAD types over XVS types is activated."),
14313 _("\
14314 This is related to the encoding used by the GNAT compiler. The debugger\n\
14315 should normally trust the contents of PAD types, but certain older versions\n\
14316 of GNAT have a bug that sometimes causes the information in the PAD type\n\
14317 to be incorrect. Turning this setting \"off\" allows the debugger to\n\
14318 work around this bug. It is always safe to turn this option \"off\", but\n\
14319 this incurs a slight performance penalty, so it is recommended to NOT change\n\
14320 this option to \"off\" unless necessary."),
14321 NULL, NULL, &set_ada_list, &show_ada_list);
14322
14323 add_setshow_boolean_cmd ("print-signatures", class_vars,
14324 &print_signatures, _("\
14325 Enable or disable the output of formal and return types for functions in the \
14326 overloads selection menu."), _("\
14327 Show whether the output of formal and return types for functions in the \
14328 overloads selection menu is activated."),
14329 NULL, NULL, NULL, &set_ada_list, &show_ada_list);
14330
14331 add_catch_command ("exception", _("\
14332 Catch Ada exceptions, when raised.\n\
14333 Usage: catch exception [ARG] [if CONDITION]\n\
14334 Without any argument, stop when any Ada exception is raised.\n\
14335 If ARG is \"unhandled\" (without the quotes), only stop when the exception\n\
14336 being raised does not have a handler (and will therefore lead to the task's\n\
14337 termination).\n\
14338 Otherwise, the catchpoint only stops when the name of the exception being\n\
14339 raised is the same as ARG.\n\
14340 CONDITION is a boolean expression that is evaluated to see whether the\n\
14341 exception should cause a stop."),
14342 catch_ada_exception_command,
14343 catch_ada_completer,
14344 CATCH_PERMANENT,
14345 CATCH_TEMPORARY);
14346
14347 add_catch_command ("handlers", _("\
14348 Catch Ada exceptions, when handled.\n\
14349 Usage: catch handlers [ARG] [if CONDITION]\n\
14350 Without any argument, stop when any Ada exception is handled.\n\
14351 With an argument, catch only exceptions with the given name.\n\
14352 CONDITION is a boolean expression that is evaluated to see whether the\n\
14353 exception should cause a stop."),
14354 catch_ada_handlers_command,
14355 catch_ada_completer,
14356 CATCH_PERMANENT,
14357 CATCH_TEMPORARY);
14358 add_catch_command ("assert", _("\
14359 Catch failed Ada assertions, when raised.\n\
14360 Usage: catch assert [if CONDITION]\n\
14361 CONDITION is a boolean expression that is evaluated to see whether the\n\
14362 exception should cause a stop."),
14363 catch_assert_command,
14364 NULL,
14365 CATCH_PERMANENT,
14366 CATCH_TEMPORARY);
14367
14368 varsize_limit = 65536;
14369 add_setshow_uinteger_cmd ("varsize-limit", class_support,
14370 &varsize_limit, _("\
14371 Set the maximum number of bytes allowed in a variable-size object."), _("\
14372 Show the maximum number of bytes allowed in a variable-size object."), _("\
14373 Attempts to access an object whose size is not a compile-time constant\n\
14374 and exceeds this limit will cause an error."),
14375 NULL, NULL, &setlist, &showlist);
14376
14377 add_info ("exceptions", info_exceptions_command,
14378 _("\
14379 List all Ada exception names.\n\
14380 Usage: info exceptions [REGEXP]\n\
14381 If a regular expression is passed as an argument, only those matching\n\
14382 the regular expression are listed."));
14383
14384 add_basic_prefix_cmd ("ada", class_maintenance,
14385 _("Set Ada maintenance-related variables."),
14386 &maint_set_ada_cmdlist, "maintenance set ada ",
14387 0/*allow-unknown*/, &maintenance_set_cmdlist);
14388
14389 add_show_prefix_cmd ("ada", class_maintenance,
14390 _("Show Ada maintenance-related variables."),
14391 &maint_show_ada_cmdlist, "maintenance show ada ",
14392 0/*allow-unknown*/, &maintenance_show_cmdlist);
14393
14394 add_setshow_boolean_cmd
14395 ("ignore-descriptive-types", class_maintenance,
14396 &ada_ignore_descriptive_types_p,
14397 _("Set whether descriptive types generated by GNAT should be ignored."),
14398 _("Show whether descriptive types generated by GNAT should be ignored."),
14399 _("\
14400 When enabled, the debugger will stop using the DW_AT_GNAT_descriptive_type\n\
14401 DWARF attribute."),
14402 NULL, NULL, &maint_set_ada_cmdlist, &maint_show_ada_cmdlist);
14403
14404 decoded_names_store = htab_create_alloc (256, htab_hash_string, streq_hash,
14405 NULL, xcalloc, xfree);
14406
14407 /* The ada-lang observers. */
14408 gdb::observers::new_objfile.attach (ada_new_objfile_observer);
14409 gdb::observers::free_objfile.attach (ada_free_objfile_observer);
14410 gdb::observers::inferior_exit.attach (ada_inferior_exit);
14411 }
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