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c906108c | 1 | /* Low level packing and unpacking of values for GDB, the GNU Debugger. |
1bac305b | 2 | |
618f726f | 3 | Copyright (C) 1986-2016 Free Software Foundation, Inc. |
c906108c | 4 | |
c5aa993b | 5 | This file is part of GDB. |
c906108c | 6 | |
c5aa993b JM |
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 | |
a9762ec7 | 9 | the Free Software Foundation; either version 3 of the License, or |
c5aa993b | 10 | (at your option) any later version. |
c906108c | 11 | |
c5aa993b JM |
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. | |
c906108c | 16 | |
c5aa993b | 17 | You should have received a copy of the GNU General Public License |
a9762ec7 | 18 | along with this program. If not, see <http://www.gnu.org/licenses/>. */ |
c906108c SS |
19 | |
20 | #include "defs.h" | |
e17c207e | 21 | #include "arch-utils.h" |
c906108c SS |
22 | #include "symtab.h" |
23 | #include "gdbtypes.h" | |
24 | #include "value.h" | |
25 | #include "gdbcore.h" | |
c906108c SS |
26 | #include "command.h" |
27 | #include "gdbcmd.h" | |
28 | #include "target.h" | |
29 | #include "language.h" | |
c906108c | 30 | #include "demangle.h" |
d16aafd8 | 31 | #include "doublest.h" |
36160dc4 | 32 | #include "regcache.h" |
fe898f56 | 33 | #include "block.h" |
27bc4d80 | 34 | #include "dfp.h" |
bccdca4a | 35 | #include "objfiles.h" |
79a45b7d | 36 | #include "valprint.h" |
bc3b79fd | 37 | #include "cli/cli-decode.h" |
6dddc817 | 38 | #include "extension.h" |
3bd0f5ef | 39 | #include <ctype.h> |
0914bcdb | 40 | #include "tracepoint.h" |
be335936 | 41 | #include "cp-abi.h" |
a58e2656 | 42 | #include "user-regs.h" |
0914bcdb | 43 | |
581e13c1 | 44 | /* Prototypes for exported functions. */ |
c906108c | 45 | |
a14ed312 | 46 | void _initialize_values (void); |
c906108c | 47 | |
bc3b79fd TJB |
48 | /* Definition of a user function. */ |
49 | struct internal_function | |
50 | { | |
51 | /* The name of the function. It is a bit odd to have this in the | |
52 | function itself -- the user might use a differently-named | |
53 | convenience variable to hold the function. */ | |
54 | char *name; | |
55 | ||
56 | /* The handler. */ | |
57 | internal_function_fn handler; | |
58 | ||
59 | /* User data for the handler. */ | |
60 | void *cookie; | |
61 | }; | |
62 | ||
4e07d55f PA |
63 | /* Defines an [OFFSET, OFFSET + LENGTH) range. */ |
64 | ||
65 | struct range | |
66 | { | |
67 | /* Lowest offset in the range. */ | |
6b850546 | 68 | LONGEST offset; |
4e07d55f PA |
69 | |
70 | /* Length of the range. */ | |
6b850546 | 71 | LONGEST length; |
4e07d55f PA |
72 | }; |
73 | ||
74 | typedef struct range range_s; | |
75 | ||
76 | DEF_VEC_O(range_s); | |
77 | ||
78 | /* Returns true if the ranges defined by [offset1, offset1+len1) and | |
79 | [offset2, offset2+len2) overlap. */ | |
80 | ||
81 | static int | |
6b850546 DT |
82 | ranges_overlap (LONGEST offset1, LONGEST len1, |
83 | LONGEST offset2, LONGEST len2) | |
4e07d55f PA |
84 | { |
85 | ULONGEST h, l; | |
86 | ||
87 | l = max (offset1, offset2); | |
88 | h = min (offset1 + len1, offset2 + len2); | |
89 | return (l < h); | |
90 | } | |
91 | ||
92 | /* Returns true if the first argument is strictly less than the | |
93 | second, useful for VEC_lower_bound. We keep ranges sorted by | |
94 | offset and coalesce overlapping and contiguous ranges, so this just | |
95 | compares the starting offset. */ | |
96 | ||
97 | static int | |
98 | range_lessthan (const range_s *r1, const range_s *r2) | |
99 | { | |
100 | return r1->offset < r2->offset; | |
101 | } | |
102 | ||
103 | /* Returns true if RANGES contains any range that overlaps [OFFSET, | |
104 | OFFSET+LENGTH). */ | |
105 | ||
106 | static int | |
6b850546 | 107 | ranges_contain (VEC(range_s) *ranges, LONGEST offset, LONGEST length) |
4e07d55f PA |
108 | { |
109 | range_s what; | |
6b850546 | 110 | LONGEST i; |
4e07d55f PA |
111 | |
112 | what.offset = offset; | |
113 | what.length = length; | |
114 | ||
115 | /* We keep ranges sorted by offset and coalesce overlapping and | |
116 | contiguous ranges, so to check if a range list contains a given | |
117 | range, we can do a binary search for the position the given range | |
118 | would be inserted if we only considered the starting OFFSET of | |
119 | ranges. We call that position I. Since we also have LENGTH to | |
120 | care for (this is a range afterall), we need to check if the | |
121 | _previous_ range overlaps the I range. E.g., | |
122 | ||
123 | R | |
124 | |---| | |
125 | |---| |---| |------| ... |--| | |
126 | 0 1 2 N | |
127 | ||
128 | I=1 | |
129 | ||
130 | In the case above, the binary search would return `I=1', meaning, | |
131 | this OFFSET should be inserted at position 1, and the current | |
132 | position 1 should be pushed further (and before 2). But, `0' | |
133 | overlaps with R. | |
134 | ||
135 | Then we need to check if the I range overlaps the I range itself. | |
136 | E.g., | |
137 | ||
138 | R | |
139 | |---| | |
140 | |---| |---| |-------| ... |--| | |
141 | 0 1 2 N | |
142 | ||
143 | I=1 | |
144 | */ | |
145 | ||
146 | i = VEC_lower_bound (range_s, ranges, &what, range_lessthan); | |
147 | ||
148 | if (i > 0) | |
149 | { | |
150 | struct range *bef = VEC_index (range_s, ranges, i - 1); | |
151 | ||
152 | if (ranges_overlap (bef->offset, bef->length, offset, length)) | |
153 | return 1; | |
154 | } | |
155 | ||
156 | if (i < VEC_length (range_s, ranges)) | |
157 | { | |
158 | struct range *r = VEC_index (range_s, ranges, i); | |
159 | ||
160 | if (ranges_overlap (r->offset, r->length, offset, length)) | |
161 | return 1; | |
162 | } | |
163 | ||
164 | return 0; | |
165 | } | |
166 | ||
bc3b79fd TJB |
167 | static struct cmd_list_element *functionlist; |
168 | ||
87784a47 TT |
169 | /* Note that the fields in this structure are arranged to save a bit |
170 | of memory. */ | |
171 | ||
91294c83 AC |
172 | struct value |
173 | { | |
174 | /* Type of value; either not an lval, or one of the various | |
175 | different possible kinds of lval. */ | |
176 | enum lval_type lval; | |
177 | ||
178 | /* Is it modifiable? Only relevant if lval != not_lval. */ | |
87784a47 TT |
179 | unsigned int modifiable : 1; |
180 | ||
181 | /* If zero, contents of this value are in the contents field. If | |
182 | nonzero, contents are in inferior. If the lval field is lval_memory, | |
183 | the contents are in inferior memory at location.address plus offset. | |
184 | The lval field may also be lval_register. | |
185 | ||
186 | WARNING: This field is used by the code which handles watchpoints | |
187 | (see breakpoint.c) to decide whether a particular value can be | |
188 | watched by hardware watchpoints. If the lazy flag is set for | |
189 | some member of a value chain, it is assumed that this member of | |
190 | the chain doesn't need to be watched as part of watching the | |
191 | value itself. This is how GDB avoids watching the entire struct | |
192 | or array when the user wants to watch a single struct member or | |
193 | array element. If you ever change the way lazy flag is set and | |
194 | reset, be sure to consider this use as well! */ | |
195 | unsigned int lazy : 1; | |
196 | ||
87784a47 TT |
197 | /* If value is a variable, is it initialized or not. */ |
198 | unsigned int initialized : 1; | |
199 | ||
200 | /* If value is from the stack. If this is set, read_stack will be | |
201 | used instead of read_memory to enable extra caching. */ | |
202 | unsigned int stack : 1; | |
91294c83 | 203 | |
e848a8a5 TT |
204 | /* If the value has been released. */ |
205 | unsigned int released : 1; | |
206 | ||
98b1cfdc TT |
207 | /* Register number if the value is from a register. */ |
208 | short regnum; | |
209 | ||
91294c83 AC |
210 | /* Location of value (if lval). */ |
211 | union | |
212 | { | |
213 | /* If lval == lval_memory, this is the address in the inferior. | |
214 | If lval == lval_register, this is the byte offset into the | |
215 | registers structure. */ | |
216 | CORE_ADDR address; | |
217 | ||
218 | /* Pointer to internal variable. */ | |
219 | struct internalvar *internalvar; | |
5f5233d4 | 220 | |
e81e7f5e SC |
221 | /* Pointer to xmethod worker. */ |
222 | struct xmethod_worker *xm_worker; | |
223 | ||
5f5233d4 PA |
224 | /* If lval == lval_computed, this is a set of function pointers |
225 | to use to access and describe the value, and a closure pointer | |
226 | for them to use. */ | |
227 | struct | |
228 | { | |
c8f2448a JK |
229 | /* Functions to call. */ |
230 | const struct lval_funcs *funcs; | |
231 | ||
232 | /* Closure for those functions to use. */ | |
233 | void *closure; | |
5f5233d4 | 234 | } computed; |
91294c83 AC |
235 | } location; |
236 | ||
3723fda8 SM |
237 | /* Describes offset of a value within lval of a structure in target |
238 | addressable memory units. If lval == lval_memory, this is an offset to | |
239 | the address. If lval == lval_register, this is a further offset from | |
240 | location.address within the registers structure. Note also the member | |
241 | embedded_offset below. */ | |
6b850546 | 242 | LONGEST offset; |
91294c83 AC |
243 | |
244 | /* Only used for bitfields; number of bits contained in them. */ | |
6b850546 | 245 | LONGEST bitsize; |
91294c83 AC |
246 | |
247 | /* Only used for bitfields; position of start of field. For | |
32c9a795 | 248 | gdbarch_bits_big_endian=0 targets, it is the position of the LSB. For |
581e13c1 | 249 | gdbarch_bits_big_endian=1 targets, it is the position of the MSB. */ |
6b850546 | 250 | LONGEST bitpos; |
91294c83 | 251 | |
87784a47 TT |
252 | /* The number of references to this value. When a value is created, |
253 | the value chain holds a reference, so REFERENCE_COUNT is 1. If | |
254 | release_value is called, this value is removed from the chain but | |
255 | the caller of release_value now has a reference to this value. | |
256 | The caller must arrange for a call to value_free later. */ | |
257 | int reference_count; | |
258 | ||
4ea48cc1 DJ |
259 | /* Only used for bitfields; the containing value. This allows a |
260 | single read from the target when displaying multiple | |
261 | bitfields. */ | |
262 | struct value *parent; | |
263 | ||
91294c83 AC |
264 | /* Frame register value is relative to. This will be described in |
265 | the lval enum above as "lval_register". */ | |
266 | struct frame_id frame_id; | |
267 | ||
268 | /* Type of the value. */ | |
269 | struct type *type; | |
270 | ||
271 | /* If a value represents a C++ object, then the `type' field gives | |
272 | the object's compile-time type. If the object actually belongs | |
273 | to some class derived from `type', perhaps with other base | |
274 | classes and additional members, then `type' is just a subobject | |
275 | of the real thing, and the full object is probably larger than | |
276 | `type' would suggest. | |
277 | ||
278 | If `type' is a dynamic class (i.e. one with a vtable), then GDB | |
279 | can actually determine the object's run-time type by looking at | |
280 | the run-time type information in the vtable. When this | |
281 | information is available, we may elect to read in the entire | |
282 | object, for several reasons: | |
283 | ||
284 | - When printing the value, the user would probably rather see the | |
285 | full object, not just the limited portion apparent from the | |
286 | compile-time type. | |
287 | ||
288 | - If `type' has virtual base classes, then even printing `type' | |
289 | alone may require reaching outside the `type' portion of the | |
290 | object to wherever the virtual base class has been stored. | |
291 | ||
292 | When we store the entire object, `enclosing_type' is the run-time | |
293 | type -- the complete object -- and `embedded_offset' is the | |
3723fda8 SM |
294 | offset of `type' within that larger type, in target addressable memory |
295 | units. The value_contents() macro takes `embedded_offset' into account, | |
296 | so most GDB code continues to see the `type' portion of the value, just | |
297 | as the inferior would. | |
91294c83 AC |
298 | |
299 | If `type' is a pointer to an object, then `enclosing_type' is a | |
300 | pointer to the object's run-time type, and `pointed_to_offset' is | |
3723fda8 SM |
301 | the offset in target addressable memory units from the full object |
302 | to the pointed-to object -- that is, the value `embedded_offset' would | |
303 | have if we followed the pointer and fetched the complete object. | |
304 | (I don't really see the point. Why not just determine the | |
305 | run-time type when you indirect, and avoid the special case? The | |
306 | contents don't matter until you indirect anyway.) | |
91294c83 AC |
307 | |
308 | If we're not doing anything fancy, `enclosing_type' is equal to | |
309 | `type', and `embedded_offset' is zero, so everything works | |
310 | normally. */ | |
311 | struct type *enclosing_type; | |
6b850546 DT |
312 | LONGEST embedded_offset; |
313 | LONGEST pointed_to_offset; | |
91294c83 AC |
314 | |
315 | /* Values are stored in a chain, so that they can be deleted easily | |
316 | over calls to the inferior. Values assigned to internal | |
a08702d6 TJB |
317 | variables, put into the value history or exposed to Python are |
318 | taken off this list. */ | |
91294c83 AC |
319 | struct value *next; |
320 | ||
3e3d7139 JG |
321 | /* Actual contents of the value. Target byte-order. NULL or not |
322 | valid if lazy is nonzero. */ | |
323 | gdb_byte *contents; | |
828d3400 | 324 | |
4e07d55f PA |
325 | /* Unavailable ranges in CONTENTS. We mark unavailable ranges, |
326 | rather than available, since the common and default case is for a | |
9a0dc9e3 PA |
327 | value to be available. This is filled in at value read time. |
328 | The unavailable ranges are tracked in bits. Note that a contents | |
329 | bit that has been optimized out doesn't really exist in the | |
330 | program, so it can't be marked unavailable either. */ | |
4e07d55f | 331 | VEC(range_s) *unavailable; |
9a0dc9e3 PA |
332 | |
333 | /* Likewise, but for optimized out contents (a chunk of the value of | |
334 | a variable that does not actually exist in the program). If LVAL | |
335 | is lval_register, this is a register ($pc, $sp, etc., never a | |
336 | program variable) that has not been saved in the frame. Not | |
337 | saved registers and optimized-out program variables values are | |
338 | treated pretty much the same, except not-saved registers have a | |
339 | different string representation and related error strings. */ | |
340 | VEC(range_s) *optimized_out; | |
91294c83 AC |
341 | }; |
342 | ||
e512cdbd SM |
343 | /* See value.h. */ |
344 | ||
345 | struct gdbarch * | |
346 | get_value_arch (const struct value *value) | |
347 | { | |
348 | return get_type_arch (value_type (value)); | |
349 | } | |
350 | ||
4e07d55f | 351 | int |
6b850546 | 352 | value_bits_available (const struct value *value, LONGEST offset, LONGEST length) |
4e07d55f PA |
353 | { |
354 | gdb_assert (!value->lazy); | |
355 | ||
356 | return !ranges_contain (value->unavailable, offset, length); | |
357 | } | |
358 | ||
bdf22206 | 359 | int |
6b850546 DT |
360 | value_bytes_available (const struct value *value, |
361 | LONGEST offset, LONGEST length) | |
bdf22206 AB |
362 | { |
363 | return value_bits_available (value, | |
364 | offset * TARGET_CHAR_BIT, | |
365 | length * TARGET_CHAR_BIT); | |
366 | } | |
367 | ||
9a0dc9e3 PA |
368 | int |
369 | value_bits_any_optimized_out (const struct value *value, int bit_offset, int bit_length) | |
370 | { | |
371 | gdb_assert (!value->lazy); | |
372 | ||
373 | return ranges_contain (value->optimized_out, bit_offset, bit_length); | |
374 | } | |
375 | ||
ec0a52e1 PA |
376 | int |
377 | value_entirely_available (struct value *value) | |
378 | { | |
379 | /* We can only tell whether the whole value is available when we try | |
380 | to read it. */ | |
381 | if (value->lazy) | |
382 | value_fetch_lazy (value); | |
383 | ||
384 | if (VEC_empty (range_s, value->unavailable)) | |
385 | return 1; | |
386 | return 0; | |
387 | } | |
388 | ||
9a0dc9e3 PA |
389 | /* Returns true if VALUE is entirely covered by RANGES. If the value |
390 | is lazy, it'll be read now. Note that RANGE is a pointer to | |
391 | pointer because reading the value might change *RANGE. */ | |
392 | ||
393 | static int | |
394 | value_entirely_covered_by_range_vector (struct value *value, | |
395 | VEC(range_s) **ranges) | |
6211c335 | 396 | { |
9a0dc9e3 PA |
397 | /* We can only tell whether the whole value is optimized out / |
398 | unavailable when we try to read it. */ | |
6211c335 YQ |
399 | if (value->lazy) |
400 | value_fetch_lazy (value); | |
401 | ||
9a0dc9e3 | 402 | if (VEC_length (range_s, *ranges) == 1) |
6211c335 | 403 | { |
9a0dc9e3 | 404 | struct range *t = VEC_index (range_s, *ranges, 0); |
6211c335 YQ |
405 | |
406 | if (t->offset == 0 | |
64c46ce4 JB |
407 | && t->length == (TARGET_CHAR_BIT |
408 | * TYPE_LENGTH (value_enclosing_type (value)))) | |
6211c335 YQ |
409 | return 1; |
410 | } | |
411 | ||
412 | return 0; | |
413 | } | |
414 | ||
9a0dc9e3 PA |
415 | int |
416 | value_entirely_unavailable (struct value *value) | |
417 | { | |
418 | return value_entirely_covered_by_range_vector (value, &value->unavailable); | |
419 | } | |
420 | ||
421 | int | |
422 | value_entirely_optimized_out (struct value *value) | |
423 | { | |
424 | return value_entirely_covered_by_range_vector (value, &value->optimized_out); | |
425 | } | |
426 | ||
427 | /* Insert into the vector pointed to by VECTORP the bit range starting of | |
428 | OFFSET bits, and extending for the next LENGTH bits. */ | |
429 | ||
430 | static void | |
6b850546 DT |
431 | insert_into_bit_range_vector (VEC(range_s) **vectorp, |
432 | LONGEST offset, LONGEST length) | |
4e07d55f PA |
433 | { |
434 | range_s newr; | |
435 | int i; | |
436 | ||
437 | /* Insert the range sorted. If there's overlap or the new range | |
438 | would be contiguous with an existing range, merge. */ | |
439 | ||
440 | newr.offset = offset; | |
441 | newr.length = length; | |
442 | ||
443 | /* Do a binary search for the position the given range would be | |
444 | inserted if we only considered the starting OFFSET of ranges. | |
445 | Call that position I. Since we also have LENGTH to care for | |
446 | (this is a range afterall), we need to check if the _previous_ | |
447 | range overlaps the I range. E.g., calling R the new range: | |
448 | ||
449 | #1 - overlaps with previous | |
450 | ||
451 | R | |
452 | |-...-| | |
453 | |---| |---| |------| ... |--| | |
454 | 0 1 2 N | |
455 | ||
456 | I=1 | |
457 | ||
458 | In the case #1 above, the binary search would return `I=1', | |
459 | meaning, this OFFSET should be inserted at position 1, and the | |
460 | current position 1 should be pushed further (and become 2). But, | |
461 | note that `0' overlaps with R, so we want to merge them. | |
462 | ||
463 | A similar consideration needs to be taken if the new range would | |
464 | be contiguous with the previous range: | |
465 | ||
466 | #2 - contiguous with previous | |
467 | ||
468 | R | |
469 | |-...-| | |
470 | |--| |---| |------| ... |--| | |
471 | 0 1 2 N | |
472 | ||
473 | I=1 | |
474 | ||
475 | If there's no overlap with the previous range, as in: | |
476 | ||
477 | #3 - not overlapping and not contiguous | |
478 | ||
479 | R | |
480 | |-...-| | |
481 | |--| |---| |------| ... |--| | |
482 | 0 1 2 N | |
483 | ||
484 | I=1 | |
485 | ||
486 | or if I is 0: | |
487 | ||
488 | #4 - R is the range with lowest offset | |
489 | ||
490 | R | |
491 | |-...-| | |
492 | |--| |---| |------| ... |--| | |
493 | 0 1 2 N | |
494 | ||
495 | I=0 | |
496 | ||
497 | ... we just push the new range to I. | |
498 | ||
499 | All the 4 cases above need to consider that the new range may | |
500 | also overlap several of the ranges that follow, or that R may be | |
501 | contiguous with the following range, and merge. E.g., | |
502 | ||
503 | #5 - overlapping following ranges | |
504 | ||
505 | R | |
506 | |------------------------| | |
507 | |--| |---| |------| ... |--| | |
508 | 0 1 2 N | |
509 | ||
510 | I=0 | |
511 | ||
512 | or: | |
513 | ||
514 | R | |
515 | |-------| | |
516 | |--| |---| |------| ... |--| | |
517 | 0 1 2 N | |
518 | ||
519 | I=1 | |
520 | ||
521 | */ | |
522 | ||
9a0dc9e3 | 523 | i = VEC_lower_bound (range_s, *vectorp, &newr, range_lessthan); |
4e07d55f PA |
524 | if (i > 0) |
525 | { | |
9a0dc9e3 | 526 | struct range *bef = VEC_index (range_s, *vectorp, i - 1); |
4e07d55f PA |
527 | |
528 | if (ranges_overlap (bef->offset, bef->length, offset, length)) | |
529 | { | |
530 | /* #1 */ | |
531 | ULONGEST l = min (bef->offset, offset); | |
532 | ULONGEST h = max (bef->offset + bef->length, offset + length); | |
533 | ||
534 | bef->offset = l; | |
535 | bef->length = h - l; | |
536 | i--; | |
537 | } | |
538 | else if (offset == bef->offset + bef->length) | |
539 | { | |
540 | /* #2 */ | |
541 | bef->length += length; | |
542 | i--; | |
543 | } | |
544 | else | |
545 | { | |
546 | /* #3 */ | |
9a0dc9e3 | 547 | VEC_safe_insert (range_s, *vectorp, i, &newr); |
4e07d55f PA |
548 | } |
549 | } | |
550 | else | |
551 | { | |
552 | /* #4 */ | |
9a0dc9e3 | 553 | VEC_safe_insert (range_s, *vectorp, i, &newr); |
4e07d55f PA |
554 | } |
555 | ||
556 | /* Check whether the ranges following the one we've just added or | |
557 | touched can be folded in (#5 above). */ | |
9a0dc9e3 | 558 | if (i + 1 < VEC_length (range_s, *vectorp)) |
4e07d55f PA |
559 | { |
560 | struct range *t; | |
561 | struct range *r; | |
562 | int removed = 0; | |
563 | int next = i + 1; | |
564 | ||
565 | /* Get the range we just touched. */ | |
9a0dc9e3 | 566 | t = VEC_index (range_s, *vectorp, i); |
4e07d55f PA |
567 | removed = 0; |
568 | ||
569 | i = next; | |
9a0dc9e3 | 570 | for (; VEC_iterate (range_s, *vectorp, i, r); i++) |
4e07d55f PA |
571 | if (r->offset <= t->offset + t->length) |
572 | { | |
573 | ULONGEST l, h; | |
574 | ||
575 | l = min (t->offset, r->offset); | |
576 | h = max (t->offset + t->length, r->offset + r->length); | |
577 | ||
578 | t->offset = l; | |
579 | t->length = h - l; | |
580 | ||
581 | removed++; | |
582 | } | |
583 | else | |
584 | { | |
585 | /* If we couldn't merge this one, we won't be able to | |
586 | merge following ones either, since the ranges are | |
587 | always sorted by OFFSET. */ | |
588 | break; | |
589 | } | |
590 | ||
591 | if (removed != 0) | |
9a0dc9e3 | 592 | VEC_block_remove (range_s, *vectorp, next, removed); |
4e07d55f PA |
593 | } |
594 | } | |
595 | ||
9a0dc9e3 | 596 | void |
6b850546 DT |
597 | mark_value_bits_unavailable (struct value *value, |
598 | LONGEST offset, LONGEST length) | |
9a0dc9e3 PA |
599 | { |
600 | insert_into_bit_range_vector (&value->unavailable, offset, length); | |
601 | } | |
602 | ||
bdf22206 | 603 | void |
6b850546 DT |
604 | mark_value_bytes_unavailable (struct value *value, |
605 | LONGEST offset, LONGEST length) | |
bdf22206 AB |
606 | { |
607 | mark_value_bits_unavailable (value, | |
608 | offset * TARGET_CHAR_BIT, | |
609 | length * TARGET_CHAR_BIT); | |
610 | } | |
611 | ||
c8c1c22f PA |
612 | /* Find the first range in RANGES that overlaps the range defined by |
613 | OFFSET and LENGTH, starting at element POS in the RANGES vector, | |
614 | Returns the index into RANGES where such overlapping range was | |
615 | found, or -1 if none was found. */ | |
616 | ||
617 | static int | |
618 | find_first_range_overlap (VEC(range_s) *ranges, int pos, | |
6b850546 | 619 | LONGEST offset, LONGEST length) |
c8c1c22f PA |
620 | { |
621 | range_s *r; | |
622 | int i; | |
623 | ||
624 | for (i = pos; VEC_iterate (range_s, ranges, i, r); i++) | |
625 | if (ranges_overlap (r->offset, r->length, offset, length)) | |
626 | return i; | |
627 | ||
628 | return -1; | |
629 | } | |
630 | ||
bdf22206 AB |
631 | /* Compare LENGTH_BITS of memory at PTR1 + OFFSET1_BITS with the memory at |
632 | PTR2 + OFFSET2_BITS. Return 0 if the memory is the same, otherwise | |
633 | return non-zero. | |
634 | ||
635 | It must always be the case that: | |
636 | OFFSET1_BITS % TARGET_CHAR_BIT == OFFSET2_BITS % TARGET_CHAR_BIT | |
637 | ||
638 | It is assumed that memory can be accessed from: | |
639 | PTR + (OFFSET_BITS / TARGET_CHAR_BIT) | |
640 | to: | |
641 | PTR + ((OFFSET_BITS + LENGTH_BITS + TARGET_CHAR_BIT - 1) | |
642 | / TARGET_CHAR_BIT) */ | |
643 | static int | |
644 | memcmp_with_bit_offsets (const gdb_byte *ptr1, size_t offset1_bits, | |
645 | const gdb_byte *ptr2, size_t offset2_bits, | |
646 | size_t length_bits) | |
647 | { | |
648 | gdb_assert (offset1_bits % TARGET_CHAR_BIT | |
649 | == offset2_bits % TARGET_CHAR_BIT); | |
650 | ||
651 | if (offset1_bits % TARGET_CHAR_BIT != 0) | |
652 | { | |
653 | size_t bits; | |
654 | gdb_byte mask, b1, b2; | |
655 | ||
656 | /* The offset from the base pointers PTR1 and PTR2 is not a complete | |
657 | number of bytes. A number of bits up to either the next exact | |
658 | byte boundary, or LENGTH_BITS (which ever is sooner) will be | |
659 | compared. */ | |
660 | bits = TARGET_CHAR_BIT - offset1_bits % TARGET_CHAR_BIT; | |
661 | gdb_assert (bits < sizeof (mask) * TARGET_CHAR_BIT); | |
662 | mask = (1 << bits) - 1; | |
663 | ||
664 | if (length_bits < bits) | |
665 | { | |
666 | mask &= ~(gdb_byte) ((1 << (bits - length_bits)) - 1); | |
667 | bits = length_bits; | |
668 | } | |
669 | ||
670 | /* Now load the two bytes and mask off the bits we care about. */ | |
671 | b1 = *(ptr1 + offset1_bits / TARGET_CHAR_BIT) & mask; | |
672 | b2 = *(ptr2 + offset2_bits / TARGET_CHAR_BIT) & mask; | |
673 | ||
674 | if (b1 != b2) | |
675 | return 1; | |
676 | ||
677 | /* Now update the length and offsets to take account of the bits | |
678 | we've just compared. */ | |
679 | length_bits -= bits; | |
680 | offset1_bits += bits; | |
681 | offset2_bits += bits; | |
682 | } | |
683 | ||
684 | if (length_bits % TARGET_CHAR_BIT != 0) | |
685 | { | |
686 | size_t bits; | |
687 | size_t o1, o2; | |
688 | gdb_byte mask, b1, b2; | |
689 | ||
690 | /* The length is not an exact number of bytes. After the previous | |
691 | IF.. block then the offsets are byte aligned, or the | |
692 | length is zero (in which case this code is not reached). Compare | |
693 | a number of bits at the end of the region, starting from an exact | |
694 | byte boundary. */ | |
695 | bits = length_bits % TARGET_CHAR_BIT; | |
696 | o1 = offset1_bits + length_bits - bits; | |
697 | o2 = offset2_bits + length_bits - bits; | |
698 | ||
699 | gdb_assert (bits < sizeof (mask) * TARGET_CHAR_BIT); | |
700 | mask = ((1 << bits) - 1) << (TARGET_CHAR_BIT - bits); | |
701 | ||
702 | gdb_assert (o1 % TARGET_CHAR_BIT == 0); | |
703 | gdb_assert (o2 % TARGET_CHAR_BIT == 0); | |
704 | ||
705 | b1 = *(ptr1 + o1 / TARGET_CHAR_BIT) & mask; | |
706 | b2 = *(ptr2 + o2 / TARGET_CHAR_BIT) & mask; | |
707 | ||
708 | if (b1 != b2) | |
709 | return 1; | |
710 | ||
711 | length_bits -= bits; | |
712 | } | |
713 | ||
714 | if (length_bits > 0) | |
715 | { | |
716 | /* We've now taken care of any stray "bits" at the start, or end of | |
717 | the region to compare, the remainder can be covered with a simple | |
718 | memcmp. */ | |
719 | gdb_assert (offset1_bits % TARGET_CHAR_BIT == 0); | |
720 | gdb_assert (offset2_bits % TARGET_CHAR_BIT == 0); | |
721 | gdb_assert (length_bits % TARGET_CHAR_BIT == 0); | |
722 | ||
723 | return memcmp (ptr1 + offset1_bits / TARGET_CHAR_BIT, | |
724 | ptr2 + offset2_bits / TARGET_CHAR_BIT, | |
725 | length_bits / TARGET_CHAR_BIT); | |
726 | } | |
727 | ||
728 | /* Length is zero, regions match. */ | |
729 | return 0; | |
730 | } | |
731 | ||
9a0dc9e3 PA |
732 | /* Helper struct for find_first_range_overlap_and_match and |
733 | value_contents_bits_eq. Keep track of which slot of a given ranges | |
734 | vector have we last looked at. */ | |
bdf22206 | 735 | |
9a0dc9e3 PA |
736 | struct ranges_and_idx |
737 | { | |
738 | /* The ranges. */ | |
739 | VEC(range_s) *ranges; | |
740 | ||
741 | /* The range we've last found in RANGES. Given ranges are sorted, | |
742 | we can start the next lookup here. */ | |
743 | int idx; | |
744 | }; | |
745 | ||
746 | /* Helper function for value_contents_bits_eq. Compare LENGTH bits of | |
747 | RP1's ranges starting at OFFSET1 bits with LENGTH bits of RP2's | |
748 | ranges starting at OFFSET2 bits. Return true if the ranges match | |
749 | and fill in *L and *H with the overlapping window relative to | |
750 | (both) OFFSET1 or OFFSET2. */ | |
bdf22206 AB |
751 | |
752 | static int | |
9a0dc9e3 PA |
753 | find_first_range_overlap_and_match (struct ranges_and_idx *rp1, |
754 | struct ranges_and_idx *rp2, | |
6b850546 DT |
755 | LONGEST offset1, LONGEST offset2, |
756 | LONGEST length, ULONGEST *l, ULONGEST *h) | |
c8c1c22f | 757 | { |
9a0dc9e3 PA |
758 | rp1->idx = find_first_range_overlap (rp1->ranges, rp1->idx, |
759 | offset1, length); | |
760 | rp2->idx = find_first_range_overlap (rp2->ranges, rp2->idx, | |
761 | offset2, length); | |
c8c1c22f | 762 | |
9a0dc9e3 PA |
763 | if (rp1->idx == -1 && rp2->idx == -1) |
764 | { | |
765 | *l = length; | |
766 | *h = length; | |
767 | return 1; | |
768 | } | |
769 | else if (rp1->idx == -1 || rp2->idx == -1) | |
770 | return 0; | |
771 | else | |
c8c1c22f PA |
772 | { |
773 | range_s *r1, *r2; | |
774 | ULONGEST l1, h1; | |
775 | ULONGEST l2, h2; | |
776 | ||
9a0dc9e3 PA |
777 | r1 = VEC_index (range_s, rp1->ranges, rp1->idx); |
778 | r2 = VEC_index (range_s, rp2->ranges, rp2->idx); | |
c8c1c22f PA |
779 | |
780 | /* Get the unavailable windows intersected by the incoming | |
781 | ranges. The first and last ranges that overlap the argument | |
782 | range may be wider than said incoming arguments ranges. */ | |
783 | l1 = max (offset1, r1->offset); | |
784 | h1 = min (offset1 + length, r1->offset + r1->length); | |
785 | ||
786 | l2 = max (offset2, r2->offset); | |
9a0dc9e3 | 787 | h2 = min (offset2 + length, offset2 + r2->length); |
c8c1c22f PA |
788 | |
789 | /* Make them relative to the respective start offsets, so we can | |
790 | compare them for equality. */ | |
791 | l1 -= offset1; | |
792 | h1 -= offset1; | |
793 | ||
794 | l2 -= offset2; | |
795 | h2 -= offset2; | |
796 | ||
9a0dc9e3 | 797 | /* Different ranges, no match. */ |
c8c1c22f PA |
798 | if (l1 != l2 || h1 != h2) |
799 | return 0; | |
800 | ||
9a0dc9e3 PA |
801 | *h = h1; |
802 | *l = l1; | |
803 | return 1; | |
804 | } | |
805 | } | |
806 | ||
807 | /* Helper function for value_contents_eq. The only difference is that | |
808 | this function is bit rather than byte based. | |
809 | ||
810 | Compare LENGTH bits of VAL1's contents starting at OFFSET1 bits | |
811 | with LENGTH bits of VAL2's contents starting at OFFSET2 bits. | |
812 | Return true if the available bits match. */ | |
813 | ||
814 | static int | |
815 | value_contents_bits_eq (const struct value *val1, int offset1, | |
816 | const struct value *val2, int offset2, | |
817 | int length) | |
818 | { | |
819 | /* Each array element corresponds to a ranges source (unavailable, | |
820 | optimized out). '1' is for VAL1, '2' for VAL2. */ | |
821 | struct ranges_and_idx rp1[2], rp2[2]; | |
822 | ||
823 | /* See function description in value.h. */ | |
824 | gdb_assert (!val1->lazy && !val2->lazy); | |
825 | ||
826 | /* We shouldn't be trying to compare past the end of the values. */ | |
827 | gdb_assert (offset1 + length | |
828 | <= TYPE_LENGTH (val1->enclosing_type) * TARGET_CHAR_BIT); | |
829 | gdb_assert (offset2 + length | |
830 | <= TYPE_LENGTH (val2->enclosing_type) * TARGET_CHAR_BIT); | |
831 | ||
832 | memset (&rp1, 0, sizeof (rp1)); | |
833 | memset (&rp2, 0, sizeof (rp2)); | |
834 | rp1[0].ranges = val1->unavailable; | |
835 | rp2[0].ranges = val2->unavailable; | |
836 | rp1[1].ranges = val1->optimized_out; | |
837 | rp2[1].ranges = val2->optimized_out; | |
838 | ||
839 | while (length > 0) | |
840 | { | |
000339af | 841 | ULONGEST l = 0, h = 0; /* init for gcc -Wall */ |
9a0dc9e3 PA |
842 | int i; |
843 | ||
844 | for (i = 0; i < 2; i++) | |
845 | { | |
846 | ULONGEST l_tmp, h_tmp; | |
847 | ||
848 | /* The contents only match equal if the invalid/unavailable | |
849 | contents ranges match as well. */ | |
850 | if (!find_first_range_overlap_and_match (&rp1[i], &rp2[i], | |
851 | offset1, offset2, length, | |
852 | &l_tmp, &h_tmp)) | |
853 | return 0; | |
854 | ||
855 | /* We're interested in the lowest/first range found. */ | |
856 | if (i == 0 || l_tmp < l) | |
857 | { | |
858 | l = l_tmp; | |
859 | h = h_tmp; | |
860 | } | |
861 | } | |
862 | ||
863 | /* Compare the available/valid contents. */ | |
bdf22206 | 864 | if (memcmp_with_bit_offsets (val1->contents, offset1, |
9a0dc9e3 | 865 | val2->contents, offset2, l) != 0) |
c8c1c22f PA |
866 | return 0; |
867 | ||
9a0dc9e3 PA |
868 | length -= h; |
869 | offset1 += h; | |
870 | offset2 += h; | |
c8c1c22f PA |
871 | } |
872 | ||
873 | return 1; | |
874 | } | |
875 | ||
bdf22206 | 876 | int |
6b850546 DT |
877 | value_contents_eq (const struct value *val1, LONGEST offset1, |
878 | const struct value *val2, LONGEST offset2, | |
879 | LONGEST length) | |
bdf22206 | 880 | { |
9a0dc9e3 PA |
881 | return value_contents_bits_eq (val1, offset1 * TARGET_CHAR_BIT, |
882 | val2, offset2 * TARGET_CHAR_BIT, | |
883 | length * TARGET_CHAR_BIT); | |
bdf22206 AB |
884 | } |
885 | ||
581e13c1 | 886 | /* Prototypes for local functions. */ |
c906108c | 887 | |
a14ed312 | 888 | static void show_values (char *, int); |
c906108c | 889 | |
a14ed312 | 890 | static void show_convenience (char *, int); |
c906108c | 891 | |
c906108c SS |
892 | |
893 | /* The value-history records all the values printed | |
894 | by print commands during this session. Each chunk | |
895 | records 60 consecutive values. The first chunk on | |
896 | the chain records the most recent values. | |
897 | The total number of values is in value_history_count. */ | |
898 | ||
899 | #define VALUE_HISTORY_CHUNK 60 | |
900 | ||
901 | struct value_history_chunk | |
c5aa993b JM |
902 | { |
903 | struct value_history_chunk *next; | |
f23631e4 | 904 | struct value *values[VALUE_HISTORY_CHUNK]; |
c5aa993b | 905 | }; |
c906108c SS |
906 | |
907 | /* Chain of chunks now in use. */ | |
908 | ||
909 | static struct value_history_chunk *value_history_chain; | |
910 | ||
581e13c1 | 911 | static int value_history_count; /* Abs number of last entry stored. */ |
bc3b79fd | 912 | |
c906108c SS |
913 | \f |
914 | /* List of all value objects currently allocated | |
915 | (except for those released by calls to release_value) | |
916 | This is so they can be freed after each command. */ | |
917 | ||
f23631e4 | 918 | static struct value *all_values; |
c906108c | 919 | |
3e3d7139 JG |
920 | /* Allocate a lazy value for type TYPE. Its actual content is |
921 | "lazily" allocated too: the content field of the return value is | |
922 | NULL; it will be allocated when it is fetched from the target. */ | |
c906108c | 923 | |
f23631e4 | 924 | struct value * |
3e3d7139 | 925 | allocate_value_lazy (struct type *type) |
c906108c | 926 | { |
f23631e4 | 927 | struct value *val; |
c54eabfa JK |
928 | |
929 | /* Call check_typedef on our type to make sure that, if TYPE | |
930 | is a TYPE_CODE_TYPEDEF, its length is set to the length | |
931 | of the target type instead of zero. However, we do not | |
932 | replace the typedef type by the target type, because we want | |
933 | to keep the typedef in order to be able to set the VAL's type | |
934 | description correctly. */ | |
935 | check_typedef (type); | |
c906108c | 936 | |
8d749320 | 937 | val = XCNEW (struct value); |
3e3d7139 | 938 | val->contents = NULL; |
df407dfe | 939 | val->next = all_values; |
c906108c | 940 | all_values = val; |
df407dfe | 941 | val->type = type; |
4754a64e | 942 | val->enclosing_type = type; |
c906108c | 943 | VALUE_LVAL (val) = not_lval; |
42ae5230 | 944 | val->location.address = 0; |
1df6926e | 945 | VALUE_FRAME_ID (val) = null_frame_id; |
df407dfe AC |
946 | val->offset = 0; |
947 | val->bitpos = 0; | |
948 | val->bitsize = 0; | |
9ee8fc9d | 949 | VALUE_REGNUM (val) = -1; |
3e3d7139 | 950 | val->lazy = 1; |
13c3b5f5 | 951 | val->embedded_offset = 0; |
b44d461b | 952 | val->pointed_to_offset = 0; |
c906108c | 953 | val->modifiable = 1; |
42be36b3 | 954 | val->initialized = 1; /* Default to initialized. */ |
828d3400 DJ |
955 | |
956 | /* Values start out on the all_values chain. */ | |
957 | val->reference_count = 1; | |
958 | ||
c906108c SS |
959 | return val; |
960 | } | |
961 | ||
5fdf6324 AB |
962 | /* The maximum size, in bytes, that GDB will try to allocate for a value. |
963 | The initial value of 64k was not selected for any specific reason, it is | |
964 | just a reasonable starting point. */ | |
965 | ||
966 | static int max_value_size = 65536; /* 64k bytes */ | |
967 | ||
968 | /* It is critical that the MAX_VALUE_SIZE is at least as big as the size of | |
969 | LONGEST, otherwise GDB will not be able to parse integer values from the | |
970 | CLI; for example if the MAX_VALUE_SIZE could be set to 1 then GDB would | |
971 | be unable to parse "set max-value-size 2". | |
972 | ||
973 | As we want a consistent GDB experience across hosts with different sizes | |
974 | of LONGEST, this arbitrary minimum value was selected, so long as this | |
975 | is bigger than LONGEST on all GDB supported hosts we're fine. */ | |
976 | ||
977 | #define MIN_VALUE_FOR_MAX_VALUE_SIZE 16 | |
978 | gdb_static_assert (sizeof (LONGEST) <= MIN_VALUE_FOR_MAX_VALUE_SIZE); | |
979 | ||
980 | /* Implement the "set max-value-size" command. */ | |
981 | ||
982 | static void | |
983 | set_max_value_size (char *args, int from_tty, | |
984 | struct cmd_list_element *c) | |
985 | { | |
986 | gdb_assert (max_value_size == -1 || max_value_size >= 0); | |
987 | ||
988 | if (max_value_size > -1 && max_value_size < MIN_VALUE_FOR_MAX_VALUE_SIZE) | |
989 | { | |
990 | max_value_size = MIN_VALUE_FOR_MAX_VALUE_SIZE; | |
991 | error (_("max-value-size set too low, increasing to %d bytes"), | |
992 | max_value_size); | |
993 | } | |
994 | } | |
995 | ||
996 | /* Implement the "show max-value-size" command. */ | |
997 | ||
998 | static void | |
999 | show_max_value_size (struct ui_file *file, int from_tty, | |
1000 | struct cmd_list_element *c, const char *value) | |
1001 | { | |
1002 | if (max_value_size == -1) | |
1003 | fprintf_filtered (file, _("Maximum value size is unlimited.\n")); | |
1004 | else | |
1005 | fprintf_filtered (file, _("Maximum value size is %d bytes.\n"), | |
1006 | max_value_size); | |
1007 | } | |
1008 | ||
1009 | /* Called before we attempt to allocate or reallocate a buffer for the | |
1010 | contents of a value. TYPE is the type of the value for which we are | |
1011 | allocating the buffer. If the buffer is too large (based on the user | |
1012 | controllable setting) then throw an error. If this function returns | |
1013 | then we should attempt to allocate the buffer. */ | |
1014 | ||
1015 | static void | |
1016 | check_type_length_before_alloc (const struct type *type) | |
1017 | { | |
1018 | unsigned int length = TYPE_LENGTH (type); | |
1019 | ||
1020 | if (max_value_size > -1 && length > max_value_size) | |
1021 | { | |
1022 | if (TYPE_NAME (type) != NULL) | |
1023 | error (_("value of type `%s' requires %u bytes, which is more " | |
1024 | "than max-value-size"), TYPE_NAME (type), length); | |
1025 | else | |
1026 | error (_("value requires %u bytes, which is more than " | |
1027 | "max-value-size"), length); | |
1028 | } | |
1029 | } | |
1030 | ||
3e3d7139 JG |
1031 | /* Allocate the contents of VAL if it has not been allocated yet. */ |
1032 | ||
548b762d | 1033 | static void |
3e3d7139 JG |
1034 | allocate_value_contents (struct value *val) |
1035 | { | |
1036 | if (!val->contents) | |
5fdf6324 AB |
1037 | { |
1038 | check_type_length_before_alloc (val->enclosing_type); | |
1039 | val->contents | |
1040 | = (gdb_byte *) xzalloc (TYPE_LENGTH (val->enclosing_type)); | |
1041 | } | |
3e3d7139 JG |
1042 | } |
1043 | ||
1044 | /* Allocate a value and its contents for type TYPE. */ | |
1045 | ||
1046 | struct value * | |
1047 | allocate_value (struct type *type) | |
1048 | { | |
1049 | struct value *val = allocate_value_lazy (type); | |
a109c7c1 | 1050 | |
3e3d7139 JG |
1051 | allocate_value_contents (val); |
1052 | val->lazy = 0; | |
1053 | return val; | |
1054 | } | |
1055 | ||
c906108c | 1056 | /* Allocate a value that has the correct length |
938f5214 | 1057 | for COUNT repetitions of type TYPE. */ |
c906108c | 1058 | |
f23631e4 | 1059 | struct value * |
fba45db2 | 1060 | allocate_repeat_value (struct type *type, int count) |
c906108c | 1061 | { |
c5aa993b | 1062 | int low_bound = current_language->string_lower_bound; /* ??? */ |
c906108c SS |
1063 | /* FIXME-type-allocation: need a way to free this type when we are |
1064 | done with it. */ | |
e3506a9f UW |
1065 | struct type *array_type |
1066 | = lookup_array_range_type (type, low_bound, count + low_bound - 1); | |
a109c7c1 | 1067 | |
e3506a9f | 1068 | return allocate_value (array_type); |
c906108c SS |
1069 | } |
1070 | ||
5f5233d4 PA |
1071 | struct value * |
1072 | allocate_computed_value (struct type *type, | |
c8f2448a | 1073 | const struct lval_funcs *funcs, |
5f5233d4 PA |
1074 | void *closure) |
1075 | { | |
41e8491f | 1076 | struct value *v = allocate_value_lazy (type); |
a109c7c1 | 1077 | |
5f5233d4 PA |
1078 | VALUE_LVAL (v) = lval_computed; |
1079 | v->location.computed.funcs = funcs; | |
1080 | v->location.computed.closure = closure; | |
5f5233d4 PA |
1081 | |
1082 | return v; | |
1083 | } | |
1084 | ||
a7035dbb JK |
1085 | /* Allocate NOT_LVAL value for type TYPE being OPTIMIZED_OUT. */ |
1086 | ||
1087 | struct value * | |
1088 | allocate_optimized_out_value (struct type *type) | |
1089 | { | |
1090 | struct value *retval = allocate_value_lazy (type); | |
1091 | ||
9a0dc9e3 PA |
1092 | mark_value_bytes_optimized_out (retval, 0, TYPE_LENGTH (type)); |
1093 | set_value_lazy (retval, 0); | |
a7035dbb JK |
1094 | return retval; |
1095 | } | |
1096 | ||
df407dfe AC |
1097 | /* Accessor methods. */ |
1098 | ||
17cf0ecd | 1099 | struct value * |
4bf7b526 | 1100 | value_next (const struct value *value) |
17cf0ecd AC |
1101 | { |
1102 | return value->next; | |
1103 | } | |
1104 | ||
df407dfe | 1105 | struct type * |
0e03807e | 1106 | value_type (const struct value *value) |
df407dfe AC |
1107 | { |
1108 | return value->type; | |
1109 | } | |
04624583 AC |
1110 | void |
1111 | deprecated_set_value_type (struct value *value, struct type *type) | |
1112 | { | |
1113 | value->type = type; | |
1114 | } | |
df407dfe | 1115 | |
6b850546 | 1116 | LONGEST |
0e03807e | 1117 | value_offset (const struct value *value) |
df407dfe AC |
1118 | { |
1119 | return value->offset; | |
1120 | } | |
f5cf64a7 | 1121 | void |
6b850546 | 1122 | set_value_offset (struct value *value, LONGEST offset) |
f5cf64a7 AC |
1123 | { |
1124 | value->offset = offset; | |
1125 | } | |
df407dfe | 1126 | |
6b850546 | 1127 | LONGEST |
0e03807e | 1128 | value_bitpos (const struct value *value) |
df407dfe AC |
1129 | { |
1130 | return value->bitpos; | |
1131 | } | |
9bbda503 | 1132 | void |
6b850546 | 1133 | set_value_bitpos (struct value *value, LONGEST bit) |
9bbda503 AC |
1134 | { |
1135 | value->bitpos = bit; | |
1136 | } | |
df407dfe | 1137 | |
6b850546 | 1138 | LONGEST |
0e03807e | 1139 | value_bitsize (const struct value *value) |
df407dfe AC |
1140 | { |
1141 | return value->bitsize; | |
1142 | } | |
9bbda503 | 1143 | void |
6b850546 | 1144 | set_value_bitsize (struct value *value, LONGEST bit) |
9bbda503 AC |
1145 | { |
1146 | value->bitsize = bit; | |
1147 | } | |
df407dfe | 1148 | |
4ea48cc1 | 1149 | struct value * |
4bf7b526 | 1150 | value_parent (const struct value *value) |
4ea48cc1 DJ |
1151 | { |
1152 | return value->parent; | |
1153 | } | |
1154 | ||
53ba8333 JB |
1155 | /* See value.h. */ |
1156 | ||
1157 | void | |
1158 | set_value_parent (struct value *value, struct value *parent) | |
1159 | { | |
40501e00 TT |
1160 | struct value *old = value->parent; |
1161 | ||
53ba8333 | 1162 | value->parent = parent; |
40501e00 TT |
1163 | if (parent != NULL) |
1164 | value_incref (parent); | |
1165 | value_free (old); | |
53ba8333 JB |
1166 | } |
1167 | ||
fc1a4b47 | 1168 | gdb_byte * |
990a07ab AC |
1169 | value_contents_raw (struct value *value) |
1170 | { | |
3ae385af SM |
1171 | struct gdbarch *arch = get_value_arch (value); |
1172 | int unit_size = gdbarch_addressable_memory_unit_size (arch); | |
1173 | ||
3e3d7139 | 1174 | allocate_value_contents (value); |
3ae385af | 1175 | return value->contents + value->embedded_offset * unit_size; |
990a07ab AC |
1176 | } |
1177 | ||
fc1a4b47 | 1178 | gdb_byte * |
990a07ab AC |
1179 | value_contents_all_raw (struct value *value) |
1180 | { | |
3e3d7139 JG |
1181 | allocate_value_contents (value); |
1182 | return value->contents; | |
990a07ab AC |
1183 | } |
1184 | ||
4754a64e | 1185 | struct type * |
4bf7b526 | 1186 | value_enclosing_type (const struct value *value) |
4754a64e AC |
1187 | { |
1188 | return value->enclosing_type; | |
1189 | } | |
1190 | ||
8264ba82 AG |
1191 | /* Look at value.h for description. */ |
1192 | ||
1193 | struct type * | |
1194 | value_actual_type (struct value *value, int resolve_simple_types, | |
1195 | int *real_type_found) | |
1196 | { | |
1197 | struct value_print_options opts; | |
8264ba82 AG |
1198 | struct type *result; |
1199 | ||
1200 | get_user_print_options (&opts); | |
1201 | ||
1202 | if (real_type_found) | |
1203 | *real_type_found = 0; | |
1204 | result = value_type (value); | |
1205 | if (opts.objectprint) | |
1206 | { | |
5e34c6c3 LM |
1207 | /* If result's target type is TYPE_CODE_STRUCT, proceed to |
1208 | fetch its rtti type. */ | |
1209 | if ((TYPE_CODE (result) == TYPE_CODE_PTR | |
444bca65 | 1210 | || TYPE_CODE (result) == TYPE_CODE_REF) |
5e34c6c3 | 1211 | && TYPE_CODE (check_typedef (TYPE_TARGET_TYPE (result))) |
ecf2e90c DB |
1212 | == TYPE_CODE_STRUCT |
1213 | && !value_optimized_out (value)) | |
8264ba82 AG |
1214 | { |
1215 | struct type *real_type; | |
1216 | ||
1217 | real_type = value_rtti_indirect_type (value, NULL, NULL, NULL); | |
1218 | if (real_type) | |
1219 | { | |
1220 | if (real_type_found) | |
1221 | *real_type_found = 1; | |
1222 | result = real_type; | |
1223 | } | |
1224 | } | |
1225 | else if (resolve_simple_types) | |
1226 | { | |
1227 | if (real_type_found) | |
1228 | *real_type_found = 1; | |
1229 | result = value_enclosing_type (value); | |
1230 | } | |
1231 | } | |
1232 | ||
1233 | return result; | |
1234 | } | |
1235 | ||
901461f8 PA |
1236 | void |
1237 | error_value_optimized_out (void) | |
1238 | { | |
1239 | error (_("value has been optimized out")); | |
1240 | } | |
1241 | ||
0e03807e | 1242 | static void |
4e07d55f | 1243 | require_not_optimized_out (const struct value *value) |
0e03807e | 1244 | { |
9a0dc9e3 | 1245 | if (!VEC_empty (range_s, value->optimized_out)) |
901461f8 PA |
1246 | { |
1247 | if (value->lval == lval_register) | |
1248 | error (_("register has not been saved in frame")); | |
1249 | else | |
1250 | error_value_optimized_out (); | |
1251 | } | |
0e03807e TT |
1252 | } |
1253 | ||
4e07d55f PA |
1254 | static void |
1255 | require_available (const struct value *value) | |
1256 | { | |
1257 | if (!VEC_empty (range_s, value->unavailable)) | |
8af8e3bc | 1258 | throw_error (NOT_AVAILABLE_ERROR, _("value is not available")); |
4e07d55f PA |
1259 | } |
1260 | ||
fc1a4b47 | 1261 | const gdb_byte * |
0e03807e | 1262 | value_contents_for_printing (struct value *value) |
46615f07 AC |
1263 | { |
1264 | if (value->lazy) | |
1265 | value_fetch_lazy (value); | |
3e3d7139 | 1266 | return value->contents; |
46615f07 AC |
1267 | } |
1268 | ||
de4127a3 PA |
1269 | const gdb_byte * |
1270 | value_contents_for_printing_const (const struct value *value) | |
1271 | { | |
1272 | gdb_assert (!value->lazy); | |
1273 | return value->contents; | |
1274 | } | |
1275 | ||
0e03807e TT |
1276 | const gdb_byte * |
1277 | value_contents_all (struct value *value) | |
1278 | { | |
1279 | const gdb_byte *result = value_contents_for_printing (value); | |
1280 | require_not_optimized_out (value); | |
4e07d55f | 1281 | require_available (value); |
0e03807e TT |
1282 | return result; |
1283 | } | |
1284 | ||
9a0dc9e3 PA |
1285 | /* Copy ranges in SRC_RANGE that overlap [SRC_BIT_OFFSET, |
1286 | SRC_BIT_OFFSET+BIT_LENGTH) ranges into *DST_RANGE, adjusted. */ | |
1287 | ||
1288 | static void | |
1289 | ranges_copy_adjusted (VEC (range_s) **dst_range, int dst_bit_offset, | |
1290 | VEC (range_s) *src_range, int src_bit_offset, | |
1291 | int bit_length) | |
1292 | { | |
1293 | range_s *r; | |
1294 | int i; | |
1295 | ||
1296 | for (i = 0; VEC_iterate (range_s, src_range, i, r); i++) | |
1297 | { | |
1298 | ULONGEST h, l; | |
1299 | ||
1300 | l = max (r->offset, src_bit_offset); | |
1301 | h = min (r->offset + r->length, src_bit_offset + bit_length); | |
1302 | ||
1303 | if (l < h) | |
1304 | insert_into_bit_range_vector (dst_range, | |
1305 | dst_bit_offset + (l - src_bit_offset), | |
1306 | h - l); | |
1307 | } | |
1308 | } | |
1309 | ||
4875ffdb PA |
1310 | /* Copy the ranges metadata in SRC that overlaps [SRC_BIT_OFFSET, |
1311 | SRC_BIT_OFFSET+BIT_LENGTH) into DST, adjusted. */ | |
1312 | ||
1313 | static void | |
1314 | value_ranges_copy_adjusted (struct value *dst, int dst_bit_offset, | |
1315 | const struct value *src, int src_bit_offset, | |
1316 | int bit_length) | |
1317 | { | |
1318 | ranges_copy_adjusted (&dst->unavailable, dst_bit_offset, | |
1319 | src->unavailable, src_bit_offset, | |
1320 | bit_length); | |
1321 | ranges_copy_adjusted (&dst->optimized_out, dst_bit_offset, | |
1322 | src->optimized_out, src_bit_offset, | |
1323 | bit_length); | |
1324 | } | |
1325 | ||
3ae385af | 1326 | /* Copy LENGTH target addressable memory units of SRC value's (all) contents |
29976f3f PA |
1327 | (value_contents_all) starting at SRC_OFFSET, into DST value's (all) |
1328 | contents, starting at DST_OFFSET. If unavailable contents are | |
1329 | being copied from SRC, the corresponding DST contents are marked | |
1330 | unavailable accordingly. Neither DST nor SRC may be lazy | |
1331 | values. | |
1332 | ||
1333 | It is assumed the contents of DST in the [DST_OFFSET, | |
1334 | DST_OFFSET+LENGTH) range are wholly available. */ | |
39d37385 PA |
1335 | |
1336 | void | |
6b850546 DT |
1337 | value_contents_copy_raw (struct value *dst, LONGEST dst_offset, |
1338 | struct value *src, LONGEST src_offset, LONGEST length) | |
39d37385 | 1339 | { |
6b850546 | 1340 | LONGEST src_bit_offset, dst_bit_offset, bit_length; |
3ae385af SM |
1341 | struct gdbarch *arch = get_value_arch (src); |
1342 | int unit_size = gdbarch_addressable_memory_unit_size (arch); | |
39d37385 PA |
1343 | |
1344 | /* A lazy DST would make that this copy operation useless, since as | |
1345 | soon as DST's contents were un-lazied (by a later value_contents | |
1346 | call, say), the contents would be overwritten. A lazy SRC would | |
1347 | mean we'd be copying garbage. */ | |
1348 | gdb_assert (!dst->lazy && !src->lazy); | |
1349 | ||
29976f3f PA |
1350 | /* The overwritten DST range gets unavailability ORed in, not |
1351 | replaced. Make sure to remember to implement replacing if it | |
1352 | turns out actually necessary. */ | |
1353 | gdb_assert (value_bytes_available (dst, dst_offset, length)); | |
9a0dc9e3 PA |
1354 | gdb_assert (!value_bits_any_optimized_out (dst, |
1355 | TARGET_CHAR_BIT * dst_offset, | |
1356 | TARGET_CHAR_BIT * length)); | |
29976f3f | 1357 | |
39d37385 | 1358 | /* Copy the data. */ |
3ae385af SM |
1359 | memcpy (value_contents_all_raw (dst) + dst_offset * unit_size, |
1360 | value_contents_all_raw (src) + src_offset * unit_size, | |
1361 | length * unit_size); | |
39d37385 PA |
1362 | |
1363 | /* Copy the meta-data, adjusted. */ | |
3ae385af SM |
1364 | src_bit_offset = src_offset * unit_size * HOST_CHAR_BIT; |
1365 | dst_bit_offset = dst_offset * unit_size * HOST_CHAR_BIT; | |
1366 | bit_length = length * unit_size * HOST_CHAR_BIT; | |
39d37385 | 1367 | |
4875ffdb PA |
1368 | value_ranges_copy_adjusted (dst, dst_bit_offset, |
1369 | src, src_bit_offset, | |
1370 | bit_length); | |
39d37385 PA |
1371 | } |
1372 | ||
29976f3f PA |
1373 | /* Copy LENGTH bytes of SRC value's (all) contents |
1374 | (value_contents_all) starting at SRC_OFFSET byte, into DST value's | |
1375 | (all) contents, starting at DST_OFFSET. If unavailable contents | |
1376 | are being copied from SRC, the corresponding DST contents are | |
1377 | marked unavailable accordingly. DST must not be lazy. If SRC is | |
9a0dc9e3 | 1378 | lazy, it will be fetched now. |
29976f3f PA |
1379 | |
1380 | It is assumed the contents of DST in the [DST_OFFSET, | |
1381 | DST_OFFSET+LENGTH) range are wholly available. */ | |
39d37385 PA |
1382 | |
1383 | void | |
6b850546 DT |
1384 | value_contents_copy (struct value *dst, LONGEST dst_offset, |
1385 | struct value *src, LONGEST src_offset, LONGEST length) | |
39d37385 | 1386 | { |
39d37385 PA |
1387 | if (src->lazy) |
1388 | value_fetch_lazy (src); | |
1389 | ||
1390 | value_contents_copy_raw (dst, dst_offset, src, src_offset, length); | |
1391 | } | |
1392 | ||
d69fe07e | 1393 | int |
4bf7b526 | 1394 | value_lazy (const struct value *value) |
d69fe07e AC |
1395 | { |
1396 | return value->lazy; | |
1397 | } | |
1398 | ||
dfa52d88 AC |
1399 | void |
1400 | set_value_lazy (struct value *value, int val) | |
1401 | { | |
1402 | value->lazy = val; | |
1403 | } | |
1404 | ||
4e5d721f | 1405 | int |
4bf7b526 | 1406 | value_stack (const struct value *value) |
4e5d721f DE |
1407 | { |
1408 | return value->stack; | |
1409 | } | |
1410 | ||
1411 | void | |
1412 | set_value_stack (struct value *value, int val) | |
1413 | { | |
1414 | value->stack = val; | |
1415 | } | |
1416 | ||
fc1a4b47 | 1417 | const gdb_byte * |
0fd88904 AC |
1418 | value_contents (struct value *value) |
1419 | { | |
0e03807e TT |
1420 | const gdb_byte *result = value_contents_writeable (value); |
1421 | require_not_optimized_out (value); | |
4e07d55f | 1422 | require_available (value); |
0e03807e | 1423 | return result; |
0fd88904 AC |
1424 | } |
1425 | ||
fc1a4b47 | 1426 | gdb_byte * |
0fd88904 AC |
1427 | value_contents_writeable (struct value *value) |
1428 | { | |
1429 | if (value->lazy) | |
1430 | value_fetch_lazy (value); | |
fc0c53a0 | 1431 | return value_contents_raw (value); |
0fd88904 AC |
1432 | } |
1433 | ||
feb13ab0 AC |
1434 | int |
1435 | value_optimized_out (struct value *value) | |
1436 | { | |
691a26f5 AB |
1437 | /* We can only know if a value is optimized out once we have tried to |
1438 | fetch it. */ | |
9a0dc9e3 | 1439 | if (VEC_empty (range_s, value->optimized_out) && value->lazy) |
ecf2e90c DB |
1440 | { |
1441 | TRY | |
1442 | { | |
1443 | value_fetch_lazy (value); | |
1444 | } | |
1445 | CATCH (ex, RETURN_MASK_ERROR) | |
1446 | { | |
1447 | /* Fall back to checking value->optimized_out. */ | |
1448 | } | |
1449 | END_CATCH | |
1450 | } | |
691a26f5 | 1451 | |
9a0dc9e3 | 1452 | return !VEC_empty (range_s, value->optimized_out); |
feb13ab0 AC |
1453 | } |
1454 | ||
9a0dc9e3 PA |
1455 | /* Mark contents of VALUE as optimized out, starting at OFFSET bytes, and |
1456 | the following LENGTH bytes. */ | |
eca07816 | 1457 | |
feb13ab0 | 1458 | void |
9a0dc9e3 | 1459 | mark_value_bytes_optimized_out (struct value *value, int offset, int length) |
feb13ab0 | 1460 | { |
9a0dc9e3 PA |
1461 | mark_value_bits_optimized_out (value, |
1462 | offset * TARGET_CHAR_BIT, | |
1463 | length * TARGET_CHAR_BIT); | |
feb13ab0 | 1464 | } |
13c3b5f5 | 1465 | |
9a0dc9e3 | 1466 | /* See value.h. */ |
0e03807e | 1467 | |
9a0dc9e3 | 1468 | void |
6b850546 DT |
1469 | mark_value_bits_optimized_out (struct value *value, |
1470 | LONGEST offset, LONGEST length) | |
0e03807e | 1471 | { |
9a0dc9e3 | 1472 | insert_into_bit_range_vector (&value->optimized_out, offset, length); |
0e03807e TT |
1473 | } |
1474 | ||
8cf6f0b1 TT |
1475 | int |
1476 | value_bits_synthetic_pointer (const struct value *value, | |
6b850546 | 1477 | LONGEST offset, LONGEST length) |
8cf6f0b1 | 1478 | { |
e7303042 | 1479 | if (value->lval != lval_computed |
8cf6f0b1 TT |
1480 | || !value->location.computed.funcs->check_synthetic_pointer) |
1481 | return 0; | |
1482 | return value->location.computed.funcs->check_synthetic_pointer (value, | |
1483 | offset, | |
1484 | length); | |
1485 | } | |
1486 | ||
6b850546 | 1487 | LONGEST |
4bf7b526 | 1488 | value_embedded_offset (const struct value *value) |
13c3b5f5 AC |
1489 | { |
1490 | return value->embedded_offset; | |
1491 | } | |
1492 | ||
1493 | void | |
6b850546 | 1494 | set_value_embedded_offset (struct value *value, LONGEST val) |
13c3b5f5 AC |
1495 | { |
1496 | value->embedded_offset = val; | |
1497 | } | |
b44d461b | 1498 | |
6b850546 | 1499 | LONGEST |
4bf7b526 | 1500 | value_pointed_to_offset (const struct value *value) |
b44d461b AC |
1501 | { |
1502 | return value->pointed_to_offset; | |
1503 | } | |
1504 | ||
1505 | void | |
6b850546 | 1506 | set_value_pointed_to_offset (struct value *value, LONGEST val) |
b44d461b AC |
1507 | { |
1508 | value->pointed_to_offset = val; | |
1509 | } | |
13bb5560 | 1510 | |
c8f2448a | 1511 | const struct lval_funcs * |
a471c594 | 1512 | value_computed_funcs (const struct value *v) |
5f5233d4 | 1513 | { |
a471c594 | 1514 | gdb_assert (value_lval_const (v) == lval_computed); |
5f5233d4 PA |
1515 | |
1516 | return v->location.computed.funcs; | |
1517 | } | |
1518 | ||
1519 | void * | |
0e03807e | 1520 | value_computed_closure (const struct value *v) |
5f5233d4 | 1521 | { |
0e03807e | 1522 | gdb_assert (v->lval == lval_computed); |
5f5233d4 PA |
1523 | |
1524 | return v->location.computed.closure; | |
1525 | } | |
1526 | ||
13bb5560 AC |
1527 | enum lval_type * |
1528 | deprecated_value_lval_hack (struct value *value) | |
1529 | { | |
1530 | return &value->lval; | |
1531 | } | |
1532 | ||
a471c594 JK |
1533 | enum lval_type |
1534 | value_lval_const (const struct value *value) | |
1535 | { | |
1536 | return value->lval; | |
1537 | } | |
1538 | ||
42ae5230 | 1539 | CORE_ADDR |
de4127a3 | 1540 | value_address (const struct value *value) |
42ae5230 TT |
1541 | { |
1542 | if (value->lval == lval_internalvar | |
e81e7f5e SC |
1543 | || value->lval == lval_internalvar_component |
1544 | || value->lval == lval_xcallable) | |
42ae5230 | 1545 | return 0; |
53ba8333 JB |
1546 | if (value->parent != NULL) |
1547 | return value_address (value->parent) + value->offset; | |
9920b434 BH |
1548 | if (NULL != TYPE_DATA_LOCATION (value_type (value))) |
1549 | { | |
1550 | gdb_assert (PROP_CONST == TYPE_DATA_LOCATION_KIND (value_type (value))); | |
1551 | return TYPE_DATA_LOCATION_ADDR (value_type (value)); | |
1552 | } | |
1553 | ||
1554 | return value->location.address + value->offset; | |
42ae5230 TT |
1555 | } |
1556 | ||
1557 | CORE_ADDR | |
4bf7b526 | 1558 | value_raw_address (const struct value *value) |
42ae5230 TT |
1559 | { |
1560 | if (value->lval == lval_internalvar | |
e81e7f5e SC |
1561 | || value->lval == lval_internalvar_component |
1562 | || value->lval == lval_xcallable) | |
42ae5230 TT |
1563 | return 0; |
1564 | return value->location.address; | |
1565 | } | |
1566 | ||
1567 | void | |
1568 | set_value_address (struct value *value, CORE_ADDR addr) | |
13bb5560 | 1569 | { |
42ae5230 | 1570 | gdb_assert (value->lval != lval_internalvar |
e81e7f5e SC |
1571 | && value->lval != lval_internalvar_component |
1572 | && value->lval != lval_xcallable); | |
42ae5230 | 1573 | value->location.address = addr; |
13bb5560 AC |
1574 | } |
1575 | ||
1576 | struct internalvar ** | |
1577 | deprecated_value_internalvar_hack (struct value *value) | |
1578 | { | |
1579 | return &value->location.internalvar; | |
1580 | } | |
1581 | ||
1582 | struct frame_id * | |
1583 | deprecated_value_frame_id_hack (struct value *value) | |
1584 | { | |
1585 | return &value->frame_id; | |
1586 | } | |
1587 | ||
1588 | short * | |
1589 | deprecated_value_regnum_hack (struct value *value) | |
1590 | { | |
1591 | return &value->regnum; | |
1592 | } | |
88e3b34b AC |
1593 | |
1594 | int | |
4bf7b526 | 1595 | deprecated_value_modifiable (const struct value *value) |
88e3b34b AC |
1596 | { |
1597 | return value->modifiable; | |
1598 | } | |
990a07ab | 1599 | \f |
c906108c SS |
1600 | /* Return a mark in the value chain. All values allocated after the |
1601 | mark is obtained (except for those released) are subject to being freed | |
1602 | if a subsequent value_free_to_mark is passed the mark. */ | |
f23631e4 | 1603 | struct value * |
fba45db2 | 1604 | value_mark (void) |
c906108c SS |
1605 | { |
1606 | return all_values; | |
1607 | } | |
1608 | ||
828d3400 DJ |
1609 | /* Take a reference to VAL. VAL will not be deallocated until all |
1610 | references are released. */ | |
1611 | ||
1612 | void | |
1613 | value_incref (struct value *val) | |
1614 | { | |
1615 | val->reference_count++; | |
1616 | } | |
1617 | ||
1618 | /* Release a reference to VAL, which was acquired with value_incref. | |
1619 | This function is also called to deallocate values from the value | |
1620 | chain. */ | |
1621 | ||
3e3d7139 JG |
1622 | void |
1623 | value_free (struct value *val) | |
1624 | { | |
1625 | if (val) | |
5f5233d4 | 1626 | { |
828d3400 DJ |
1627 | gdb_assert (val->reference_count > 0); |
1628 | val->reference_count--; | |
1629 | if (val->reference_count > 0) | |
1630 | return; | |
1631 | ||
4ea48cc1 DJ |
1632 | /* If there's an associated parent value, drop our reference to |
1633 | it. */ | |
1634 | if (val->parent != NULL) | |
1635 | value_free (val->parent); | |
1636 | ||
5f5233d4 PA |
1637 | if (VALUE_LVAL (val) == lval_computed) |
1638 | { | |
c8f2448a | 1639 | const struct lval_funcs *funcs = val->location.computed.funcs; |
5f5233d4 PA |
1640 | |
1641 | if (funcs->free_closure) | |
1642 | funcs->free_closure (val); | |
1643 | } | |
e81e7f5e SC |
1644 | else if (VALUE_LVAL (val) == lval_xcallable) |
1645 | free_xmethod_worker (val->location.xm_worker); | |
5f5233d4 PA |
1646 | |
1647 | xfree (val->contents); | |
4e07d55f | 1648 | VEC_free (range_s, val->unavailable); |
5f5233d4 | 1649 | } |
3e3d7139 JG |
1650 | xfree (val); |
1651 | } | |
1652 | ||
c906108c SS |
1653 | /* Free all values allocated since MARK was obtained by value_mark |
1654 | (except for those released). */ | |
1655 | void | |
4bf7b526 | 1656 | value_free_to_mark (const struct value *mark) |
c906108c | 1657 | { |
f23631e4 AC |
1658 | struct value *val; |
1659 | struct value *next; | |
c906108c SS |
1660 | |
1661 | for (val = all_values; val && val != mark; val = next) | |
1662 | { | |
df407dfe | 1663 | next = val->next; |
e848a8a5 | 1664 | val->released = 1; |
c906108c SS |
1665 | value_free (val); |
1666 | } | |
1667 | all_values = val; | |
1668 | } | |
1669 | ||
1670 | /* Free all the values that have been allocated (except for those released). | |
725e88af DE |
1671 | Call after each command, successful or not. |
1672 | In practice this is called before each command, which is sufficient. */ | |
c906108c SS |
1673 | |
1674 | void | |
fba45db2 | 1675 | free_all_values (void) |
c906108c | 1676 | { |
f23631e4 AC |
1677 | struct value *val; |
1678 | struct value *next; | |
c906108c SS |
1679 | |
1680 | for (val = all_values; val; val = next) | |
1681 | { | |
df407dfe | 1682 | next = val->next; |
e848a8a5 | 1683 | val->released = 1; |
c906108c SS |
1684 | value_free (val); |
1685 | } | |
1686 | ||
1687 | all_values = 0; | |
1688 | } | |
1689 | ||
0cf6dd15 TJB |
1690 | /* Frees all the elements in a chain of values. */ |
1691 | ||
1692 | void | |
1693 | free_value_chain (struct value *v) | |
1694 | { | |
1695 | struct value *next; | |
1696 | ||
1697 | for (; v; v = next) | |
1698 | { | |
1699 | next = value_next (v); | |
1700 | value_free (v); | |
1701 | } | |
1702 | } | |
1703 | ||
c906108c SS |
1704 | /* Remove VAL from the chain all_values |
1705 | so it will not be freed automatically. */ | |
1706 | ||
1707 | void | |
f23631e4 | 1708 | release_value (struct value *val) |
c906108c | 1709 | { |
f23631e4 | 1710 | struct value *v; |
c906108c SS |
1711 | |
1712 | if (all_values == val) | |
1713 | { | |
1714 | all_values = val->next; | |
06a64a0b | 1715 | val->next = NULL; |
e848a8a5 | 1716 | val->released = 1; |
c906108c SS |
1717 | return; |
1718 | } | |
1719 | ||
1720 | for (v = all_values; v; v = v->next) | |
1721 | { | |
1722 | if (v->next == val) | |
1723 | { | |
1724 | v->next = val->next; | |
06a64a0b | 1725 | val->next = NULL; |
e848a8a5 | 1726 | val->released = 1; |
c906108c SS |
1727 | break; |
1728 | } | |
1729 | } | |
1730 | } | |
1731 | ||
e848a8a5 TT |
1732 | /* If the value is not already released, release it. |
1733 | If the value is already released, increment its reference count. | |
1734 | That is, this function ensures that the value is released from the | |
1735 | value chain and that the caller owns a reference to it. */ | |
1736 | ||
1737 | void | |
1738 | release_value_or_incref (struct value *val) | |
1739 | { | |
1740 | if (val->released) | |
1741 | value_incref (val); | |
1742 | else | |
1743 | release_value (val); | |
1744 | } | |
1745 | ||
c906108c | 1746 | /* Release all values up to mark */ |
f23631e4 | 1747 | struct value * |
4bf7b526 | 1748 | value_release_to_mark (const struct value *mark) |
c906108c | 1749 | { |
f23631e4 AC |
1750 | struct value *val; |
1751 | struct value *next; | |
c906108c | 1752 | |
df407dfe | 1753 | for (val = next = all_values; next; next = next->next) |
e848a8a5 TT |
1754 | { |
1755 | if (next->next == mark) | |
1756 | { | |
1757 | all_values = next->next; | |
1758 | next->next = NULL; | |
1759 | return val; | |
1760 | } | |
1761 | next->released = 1; | |
1762 | } | |
c906108c SS |
1763 | all_values = 0; |
1764 | return val; | |
1765 | } | |
1766 | ||
1767 | /* Return a copy of the value ARG. | |
1768 | It contains the same contents, for same memory address, | |
1769 | but it's a different block of storage. */ | |
1770 | ||
f23631e4 AC |
1771 | struct value * |
1772 | value_copy (struct value *arg) | |
c906108c | 1773 | { |
4754a64e | 1774 | struct type *encl_type = value_enclosing_type (arg); |
3e3d7139 JG |
1775 | struct value *val; |
1776 | ||
1777 | if (value_lazy (arg)) | |
1778 | val = allocate_value_lazy (encl_type); | |
1779 | else | |
1780 | val = allocate_value (encl_type); | |
df407dfe | 1781 | val->type = arg->type; |
c906108c | 1782 | VALUE_LVAL (val) = VALUE_LVAL (arg); |
6f7c8fc2 | 1783 | val->location = arg->location; |
df407dfe AC |
1784 | val->offset = arg->offset; |
1785 | val->bitpos = arg->bitpos; | |
1786 | val->bitsize = arg->bitsize; | |
1df6926e | 1787 | VALUE_FRAME_ID (val) = VALUE_FRAME_ID (arg); |
9ee8fc9d | 1788 | VALUE_REGNUM (val) = VALUE_REGNUM (arg); |
d69fe07e | 1789 | val->lazy = arg->lazy; |
13c3b5f5 | 1790 | val->embedded_offset = value_embedded_offset (arg); |
b44d461b | 1791 | val->pointed_to_offset = arg->pointed_to_offset; |
c906108c | 1792 | val->modifiable = arg->modifiable; |
d69fe07e | 1793 | if (!value_lazy (val)) |
c906108c | 1794 | { |
990a07ab | 1795 | memcpy (value_contents_all_raw (val), value_contents_all_raw (arg), |
4754a64e | 1796 | TYPE_LENGTH (value_enclosing_type (arg))); |
c906108c SS |
1797 | |
1798 | } | |
4e07d55f | 1799 | val->unavailable = VEC_copy (range_s, arg->unavailable); |
9a0dc9e3 | 1800 | val->optimized_out = VEC_copy (range_s, arg->optimized_out); |
40501e00 | 1801 | set_value_parent (val, arg->parent); |
5f5233d4 PA |
1802 | if (VALUE_LVAL (val) == lval_computed) |
1803 | { | |
c8f2448a | 1804 | const struct lval_funcs *funcs = val->location.computed.funcs; |
5f5233d4 PA |
1805 | |
1806 | if (funcs->copy_closure) | |
1807 | val->location.computed.closure = funcs->copy_closure (val); | |
1808 | } | |
c906108c SS |
1809 | return val; |
1810 | } | |
74bcbdf3 | 1811 | |
4c082a81 SC |
1812 | /* Return a "const" and/or "volatile" qualified version of the value V. |
1813 | If CNST is true, then the returned value will be qualified with | |
1814 | "const". | |
1815 | if VOLTL is true, then the returned value will be qualified with | |
1816 | "volatile". */ | |
1817 | ||
1818 | struct value * | |
1819 | make_cv_value (int cnst, int voltl, struct value *v) | |
1820 | { | |
1821 | struct type *val_type = value_type (v); | |
1822 | struct type *enclosing_type = value_enclosing_type (v); | |
1823 | struct value *cv_val = value_copy (v); | |
1824 | ||
1825 | deprecated_set_value_type (cv_val, | |
1826 | make_cv_type (cnst, voltl, val_type, NULL)); | |
1827 | set_value_enclosing_type (cv_val, | |
1828 | make_cv_type (cnst, voltl, enclosing_type, NULL)); | |
1829 | ||
1830 | return cv_val; | |
1831 | } | |
1832 | ||
c37f7098 KW |
1833 | /* Return a version of ARG that is non-lvalue. */ |
1834 | ||
1835 | struct value * | |
1836 | value_non_lval (struct value *arg) | |
1837 | { | |
1838 | if (VALUE_LVAL (arg) != not_lval) | |
1839 | { | |
1840 | struct type *enc_type = value_enclosing_type (arg); | |
1841 | struct value *val = allocate_value (enc_type); | |
1842 | ||
1843 | memcpy (value_contents_all_raw (val), value_contents_all (arg), | |
1844 | TYPE_LENGTH (enc_type)); | |
1845 | val->type = arg->type; | |
1846 | set_value_embedded_offset (val, value_embedded_offset (arg)); | |
1847 | set_value_pointed_to_offset (val, value_pointed_to_offset (arg)); | |
1848 | return val; | |
1849 | } | |
1850 | return arg; | |
1851 | } | |
1852 | ||
6c659fc2 SC |
1853 | /* Write contents of V at ADDR and set its lval type to be LVAL_MEMORY. */ |
1854 | ||
1855 | void | |
1856 | value_force_lval (struct value *v, CORE_ADDR addr) | |
1857 | { | |
1858 | gdb_assert (VALUE_LVAL (v) == not_lval); | |
1859 | ||
1860 | write_memory (addr, value_contents_raw (v), TYPE_LENGTH (value_type (v))); | |
1861 | v->lval = lval_memory; | |
1862 | v->location.address = addr; | |
1863 | } | |
1864 | ||
74bcbdf3 | 1865 | void |
0e03807e TT |
1866 | set_value_component_location (struct value *component, |
1867 | const struct value *whole) | |
74bcbdf3 | 1868 | { |
9920b434 BH |
1869 | struct type *type; |
1870 | ||
e81e7f5e SC |
1871 | gdb_assert (whole->lval != lval_xcallable); |
1872 | ||
0e03807e | 1873 | if (whole->lval == lval_internalvar) |
74bcbdf3 PA |
1874 | VALUE_LVAL (component) = lval_internalvar_component; |
1875 | else | |
0e03807e | 1876 | VALUE_LVAL (component) = whole->lval; |
5f5233d4 | 1877 | |
74bcbdf3 | 1878 | component->location = whole->location; |
0e03807e | 1879 | if (whole->lval == lval_computed) |
5f5233d4 | 1880 | { |
c8f2448a | 1881 | const struct lval_funcs *funcs = whole->location.computed.funcs; |
5f5233d4 PA |
1882 | |
1883 | if (funcs->copy_closure) | |
1884 | component->location.computed.closure = funcs->copy_closure (whole); | |
1885 | } | |
9920b434 BH |
1886 | |
1887 | /* If type has a dynamic resolved location property | |
1888 | update it's value address. */ | |
1889 | type = value_type (whole); | |
1890 | if (NULL != TYPE_DATA_LOCATION (type) | |
1891 | && TYPE_DATA_LOCATION_KIND (type) == PROP_CONST) | |
1892 | set_value_address (component, TYPE_DATA_LOCATION_ADDR (type)); | |
74bcbdf3 PA |
1893 | } |
1894 | ||
c906108c SS |
1895 | /* Access to the value history. */ |
1896 | ||
1897 | /* Record a new value in the value history. | |
eddf0bae | 1898 | Returns the absolute history index of the entry. */ |
c906108c SS |
1899 | |
1900 | int | |
f23631e4 | 1901 | record_latest_value (struct value *val) |
c906108c SS |
1902 | { |
1903 | int i; | |
1904 | ||
1905 | /* We don't want this value to have anything to do with the inferior anymore. | |
1906 | In particular, "set $1 = 50" should not affect the variable from which | |
1907 | the value was taken, and fast watchpoints should be able to assume that | |
1908 | a value on the value history never changes. */ | |
d69fe07e | 1909 | if (value_lazy (val)) |
c906108c SS |
1910 | value_fetch_lazy (val); |
1911 | /* We preserve VALUE_LVAL so that the user can find out where it was fetched | |
1912 | from. This is a bit dubious, because then *&$1 does not just return $1 | |
1913 | but the current contents of that location. c'est la vie... */ | |
1914 | val->modifiable = 0; | |
350e1a76 DE |
1915 | |
1916 | /* The value may have already been released, in which case we're adding a | |
1917 | new reference for its entry in the history. That is why we call | |
1918 | release_value_or_incref here instead of release_value. */ | |
1919 | release_value_or_incref (val); | |
c906108c SS |
1920 | |
1921 | /* Here we treat value_history_count as origin-zero | |
1922 | and applying to the value being stored now. */ | |
1923 | ||
1924 | i = value_history_count % VALUE_HISTORY_CHUNK; | |
1925 | if (i == 0) | |
1926 | { | |
8d749320 | 1927 | struct value_history_chunk *newobj = XCNEW (struct value_history_chunk); |
a109c7c1 | 1928 | |
fe978cb0 PA |
1929 | newobj->next = value_history_chain; |
1930 | value_history_chain = newobj; | |
c906108c SS |
1931 | } |
1932 | ||
1933 | value_history_chain->values[i] = val; | |
1934 | ||
1935 | /* Now we regard value_history_count as origin-one | |
1936 | and applying to the value just stored. */ | |
1937 | ||
1938 | return ++value_history_count; | |
1939 | } | |
1940 | ||
1941 | /* Return a copy of the value in the history with sequence number NUM. */ | |
1942 | ||
f23631e4 | 1943 | struct value * |
fba45db2 | 1944 | access_value_history (int num) |
c906108c | 1945 | { |
f23631e4 | 1946 | struct value_history_chunk *chunk; |
52f0bd74 AC |
1947 | int i; |
1948 | int absnum = num; | |
c906108c SS |
1949 | |
1950 | if (absnum <= 0) | |
1951 | absnum += value_history_count; | |
1952 | ||
1953 | if (absnum <= 0) | |
1954 | { | |
1955 | if (num == 0) | |
8a3fe4f8 | 1956 | error (_("The history is empty.")); |
c906108c | 1957 | else if (num == 1) |
8a3fe4f8 | 1958 | error (_("There is only one value in the history.")); |
c906108c | 1959 | else |
8a3fe4f8 | 1960 | error (_("History does not go back to $$%d."), -num); |
c906108c SS |
1961 | } |
1962 | if (absnum > value_history_count) | |
8a3fe4f8 | 1963 | error (_("History has not yet reached $%d."), absnum); |
c906108c SS |
1964 | |
1965 | absnum--; | |
1966 | ||
1967 | /* Now absnum is always absolute and origin zero. */ | |
1968 | ||
1969 | chunk = value_history_chain; | |
3e43a32a MS |
1970 | for (i = (value_history_count - 1) / VALUE_HISTORY_CHUNK |
1971 | - absnum / VALUE_HISTORY_CHUNK; | |
c906108c SS |
1972 | i > 0; i--) |
1973 | chunk = chunk->next; | |
1974 | ||
1975 | return value_copy (chunk->values[absnum % VALUE_HISTORY_CHUNK]); | |
1976 | } | |
1977 | ||
c906108c | 1978 | static void |
fba45db2 | 1979 | show_values (char *num_exp, int from_tty) |
c906108c | 1980 | { |
52f0bd74 | 1981 | int i; |
f23631e4 | 1982 | struct value *val; |
c906108c SS |
1983 | static int num = 1; |
1984 | ||
1985 | if (num_exp) | |
1986 | { | |
f132ba9d TJB |
1987 | /* "show values +" should print from the stored position. |
1988 | "show values <exp>" should print around value number <exp>. */ | |
c906108c | 1989 | if (num_exp[0] != '+' || num_exp[1] != '\0') |
bb518678 | 1990 | num = parse_and_eval_long (num_exp) - 5; |
c906108c SS |
1991 | } |
1992 | else | |
1993 | { | |
f132ba9d | 1994 | /* "show values" means print the last 10 values. */ |
c906108c SS |
1995 | num = value_history_count - 9; |
1996 | } | |
1997 | ||
1998 | if (num <= 0) | |
1999 | num = 1; | |
2000 | ||
2001 | for (i = num; i < num + 10 && i <= value_history_count; i++) | |
2002 | { | |
79a45b7d | 2003 | struct value_print_options opts; |
a109c7c1 | 2004 | |
c906108c | 2005 | val = access_value_history (i); |
a3f17187 | 2006 | printf_filtered (("$%d = "), i); |
79a45b7d TT |
2007 | get_user_print_options (&opts); |
2008 | value_print (val, gdb_stdout, &opts); | |
a3f17187 | 2009 | printf_filtered (("\n")); |
c906108c SS |
2010 | } |
2011 | ||
f132ba9d | 2012 | /* The next "show values +" should start after what we just printed. */ |
c906108c SS |
2013 | num += 10; |
2014 | ||
2015 | /* Hitting just return after this command should do the same thing as | |
f132ba9d TJB |
2016 | "show values +". If num_exp is null, this is unnecessary, since |
2017 | "show values +" is not useful after "show values". */ | |
c906108c SS |
2018 | if (from_tty && num_exp) |
2019 | { | |
2020 | num_exp[0] = '+'; | |
2021 | num_exp[1] = '\0'; | |
2022 | } | |
2023 | } | |
2024 | \f | |
52059ffd TT |
2025 | enum internalvar_kind |
2026 | { | |
2027 | /* The internal variable is empty. */ | |
2028 | INTERNALVAR_VOID, | |
2029 | ||
2030 | /* The value of the internal variable is provided directly as | |
2031 | a GDB value object. */ | |
2032 | INTERNALVAR_VALUE, | |
2033 | ||
2034 | /* A fresh value is computed via a call-back routine on every | |
2035 | access to the internal variable. */ | |
2036 | INTERNALVAR_MAKE_VALUE, | |
2037 | ||
2038 | /* The internal variable holds a GDB internal convenience function. */ | |
2039 | INTERNALVAR_FUNCTION, | |
2040 | ||
2041 | /* The variable holds an integer value. */ | |
2042 | INTERNALVAR_INTEGER, | |
2043 | ||
2044 | /* The variable holds a GDB-provided string. */ | |
2045 | INTERNALVAR_STRING, | |
2046 | }; | |
2047 | ||
2048 | union internalvar_data | |
2049 | { | |
2050 | /* A value object used with INTERNALVAR_VALUE. */ | |
2051 | struct value *value; | |
2052 | ||
2053 | /* The call-back routine used with INTERNALVAR_MAKE_VALUE. */ | |
2054 | struct | |
2055 | { | |
2056 | /* The functions to call. */ | |
2057 | const struct internalvar_funcs *functions; | |
2058 | ||
2059 | /* The function's user-data. */ | |
2060 | void *data; | |
2061 | } make_value; | |
2062 | ||
2063 | /* The internal function used with INTERNALVAR_FUNCTION. */ | |
2064 | struct | |
2065 | { | |
2066 | struct internal_function *function; | |
2067 | /* True if this is the canonical name for the function. */ | |
2068 | int canonical; | |
2069 | } fn; | |
2070 | ||
2071 | /* An integer value used with INTERNALVAR_INTEGER. */ | |
2072 | struct | |
2073 | { | |
2074 | /* If type is non-NULL, it will be used as the type to generate | |
2075 | a value for this internal variable. If type is NULL, a default | |
2076 | integer type for the architecture is used. */ | |
2077 | struct type *type; | |
2078 | LONGEST val; | |
2079 | } integer; | |
2080 | ||
2081 | /* A string value used with INTERNALVAR_STRING. */ | |
2082 | char *string; | |
2083 | }; | |
2084 | ||
c906108c SS |
2085 | /* Internal variables. These are variables within the debugger |
2086 | that hold values assigned by debugger commands. | |
2087 | The user refers to them with a '$' prefix | |
2088 | that does not appear in the variable names stored internally. */ | |
2089 | ||
4fa62494 UW |
2090 | struct internalvar |
2091 | { | |
2092 | struct internalvar *next; | |
2093 | char *name; | |
4fa62494 | 2094 | |
78267919 UW |
2095 | /* We support various different kinds of content of an internal variable. |
2096 | enum internalvar_kind specifies the kind, and union internalvar_data | |
2097 | provides the data associated with this particular kind. */ | |
2098 | ||
52059ffd | 2099 | enum internalvar_kind kind; |
4fa62494 | 2100 | |
52059ffd | 2101 | union internalvar_data u; |
4fa62494 UW |
2102 | }; |
2103 | ||
c906108c SS |
2104 | static struct internalvar *internalvars; |
2105 | ||
3e43a32a MS |
2106 | /* If the variable does not already exist create it and give it the |
2107 | value given. If no value is given then the default is zero. */ | |
53e5f3cf AS |
2108 | static void |
2109 | init_if_undefined_command (char* args, int from_tty) | |
2110 | { | |
2111 | struct internalvar* intvar; | |
2112 | ||
2113 | /* Parse the expression - this is taken from set_command(). */ | |
2114 | struct expression *expr = parse_expression (args); | |
2115 | register struct cleanup *old_chain = | |
2116 | make_cleanup (free_current_contents, &expr); | |
2117 | ||
2118 | /* Validate the expression. | |
2119 | Was the expression an assignment? | |
2120 | Or even an expression at all? */ | |
2121 | if (expr->nelts == 0 || expr->elts[0].opcode != BINOP_ASSIGN) | |
2122 | error (_("Init-if-undefined requires an assignment expression.")); | |
2123 | ||
2124 | /* Extract the variable from the parsed expression. | |
2125 | In the case of an assign the lvalue will be in elts[1] and elts[2]. */ | |
2126 | if (expr->elts[1].opcode != OP_INTERNALVAR) | |
3e43a32a MS |
2127 | error (_("The first parameter to init-if-undefined " |
2128 | "should be a GDB variable.")); | |
53e5f3cf AS |
2129 | intvar = expr->elts[2].internalvar; |
2130 | ||
2131 | /* Only evaluate the expression if the lvalue is void. | |
2132 | This may still fail if the expresssion is invalid. */ | |
78267919 | 2133 | if (intvar->kind == INTERNALVAR_VOID) |
53e5f3cf AS |
2134 | evaluate_expression (expr); |
2135 | ||
2136 | do_cleanups (old_chain); | |
2137 | } | |
2138 | ||
2139 | ||
c906108c SS |
2140 | /* Look up an internal variable with name NAME. NAME should not |
2141 | normally include a dollar sign. | |
2142 | ||
2143 | If the specified internal variable does not exist, | |
c4a3d09a | 2144 | the return value is NULL. */ |
c906108c SS |
2145 | |
2146 | struct internalvar * | |
bc3b79fd | 2147 | lookup_only_internalvar (const char *name) |
c906108c | 2148 | { |
52f0bd74 | 2149 | struct internalvar *var; |
c906108c SS |
2150 | |
2151 | for (var = internalvars; var; var = var->next) | |
5cb316ef | 2152 | if (strcmp (var->name, name) == 0) |
c906108c SS |
2153 | return var; |
2154 | ||
c4a3d09a MF |
2155 | return NULL; |
2156 | } | |
2157 | ||
d55637df TT |
2158 | /* Complete NAME by comparing it to the names of internal variables. |
2159 | Returns a vector of newly allocated strings, or NULL if no matches | |
2160 | were found. */ | |
2161 | ||
2162 | VEC (char_ptr) * | |
2163 | complete_internalvar (const char *name) | |
2164 | { | |
2165 | VEC (char_ptr) *result = NULL; | |
2166 | struct internalvar *var; | |
2167 | int len; | |
2168 | ||
2169 | len = strlen (name); | |
2170 | ||
2171 | for (var = internalvars; var; var = var->next) | |
2172 | if (strncmp (var->name, name, len) == 0) | |
2173 | { | |
2174 | char *r = xstrdup (var->name); | |
2175 | ||
2176 | VEC_safe_push (char_ptr, result, r); | |
2177 | } | |
2178 | ||
2179 | return result; | |
2180 | } | |
c4a3d09a MF |
2181 | |
2182 | /* Create an internal variable with name NAME and with a void value. | |
2183 | NAME should not normally include a dollar sign. */ | |
2184 | ||
2185 | struct internalvar * | |
bc3b79fd | 2186 | create_internalvar (const char *name) |
c4a3d09a | 2187 | { |
8d749320 | 2188 | struct internalvar *var = XNEW (struct internalvar); |
a109c7c1 | 2189 | |
1754f103 | 2190 | var->name = concat (name, (char *)NULL); |
78267919 | 2191 | var->kind = INTERNALVAR_VOID; |
c906108c SS |
2192 | var->next = internalvars; |
2193 | internalvars = var; | |
2194 | return var; | |
2195 | } | |
2196 | ||
4aa995e1 PA |
2197 | /* Create an internal variable with name NAME and register FUN as the |
2198 | function that value_of_internalvar uses to create a value whenever | |
2199 | this variable is referenced. NAME should not normally include a | |
22d2b532 SDJ |
2200 | dollar sign. DATA is passed uninterpreted to FUN when it is |
2201 | called. CLEANUP, if not NULL, is called when the internal variable | |
2202 | is destroyed. It is passed DATA as its only argument. */ | |
4aa995e1 PA |
2203 | |
2204 | struct internalvar * | |
22d2b532 SDJ |
2205 | create_internalvar_type_lazy (const char *name, |
2206 | const struct internalvar_funcs *funcs, | |
2207 | void *data) | |
4aa995e1 | 2208 | { |
4fa62494 | 2209 | struct internalvar *var = create_internalvar (name); |
a109c7c1 | 2210 | |
78267919 | 2211 | var->kind = INTERNALVAR_MAKE_VALUE; |
22d2b532 SDJ |
2212 | var->u.make_value.functions = funcs; |
2213 | var->u.make_value.data = data; | |
4aa995e1 PA |
2214 | return var; |
2215 | } | |
c4a3d09a | 2216 | |
22d2b532 SDJ |
2217 | /* See documentation in value.h. */ |
2218 | ||
2219 | int | |
2220 | compile_internalvar_to_ax (struct internalvar *var, | |
2221 | struct agent_expr *expr, | |
2222 | struct axs_value *value) | |
2223 | { | |
2224 | if (var->kind != INTERNALVAR_MAKE_VALUE | |
2225 | || var->u.make_value.functions->compile_to_ax == NULL) | |
2226 | return 0; | |
2227 | ||
2228 | var->u.make_value.functions->compile_to_ax (var, expr, value, | |
2229 | var->u.make_value.data); | |
2230 | return 1; | |
2231 | } | |
2232 | ||
c4a3d09a MF |
2233 | /* Look up an internal variable with name NAME. NAME should not |
2234 | normally include a dollar sign. | |
2235 | ||
2236 | If the specified internal variable does not exist, | |
2237 | one is created, with a void value. */ | |
2238 | ||
2239 | struct internalvar * | |
bc3b79fd | 2240 | lookup_internalvar (const char *name) |
c4a3d09a MF |
2241 | { |
2242 | struct internalvar *var; | |
2243 | ||
2244 | var = lookup_only_internalvar (name); | |
2245 | if (var) | |
2246 | return var; | |
2247 | ||
2248 | return create_internalvar (name); | |
2249 | } | |
2250 | ||
78267919 UW |
2251 | /* Return current value of internal variable VAR. For variables that |
2252 | are not inherently typed, use a value type appropriate for GDBARCH. */ | |
2253 | ||
f23631e4 | 2254 | struct value * |
78267919 | 2255 | value_of_internalvar (struct gdbarch *gdbarch, struct internalvar *var) |
c906108c | 2256 | { |
f23631e4 | 2257 | struct value *val; |
0914bcdb SS |
2258 | struct trace_state_variable *tsv; |
2259 | ||
2260 | /* If there is a trace state variable of the same name, assume that | |
2261 | is what we really want to see. */ | |
2262 | tsv = find_trace_state_variable (var->name); | |
2263 | if (tsv) | |
2264 | { | |
2265 | tsv->value_known = target_get_trace_state_variable_value (tsv->number, | |
2266 | &(tsv->value)); | |
2267 | if (tsv->value_known) | |
2268 | val = value_from_longest (builtin_type (gdbarch)->builtin_int64, | |
2269 | tsv->value); | |
2270 | else | |
2271 | val = allocate_value (builtin_type (gdbarch)->builtin_void); | |
2272 | return val; | |
2273 | } | |
c906108c | 2274 | |
78267919 | 2275 | switch (var->kind) |
5f5233d4 | 2276 | { |
78267919 UW |
2277 | case INTERNALVAR_VOID: |
2278 | val = allocate_value (builtin_type (gdbarch)->builtin_void); | |
2279 | break; | |
4fa62494 | 2280 | |
78267919 UW |
2281 | case INTERNALVAR_FUNCTION: |
2282 | val = allocate_value (builtin_type (gdbarch)->internal_fn); | |
2283 | break; | |
4fa62494 | 2284 | |
cab0c772 UW |
2285 | case INTERNALVAR_INTEGER: |
2286 | if (!var->u.integer.type) | |
78267919 | 2287 | val = value_from_longest (builtin_type (gdbarch)->builtin_int, |
cab0c772 | 2288 | var->u.integer.val); |
78267919 | 2289 | else |
cab0c772 UW |
2290 | val = value_from_longest (var->u.integer.type, var->u.integer.val); |
2291 | break; | |
2292 | ||
78267919 UW |
2293 | case INTERNALVAR_STRING: |
2294 | val = value_cstring (var->u.string, strlen (var->u.string), | |
2295 | builtin_type (gdbarch)->builtin_char); | |
2296 | break; | |
4fa62494 | 2297 | |
78267919 UW |
2298 | case INTERNALVAR_VALUE: |
2299 | val = value_copy (var->u.value); | |
4aa995e1 PA |
2300 | if (value_lazy (val)) |
2301 | value_fetch_lazy (val); | |
78267919 | 2302 | break; |
4aa995e1 | 2303 | |
78267919 | 2304 | case INTERNALVAR_MAKE_VALUE: |
22d2b532 SDJ |
2305 | val = (*var->u.make_value.functions->make_value) (gdbarch, var, |
2306 | var->u.make_value.data); | |
78267919 UW |
2307 | break; |
2308 | ||
2309 | default: | |
9b20d036 | 2310 | internal_error (__FILE__, __LINE__, _("bad kind")); |
78267919 UW |
2311 | } |
2312 | ||
2313 | /* Change the VALUE_LVAL to lval_internalvar so that future operations | |
2314 | on this value go back to affect the original internal variable. | |
2315 | ||
2316 | Do not do this for INTERNALVAR_MAKE_VALUE variables, as those have | |
2317 | no underlying modifyable state in the internal variable. | |
2318 | ||
2319 | Likewise, if the variable's value is a computed lvalue, we want | |
2320 | references to it to produce another computed lvalue, where | |
2321 | references and assignments actually operate through the | |
2322 | computed value's functions. | |
2323 | ||
2324 | This means that internal variables with computed values | |
2325 | behave a little differently from other internal variables: | |
2326 | assignments to them don't just replace the previous value | |
2327 | altogether. At the moment, this seems like the behavior we | |
2328 | want. */ | |
2329 | ||
2330 | if (var->kind != INTERNALVAR_MAKE_VALUE | |
2331 | && val->lval != lval_computed) | |
2332 | { | |
2333 | VALUE_LVAL (val) = lval_internalvar; | |
2334 | VALUE_INTERNALVAR (val) = var; | |
5f5233d4 | 2335 | } |
d3c139e9 | 2336 | |
4fa62494 UW |
2337 | return val; |
2338 | } | |
d3c139e9 | 2339 | |
4fa62494 UW |
2340 | int |
2341 | get_internalvar_integer (struct internalvar *var, LONGEST *result) | |
2342 | { | |
3158c6ed | 2343 | if (var->kind == INTERNALVAR_INTEGER) |
4fa62494 | 2344 | { |
cab0c772 UW |
2345 | *result = var->u.integer.val; |
2346 | return 1; | |
3158c6ed | 2347 | } |
d3c139e9 | 2348 | |
3158c6ed PA |
2349 | if (var->kind == INTERNALVAR_VALUE) |
2350 | { | |
2351 | struct type *type = check_typedef (value_type (var->u.value)); | |
2352 | ||
2353 | if (TYPE_CODE (type) == TYPE_CODE_INT) | |
2354 | { | |
2355 | *result = value_as_long (var->u.value); | |
2356 | return 1; | |
2357 | } | |
4fa62494 | 2358 | } |
3158c6ed PA |
2359 | |
2360 | return 0; | |
4fa62494 | 2361 | } |
d3c139e9 | 2362 | |
4fa62494 UW |
2363 | static int |
2364 | get_internalvar_function (struct internalvar *var, | |
2365 | struct internal_function **result) | |
2366 | { | |
78267919 | 2367 | switch (var->kind) |
d3c139e9 | 2368 | { |
78267919 UW |
2369 | case INTERNALVAR_FUNCTION: |
2370 | *result = var->u.fn.function; | |
4fa62494 | 2371 | return 1; |
d3c139e9 | 2372 | |
4fa62494 UW |
2373 | default: |
2374 | return 0; | |
2375 | } | |
c906108c SS |
2376 | } |
2377 | ||
2378 | void | |
6b850546 DT |
2379 | set_internalvar_component (struct internalvar *var, |
2380 | LONGEST offset, LONGEST bitpos, | |
2381 | LONGEST bitsize, struct value *newval) | |
c906108c | 2382 | { |
4fa62494 | 2383 | gdb_byte *addr; |
3ae385af SM |
2384 | struct gdbarch *arch; |
2385 | int unit_size; | |
c906108c | 2386 | |
78267919 | 2387 | switch (var->kind) |
4fa62494 | 2388 | { |
78267919 UW |
2389 | case INTERNALVAR_VALUE: |
2390 | addr = value_contents_writeable (var->u.value); | |
3ae385af SM |
2391 | arch = get_value_arch (var->u.value); |
2392 | unit_size = gdbarch_addressable_memory_unit_size (arch); | |
4fa62494 UW |
2393 | |
2394 | if (bitsize) | |
50810684 | 2395 | modify_field (value_type (var->u.value), addr + offset, |
4fa62494 UW |
2396 | value_as_long (newval), bitpos, bitsize); |
2397 | else | |
3ae385af | 2398 | memcpy (addr + offset * unit_size, value_contents (newval), |
4fa62494 UW |
2399 | TYPE_LENGTH (value_type (newval))); |
2400 | break; | |
78267919 UW |
2401 | |
2402 | default: | |
2403 | /* We can never get a component of any other kind. */ | |
9b20d036 | 2404 | internal_error (__FILE__, __LINE__, _("set_internalvar_component")); |
4fa62494 | 2405 | } |
c906108c SS |
2406 | } |
2407 | ||
2408 | void | |
f23631e4 | 2409 | set_internalvar (struct internalvar *var, struct value *val) |
c906108c | 2410 | { |
78267919 | 2411 | enum internalvar_kind new_kind; |
4fa62494 | 2412 | union internalvar_data new_data = { 0 }; |
c906108c | 2413 | |
78267919 | 2414 | if (var->kind == INTERNALVAR_FUNCTION && var->u.fn.canonical) |
bc3b79fd TJB |
2415 | error (_("Cannot overwrite convenience function %s"), var->name); |
2416 | ||
4fa62494 | 2417 | /* Prepare new contents. */ |
78267919 | 2418 | switch (TYPE_CODE (check_typedef (value_type (val)))) |
4fa62494 UW |
2419 | { |
2420 | case TYPE_CODE_VOID: | |
78267919 | 2421 | new_kind = INTERNALVAR_VOID; |
4fa62494 UW |
2422 | break; |
2423 | ||
2424 | case TYPE_CODE_INTERNAL_FUNCTION: | |
2425 | gdb_assert (VALUE_LVAL (val) == lval_internalvar); | |
78267919 UW |
2426 | new_kind = INTERNALVAR_FUNCTION; |
2427 | get_internalvar_function (VALUE_INTERNALVAR (val), | |
2428 | &new_data.fn.function); | |
2429 | /* Copies created here are never canonical. */ | |
4fa62494 UW |
2430 | break; |
2431 | ||
4fa62494 | 2432 | default: |
78267919 UW |
2433 | new_kind = INTERNALVAR_VALUE; |
2434 | new_data.value = value_copy (val); | |
2435 | new_data.value->modifiable = 1; | |
4fa62494 UW |
2436 | |
2437 | /* Force the value to be fetched from the target now, to avoid problems | |
2438 | later when this internalvar is referenced and the target is gone or | |
2439 | has changed. */ | |
78267919 UW |
2440 | if (value_lazy (new_data.value)) |
2441 | value_fetch_lazy (new_data.value); | |
4fa62494 UW |
2442 | |
2443 | /* Release the value from the value chain to prevent it from being | |
2444 | deleted by free_all_values. From here on this function should not | |
2445 | call error () until new_data is installed into the var->u to avoid | |
2446 | leaking memory. */ | |
78267919 | 2447 | release_value (new_data.value); |
9920b434 BH |
2448 | |
2449 | /* Internal variables which are created from values with a dynamic | |
2450 | location don't need the location property of the origin anymore. | |
2451 | The resolved dynamic location is used prior then any other address | |
2452 | when accessing the value. | |
2453 | If we keep it, we would still refer to the origin value. | |
2454 | Remove the location property in case it exist. */ | |
2455 | remove_dyn_prop (DYN_PROP_DATA_LOCATION, value_type (new_data.value)); | |
2456 | ||
4fa62494 UW |
2457 | break; |
2458 | } | |
2459 | ||
2460 | /* Clean up old contents. */ | |
2461 | clear_internalvar (var); | |
2462 | ||
2463 | /* Switch over. */ | |
78267919 | 2464 | var->kind = new_kind; |
4fa62494 | 2465 | var->u = new_data; |
c906108c SS |
2466 | /* End code which must not call error(). */ |
2467 | } | |
2468 | ||
4fa62494 UW |
2469 | void |
2470 | set_internalvar_integer (struct internalvar *var, LONGEST l) | |
2471 | { | |
2472 | /* Clean up old contents. */ | |
2473 | clear_internalvar (var); | |
2474 | ||
cab0c772 UW |
2475 | var->kind = INTERNALVAR_INTEGER; |
2476 | var->u.integer.type = NULL; | |
2477 | var->u.integer.val = l; | |
78267919 UW |
2478 | } |
2479 | ||
2480 | void | |
2481 | set_internalvar_string (struct internalvar *var, const char *string) | |
2482 | { | |
2483 | /* Clean up old contents. */ | |
2484 | clear_internalvar (var); | |
2485 | ||
2486 | var->kind = INTERNALVAR_STRING; | |
2487 | var->u.string = xstrdup (string); | |
4fa62494 UW |
2488 | } |
2489 | ||
2490 | static void | |
2491 | set_internalvar_function (struct internalvar *var, struct internal_function *f) | |
2492 | { | |
2493 | /* Clean up old contents. */ | |
2494 | clear_internalvar (var); | |
2495 | ||
78267919 UW |
2496 | var->kind = INTERNALVAR_FUNCTION; |
2497 | var->u.fn.function = f; | |
2498 | var->u.fn.canonical = 1; | |
2499 | /* Variables installed here are always the canonical version. */ | |
4fa62494 UW |
2500 | } |
2501 | ||
2502 | void | |
2503 | clear_internalvar (struct internalvar *var) | |
2504 | { | |
2505 | /* Clean up old contents. */ | |
78267919 | 2506 | switch (var->kind) |
4fa62494 | 2507 | { |
78267919 UW |
2508 | case INTERNALVAR_VALUE: |
2509 | value_free (var->u.value); | |
2510 | break; | |
2511 | ||
2512 | case INTERNALVAR_STRING: | |
2513 | xfree (var->u.string); | |
4fa62494 UW |
2514 | break; |
2515 | ||
22d2b532 SDJ |
2516 | case INTERNALVAR_MAKE_VALUE: |
2517 | if (var->u.make_value.functions->destroy != NULL) | |
2518 | var->u.make_value.functions->destroy (var->u.make_value.data); | |
2519 | break; | |
2520 | ||
4fa62494 | 2521 | default: |
4fa62494 UW |
2522 | break; |
2523 | } | |
2524 | ||
78267919 UW |
2525 | /* Reset to void kind. */ |
2526 | var->kind = INTERNALVAR_VOID; | |
4fa62494 UW |
2527 | } |
2528 | ||
c906108c | 2529 | char * |
4bf7b526 | 2530 | internalvar_name (const struct internalvar *var) |
c906108c SS |
2531 | { |
2532 | return var->name; | |
2533 | } | |
2534 | ||
4fa62494 UW |
2535 | static struct internal_function * |
2536 | create_internal_function (const char *name, | |
2537 | internal_function_fn handler, void *cookie) | |
bc3b79fd | 2538 | { |
bc3b79fd | 2539 | struct internal_function *ifn = XNEW (struct internal_function); |
a109c7c1 | 2540 | |
bc3b79fd TJB |
2541 | ifn->name = xstrdup (name); |
2542 | ifn->handler = handler; | |
2543 | ifn->cookie = cookie; | |
4fa62494 | 2544 | return ifn; |
bc3b79fd TJB |
2545 | } |
2546 | ||
2547 | char * | |
2548 | value_internal_function_name (struct value *val) | |
2549 | { | |
4fa62494 UW |
2550 | struct internal_function *ifn; |
2551 | int result; | |
2552 | ||
2553 | gdb_assert (VALUE_LVAL (val) == lval_internalvar); | |
2554 | result = get_internalvar_function (VALUE_INTERNALVAR (val), &ifn); | |
2555 | gdb_assert (result); | |
2556 | ||
bc3b79fd TJB |
2557 | return ifn->name; |
2558 | } | |
2559 | ||
2560 | struct value * | |
d452c4bc UW |
2561 | call_internal_function (struct gdbarch *gdbarch, |
2562 | const struct language_defn *language, | |
2563 | struct value *func, int argc, struct value **argv) | |
bc3b79fd | 2564 | { |
4fa62494 UW |
2565 | struct internal_function *ifn; |
2566 | int result; | |
2567 | ||
2568 | gdb_assert (VALUE_LVAL (func) == lval_internalvar); | |
2569 | result = get_internalvar_function (VALUE_INTERNALVAR (func), &ifn); | |
2570 | gdb_assert (result); | |
2571 | ||
d452c4bc | 2572 | return (*ifn->handler) (gdbarch, language, ifn->cookie, argc, argv); |
bc3b79fd TJB |
2573 | } |
2574 | ||
2575 | /* The 'function' command. This does nothing -- it is just a | |
2576 | placeholder to let "help function NAME" work. This is also used as | |
2577 | the implementation of the sub-command that is created when | |
2578 | registering an internal function. */ | |
2579 | static void | |
2580 | function_command (char *command, int from_tty) | |
2581 | { | |
2582 | /* Do nothing. */ | |
2583 | } | |
2584 | ||
2585 | /* Clean up if an internal function's command is destroyed. */ | |
2586 | static void | |
2587 | function_destroyer (struct cmd_list_element *self, void *ignore) | |
2588 | { | |
6f937416 | 2589 | xfree ((char *) self->name); |
1947513d | 2590 | xfree ((char *) self->doc); |
bc3b79fd TJB |
2591 | } |
2592 | ||
2593 | /* Add a new internal function. NAME is the name of the function; DOC | |
2594 | is a documentation string describing the function. HANDLER is | |
2595 | called when the function is invoked. COOKIE is an arbitrary | |
2596 | pointer which is passed to HANDLER and is intended for "user | |
2597 | data". */ | |
2598 | void | |
2599 | add_internal_function (const char *name, const char *doc, | |
2600 | internal_function_fn handler, void *cookie) | |
2601 | { | |
2602 | struct cmd_list_element *cmd; | |
4fa62494 | 2603 | struct internal_function *ifn; |
bc3b79fd | 2604 | struct internalvar *var = lookup_internalvar (name); |
4fa62494 UW |
2605 | |
2606 | ifn = create_internal_function (name, handler, cookie); | |
2607 | set_internalvar_function (var, ifn); | |
bc3b79fd TJB |
2608 | |
2609 | cmd = add_cmd (xstrdup (name), no_class, function_command, (char *) doc, | |
2610 | &functionlist); | |
2611 | cmd->destroyer = function_destroyer; | |
2612 | } | |
2613 | ||
ae5a43e0 DJ |
2614 | /* Update VALUE before discarding OBJFILE. COPIED_TYPES is used to |
2615 | prevent cycles / duplicates. */ | |
2616 | ||
4e7a5ef5 | 2617 | void |
ae5a43e0 DJ |
2618 | preserve_one_value (struct value *value, struct objfile *objfile, |
2619 | htab_t copied_types) | |
2620 | { | |
2621 | if (TYPE_OBJFILE (value->type) == objfile) | |
2622 | value->type = copy_type_recursive (objfile, value->type, copied_types); | |
2623 | ||
2624 | if (TYPE_OBJFILE (value->enclosing_type) == objfile) | |
2625 | value->enclosing_type = copy_type_recursive (objfile, | |
2626 | value->enclosing_type, | |
2627 | copied_types); | |
2628 | } | |
2629 | ||
78267919 UW |
2630 | /* Likewise for internal variable VAR. */ |
2631 | ||
2632 | static void | |
2633 | preserve_one_internalvar (struct internalvar *var, struct objfile *objfile, | |
2634 | htab_t copied_types) | |
2635 | { | |
2636 | switch (var->kind) | |
2637 | { | |
cab0c772 UW |
2638 | case INTERNALVAR_INTEGER: |
2639 | if (var->u.integer.type && TYPE_OBJFILE (var->u.integer.type) == objfile) | |
2640 | var->u.integer.type | |
2641 | = copy_type_recursive (objfile, var->u.integer.type, copied_types); | |
2642 | break; | |
2643 | ||
78267919 UW |
2644 | case INTERNALVAR_VALUE: |
2645 | preserve_one_value (var->u.value, objfile, copied_types); | |
2646 | break; | |
2647 | } | |
2648 | } | |
2649 | ||
ae5a43e0 DJ |
2650 | /* Update the internal variables and value history when OBJFILE is |
2651 | discarded; we must copy the types out of the objfile. New global types | |
2652 | will be created for every convenience variable which currently points to | |
2653 | this objfile's types, and the convenience variables will be adjusted to | |
2654 | use the new global types. */ | |
c906108c SS |
2655 | |
2656 | void | |
ae5a43e0 | 2657 | preserve_values (struct objfile *objfile) |
c906108c | 2658 | { |
ae5a43e0 DJ |
2659 | htab_t copied_types; |
2660 | struct value_history_chunk *cur; | |
52f0bd74 | 2661 | struct internalvar *var; |
ae5a43e0 | 2662 | int i; |
c906108c | 2663 | |
ae5a43e0 DJ |
2664 | /* Create the hash table. We allocate on the objfile's obstack, since |
2665 | it is soon to be deleted. */ | |
2666 | copied_types = create_copied_types_hash (objfile); | |
2667 | ||
2668 | for (cur = value_history_chain; cur; cur = cur->next) | |
2669 | for (i = 0; i < VALUE_HISTORY_CHUNK; i++) | |
2670 | if (cur->values[i]) | |
2671 | preserve_one_value (cur->values[i], objfile, copied_types); | |
2672 | ||
2673 | for (var = internalvars; var; var = var->next) | |
78267919 | 2674 | preserve_one_internalvar (var, objfile, copied_types); |
ae5a43e0 | 2675 | |
6dddc817 | 2676 | preserve_ext_lang_values (objfile, copied_types); |
a08702d6 | 2677 | |
ae5a43e0 | 2678 | htab_delete (copied_types); |
c906108c SS |
2679 | } |
2680 | ||
2681 | static void | |
fba45db2 | 2682 | show_convenience (char *ignore, int from_tty) |
c906108c | 2683 | { |
e17c207e | 2684 | struct gdbarch *gdbarch = get_current_arch (); |
52f0bd74 | 2685 | struct internalvar *var; |
c906108c | 2686 | int varseen = 0; |
79a45b7d | 2687 | struct value_print_options opts; |
c906108c | 2688 | |
79a45b7d | 2689 | get_user_print_options (&opts); |
c906108c SS |
2690 | for (var = internalvars; var; var = var->next) |
2691 | { | |
c709acd1 | 2692 | |
c906108c SS |
2693 | if (!varseen) |
2694 | { | |
2695 | varseen = 1; | |
2696 | } | |
a3f17187 | 2697 | printf_filtered (("$%s = "), var->name); |
c709acd1 | 2698 | |
492d29ea | 2699 | TRY |
c709acd1 PA |
2700 | { |
2701 | struct value *val; | |
2702 | ||
2703 | val = value_of_internalvar (gdbarch, var); | |
2704 | value_print (val, gdb_stdout, &opts); | |
2705 | } | |
492d29ea PA |
2706 | CATCH (ex, RETURN_MASK_ERROR) |
2707 | { | |
2708 | fprintf_filtered (gdb_stdout, _("<error: %s>"), ex.message); | |
2709 | } | |
2710 | END_CATCH | |
2711 | ||
a3f17187 | 2712 | printf_filtered (("\n")); |
c906108c SS |
2713 | } |
2714 | if (!varseen) | |
f47f77df DE |
2715 | { |
2716 | /* This text does not mention convenience functions on purpose. | |
2717 | The user can't create them except via Python, and if Python support | |
2718 | is installed this message will never be printed ($_streq will | |
2719 | exist). */ | |
2720 | printf_unfiltered (_("No debugger convenience variables now defined.\n" | |
2721 | "Convenience variables have " | |
2722 | "names starting with \"$\";\n" | |
2723 | "use \"set\" as in \"set " | |
2724 | "$foo = 5\" to define them.\n")); | |
2725 | } | |
c906108c SS |
2726 | } |
2727 | \f | |
e81e7f5e SC |
2728 | /* Return the TYPE_CODE_XMETHOD value corresponding to WORKER. */ |
2729 | ||
2730 | struct value * | |
2731 | value_of_xmethod (struct xmethod_worker *worker) | |
2732 | { | |
2733 | if (worker->value == NULL) | |
2734 | { | |
2735 | struct value *v; | |
2736 | ||
2737 | v = allocate_value (builtin_type (target_gdbarch ())->xmethod); | |
2738 | v->lval = lval_xcallable; | |
2739 | v->location.xm_worker = worker; | |
2740 | v->modifiable = 0; | |
2741 | worker->value = v; | |
2742 | } | |
2743 | ||
2744 | return worker->value; | |
2745 | } | |
2746 | ||
2ce1cdbf DE |
2747 | /* Return the type of the result of TYPE_CODE_XMETHOD value METHOD. */ |
2748 | ||
2749 | struct type * | |
2750 | result_type_of_xmethod (struct value *method, int argc, struct value **argv) | |
2751 | { | |
2752 | gdb_assert (TYPE_CODE (value_type (method)) == TYPE_CODE_XMETHOD | |
2753 | && method->lval == lval_xcallable && argc > 0); | |
2754 | ||
2755 | return get_xmethod_result_type (method->location.xm_worker, | |
2756 | argv[0], argv + 1, argc - 1); | |
2757 | } | |
2758 | ||
e81e7f5e SC |
2759 | /* Call the xmethod corresponding to the TYPE_CODE_XMETHOD value METHOD. */ |
2760 | ||
2761 | struct value * | |
2762 | call_xmethod (struct value *method, int argc, struct value **argv) | |
2763 | { | |
2764 | gdb_assert (TYPE_CODE (value_type (method)) == TYPE_CODE_XMETHOD | |
2765 | && method->lval == lval_xcallable && argc > 0); | |
2766 | ||
2767 | return invoke_xmethod (method->location.xm_worker, | |
2768 | argv[0], argv + 1, argc - 1); | |
2769 | } | |
2770 | \f | |
c906108c SS |
2771 | /* Extract a value as a C number (either long or double). |
2772 | Knows how to convert fixed values to double, or | |
2773 | floating values to long. | |
2774 | Does not deallocate the value. */ | |
2775 | ||
2776 | LONGEST | |
f23631e4 | 2777 | value_as_long (struct value *val) |
c906108c SS |
2778 | { |
2779 | /* This coerces arrays and functions, which is necessary (e.g. | |
2780 | in disassemble_command). It also dereferences references, which | |
2781 | I suspect is the most logical thing to do. */ | |
994b9211 | 2782 | val = coerce_array (val); |
0fd88904 | 2783 | return unpack_long (value_type (val), value_contents (val)); |
c906108c SS |
2784 | } |
2785 | ||
2786 | DOUBLEST | |
f23631e4 | 2787 | value_as_double (struct value *val) |
c906108c SS |
2788 | { |
2789 | DOUBLEST foo; | |
2790 | int inv; | |
c5aa993b | 2791 | |
0fd88904 | 2792 | foo = unpack_double (value_type (val), value_contents (val), &inv); |
c906108c | 2793 | if (inv) |
8a3fe4f8 | 2794 | error (_("Invalid floating value found in program.")); |
c906108c SS |
2795 | return foo; |
2796 | } | |
4ef30785 | 2797 | |
581e13c1 | 2798 | /* Extract a value as a C pointer. Does not deallocate the value. |
4478b372 JB |
2799 | Note that val's type may not actually be a pointer; value_as_long |
2800 | handles all the cases. */ | |
c906108c | 2801 | CORE_ADDR |
f23631e4 | 2802 | value_as_address (struct value *val) |
c906108c | 2803 | { |
50810684 UW |
2804 | struct gdbarch *gdbarch = get_type_arch (value_type (val)); |
2805 | ||
c906108c SS |
2806 | /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure |
2807 | whether we want this to be true eventually. */ | |
2808 | #if 0 | |
bf6ae464 | 2809 | /* gdbarch_addr_bits_remove is wrong if we are being called for a |
c906108c SS |
2810 | non-address (e.g. argument to "signal", "info break", etc.), or |
2811 | for pointers to char, in which the low bits *are* significant. */ | |
50810684 | 2812 | return gdbarch_addr_bits_remove (gdbarch, value_as_long (val)); |
c906108c | 2813 | #else |
f312f057 JB |
2814 | |
2815 | /* There are several targets (IA-64, PowerPC, and others) which | |
2816 | don't represent pointers to functions as simply the address of | |
2817 | the function's entry point. For example, on the IA-64, a | |
2818 | function pointer points to a two-word descriptor, generated by | |
2819 | the linker, which contains the function's entry point, and the | |
2820 | value the IA-64 "global pointer" register should have --- to | |
2821 | support position-independent code. The linker generates | |
2822 | descriptors only for those functions whose addresses are taken. | |
2823 | ||
2824 | On such targets, it's difficult for GDB to convert an arbitrary | |
2825 | function address into a function pointer; it has to either find | |
2826 | an existing descriptor for that function, or call malloc and | |
2827 | build its own. On some targets, it is impossible for GDB to | |
2828 | build a descriptor at all: the descriptor must contain a jump | |
2829 | instruction; data memory cannot be executed; and code memory | |
2830 | cannot be modified. | |
2831 | ||
2832 | Upon entry to this function, if VAL is a value of type `function' | |
2833 | (that is, TYPE_CODE (VALUE_TYPE (val)) == TYPE_CODE_FUNC), then | |
42ae5230 | 2834 | value_address (val) is the address of the function. This is what |
f312f057 JB |
2835 | you'll get if you evaluate an expression like `main'. The call |
2836 | to COERCE_ARRAY below actually does all the usual unary | |
2837 | conversions, which includes converting values of type `function' | |
2838 | to `pointer to function'. This is the challenging conversion | |
2839 | discussed above. Then, `unpack_long' will convert that pointer | |
2840 | back into an address. | |
2841 | ||
2842 | So, suppose the user types `disassemble foo' on an architecture | |
2843 | with a strange function pointer representation, on which GDB | |
2844 | cannot build its own descriptors, and suppose further that `foo' | |
2845 | has no linker-built descriptor. The address->pointer conversion | |
2846 | will signal an error and prevent the command from running, even | |
2847 | though the next step would have been to convert the pointer | |
2848 | directly back into the same address. | |
2849 | ||
2850 | The following shortcut avoids this whole mess. If VAL is a | |
2851 | function, just return its address directly. */ | |
df407dfe AC |
2852 | if (TYPE_CODE (value_type (val)) == TYPE_CODE_FUNC |
2853 | || TYPE_CODE (value_type (val)) == TYPE_CODE_METHOD) | |
42ae5230 | 2854 | return value_address (val); |
f312f057 | 2855 | |
994b9211 | 2856 | val = coerce_array (val); |
fc0c74b1 AC |
2857 | |
2858 | /* Some architectures (e.g. Harvard), map instruction and data | |
2859 | addresses onto a single large unified address space. For | |
2860 | instance: An architecture may consider a large integer in the | |
2861 | range 0x10000000 .. 0x1000ffff to already represent a data | |
2862 | addresses (hence not need a pointer to address conversion) while | |
2863 | a small integer would still need to be converted integer to | |
2864 | pointer to address. Just assume such architectures handle all | |
2865 | integer conversions in a single function. */ | |
2866 | ||
2867 | /* JimB writes: | |
2868 | ||
2869 | I think INTEGER_TO_ADDRESS is a good idea as proposed --- but we | |
2870 | must admonish GDB hackers to make sure its behavior matches the | |
2871 | compiler's, whenever possible. | |
2872 | ||
2873 | In general, I think GDB should evaluate expressions the same way | |
2874 | the compiler does. When the user copies an expression out of | |
2875 | their source code and hands it to a `print' command, they should | |
2876 | get the same value the compiler would have computed. Any | |
2877 | deviation from this rule can cause major confusion and annoyance, | |
2878 | and needs to be justified carefully. In other words, GDB doesn't | |
2879 | really have the freedom to do these conversions in clever and | |
2880 | useful ways. | |
2881 | ||
2882 | AndrewC pointed out that users aren't complaining about how GDB | |
2883 | casts integers to pointers; they are complaining that they can't | |
2884 | take an address from a disassembly listing and give it to `x/i'. | |
2885 | This is certainly important. | |
2886 | ||
79dd2d24 | 2887 | Adding an architecture method like integer_to_address() certainly |
fc0c74b1 AC |
2888 | makes it possible for GDB to "get it right" in all circumstances |
2889 | --- the target has complete control over how things get done, so | |
2890 | people can Do The Right Thing for their target without breaking | |
2891 | anyone else. The standard doesn't specify how integers get | |
2892 | converted to pointers; usually, the ABI doesn't either, but | |
2893 | ABI-specific code is a more reasonable place to handle it. */ | |
2894 | ||
df407dfe AC |
2895 | if (TYPE_CODE (value_type (val)) != TYPE_CODE_PTR |
2896 | && TYPE_CODE (value_type (val)) != TYPE_CODE_REF | |
50810684 UW |
2897 | && gdbarch_integer_to_address_p (gdbarch)) |
2898 | return gdbarch_integer_to_address (gdbarch, value_type (val), | |
0fd88904 | 2899 | value_contents (val)); |
fc0c74b1 | 2900 | |
0fd88904 | 2901 | return unpack_long (value_type (val), value_contents (val)); |
c906108c SS |
2902 | #endif |
2903 | } | |
2904 | \f | |
2905 | /* Unpack raw data (copied from debugee, target byte order) at VALADDR | |
2906 | as a long, or as a double, assuming the raw data is described | |
2907 | by type TYPE. Knows how to convert different sizes of values | |
2908 | and can convert between fixed and floating point. We don't assume | |
2909 | any alignment for the raw data. Return value is in host byte order. | |
2910 | ||
2911 | If you want functions and arrays to be coerced to pointers, and | |
2912 | references to be dereferenced, call value_as_long() instead. | |
2913 | ||
2914 | C++: It is assumed that the front-end has taken care of | |
2915 | all matters concerning pointers to members. A pointer | |
2916 | to member which reaches here is considered to be equivalent | |
2917 | to an INT (or some size). After all, it is only an offset. */ | |
2918 | ||
2919 | LONGEST | |
fc1a4b47 | 2920 | unpack_long (struct type *type, const gdb_byte *valaddr) |
c906108c | 2921 | { |
e17a4113 | 2922 | enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); |
52f0bd74 AC |
2923 | enum type_code code = TYPE_CODE (type); |
2924 | int len = TYPE_LENGTH (type); | |
2925 | int nosign = TYPE_UNSIGNED (type); | |
c906108c | 2926 | |
c906108c SS |
2927 | switch (code) |
2928 | { | |
2929 | case TYPE_CODE_TYPEDEF: | |
2930 | return unpack_long (check_typedef (type), valaddr); | |
2931 | case TYPE_CODE_ENUM: | |
4f2aea11 | 2932 | case TYPE_CODE_FLAGS: |
c906108c SS |
2933 | case TYPE_CODE_BOOL: |
2934 | case TYPE_CODE_INT: | |
2935 | case TYPE_CODE_CHAR: | |
2936 | case TYPE_CODE_RANGE: | |
0d5de010 | 2937 | case TYPE_CODE_MEMBERPTR: |
c906108c | 2938 | if (nosign) |
e17a4113 | 2939 | return extract_unsigned_integer (valaddr, len, byte_order); |
c906108c | 2940 | else |
e17a4113 | 2941 | return extract_signed_integer (valaddr, len, byte_order); |
c906108c SS |
2942 | |
2943 | case TYPE_CODE_FLT: | |
aebf07fc | 2944 | return (LONGEST) extract_typed_floating (valaddr, type); |
c906108c | 2945 | |
4ef30785 TJB |
2946 | case TYPE_CODE_DECFLOAT: |
2947 | /* libdecnumber has a function to convert from decimal to integer, but | |
2948 | it doesn't work when the decimal number has a fractional part. */ | |
aebf07fc | 2949 | return (LONGEST) decimal_to_doublest (valaddr, len, byte_order); |
4ef30785 | 2950 | |
c906108c SS |
2951 | case TYPE_CODE_PTR: |
2952 | case TYPE_CODE_REF: | |
2953 | /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure | |
c5aa993b | 2954 | whether we want this to be true eventually. */ |
4478b372 | 2955 | return extract_typed_address (valaddr, type); |
c906108c | 2956 | |
c906108c | 2957 | default: |
8a3fe4f8 | 2958 | error (_("Value can't be converted to integer.")); |
c906108c | 2959 | } |
c5aa993b | 2960 | return 0; /* Placate lint. */ |
c906108c SS |
2961 | } |
2962 | ||
2963 | /* Return a double value from the specified type and address. | |
2964 | INVP points to an int which is set to 0 for valid value, | |
2965 | 1 for invalid value (bad float format). In either case, | |
2966 | the returned double is OK to use. Argument is in target | |
2967 | format, result is in host format. */ | |
2968 | ||
2969 | DOUBLEST | |
fc1a4b47 | 2970 | unpack_double (struct type *type, const gdb_byte *valaddr, int *invp) |
c906108c | 2971 | { |
e17a4113 | 2972 | enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); |
c906108c SS |
2973 | enum type_code code; |
2974 | int len; | |
2975 | int nosign; | |
2976 | ||
581e13c1 | 2977 | *invp = 0; /* Assume valid. */ |
f168693b | 2978 | type = check_typedef (type); |
c906108c SS |
2979 | code = TYPE_CODE (type); |
2980 | len = TYPE_LENGTH (type); | |
2981 | nosign = TYPE_UNSIGNED (type); | |
2982 | if (code == TYPE_CODE_FLT) | |
2983 | { | |
75bc7ddf AC |
2984 | /* NOTE: cagney/2002-02-19: There was a test here to see if the |
2985 | floating-point value was valid (using the macro | |
2986 | INVALID_FLOAT). That test/macro have been removed. | |
2987 | ||
2988 | It turns out that only the VAX defined this macro and then | |
2989 | only in a non-portable way. Fixing the portability problem | |
2990 | wouldn't help since the VAX floating-point code is also badly | |
2991 | bit-rotten. The target needs to add definitions for the | |
ea06eb3d | 2992 | methods gdbarch_float_format and gdbarch_double_format - these |
75bc7ddf AC |
2993 | exactly describe the target floating-point format. The |
2994 | problem here is that the corresponding floatformat_vax_f and | |
2995 | floatformat_vax_d values these methods should be set to are | |
2996 | also not defined either. Oops! | |
2997 | ||
2998 | Hopefully someone will add both the missing floatformat | |
ac79b88b DJ |
2999 | definitions and the new cases for floatformat_is_valid (). */ |
3000 | ||
3001 | if (!floatformat_is_valid (floatformat_from_type (type), valaddr)) | |
3002 | { | |
3003 | *invp = 1; | |
3004 | return 0.0; | |
3005 | } | |
3006 | ||
96d2f608 | 3007 | return extract_typed_floating (valaddr, type); |
c906108c | 3008 | } |
4ef30785 | 3009 | else if (code == TYPE_CODE_DECFLOAT) |
e17a4113 | 3010 | return decimal_to_doublest (valaddr, len, byte_order); |
c906108c SS |
3011 | else if (nosign) |
3012 | { | |
3013 | /* Unsigned -- be sure we compensate for signed LONGEST. */ | |
c906108c | 3014 | return (ULONGEST) unpack_long (type, valaddr); |
c906108c SS |
3015 | } |
3016 | else | |
3017 | { | |
3018 | /* Signed -- we are OK with unpack_long. */ | |
3019 | return unpack_long (type, valaddr); | |
3020 | } | |
3021 | } | |
3022 | ||
3023 | /* Unpack raw data (copied from debugee, target byte order) at VALADDR | |
3024 | as a CORE_ADDR, assuming the raw data is described by type TYPE. | |
3025 | We don't assume any alignment for the raw data. Return value is in | |
3026 | host byte order. | |
3027 | ||
3028 | If you want functions and arrays to be coerced to pointers, and | |
1aa20aa8 | 3029 | references to be dereferenced, call value_as_address() instead. |
c906108c SS |
3030 | |
3031 | C++: It is assumed that the front-end has taken care of | |
3032 | all matters concerning pointers to members. A pointer | |
3033 | to member which reaches here is considered to be equivalent | |
3034 | to an INT (or some size). After all, it is only an offset. */ | |
3035 | ||
3036 | CORE_ADDR | |
fc1a4b47 | 3037 | unpack_pointer (struct type *type, const gdb_byte *valaddr) |
c906108c SS |
3038 | { |
3039 | /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure | |
3040 | whether we want this to be true eventually. */ | |
3041 | return unpack_long (type, valaddr); | |
3042 | } | |
4478b372 | 3043 | |
c906108c | 3044 | \f |
1596cb5d | 3045 | /* Get the value of the FIELDNO'th field (which must be static) of |
686d4def | 3046 | TYPE. */ |
c906108c | 3047 | |
f23631e4 | 3048 | struct value * |
fba45db2 | 3049 | value_static_field (struct type *type, int fieldno) |
c906108c | 3050 | { |
948e66d9 DJ |
3051 | struct value *retval; |
3052 | ||
1596cb5d | 3053 | switch (TYPE_FIELD_LOC_KIND (type, fieldno)) |
c906108c | 3054 | { |
1596cb5d | 3055 | case FIELD_LOC_KIND_PHYSADDR: |
52e9fde8 SS |
3056 | retval = value_at_lazy (TYPE_FIELD_TYPE (type, fieldno), |
3057 | TYPE_FIELD_STATIC_PHYSADDR (type, fieldno)); | |
1596cb5d DE |
3058 | break; |
3059 | case FIELD_LOC_KIND_PHYSNAME: | |
c906108c | 3060 | { |
ff355380 | 3061 | const char *phys_name = TYPE_FIELD_STATIC_PHYSNAME (type, fieldno); |
581e13c1 | 3062 | /* TYPE_FIELD_NAME (type, fieldno); */ |
d12307c1 | 3063 | struct block_symbol sym = lookup_symbol (phys_name, 0, VAR_DOMAIN, 0); |
94af9270 | 3064 | |
d12307c1 | 3065 | if (sym.symbol == NULL) |
c906108c | 3066 | { |
a109c7c1 | 3067 | /* With some compilers, e.g. HP aCC, static data members are |
581e13c1 | 3068 | reported as non-debuggable symbols. */ |
3b7344d5 TT |
3069 | struct bound_minimal_symbol msym |
3070 | = lookup_minimal_symbol (phys_name, NULL, NULL); | |
a109c7c1 | 3071 | |
3b7344d5 | 3072 | if (!msym.minsym) |
686d4def | 3073 | return allocate_optimized_out_value (type); |
c906108c | 3074 | else |
c5aa993b | 3075 | { |
52e9fde8 | 3076 | retval = value_at_lazy (TYPE_FIELD_TYPE (type, fieldno), |
77e371c0 | 3077 | BMSYMBOL_VALUE_ADDRESS (msym)); |
c906108c SS |
3078 | } |
3079 | } | |
3080 | else | |
d12307c1 | 3081 | retval = value_of_variable (sym.symbol, sym.block); |
1596cb5d | 3082 | break; |
c906108c | 3083 | } |
1596cb5d | 3084 | default: |
f3574227 | 3085 | gdb_assert_not_reached ("unexpected field location kind"); |
1596cb5d DE |
3086 | } |
3087 | ||
948e66d9 | 3088 | return retval; |
c906108c SS |
3089 | } |
3090 | ||
4dfea560 DE |
3091 | /* Change the enclosing type of a value object VAL to NEW_ENCL_TYPE. |
3092 | You have to be careful here, since the size of the data area for the value | |
3093 | is set by the length of the enclosing type. So if NEW_ENCL_TYPE is bigger | |
3094 | than the old enclosing type, you have to allocate more space for the | |
3095 | data. */ | |
2b127877 | 3096 | |
4dfea560 DE |
3097 | void |
3098 | set_value_enclosing_type (struct value *val, struct type *new_encl_type) | |
2b127877 | 3099 | { |
5fdf6324 AB |
3100 | if (TYPE_LENGTH (new_encl_type) > TYPE_LENGTH (value_enclosing_type (val))) |
3101 | { | |
3102 | check_type_length_before_alloc (new_encl_type); | |
3103 | val->contents | |
3104 | = (gdb_byte *) xrealloc (val->contents, TYPE_LENGTH (new_encl_type)); | |
3105 | } | |
3e3d7139 JG |
3106 | |
3107 | val->enclosing_type = new_encl_type; | |
2b127877 DB |
3108 | } |
3109 | ||
c906108c SS |
3110 | /* Given a value ARG1 (offset by OFFSET bytes) |
3111 | of a struct or union type ARG_TYPE, | |
3112 | extract and return the value of one of its (non-static) fields. | |
581e13c1 | 3113 | FIELDNO says which field. */ |
c906108c | 3114 | |
f23631e4 | 3115 | struct value * |
6b850546 | 3116 | value_primitive_field (struct value *arg1, LONGEST offset, |
aa1ee363 | 3117 | int fieldno, struct type *arg_type) |
c906108c | 3118 | { |
f23631e4 | 3119 | struct value *v; |
52f0bd74 | 3120 | struct type *type; |
3ae385af SM |
3121 | struct gdbarch *arch = get_value_arch (arg1); |
3122 | int unit_size = gdbarch_addressable_memory_unit_size (arch); | |
c906108c | 3123 | |
f168693b | 3124 | arg_type = check_typedef (arg_type); |
c906108c | 3125 | type = TYPE_FIELD_TYPE (arg_type, fieldno); |
c54eabfa JK |
3126 | |
3127 | /* Call check_typedef on our type to make sure that, if TYPE | |
3128 | is a TYPE_CODE_TYPEDEF, its length is set to the length | |
3129 | of the target type instead of zero. However, we do not | |
3130 | replace the typedef type by the target type, because we want | |
3131 | to keep the typedef in order to be able to print the type | |
3132 | description correctly. */ | |
3133 | check_typedef (type); | |
c906108c | 3134 | |
691a26f5 | 3135 | if (TYPE_FIELD_BITSIZE (arg_type, fieldno)) |
c906108c | 3136 | { |
22c05d8a JK |
3137 | /* Handle packed fields. |
3138 | ||
3139 | Create a new value for the bitfield, with bitpos and bitsize | |
4ea48cc1 DJ |
3140 | set. If possible, arrange offset and bitpos so that we can |
3141 | do a single aligned read of the size of the containing type. | |
3142 | Otherwise, adjust offset to the byte containing the first | |
3143 | bit. Assume that the address, offset, and embedded offset | |
3144 | are sufficiently aligned. */ | |
22c05d8a | 3145 | |
6b850546 DT |
3146 | LONGEST bitpos = TYPE_FIELD_BITPOS (arg_type, fieldno); |
3147 | LONGEST container_bitsize = TYPE_LENGTH (type) * 8; | |
4ea48cc1 | 3148 | |
9a0dc9e3 PA |
3149 | v = allocate_value_lazy (type); |
3150 | v->bitsize = TYPE_FIELD_BITSIZE (arg_type, fieldno); | |
3151 | if ((bitpos % container_bitsize) + v->bitsize <= container_bitsize | |
3152 | && TYPE_LENGTH (type) <= (int) sizeof (LONGEST)) | |
3153 | v->bitpos = bitpos % container_bitsize; | |
4ea48cc1 | 3154 | else |
9a0dc9e3 PA |
3155 | v->bitpos = bitpos % 8; |
3156 | v->offset = (value_embedded_offset (arg1) | |
3157 | + offset | |
3158 | + (bitpos - v->bitpos) / 8); | |
3159 | set_value_parent (v, arg1); | |
3160 | if (!value_lazy (arg1)) | |
3161 | value_fetch_lazy (v); | |
c906108c SS |
3162 | } |
3163 | else if (fieldno < TYPE_N_BASECLASSES (arg_type)) | |
3164 | { | |
3165 | /* This field is actually a base subobject, so preserve the | |
39d37385 PA |
3166 | entire object's contents for later references to virtual |
3167 | bases, etc. */ | |
6b850546 | 3168 | LONGEST boffset; |
a4e2ee12 DJ |
3169 | |
3170 | /* Lazy register values with offsets are not supported. */ | |
3171 | if (VALUE_LVAL (arg1) == lval_register && value_lazy (arg1)) | |
3172 | value_fetch_lazy (arg1); | |
3173 | ||
9a0dc9e3 PA |
3174 | /* We special case virtual inheritance here because this |
3175 | requires access to the contents, which we would rather avoid | |
3176 | for references to ordinary fields of unavailable values. */ | |
3177 | if (BASETYPE_VIA_VIRTUAL (arg_type, fieldno)) | |
3178 | boffset = baseclass_offset (arg_type, fieldno, | |
3179 | value_contents (arg1), | |
3180 | value_embedded_offset (arg1), | |
3181 | value_address (arg1), | |
3182 | arg1); | |
c906108c | 3183 | else |
9a0dc9e3 | 3184 | boffset = TYPE_FIELD_BITPOS (arg_type, fieldno) / 8; |
691a26f5 | 3185 | |
9a0dc9e3 PA |
3186 | if (value_lazy (arg1)) |
3187 | v = allocate_value_lazy (value_enclosing_type (arg1)); | |
3188 | else | |
3189 | { | |
3190 | v = allocate_value (value_enclosing_type (arg1)); | |
3191 | value_contents_copy_raw (v, 0, arg1, 0, | |
3192 | TYPE_LENGTH (value_enclosing_type (arg1))); | |
3e3d7139 | 3193 | } |
9a0dc9e3 PA |
3194 | v->type = type; |
3195 | v->offset = value_offset (arg1); | |
3196 | v->embedded_offset = offset + value_embedded_offset (arg1) + boffset; | |
c906108c | 3197 | } |
9920b434 BH |
3198 | else if (NULL != TYPE_DATA_LOCATION (type)) |
3199 | { | |
3200 | /* Field is a dynamic data member. */ | |
3201 | ||
3202 | gdb_assert (0 == offset); | |
3203 | /* We expect an already resolved data location. */ | |
3204 | gdb_assert (PROP_CONST == TYPE_DATA_LOCATION_KIND (type)); | |
3205 | /* For dynamic data types defer memory allocation | |
3206 | until we actual access the value. */ | |
3207 | v = allocate_value_lazy (type); | |
3208 | } | |
c906108c SS |
3209 | else |
3210 | { | |
3211 | /* Plain old data member */ | |
3ae385af SM |
3212 | offset += (TYPE_FIELD_BITPOS (arg_type, fieldno) |
3213 | / (HOST_CHAR_BIT * unit_size)); | |
a4e2ee12 DJ |
3214 | |
3215 | /* Lazy register values with offsets are not supported. */ | |
3216 | if (VALUE_LVAL (arg1) == lval_register && value_lazy (arg1)) | |
3217 | value_fetch_lazy (arg1); | |
3218 | ||
9a0dc9e3 | 3219 | if (value_lazy (arg1)) |
3e3d7139 | 3220 | v = allocate_value_lazy (type); |
c906108c | 3221 | else |
3e3d7139 JG |
3222 | { |
3223 | v = allocate_value (type); | |
39d37385 PA |
3224 | value_contents_copy_raw (v, value_embedded_offset (v), |
3225 | arg1, value_embedded_offset (arg1) + offset, | |
3ae385af | 3226 | type_length_units (type)); |
3e3d7139 | 3227 | } |
df407dfe | 3228 | v->offset = (value_offset (arg1) + offset |
13c3b5f5 | 3229 | + value_embedded_offset (arg1)); |
c906108c | 3230 | } |
74bcbdf3 | 3231 | set_value_component_location (v, arg1); |
9ee8fc9d | 3232 | VALUE_REGNUM (v) = VALUE_REGNUM (arg1); |
0c16dd26 | 3233 | VALUE_FRAME_ID (v) = VALUE_FRAME_ID (arg1); |
c906108c SS |
3234 | return v; |
3235 | } | |
3236 | ||
3237 | /* Given a value ARG1 of a struct or union type, | |
3238 | extract and return the value of one of its (non-static) fields. | |
581e13c1 | 3239 | FIELDNO says which field. */ |
c906108c | 3240 | |
f23631e4 | 3241 | struct value * |
aa1ee363 | 3242 | value_field (struct value *arg1, int fieldno) |
c906108c | 3243 | { |
df407dfe | 3244 | return value_primitive_field (arg1, 0, fieldno, value_type (arg1)); |
c906108c SS |
3245 | } |
3246 | ||
3247 | /* Return a non-virtual function as a value. | |
3248 | F is the list of member functions which contains the desired method. | |
0478d61c FF |
3249 | J is an index into F which provides the desired method. |
3250 | ||
3251 | We only use the symbol for its address, so be happy with either a | |
581e13c1 | 3252 | full symbol or a minimal symbol. */ |
c906108c | 3253 | |
f23631e4 | 3254 | struct value * |
3e43a32a MS |
3255 | value_fn_field (struct value **arg1p, struct fn_field *f, |
3256 | int j, struct type *type, | |
6b850546 | 3257 | LONGEST offset) |
c906108c | 3258 | { |
f23631e4 | 3259 | struct value *v; |
52f0bd74 | 3260 | struct type *ftype = TYPE_FN_FIELD_TYPE (f, j); |
1d06ead6 | 3261 | const char *physname = TYPE_FN_FIELD_PHYSNAME (f, j); |
c906108c | 3262 | struct symbol *sym; |
7c7b6655 | 3263 | struct bound_minimal_symbol msym; |
c906108c | 3264 | |
d12307c1 | 3265 | sym = lookup_symbol (physname, 0, VAR_DOMAIN, 0).symbol; |
5ae326fa | 3266 | if (sym != NULL) |
0478d61c | 3267 | { |
7c7b6655 | 3268 | memset (&msym, 0, sizeof (msym)); |
5ae326fa AC |
3269 | } |
3270 | else | |
3271 | { | |
3272 | gdb_assert (sym == NULL); | |
7c7b6655 TT |
3273 | msym = lookup_bound_minimal_symbol (physname); |
3274 | if (msym.minsym == NULL) | |
5ae326fa | 3275 | return NULL; |
0478d61c FF |
3276 | } |
3277 | ||
c906108c | 3278 | v = allocate_value (ftype); |
0478d61c FF |
3279 | if (sym) |
3280 | { | |
42ae5230 | 3281 | set_value_address (v, BLOCK_START (SYMBOL_BLOCK_VALUE (sym))); |
0478d61c FF |
3282 | } |
3283 | else | |
3284 | { | |
bccdca4a UW |
3285 | /* The minimal symbol might point to a function descriptor; |
3286 | resolve it to the actual code address instead. */ | |
7c7b6655 | 3287 | struct objfile *objfile = msym.objfile; |
bccdca4a UW |
3288 | struct gdbarch *gdbarch = get_objfile_arch (objfile); |
3289 | ||
42ae5230 TT |
3290 | set_value_address (v, |
3291 | gdbarch_convert_from_func_ptr_addr | |
77e371c0 | 3292 | (gdbarch, BMSYMBOL_VALUE_ADDRESS (msym), ¤t_target)); |
0478d61c | 3293 | } |
c906108c SS |
3294 | |
3295 | if (arg1p) | |
c5aa993b | 3296 | { |
df407dfe | 3297 | if (type != value_type (*arg1p)) |
c5aa993b JM |
3298 | *arg1p = value_ind (value_cast (lookup_pointer_type (type), |
3299 | value_addr (*arg1p))); | |
3300 | ||
070ad9f0 | 3301 | /* Move the `this' pointer according to the offset. |
581e13c1 | 3302 | VALUE_OFFSET (*arg1p) += offset; */ |
c906108c SS |
3303 | } |
3304 | ||
3305 | return v; | |
3306 | } | |
3307 | ||
c906108c | 3308 | \f |
c906108c | 3309 | |
4875ffdb PA |
3310 | /* Unpack a bitfield of the specified FIELD_TYPE, from the object at |
3311 | VALADDR, and store the result in *RESULT. | |
3312 | The bitfield starts at BITPOS bits and contains BITSIZE bits. | |
c906108c | 3313 | |
4875ffdb PA |
3314 | Extracting bits depends on endianness of the machine. Compute the |
3315 | number of least significant bits to discard. For big endian machines, | |
3316 | we compute the total number of bits in the anonymous object, subtract | |
3317 | off the bit count from the MSB of the object to the MSB of the | |
3318 | bitfield, then the size of the bitfield, which leaves the LSB discard | |
3319 | count. For little endian machines, the discard count is simply the | |
3320 | number of bits from the LSB of the anonymous object to the LSB of the | |
3321 | bitfield. | |
3322 | ||
3323 | If the field is signed, we also do sign extension. */ | |
3324 | ||
3325 | static LONGEST | |
3326 | unpack_bits_as_long (struct type *field_type, const gdb_byte *valaddr, | |
6b850546 | 3327 | LONGEST bitpos, LONGEST bitsize) |
c906108c | 3328 | { |
4ea48cc1 | 3329 | enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (field_type)); |
c906108c SS |
3330 | ULONGEST val; |
3331 | ULONGEST valmask; | |
c906108c | 3332 | int lsbcount; |
6b850546 DT |
3333 | LONGEST bytes_read; |
3334 | LONGEST read_offset; | |
c906108c | 3335 | |
4a76eae5 DJ |
3336 | /* Read the minimum number of bytes required; there may not be |
3337 | enough bytes to read an entire ULONGEST. */ | |
f168693b | 3338 | field_type = check_typedef (field_type); |
4a76eae5 DJ |
3339 | if (bitsize) |
3340 | bytes_read = ((bitpos % 8) + bitsize + 7) / 8; | |
3341 | else | |
3342 | bytes_read = TYPE_LENGTH (field_type); | |
3343 | ||
5467c6c8 PA |
3344 | read_offset = bitpos / 8; |
3345 | ||
4875ffdb | 3346 | val = extract_unsigned_integer (valaddr + read_offset, |
4a76eae5 | 3347 | bytes_read, byte_order); |
c906108c | 3348 | |
581e13c1 | 3349 | /* Extract bits. See comment above. */ |
c906108c | 3350 | |
4ea48cc1 | 3351 | if (gdbarch_bits_big_endian (get_type_arch (field_type))) |
4a76eae5 | 3352 | lsbcount = (bytes_read * 8 - bitpos % 8 - bitsize); |
c906108c SS |
3353 | else |
3354 | lsbcount = (bitpos % 8); | |
3355 | val >>= lsbcount; | |
3356 | ||
3357 | /* If the field does not entirely fill a LONGEST, then zero the sign bits. | |
581e13c1 | 3358 | If the field is signed, and is negative, then sign extend. */ |
c906108c SS |
3359 | |
3360 | if ((bitsize > 0) && (bitsize < 8 * (int) sizeof (val))) | |
3361 | { | |
3362 | valmask = (((ULONGEST) 1) << bitsize) - 1; | |
3363 | val &= valmask; | |
3364 | if (!TYPE_UNSIGNED (field_type)) | |
3365 | { | |
3366 | if (val & (valmask ^ (valmask >> 1))) | |
3367 | { | |
3368 | val |= ~valmask; | |
3369 | } | |
3370 | } | |
3371 | } | |
5467c6c8 | 3372 | |
4875ffdb | 3373 | return val; |
5467c6c8 PA |
3374 | } |
3375 | ||
3376 | /* Unpack a field FIELDNO of the specified TYPE, from the object at | |
3377 | VALADDR + EMBEDDED_OFFSET. VALADDR points to the contents of | |
3378 | ORIGINAL_VALUE, which must not be NULL. See | |
3379 | unpack_value_bits_as_long for more details. */ | |
3380 | ||
3381 | int | |
3382 | unpack_value_field_as_long (struct type *type, const gdb_byte *valaddr, | |
6b850546 | 3383 | LONGEST embedded_offset, int fieldno, |
5467c6c8 PA |
3384 | const struct value *val, LONGEST *result) |
3385 | { | |
4875ffdb PA |
3386 | int bitpos = TYPE_FIELD_BITPOS (type, fieldno); |
3387 | int bitsize = TYPE_FIELD_BITSIZE (type, fieldno); | |
3388 | struct type *field_type = TYPE_FIELD_TYPE (type, fieldno); | |
3389 | int bit_offset; | |
3390 | ||
5467c6c8 PA |
3391 | gdb_assert (val != NULL); |
3392 | ||
4875ffdb PA |
3393 | bit_offset = embedded_offset * TARGET_CHAR_BIT + bitpos; |
3394 | if (value_bits_any_optimized_out (val, bit_offset, bitsize) | |
3395 | || !value_bits_available (val, bit_offset, bitsize)) | |
3396 | return 0; | |
3397 | ||
3398 | *result = unpack_bits_as_long (field_type, valaddr + embedded_offset, | |
3399 | bitpos, bitsize); | |
3400 | return 1; | |
5467c6c8 PA |
3401 | } |
3402 | ||
3403 | /* Unpack a field FIELDNO of the specified TYPE, from the anonymous | |
4875ffdb | 3404 | object at VALADDR. See unpack_bits_as_long for more details. */ |
5467c6c8 PA |
3405 | |
3406 | LONGEST | |
3407 | unpack_field_as_long (struct type *type, const gdb_byte *valaddr, int fieldno) | |
3408 | { | |
4875ffdb PA |
3409 | int bitpos = TYPE_FIELD_BITPOS (type, fieldno); |
3410 | int bitsize = TYPE_FIELD_BITSIZE (type, fieldno); | |
3411 | struct type *field_type = TYPE_FIELD_TYPE (type, fieldno); | |
5467c6c8 | 3412 | |
4875ffdb PA |
3413 | return unpack_bits_as_long (field_type, valaddr, bitpos, bitsize); |
3414 | } | |
3415 | ||
3416 | /* Unpack a bitfield of BITSIZE bits found at BITPOS in the object at | |
3417 | VALADDR + EMBEDDEDOFFSET that has the type of DEST_VAL and store | |
3418 | the contents in DEST_VAL, zero or sign extending if the type of | |
3419 | DEST_VAL is wider than BITSIZE. VALADDR points to the contents of | |
3420 | VAL. If the VAL's contents required to extract the bitfield from | |
3421 | are unavailable/optimized out, DEST_VAL is correspondingly | |
3422 | marked unavailable/optimized out. */ | |
3423 | ||
bb9d5f81 | 3424 | void |
4875ffdb | 3425 | unpack_value_bitfield (struct value *dest_val, |
6b850546 DT |
3426 | LONGEST bitpos, LONGEST bitsize, |
3427 | const gdb_byte *valaddr, LONGEST embedded_offset, | |
4875ffdb PA |
3428 | const struct value *val) |
3429 | { | |
3430 | enum bfd_endian byte_order; | |
3431 | int src_bit_offset; | |
3432 | int dst_bit_offset; | |
4875ffdb PA |
3433 | struct type *field_type = value_type (dest_val); |
3434 | ||
4875ffdb | 3435 | byte_order = gdbarch_byte_order (get_type_arch (field_type)); |
e5ca03b4 PA |
3436 | |
3437 | /* First, unpack and sign extend the bitfield as if it was wholly | |
3438 | valid. Optimized out/unavailable bits are read as zero, but | |
3439 | that's OK, as they'll end up marked below. If the VAL is | |
3440 | wholly-invalid we may have skipped allocating its contents, | |
3441 | though. See allocate_optimized_out_value. */ | |
3442 | if (valaddr != NULL) | |
3443 | { | |
3444 | LONGEST num; | |
3445 | ||
3446 | num = unpack_bits_as_long (field_type, valaddr + embedded_offset, | |
3447 | bitpos, bitsize); | |
3448 | store_signed_integer (value_contents_raw (dest_val), | |
3449 | TYPE_LENGTH (field_type), byte_order, num); | |
3450 | } | |
4875ffdb PA |
3451 | |
3452 | /* Now copy the optimized out / unavailability ranges to the right | |
3453 | bits. */ | |
3454 | src_bit_offset = embedded_offset * TARGET_CHAR_BIT + bitpos; | |
3455 | if (byte_order == BFD_ENDIAN_BIG) | |
3456 | dst_bit_offset = TYPE_LENGTH (field_type) * TARGET_CHAR_BIT - bitsize; | |
3457 | else | |
3458 | dst_bit_offset = 0; | |
3459 | value_ranges_copy_adjusted (dest_val, dst_bit_offset, | |
3460 | val, src_bit_offset, bitsize); | |
5467c6c8 PA |
3461 | } |
3462 | ||
3463 | /* Return a new value with type TYPE, which is FIELDNO field of the | |
3464 | object at VALADDR + EMBEDDEDOFFSET. VALADDR points to the contents | |
3465 | of VAL. If the VAL's contents required to extract the bitfield | |
4875ffdb PA |
3466 | from are unavailable/optimized out, the new value is |
3467 | correspondingly marked unavailable/optimized out. */ | |
5467c6c8 PA |
3468 | |
3469 | struct value * | |
3470 | value_field_bitfield (struct type *type, int fieldno, | |
3471 | const gdb_byte *valaddr, | |
6b850546 | 3472 | LONGEST embedded_offset, const struct value *val) |
5467c6c8 | 3473 | { |
4875ffdb PA |
3474 | int bitpos = TYPE_FIELD_BITPOS (type, fieldno); |
3475 | int bitsize = TYPE_FIELD_BITSIZE (type, fieldno); | |
3476 | struct value *res_val = allocate_value (TYPE_FIELD_TYPE (type, fieldno)); | |
5467c6c8 | 3477 | |
4875ffdb PA |
3478 | unpack_value_bitfield (res_val, bitpos, bitsize, |
3479 | valaddr, embedded_offset, val); | |
3480 | ||
3481 | return res_val; | |
4ea48cc1 DJ |
3482 | } |
3483 | ||
c906108c SS |
3484 | /* Modify the value of a bitfield. ADDR points to a block of memory in |
3485 | target byte order; the bitfield starts in the byte pointed to. FIELDVAL | |
3486 | is the desired value of the field, in host byte order. BITPOS and BITSIZE | |
581e13c1 | 3487 | indicate which bits (in target bit order) comprise the bitfield. |
19f220c3 | 3488 | Requires 0 < BITSIZE <= lbits, 0 <= BITPOS % 8 + BITSIZE <= lbits, and |
f4e88c8e | 3489 | 0 <= BITPOS, where lbits is the size of a LONGEST in bits. */ |
c906108c SS |
3490 | |
3491 | void | |
50810684 | 3492 | modify_field (struct type *type, gdb_byte *addr, |
6b850546 | 3493 | LONGEST fieldval, LONGEST bitpos, LONGEST bitsize) |
c906108c | 3494 | { |
e17a4113 | 3495 | enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); |
f4e88c8e PH |
3496 | ULONGEST oword; |
3497 | ULONGEST mask = (ULONGEST) -1 >> (8 * sizeof (ULONGEST) - bitsize); | |
6b850546 | 3498 | LONGEST bytesize; |
19f220c3 JK |
3499 | |
3500 | /* Normalize BITPOS. */ | |
3501 | addr += bitpos / 8; | |
3502 | bitpos %= 8; | |
c906108c SS |
3503 | |
3504 | /* If a negative fieldval fits in the field in question, chop | |
3505 | off the sign extension bits. */ | |
f4e88c8e PH |
3506 | if ((~fieldval & ~(mask >> 1)) == 0) |
3507 | fieldval &= mask; | |
c906108c SS |
3508 | |
3509 | /* Warn if value is too big to fit in the field in question. */ | |
f4e88c8e | 3510 | if (0 != (fieldval & ~mask)) |
c906108c SS |
3511 | { |
3512 | /* FIXME: would like to include fieldval in the message, but | |
c5aa993b | 3513 | we don't have a sprintf_longest. */ |
6b850546 | 3514 | warning (_("Value does not fit in %s bits."), plongest (bitsize)); |
c906108c SS |
3515 | |
3516 | /* Truncate it, otherwise adjoining fields may be corrupted. */ | |
f4e88c8e | 3517 | fieldval &= mask; |
c906108c SS |
3518 | } |
3519 | ||
19f220c3 JK |
3520 | /* Ensure no bytes outside of the modified ones get accessed as it may cause |
3521 | false valgrind reports. */ | |
3522 | ||
3523 | bytesize = (bitpos + bitsize + 7) / 8; | |
3524 | oword = extract_unsigned_integer (addr, bytesize, byte_order); | |
c906108c SS |
3525 | |
3526 | /* Shifting for bit field depends on endianness of the target machine. */ | |
50810684 | 3527 | if (gdbarch_bits_big_endian (get_type_arch (type))) |
19f220c3 | 3528 | bitpos = bytesize * 8 - bitpos - bitsize; |
c906108c | 3529 | |
f4e88c8e | 3530 | oword &= ~(mask << bitpos); |
c906108c SS |
3531 | oword |= fieldval << bitpos; |
3532 | ||
19f220c3 | 3533 | store_unsigned_integer (addr, bytesize, byte_order, oword); |
c906108c SS |
3534 | } |
3535 | \f | |
14d06750 | 3536 | /* Pack NUM into BUF using a target format of TYPE. */ |
c906108c | 3537 | |
14d06750 DJ |
3538 | void |
3539 | pack_long (gdb_byte *buf, struct type *type, LONGEST num) | |
c906108c | 3540 | { |
e17a4113 | 3541 | enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); |
6b850546 | 3542 | LONGEST len; |
14d06750 DJ |
3543 | |
3544 | type = check_typedef (type); | |
c906108c SS |
3545 | len = TYPE_LENGTH (type); |
3546 | ||
14d06750 | 3547 | switch (TYPE_CODE (type)) |
c906108c | 3548 | { |
c906108c SS |
3549 | case TYPE_CODE_INT: |
3550 | case TYPE_CODE_CHAR: | |
3551 | case TYPE_CODE_ENUM: | |
4f2aea11 | 3552 | case TYPE_CODE_FLAGS: |
c906108c SS |
3553 | case TYPE_CODE_BOOL: |
3554 | case TYPE_CODE_RANGE: | |
0d5de010 | 3555 | case TYPE_CODE_MEMBERPTR: |
e17a4113 | 3556 | store_signed_integer (buf, len, byte_order, num); |
c906108c | 3557 | break; |
c5aa993b | 3558 | |
c906108c SS |
3559 | case TYPE_CODE_REF: |
3560 | case TYPE_CODE_PTR: | |
14d06750 | 3561 | store_typed_address (buf, type, (CORE_ADDR) num); |
c906108c | 3562 | break; |
c5aa993b | 3563 | |
c906108c | 3564 | default: |
14d06750 DJ |
3565 | error (_("Unexpected type (%d) encountered for integer constant."), |
3566 | TYPE_CODE (type)); | |
c906108c | 3567 | } |
14d06750 DJ |
3568 | } |
3569 | ||
3570 | ||
595939de PM |
3571 | /* Pack NUM into BUF using a target format of TYPE. */ |
3572 | ||
70221824 | 3573 | static void |
595939de PM |
3574 | pack_unsigned_long (gdb_byte *buf, struct type *type, ULONGEST num) |
3575 | { | |
6b850546 | 3576 | LONGEST len; |
595939de PM |
3577 | enum bfd_endian byte_order; |
3578 | ||
3579 | type = check_typedef (type); | |
3580 | len = TYPE_LENGTH (type); | |
3581 | byte_order = gdbarch_byte_order (get_type_arch (type)); | |
3582 | ||
3583 | switch (TYPE_CODE (type)) | |
3584 | { | |
3585 | case TYPE_CODE_INT: | |
3586 | case TYPE_CODE_CHAR: | |
3587 | case TYPE_CODE_ENUM: | |
3588 | case TYPE_CODE_FLAGS: | |
3589 | case TYPE_CODE_BOOL: | |
3590 | case TYPE_CODE_RANGE: | |
3591 | case TYPE_CODE_MEMBERPTR: | |
3592 | store_unsigned_integer (buf, len, byte_order, num); | |
3593 | break; | |
3594 | ||
3595 | case TYPE_CODE_REF: | |
3596 | case TYPE_CODE_PTR: | |
3597 | store_typed_address (buf, type, (CORE_ADDR) num); | |
3598 | break; | |
3599 | ||
3600 | default: | |
3e43a32a MS |
3601 | error (_("Unexpected type (%d) encountered " |
3602 | "for unsigned integer constant."), | |
595939de PM |
3603 | TYPE_CODE (type)); |
3604 | } | |
3605 | } | |
3606 | ||
3607 | ||
14d06750 DJ |
3608 | /* Convert C numbers into newly allocated values. */ |
3609 | ||
3610 | struct value * | |
3611 | value_from_longest (struct type *type, LONGEST num) | |
3612 | { | |
3613 | struct value *val = allocate_value (type); | |
3614 | ||
3615 | pack_long (value_contents_raw (val), type, num); | |
c906108c SS |
3616 | return val; |
3617 | } | |
3618 | ||
4478b372 | 3619 | |
595939de PM |
3620 | /* Convert C unsigned numbers into newly allocated values. */ |
3621 | ||
3622 | struct value * | |
3623 | value_from_ulongest (struct type *type, ULONGEST num) | |
3624 | { | |
3625 | struct value *val = allocate_value (type); | |
3626 | ||
3627 | pack_unsigned_long (value_contents_raw (val), type, num); | |
3628 | ||
3629 | return val; | |
3630 | } | |
3631 | ||
3632 | ||
4478b372 | 3633 | /* Create a value representing a pointer of type TYPE to the address |
cb417230 | 3634 | ADDR. */ |
80180f79 | 3635 | |
f23631e4 | 3636 | struct value * |
4478b372 JB |
3637 | value_from_pointer (struct type *type, CORE_ADDR addr) |
3638 | { | |
cb417230 | 3639 | struct value *val = allocate_value (type); |
a109c7c1 | 3640 | |
80180f79 | 3641 | store_typed_address (value_contents_raw (val), |
cb417230 | 3642 | check_typedef (type), addr); |
4478b372 JB |
3643 | return val; |
3644 | } | |
3645 | ||
3646 | ||
012370f6 TT |
3647 | /* Create a value of type TYPE whose contents come from VALADDR, if it |
3648 | is non-null, and whose memory address (in the inferior) is | |
3649 | ADDRESS. The type of the created value may differ from the passed | |
3650 | type TYPE. Make sure to retrieve values new type after this call. | |
3651 | Note that TYPE is not passed through resolve_dynamic_type; this is | |
3652 | a special API intended for use only by Ada. */ | |
3653 | ||
3654 | struct value * | |
3655 | value_from_contents_and_address_unresolved (struct type *type, | |
3656 | const gdb_byte *valaddr, | |
3657 | CORE_ADDR address) | |
3658 | { | |
3659 | struct value *v; | |
3660 | ||
3661 | if (valaddr == NULL) | |
3662 | v = allocate_value_lazy (type); | |
3663 | else | |
3664 | v = value_from_contents (type, valaddr); | |
3665 | set_value_address (v, address); | |
3666 | VALUE_LVAL (v) = lval_memory; | |
3667 | return v; | |
3668 | } | |
3669 | ||
8acb6b92 TT |
3670 | /* Create a value of type TYPE whose contents come from VALADDR, if it |
3671 | is non-null, and whose memory address (in the inferior) is | |
80180f79 SA |
3672 | ADDRESS. The type of the created value may differ from the passed |
3673 | type TYPE. Make sure to retrieve values new type after this call. */ | |
8acb6b92 TT |
3674 | |
3675 | struct value * | |
3676 | value_from_contents_and_address (struct type *type, | |
3677 | const gdb_byte *valaddr, | |
3678 | CORE_ADDR address) | |
3679 | { | |
c3345124 | 3680 | struct type *resolved_type = resolve_dynamic_type (type, valaddr, address); |
d36430db | 3681 | struct type *resolved_type_no_typedef = check_typedef (resolved_type); |
41e8491f | 3682 | struct value *v; |
a109c7c1 | 3683 | |
8acb6b92 | 3684 | if (valaddr == NULL) |
80180f79 | 3685 | v = allocate_value_lazy (resolved_type); |
8acb6b92 | 3686 | else |
80180f79 | 3687 | v = value_from_contents (resolved_type, valaddr); |
d36430db JB |
3688 | if (TYPE_DATA_LOCATION (resolved_type_no_typedef) != NULL |
3689 | && TYPE_DATA_LOCATION_KIND (resolved_type_no_typedef) == PROP_CONST) | |
3690 | address = TYPE_DATA_LOCATION_ADDR (resolved_type_no_typedef); | |
42ae5230 | 3691 | set_value_address (v, address); |
33d502b4 | 3692 | VALUE_LVAL (v) = lval_memory; |
8acb6b92 TT |
3693 | return v; |
3694 | } | |
3695 | ||
8a9b8146 TT |
3696 | /* Create a value of type TYPE holding the contents CONTENTS. |
3697 | The new value is `not_lval'. */ | |
3698 | ||
3699 | struct value * | |
3700 | value_from_contents (struct type *type, const gdb_byte *contents) | |
3701 | { | |
3702 | struct value *result; | |
3703 | ||
3704 | result = allocate_value (type); | |
3705 | memcpy (value_contents_raw (result), contents, TYPE_LENGTH (type)); | |
3706 | return result; | |
3707 | } | |
3708 | ||
f23631e4 | 3709 | struct value * |
fba45db2 | 3710 | value_from_double (struct type *type, DOUBLEST num) |
c906108c | 3711 | { |
f23631e4 | 3712 | struct value *val = allocate_value (type); |
c906108c | 3713 | struct type *base_type = check_typedef (type); |
52f0bd74 | 3714 | enum type_code code = TYPE_CODE (base_type); |
c906108c SS |
3715 | |
3716 | if (code == TYPE_CODE_FLT) | |
3717 | { | |
990a07ab | 3718 | store_typed_floating (value_contents_raw (val), base_type, num); |
c906108c SS |
3719 | } |
3720 | else | |
8a3fe4f8 | 3721 | error (_("Unexpected type encountered for floating constant.")); |
c906108c SS |
3722 | |
3723 | return val; | |
3724 | } | |
994b9211 | 3725 | |
27bc4d80 | 3726 | struct value * |
4ef30785 | 3727 | value_from_decfloat (struct type *type, const gdb_byte *dec) |
27bc4d80 TJB |
3728 | { |
3729 | struct value *val = allocate_value (type); | |
27bc4d80 | 3730 | |
4ef30785 | 3731 | memcpy (value_contents_raw (val), dec, TYPE_LENGTH (type)); |
27bc4d80 TJB |
3732 | return val; |
3733 | } | |
3734 | ||
3bd0f5ef MS |
3735 | /* Extract a value from the history file. Input will be of the form |
3736 | $digits or $$digits. See block comment above 'write_dollar_variable' | |
3737 | for details. */ | |
3738 | ||
3739 | struct value * | |
e799154c | 3740 | value_from_history_ref (const char *h, const char **endp) |
3bd0f5ef MS |
3741 | { |
3742 | int index, len; | |
3743 | ||
3744 | if (h[0] == '$') | |
3745 | len = 1; | |
3746 | else | |
3747 | return NULL; | |
3748 | ||
3749 | if (h[1] == '$') | |
3750 | len = 2; | |
3751 | ||
3752 | /* Find length of numeral string. */ | |
3753 | for (; isdigit (h[len]); len++) | |
3754 | ; | |
3755 | ||
3756 | /* Make sure numeral string is not part of an identifier. */ | |
3757 | if (h[len] == '_' || isalpha (h[len])) | |
3758 | return NULL; | |
3759 | ||
3760 | /* Now collect the index value. */ | |
3761 | if (h[1] == '$') | |
3762 | { | |
3763 | if (len == 2) | |
3764 | { | |
3765 | /* For some bizarre reason, "$$" is equivalent to "$$1", | |
3766 | rather than to "$$0" as it ought to be! */ | |
3767 | index = -1; | |
3768 | *endp += len; | |
3769 | } | |
3770 | else | |
e799154c TT |
3771 | { |
3772 | char *local_end; | |
3773 | ||
3774 | index = -strtol (&h[2], &local_end, 10); | |
3775 | *endp = local_end; | |
3776 | } | |
3bd0f5ef MS |
3777 | } |
3778 | else | |
3779 | { | |
3780 | if (len == 1) | |
3781 | { | |
3782 | /* "$" is equivalent to "$0". */ | |
3783 | index = 0; | |
3784 | *endp += len; | |
3785 | } | |
3786 | else | |
e799154c TT |
3787 | { |
3788 | char *local_end; | |
3789 | ||
3790 | index = strtol (&h[1], &local_end, 10); | |
3791 | *endp = local_end; | |
3792 | } | |
3bd0f5ef MS |
3793 | } |
3794 | ||
3795 | return access_value_history (index); | |
3796 | } | |
3797 | ||
a471c594 JK |
3798 | struct value * |
3799 | coerce_ref_if_computed (const struct value *arg) | |
3800 | { | |
3801 | const struct lval_funcs *funcs; | |
3802 | ||
3803 | if (TYPE_CODE (check_typedef (value_type (arg))) != TYPE_CODE_REF) | |
3804 | return NULL; | |
3805 | ||
3806 | if (value_lval_const (arg) != lval_computed) | |
3807 | return NULL; | |
3808 | ||
3809 | funcs = value_computed_funcs (arg); | |
3810 | if (funcs->coerce_ref == NULL) | |
3811 | return NULL; | |
3812 | ||
3813 | return funcs->coerce_ref (arg); | |
3814 | } | |
3815 | ||
dfcee124 AG |
3816 | /* Look at value.h for description. */ |
3817 | ||
3818 | struct value * | |
3819 | readjust_indirect_value_type (struct value *value, struct type *enc_type, | |
4bf7b526 MG |
3820 | const struct type *original_type, |
3821 | const struct value *original_value) | |
dfcee124 AG |
3822 | { |
3823 | /* Re-adjust type. */ | |
3824 | deprecated_set_value_type (value, TYPE_TARGET_TYPE (original_type)); | |
3825 | ||
3826 | /* Add embedding info. */ | |
3827 | set_value_enclosing_type (value, enc_type); | |
3828 | set_value_embedded_offset (value, value_pointed_to_offset (original_value)); | |
3829 | ||
3830 | /* We may be pointing to an object of some derived type. */ | |
3831 | return value_full_object (value, NULL, 0, 0, 0); | |
3832 | } | |
3833 | ||
994b9211 AC |
3834 | struct value * |
3835 | coerce_ref (struct value *arg) | |
3836 | { | |
df407dfe | 3837 | struct type *value_type_arg_tmp = check_typedef (value_type (arg)); |
a471c594 | 3838 | struct value *retval; |
dfcee124 | 3839 | struct type *enc_type; |
a109c7c1 | 3840 | |
a471c594 JK |
3841 | retval = coerce_ref_if_computed (arg); |
3842 | if (retval) | |
3843 | return retval; | |
3844 | ||
3845 | if (TYPE_CODE (value_type_arg_tmp) != TYPE_CODE_REF) | |
3846 | return arg; | |
3847 | ||
dfcee124 AG |
3848 | enc_type = check_typedef (value_enclosing_type (arg)); |
3849 | enc_type = TYPE_TARGET_TYPE (enc_type); | |
3850 | ||
3851 | retval = value_at_lazy (enc_type, | |
3852 | unpack_pointer (value_type (arg), | |
3853 | value_contents (arg))); | |
9f1f738a | 3854 | enc_type = value_type (retval); |
dfcee124 AG |
3855 | return readjust_indirect_value_type (retval, enc_type, |
3856 | value_type_arg_tmp, arg); | |
994b9211 AC |
3857 | } |
3858 | ||
3859 | struct value * | |
3860 | coerce_array (struct value *arg) | |
3861 | { | |
f3134b88 TT |
3862 | struct type *type; |
3863 | ||
994b9211 | 3864 | arg = coerce_ref (arg); |
f3134b88 TT |
3865 | type = check_typedef (value_type (arg)); |
3866 | ||
3867 | switch (TYPE_CODE (type)) | |
3868 | { | |
3869 | case TYPE_CODE_ARRAY: | |
7346b668 | 3870 | if (!TYPE_VECTOR (type) && current_language->c_style_arrays) |
f3134b88 TT |
3871 | arg = value_coerce_array (arg); |
3872 | break; | |
3873 | case TYPE_CODE_FUNC: | |
3874 | arg = value_coerce_function (arg); | |
3875 | break; | |
3876 | } | |
994b9211 AC |
3877 | return arg; |
3878 | } | |
c906108c | 3879 | \f |
c906108c | 3880 | |
bbfdfe1c DM |
3881 | /* Return the return value convention that will be used for the |
3882 | specified type. */ | |
3883 | ||
3884 | enum return_value_convention | |
3885 | struct_return_convention (struct gdbarch *gdbarch, | |
3886 | struct value *function, struct type *value_type) | |
3887 | { | |
3888 | enum type_code code = TYPE_CODE (value_type); | |
3889 | ||
3890 | if (code == TYPE_CODE_ERROR) | |
3891 | error (_("Function return type unknown.")); | |
3892 | ||
3893 | /* Probe the architecture for the return-value convention. */ | |
3894 | return gdbarch_return_value (gdbarch, function, value_type, | |
3895 | NULL, NULL, NULL); | |
3896 | } | |
3897 | ||
48436ce6 AC |
3898 | /* Return true if the function returning the specified type is using |
3899 | the convention of returning structures in memory (passing in the | |
82585c72 | 3900 | address as a hidden first parameter). */ |
c906108c SS |
3901 | |
3902 | int | |
d80b854b | 3903 | using_struct_return (struct gdbarch *gdbarch, |
6a3a010b | 3904 | struct value *function, struct type *value_type) |
c906108c | 3905 | { |
bbfdfe1c | 3906 | if (TYPE_CODE (value_type) == TYPE_CODE_VOID) |
667e784f | 3907 | /* A void return value is never in memory. See also corresponding |
44e5158b | 3908 | code in "print_return_value". */ |
667e784f AC |
3909 | return 0; |
3910 | ||
bbfdfe1c | 3911 | return (struct_return_convention (gdbarch, function, value_type) |
31db7b6c | 3912 | != RETURN_VALUE_REGISTER_CONVENTION); |
c906108c SS |
3913 | } |
3914 | ||
42be36b3 CT |
3915 | /* Set the initialized field in a value struct. */ |
3916 | ||
3917 | void | |
3918 | set_value_initialized (struct value *val, int status) | |
3919 | { | |
3920 | val->initialized = status; | |
3921 | } | |
3922 | ||
3923 | /* Return the initialized field in a value struct. */ | |
3924 | ||
3925 | int | |
4bf7b526 | 3926 | value_initialized (const struct value *val) |
42be36b3 CT |
3927 | { |
3928 | return val->initialized; | |
3929 | } | |
3930 | ||
a844296a SM |
3931 | /* Load the actual content of a lazy value. Fetch the data from the |
3932 | user's process and clear the lazy flag to indicate that the data in | |
3933 | the buffer is valid. | |
a58e2656 AB |
3934 | |
3935 | If the value is zero-length, we avoid calling read_memory, which | |
3936 | would abort. We mark the value as fetched anyway -- all 0 bytes of | |
a844296a | 3937 | it. */ |
a58e2656 | 3938 | |
a844296a | 3939 | void |
a58e2656 AB |
3940 | value_fetch_lazy (struct value *val) |
3941 | { | |
3942 | gdb_assert (value_lazy (val)); | |
3943 | allocate_value_contents (val); | |
9a0dc9e3 PA |
3944 | /* A value is either lazy, or fully fetched. The |
3945 | availability/validity is only established as we try to fetch a | |
3946 | value. */ | |
3947 | gdb_assert (VEC_empty (range_s, val->optimized_out)); | |
3948 | gdb_assert (VEC_empty (range_s, val->unavailable)); | |
a58e2656 AB |
3949 | if (value_bitsize (val)) |
3950 | { | |
3951 | /* To read a lazy bitfield, read the entire enclosing value. This | |
3952 | prevents reading the same block of (possibly volatile) memory once | |
3953 | per bitfield. It would be even better to read only the containing | |
3954 | word, but we have no way to record that just specific bits of a | |
3955 | value have been fetched. */ | |
3956 | struct type *type = check_typedef (value_type (val)); | |
a58e2656 | 3957 | struct value *parent = value_parent (val); |
a58e2656 | 3958 | |
b0c54aa5 AB |
3959 | if (value_lazy (parent)) |
3960 | value_fetch_lazy (parent); | |
3961 | ||
4875ffdb PA |
3962 | unpack_value_bitfield (val, |
3963 | value_bitpos (val), value_bitsize (val), | |
3964 | value_contents_for_printing (parent), | |
3965 | value_offset (val), parent); | |
a58e2656 AB |
3966 | } |
3967 | else if (VALUE_LVAL (val) == lval_memory) | |
3968 | { | |
3969 | CORE_ADDR addr = value_address (val); | |
3970 | struct type *type = check_typedef (value_enclosing_type (val)); | |
3971 | ||
3972 | if (TYPE_LENGTH (type)) | |
3973 | read_value_memory (val, 0, value_stack (val), | |
3974 | addr, value_contents_all_raw (val), | |
3ae385af | 3975 | type_length_units (type)); |
a58e2656 AB |
3976 | } |
3977 | else if (VALUE_LVAL (val) == lval_register) | |
3978 | { | |
3979 | struct frame_info *frame; | |
3980 | int regnum; | |
3981 | struct type *type = check_typedef (value_type (val)); | |
3982 | struct value *new_val = val, *mark = value_mark (); | |
3983 | ||
3984 | /* Offsets are not supported here; lazy register values must | |
3985 | refer to the entire register. */ | |
3986 | gdb_assert (value_offset (val) == 0); | |
3987 | ||
3988 | while (VALUE_LVAL (new_val) == lval_register && value_lazy (new_val)) | |
3989 | { | |
6eeee81c TT |
3990 | struct frame_id frame_id = VALUE_FRAME_ID (new_val); |
3991 | ||
3992 | frame = frame_find_by_id (frame_id); | |
a58e2656 AB |
3993 | regnum = VALUE_REGNUM (new_val); |
3994 | ||
3995 | gdb_assert (frame != NULL); | |
3996 | ||
3997 | /* Convertible register routines are used for multi-register | |
3998 | values and for interpretation in different types | |
3999 | (e.g. float or int from a double register). Lazy | |
4000 | register values should have the register's natural type, | |
4001 | so they do not apply. */ | |
4002 | gdb_assert (!gdbarch_convert_register_p (get_frame_arch (frame), | |
4003 | regnum, type)); | |
4004 | ||
4005 | new_val = get_frame_register_value (frame, regnum); | |
6eeee81c TT |
4006 | |
4007 | /* If we get another lazy lval_register value, it means the | |
4008 | register is found by reading it from the next frame. | |
4009 | get_frame_register_value should never return a value with | |
4010 | the frame id pointing to FRAME. If it does, it means we | |
4011 | either have two consecutive frames with the same frame id | |
4012 | in the frame chain, or some code is trying to unwind | |
4013 | behind get_prev_frame's back (e.g., a frame unwind | |
4014 | sniffer trying to unwind), bypassing its validations. In | |
4015 | any case, it should always be an internal error to end up | |
4016 | in this situation. */ | |
4017 | if (VALUE_LVAL (new_val) == lval_register | |
4018 | && value_lazy (new_val) | |
4019 | && frame_id_eq (VALUE_FRAME_ID (new_val), frame_id)) | |
4020 | internal_error (__FILE__, __LINE__, | |
4021 | _("infinite loop while fetching a register")); | |
a58e2656 AB |
4022 | } |
4023 | ||
4024 | /* If it's still lazy (for instance, a saved register on the | |
4025 | stack), fetch it. */ | |
4026 | if (value_lazy (new_val)) | |
4027 | value_fetch_lazy (new_val); | |
4028 | ||
9a0dc9e3 PA |
4029 | /* Copy the contents and the unavailability/optimized-out |
4030 | meta-data from NEW_VAL to VAL. */ | |
4031 | set_value_lazy (val, 0); | |
4032 | value_contents_copy (val, value_embedded_offset (val), | |
4033 | new_val, value_embedded_offset (new_val), | |
3ae385af | 4034 | type_length_units (type)); |
a58e2656 AB |
4035 | |
4036 | if (frame_debug) | |
4037 | { | |
4038 | struct gdbarch *gdbarch; | |
4039 | frame = frame_find_by_id (VALUE_FRAME_ID (val)); | |
4040 | regnum = VALUE_REGNUM (val); | |
4041 | gdbarch = get_frame_arch (frame); | |
4042 | ||
4043 | fprintf_unfiltered (gdb_stdlog, | |
4044 | "{ value_fetch_lazy " | |
4045 | "(frame=%d,regnum=%d(%s),...) ", | |
4046 | frame_relative_level (frame), regnum, | |
4047 | user_reg_map_regnum_to_name (gdbarch, regnum)); | |
4048 | ||
4049 | fprintf_unfiltered (gdb_stdlog, "->"); | |
4050 | if (value_optimized_out (new_val)) | |
f6c01fc5 AB |
4051 | { |
4052 | fprintf_unfiltered (gdb_stdlog, " "); | |
4053 | val_print_optimized_out (new_val, gdb_stdlog); | |
4054 | } | |
a58e2656 AB |
4055 | else |
4056 | { | |
4057 | int i; | |
4058 | const gdb_byte *buf = value_contents (new_val); | |
4059 | ||
4060 | if (VALUE_LVAL (new_val) == lval_register) | |
4061 | fprintf_unfiltered (gdb_stdlog, " register=%d", | |
4062 | VALUE_REGNUM (new_val)); | |
4063 | else if (VALUE_LVAL (new_val) == lval_memory) | |
4064 | fprintf_unfiltered (gdb_stdlog, " address=%s", | |
4065 | paddress (gdbarch, | |
4066 | value_address (new_val))); | |
4067 | else | |
4068 | fprintf_unfiltered (gdb_stdlog, " computed"); | |
4069 | ||
4070 | fprintf_unfiltered (gdb_stdlog, " bytes="); | |
4071 | fprintf_unfiltered (gdb_stdlog, "["); | |
4072 | for (i = 0; i < register_size (gdbarch, regnum); i++) | |
4073 | fprintf_unfiltered (gdb_stdlog, "%02x", buf[i]); | |
4074 | fprintf_unfiltered (gdb_stdlog, "]"); | |
4075 | } | |
4076 | ||
4077 | fprintf_unfiltered (gdb_stdlog, " }\n"); | |
4078 | } | |
4079 | ||
4080 | /* Dispose of the intermediate values. This prevents | |
4081 | watchpoints from trying to watch the saved frame pointer. */ | |
4082 | value_free_to_mark (mark); | |
4083 | } | |
4084 | else if (VALUE_LVAL (val) == lval_computed | |
4085 | && value_computed_funcs (val)->read != NULL) | |
4086 | value_computed_funcs (val)->read (val); | |
a58e2656 AB |
4087 | else |
4088 | internal_error (__FILE__, __LINE__, _("Unexpected lazy value type.")); | |
4089 | ||
4090 | set_value_lazy (val, 0); | |
a58e2656 AB |
4091 | } |
4092 | ||
a280dbd1 SDJ |
4093 | /* Implementation of the convenience function $_isvoid. */ |
4094 | ||
4095 | static struct value * | |
4096 | isvoid_internal_fn (struct gdbarch *gdbarch, | |
4097 | const struct language_defn *language, | |
4098 | void *cookie, int argc, struct value **argv) | |
4099 | { | |
4100 | int ret; | |
4101 | ||
4102 | if (argc != 1) | |
6bc305f5 | 4103 | error (_("You must provide one argument for $_isvoid.")); |
a280dbd1 SDJ |
4104 | |
4105 | ret = TYPE_CODE (value_type (argv[0])) == TYPE_CODE_VOID; | |
4106 | ||
4107 | return value_from_longest (builtin_type (gdbarch)->builtin_int, ret); | |
4108 | } | |
4109 | ||
c906108c | 4110 | void |
fba45db2 | 4111 | _initialize_values (void) |
c906108c | 4112 | { |
1a966eab | 4113 | add_cmd ("convenience", no_class, show_convenience, _("\ |
f47f77df DE |
4114 | Debugger convenience (\"$foo\") variables and functions.\n\ |
4115 | Convenience variables are created when you assign them values;\n\ | |
4116 | thus, \"set $foo=1\" gives \"$foo\" the value 1. Values may be any type.\n\ | |
1a966eab | 4117 | \n\ |
c906108c SS |
4118 | A few convenience variables are given values automatically:\n\ |
4119 | \"$_\"holds the last address examined with \"x\" or \"info lines\",\n\ | |
f47f77df DE |
4120 | \"$__\" holds the contents of the last address examined with \"x\"." |
4121 | #ifdef HAVE_PYTHON | |
4122 | "\n\n\ | |
4123 | Convenience functions are defined via the Python API." | |
4124 | #endif | |
4125 | ), &showlist); | |
7e20dfcd | 4126 | add_alias_cmd ("conv", "convenience", no_class, 1, &showlist); |
c906108c | 4127 | |
db5f229b | 4128 | add_cmd ("values", no_set_class, show_values, _("\ |
3e43a32a | 4129 | Elements of value history around item number IDX (or last ten)."), |
c906108c | 4130 | &showlist); |
53e5f3cf AS |
4131 | |
4132 | add_com ("init-if-undefined", class_vars, init_if_undefined_command, _("\ | |
4133 | Initialize a convenience variable if necessary.\n\ | |
4134 | init-if-undefined VARIABLE = EXPRESSION\n\ | |
4135 | Set an internal VARIABLE to the result of the EXPRESSION if it does not\n\ | |
4136 | exist or does not contain a value. The EXPRESSION is not evaluated if the\n\ | |
4137 | VARIABLE is already initialized.")); | |
bc3b79fd TJB |
4138 | |
4139 | add_prefix_cmd ("function", no_class, function_command, _("\ | |
4140 | Placeholder command for showing help on convenience functions."), | |
4141 | &functionlist, "function ", 0, &cmdlist); | |
a280dbd1 SDJ |
4142 | |
4143 | add_internal_function ("_isvoid", _("\ | |
4144 | Check whether an expression is void.\n\ | |
4145 | Usage: $_isvoid (expression)\n\ | |
4146 | Return 1 if the expression is void, zero otherwise."), | |
4147 | isvoid_internal_fn, NULL); | |
5fdf6324 AB |
4148 | |
4149 | add_setshow_zuinteger_unlimited_cmd ("max-value-size", | |
4150 | class_support, &max_value_size, _("\ | |
4151 | Set maximum sized value gdb will load from the inferior."), _("\ | |
4152 | Show maximum sized value gdb will load from the inferior."), _("\ | |
4153 | Use this to control the maximum size, in bytes, of a value that gdb\n\ | |
4154 | will load from the inferior. Setting this value to 'unlimited'\n\ | |
4155 | disables checking.\n\ | |
4156 | Setting this does not invalidate already allocated values, it only\n\ | |
4157 | prevents future values, larger than this size, from being allocated."), | |
4158 | set_max_value_size, | |
4159 | show_max_value_size, | |
4160 | &setlist, &showlist); | |
c906108c | 4161 | } |