| blob | bc1239d05aa01b84dea2102f77009ae5b6c34425 |
1 /* Low level packing and unpacking of values for GDB, the GNU Debugger.
3 Copyright (C) 1986-2013 Free Software Foundation, Inc.
5 This file is part of GDB.
7 This program is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3 of the License, or
10 (at your option) any later version.
12 This program is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with this program. If not, see <http://www.gnu.org/licenses/>. */
42 #include <ctype.h>
47 /* Prototypes for exported functions. */
51 /* Definition of a user function. */
52 struct internal_function
53 {
54 /* The name of the function. It is a bit odd to have this in the
55 function itself -- the user might use a differently-named
56 convenience variable to hold the function. */
59 /* The handler. */
60 internal_function_fn handler;
62 /* User data for the handler. */
64 };
66 /* Defines an [OFFSET, OFFSET + LENGTH) range. */
68 struct range
69 {
70 /* Lowest offset in the range. */
73 /* Length of the range. */
75 };
81 /* Returns true if the ranges defined by [offset1, offset1+len1) and
82 [offset2, offset2+len2) overlap. */
84 static int
87 {
93 }
95 /* Returns true if the first argument is strictly less than the
96 second, useful for VEC_lower_bound. We keep ranges sorted by
97 offset and coalesce overlapping and contiguous ranges, so this just
98 compares the starting offset. */
100 static int
102 {
104 }
106 /* Returns true if RANGES contains any range that overlaps [OFFSET,
107 OFFSET+LENGTH). */
109 static int
111 {
112 range_s what;
118 /* We keep ranges sorted by offset and coalesce overlapping and
119 contiguous ranges, so to check if a range list contains a given
120 range, we can do a binary search for the position the given range
121 would be inserted if we only considered the starting OFFSET of
122 ranges. We call that position I. Since we also have LENGTH to
123 care for (this is a range afterall), we need to check if the
124 _previous_ range overlaps the I range. E.g.,
126 R
127 |---|
128 |---| |---| |------| ... |--|
129 0 1 2 N
131 I=1
133 In the case above, the binary search would return `I=1', meaning,
134 this OFFSET should be inserted at position 1, and the current
135 position 1 should be pushed further (and before 2). But, `0'
136 overlaps with R.
138 Then we need to check if the I range overlaps the I range itself.
139 E.g.,
141 R
142 |---|
143 |---| |---| |-------| ... |--|
144 0 1 2 N
146 I=1
147 */
152 {
157 }
160 {
165 }
168 }
172 /* Note that the fields in this structure are arranged to save a bit
173 of memory. */
175 struct value
176 {
177 /* Type of value; either not an lval, or one of the various
178 different possible kinds of lval. */
181 /* Is it modifiable? Only relevant if lval != not_lval. */
184 /* If zero, contents of this value are in the contents field. If
185 nonzero, contents are in inferior. If the lval field is lval_memory,
186 the contents are in inferior memory at location.address plus offset.
187 The lval field may also be lval_register.
189 WARNING: This field is used by the code which handles watchpoints
190 (see breakpoint.c) to decide whether a particular value can be
191 watched by hardware watchpoints. If the lazy flag is set for
192 some member of a value chain, it is assumed that this member of
193 the chain doesn't need to be watched as part of watching the
194 value itself. This is how GDB avoids watching the entire struct
195 or array when the user wants to watch a single struct member or
196 array element. If you ever change the way lazy flag is set and
197 reset, be sure to consider this use as well! */
200 /* If nonzero, this is the value of a variable which does not
201 actually exist in the program. */
204 /* If value is a variable, is it initialized or not. */
207 /* If value is from the stack. If this is set, read_stack will be
208 used instead of read_memory to enable extra caching. */
211 /* If the value has been released. */
214 /* Location of value (if lval). */
215 union
216 {
217 /* If lval == lval_memory, this is the address in the inferior.
218 If lval == lval_register, this is the byte offset into the
219 registers structure. */
220 CORE_ADDR address;
222 /* Pointer to internal variable. */
225 /* If lval == lval_computed, this is a set of function pointers
226 to use to access and describe the value, and a closure pointer
227 for them to use. */
228 struct
229 {
230 /* Functions to call. */
233 /* Closure for those functions to use. */
238 /* Describes offset of a value within lval of a structure in bytes.
239 If lval == lval_memory, this is an offset to the address. If
240 lval == lval_register, this is a further offset from
241 location.address within the registers structure. Note also the
242 member embedded_offset below. */
245 /* Only used for bitfields; number of bits contained in them. */
248 /* Only used for bitfields; position of start of field. For
249 gdbarch_bits_big_endian=0 targets, it is the position of the LSB. For
250 gdbarch_bits_big_endian=1 targets, it is the position of the MSB. */
253 /* The number of references to this value. When a value is created,
254 the value chain holds a reference, so REFERENCE_COUNT is 1. If
255 release_value is called, this value is removed from the chain but
256 the caller of release_value now has a reference to this value.
257 The caller must arrange for a call to value_free later. */
260 /* Only used for bitfields; the containing value. This allows a
261 single read from the target when displaying multiple
262 bitfields. */
265 /* Frame register value is relative to. This will be described in
266 the lval enum above as "lval_register". */
269 /* Type of the value. */
272 /* If a value represents a C++ object, then the `type' field gives
273 the object's compile-time type. If the object actually belongs
274 to some class derived from `type', perhaps with other base
275 classes and additional members, then `type' is just a subobject
276 of the real thing, and the full object is probably larger than
277 `type' would suggest.
279 If `type' is a dynamic class (i.e. one with a vtable), then GDB
280 can actually determine the object's run-time type by looking at
281 the run-time type information in the vtable. When this
282 information is available, we may elect to read in the entire
283 object, for several reasons:
285 - When printing the value, the user would probably rather see the
286 full object, not just the limited portion apparent from the
287 compile-time type.
289 - If `type' has virtual base classes, then even printing `type'
290 alone may require reaching outside the `type' portion of the
291 object to wherever the virtual base class has been stored.
293 When we store the entire object, `enclosing_type' is the run-time
294 type -- the complete object -- and `embedded_offset' is the
295 offset of `type' within that larger type, in bytes. The
296 value_contents() macro takes `embedded_offset' into account, so
297 most GDB code continues to see the `type' portion of the value,
298 just as the inferior would.
300 If `type' is a pointer to an object, then `enclosing_type' is a
301 pointer to the object's run-time type, and `pointed_to_offset' is
302 the offset in bytes from the full object to the pointed-to object
303 -- that is, the value `embedded_offset' would have if we followed
304 the pointer and fetched the complete object. (I don't really see
305 the point. Why not just determine the run-time type when you
306 indirect, and avoid the special case? The contents don't matter
307 until you indirect anyway.)
309 If we're not doing anything fancy, `enclosing_type' is equal to
310 `type', and `embedded_offset' is zero, so everything works
311 normally. */
316 /* Values are stored in a chain, so that they can be deleted easily
317 over calls to the inferior. Values assigned to internal
318 variables, put into the value history or exposed to Python are
319 taken off this list. */
322 /* Register number if the value is from a register. */
325 /* Actual contents of the value. Target byte-order. NULL or not
326 valid if lazy is nonzero. */
329 /* Unavailable ranges in CONTENTS. We mark unavailable ranges,
330 rather than available, since the common and default case is for a
331 value to be available. This is filled in at value read time. */
333 };
335 int
337 {
341 }
343 int
345 {
346 /* We can only tell whether the whole value is available when we try
347 to read it. */
354 }
356 int
358 {
359 /* We can only tell whether the whole value is available when we try
360 to read it. */
365 {
371 }
374 }
376 void
378 {
379 range_s newr;
382 /* Insert the range sorted. If there's overlap or the new range
383 would be contiguous with an existing range, merge. */
388 /* Do a binary search for the position the given range would be
389 inserted if we only considered the starting OFFSET of ranges.
390 Call that position I. Since we also have LENGTH to care for
391 (this is a range afterall), we need to check if the _previous_
392 range overlaps the I range. E.g., calling R the new range:
394 #1 - overlaps with previous
396 R
397 |-...-|
398 |---| |---| |------| ... |--|
399 0 1 2 N
401 I=1
403 In the case #1 above, the binary search would return `I=1',
404 meaning, this OFFSET should be inserted at position 1, and the
405 current position 1 should be pushed further (and become 2). But,
406 note that `0' overlaps with R, so we want to merge them.
408 A similar consideration needs to be taken if the new range would
409 be contiguous with the previous range:
411 #2 - contiguous with previous
413 R
414 |-...-|
415 |--| |---| |------| ... |--|
416 0 1 2 N
418 I=1
420 If there's no overlap with the previous range, as in:
422 #3 - not overlapping and not contiguous
424 R
425 |-...-|
426 |--| |---| |------| ... |--|
427 0 1 2 N
429 I=1
431 or if I is 0:
433 #4 - R is the range with lowest offset
435 R
436 |-...-|
437 |--| |---| |------| ... |--|
438 0 1 2 N
440 I=0
442 ... we just push the new range to I.
444 All the 4 cases above need to consider that the new range may
445 also overlap several of the ranges that follow, or that R may be
446 contiguous with the following range, and merge. E.g.,
448 #5 - overlapping following ranges
450 R
451 |------------------------|
452 |--| |---| |------| ... |--|
453 0 1 2 N
455 I=0
457 or:
459 R
460 |-------|
461 |--| |---| |------| ... |--|
462 0 1 2 N
464 I=1
466 */
470 {
474 {
475 /* #1 */
481 i--;
482 }
484 {
485 /* #2 */
487 i--;
488 }
489 else
490 {
491 /* #3 */
493 }
494 }
495 else
496 {
497 /* #4 */
499 }
501 /* Check whether the ranges following the one we've just added or
502 touched can be folded in (#5 above). */
504 {
510 /* Get the range we just touched. */
517 {
526 removed++;
527 }
528 else
529 {
530 /* If we couldn't merge this one, we won't be able to
531 merge following ones either, since the ranges are
532 always sorted by OFFSET. */
534 }
538 }
539 }
541 /* Find the first range in RANGES that overlaps the range defined by
542 OFFSET and LENGTH, starting at element POS in the RANGES vector,
543 Returns the index into RANGES where such overlapping range was
544 found, or -1 if none was found. */
546 static int
549 {
558 }
560 int
564 {
567 /* See function description in value.h. */
571 {
581 /* The usual case is for both values to be completely available. */
586 /* The contents only match equal if the available set matches as
587 well. */
596 /* Get the unavailable windows intersected by the incoming
597 ranges. The first and last ranges that overlap the argument
598 range may be wider than said incoming arguments ranges. */
605 /* Make them relative to the respective start offsets, so we can
606 compare them for equality. */
613 /* Different availability, no match. */
617 /* Compare the _available_ contents. */
626 }
629 }
631 /* Prototypes for local functions. */
638 /* The value-history records all the values printed
639 by print commands during this session. Each chunk
640 records 60 consecutive values. The first chunk on
641 the chain records the most recent values.
642 The total number of values is in value_history_count. */
644 #define VALUE_HISTORY_CHUNK 60
646 struct value_history_chunk
647 {
650 };
652 /* Chain of chunks now in use. */
658 \f
659 /* List of all value objects currently allocated
660 (except for those released by calls to release_value)
661 This is so they can be freed after each command. */
665 /* Allocate a lazy value for type TYPE. Its actual content is
666 "lazily" allocated too: the content field of the return value is
667 NULL; it will be allocated when it is fetched from the target. */
671 {
674 /* Call check_typedef on our type to make sure that, if TYPE
675 is a TYPE_CODE_TYPEDEF, its length is set to the length
676 of the target type instead of zero. However, we do not
677 replace the typedef type by the target type, because we want
678 to keep the typedef in order to be able to set the VAL's type
679 description correctly. */
702 /* Values start out on the all_values chain. */
706 }
708 /* Allocate the contents of VAL if it has not been allocated yet. */
710 static void
712 {
715 }
717 /* Allocate a value and its contents for type TYPE. */
721 {
727 }
729 /* Allocate a value that has the correct length
730 for COUNT repetitions of type TYPE. */
734 {
736 /* FIXME-type-allocation: need a way to free this type when we are
737 done with it. */
742 }
748 {
756 }
758 /* Allocate NOT_LVAL value for type TYPE being OPTIMIZED_OUT. */
762 {
768 }
770 /* Accessor methods. */
774 {
776 }
780 {
782 }
783 void
785 {
787 }
789 int
791 {
793 }
794 void
796 {
798 }
800 int
802 {
804 }
805 void
807 {
809 }
811 int
813 {
815 }
816 void
818 {
820 }
824 {
826 }
828 /* See value.h. */
830 void
832 {
839 }
841 gdb_byte *
843 {
846 }
848 gdb_byte *
850 {
853 }
857 {
859 }
861 /* Look at value.h for description. */
866 {
876 {
877 /* If result's target type is TYPE_CODE_STRUCT, proceed to
878 fetch its rtti type. */
883 {
888 {
892 }
893 }
895 {
899 }
900 }
903 }
905 static void
907 {
910 }
912 static void
914 {
917 }
921 {
925 }
929 {
932 }
936 {
941 }
943 /* Copy LENGTH bytes of SRC value's (all) contents
944 (value_contents_all) starting at SRC_OFFSET, into DST value's (all)
945 contents, starting at DST_OFFSET. If unavailable contents are
946 being copied from SRC, the corresponding DST contents are marked
947 unavailable accordingly. Neither DST nor SRC may be lazy
948 values.
950 It is assumed the contents of DST in the [DST_OFFSET,
951 DST_OFFSET+LENGTH) range are wholly available. */
953 void
956 {
960 /* A lazy DST would make that this copy operation useless, since as
961 soon as DST's contents were un-lazied (by a later value_contents
962 call, say), the contents would be overwritten. A lazy SRC would
963 mean we'd be copying garbage. */
966 /* The overwritten DST range gets unavailability ORed in, not
967 replaced. Make sure to remember to implement replacing if it
968 turns out actually necessary. */
971 /* Copy the data. */
974 length);
976 /* Copy the meta-data, adjusted. */
978 {
988 }
989 }
991 /* Copy LENGTH bytes of SRC value's (all) contents
992 (value_contents_all) starting at SRC_OFFSET byte, into DST value's
993 (all) contents, starting at DST_OFFSET. If unavailable contents
994 are being copied from SRC, the corresponding DST contents are
995 marked unavailable accordingly. DST must not be lazy. If SRC is
996 lazy, it will be fetched now. If SRC is not valid (is optimized
997 out), an error is thrown.
999 It is assumed the contents of DST in the [DST_OFFSET,
1000 DST_OFFSET+LENGTH) range are wholly available. */
1002 void
1005 {
1012 }
1014 int
1016 {
1018 }
1020 void
1022 {
1024 }
1026 int
1028 {
1030 }
1032 void
1034 {
1036 }
1040 {
1045 }
1047 gdb_byte *
1049 {
1053 }
1055 /* Return non-zero if VAL1 and VAL2 have the same contents. Note that
1056 this function is different from value_equal; in C the operator ==
1057 can return 0 even if the two values being compared are equal. */
1059 int
1061 {
1072 }
1074 int
1076 {
1077 /* We can only know if a value is optimized out once we have tried to
1078 fetch it. */
1083 }
1085 int
1087 {
1089 }
1091 void
1093 {
1095 }
1097 int
1099 {
1106 }
1108 int
1110 {
1117 length);
1118 }
1120 int
1123 {
1128 offset,
1129 length);
1130 }
1132 int
1134 {
1136 }
1138 void
1140 {
1142 }
1144 int
1146 {
1148 }
1150 void
1152 {
1154 }
1158 {
1162 }
1166 {
1170 }
1174 {
1176 }
1178 enum lval_type
1180 {
1182 }
1184 CORE_ADDR
1186 {
1192 else
1194 }
1196 CORE_ADDR
1198 {
1203 }
1205 void
1207 {
1211 }
1215 {
1217 }
1221 {
1223 }
1227 {
1229 }
1231 int
1233 {
1235 }
1236 \f
1237 /* Return a mark in the value chain. All values allocated after the
1238 mark is obtained (except for those released) are subject to being freed
1239 if a subsequent value_free_to_mark is passed the mark. */
1242 {
1244 }
1246 /* Take a reference to VAL. VAL will not be deallocated until all
1247 references are released. */
1249 void
1251 {
1253 }
1255 /* Release a reference to VAL, which was acquired with value_incref.
1256 This function is also called to deallocate values from the value
1257 chain. */
1259 void
1261 {
1263 {
1269 /* If there's an associated parent value, drop our reference to
1270 it. */
1275 {
1280 }
1284 }
1286 }
1288 /* Free all values allocated since MARK was obtained by value_mark
1289 (except for those released). */
1290 void
1292 {
1297 {
1301 }
1303 }
1305 /* Free all the values that have been allocated (except for those released).
1306 Call after each command, successful or not.
1307 In practice this is called before each command, which is sufficient. */
1309 void
1311 {
1316 {
1320 }
1323 }
1325 /* Frees all the elements in a chain of values. */
1327 void
1329 {
1333 {
1336 }
1337 }
1339 /* Remove VAL from the chain all_values
1340 so it will not be freed automatically. */
1342 void
1344 {
1348 {
1353 }
1356 {
1358 {
1363 }
1364 }
1365 }
1367 /* If the value is not already released, release it.
1368 If the value is already released, increment its reference count.
1369 That is, this function ensures that the value is released from the
1370 value chain and that the caller owns a reference to it. */
1372 void
1374 {
1377 else
1379 }
1381 /* Release all values up to mark */
1384 {
1389 {
1391 {
1395 }
1397 }
1400 }
1402 /* Return a copy of the value ARG.
1403 It contains the same contents, for same memory address,
1404 but it's a different block of storage. */
1408 {
1414 else
1430 {
1434 }
1438 {
1443 }
1445 }
1447 /* Return a version of ARG that is non-lvalue. */
1451 {
1453 {
1463 }
1465 }
1467 void
1470 {
1473 else
1478 {
1483 }
1484 }
1486 \f
1487 /* Access to the value history. */
1489 /* Record a new value in the value history.
1490 Returns the absolute history index of the entry.
1491 Result of -1 indicates the value was not saved; otherwise it is the
1492 value history index of this new item. */
1494 int
1496 {
1499 /* We don't want this value to have anything to do with the inferior anymore.
1500 In particular, "set $1 = 50" should not affect the variable from which
1501 the value was taken, and fast watchpoints should be able to assume that
1502 a value on the value history never changes. */
1505 /* We preserve VALUE_LVAL so that the user can find out where it was fetched
1506 from. This is a bit dubious, because then *&$1 does not just return $1
1507 but the current contents of that location. c'est la vie... */
1511 /* Here we treat value_history_count as origin-zero
1512 and applying to the value being stored now. */
1516 {
1524 }
1528 /* Now we regard value_history_count as origin-one
1529 and applying to the value just stored. */
1532 }
1534 /* Return a copy of the value in the history with sequence number NUM. */
1538 {
1547 {
1552 else
1554 }
1558 absnum--;
1560 /* Now absnum is always absolute and origin zero. */
1569 }
1571 static void
1573 {
1579 {
1580 /* "show values +" should print from the stored position.
1581 "show values <exp>" should print around value number <exp>. */
1584 }
1585 else
1586 {
1587 /* "show values" means print the last 10 values. */
1589 }
1595 {
1603 }
1605 /* The next "show values +" should start after what we just printed. */
1608 /* Hitting just return after this command should do the same thing as
1609 "show values +". If num_exp is null, this is unnecessary, since
1610 "show values +" is not useful after "show values". */
1612 {
1615 }
1616 }
1617 \f
1618 /* Internal variables. These are variables within the debugger
1619 that hold values assigned by debugger commands.
1620 The user refers to them with a '$' prefix
1621 that does not appear in the variable names stored internally. */
1623 struct internalvar
1624 {
1628 /* We support various different kinds of content of an internal variable.
1629 enum internalvar_kind specifies the kind, and union internalvar_data
1630 provides the data associated with this particular kind. */
1632 enum internalvar_kind
1633 {
1634 /* The internal variable is empty. */
1635 INTERNALVAR_VOID,
1637 /* The value of the internal variable is provided directly as
1638 a GDB value object. */
1639 INTERNALVAR_VALUE,
1641 /* A fresh value is computed via a call-back routine on every
1642 access to the internal variable. */
1643 INTERNALVAR_MAKE_VALUE,
1645 /* The internal variable holds a GDB internal convenience function. */
1646 INTERNALVAR_FUNCTION,
1648 /* The variable holds an integer value. */
1649 INTERNALVAR_INTEGER,
1651 /* The variable holds a GDB-provided string. */
1652 INTERNALVAR_STRING,
1656 union internalvar_data
1657 {
1658 /* A value object used with INTERNALVAR_VALUE. */
1661 /* The call-back routine used with INTERNALVAR_MAKE_VALUE. */
1662 struct
1663 {
1664 /* The functions to call. */
1667 /* The function's user-data. */
1671 /* The internal function used with INTERNALVAR_FUNCTION. */
1672 struct
1673 {
1675 /* True if this is the canonical name for the function. */
1679 /* An integer value used with INTERNALVAR_INTEGER. */
1680 struct
1681 {
1682 /* If type is non-NULL, it will be used as the type to generate
1683 a value for this internal variable. If type is NULL, a default
1684 integer type for the architecture is used. */
1686 LONGEST val;
1689 /* A string value used with INTERNALVAR_STRING. */
1692 };
1696 /* If the variable does not already exist create it and give it the
1697 value given. If no value is given then the default is zero. */
1698 static void
1700 {
1703 /* Parse the expression - this is taken from set_command(). */
1708 /* Validate the expression.
1709 Was the expression an assignment?
1710 Or even an expression at all? */
1714 /* Extract the variable from the parsed expression.
1715 In the case of an assign the lvalue will be in elts[1] and elts[2]. */
1721 /* Only evaluate the expression if the lvalue is void.
1722 This may still fail if the expresssion is invalid. */
1727 }
1730 /* Look up an internal variable with name NAME. NAME should not
1731 normally include a dollar sign.
1733 If the specified internal variable does not exist,
1734 the return value is NULL. */
1738 {
1746 }
1748 /* Complete NAME by comparing it to the names of internal variables.
1749 Returns a vector of newly allocated strings, or NULL if no matches
1750 were found. */
1754 {
1763 {
1767 }
1770 }
1772 /* Create an internal variable with name NAME and with a void value.
1773 NAME should not normally include a dollar sign. */
1777 {
1786 }
1788 /* Create an internal variable with name NAME and register FUN as the
1789 function that value_of_internalvar uses to create a value whenever
1790 this variable is referenced. NAME should not normally include a
1791 dollar sign. DATA is passed uninterpreted to FUN when it is
1792 called. CLEANUP, if not NULL, is called when the internal variable
1793 is destroyed. It is passed DATA as its only argument. */
1799 {
1806 }
1808 /* See documentation in value.h. */
1810 int
1814 {
1822 }
1824 /* Look up an internal variable with name NAME. NAME should not
1825 normally include a dollar sign.
1827 If the specified internal variable does not exist,
1828 one is created, with a void value. */
1832 {
1840 }
1842 /* Return current value of internal variable VAR. For variables that
1843 are not inherently typed, use a value type appropriate for GDBARCH. */
1847 {
1851 /* If there is a trace state variable of the same name, assume that
1852 is what we really want to see. */
1855 {
1861 else
1864 }
1867 {
1880 else
1902 }
1904 /* Change the VALUE_LVAL to lval_internalvar so that future operations
1905 on this value go back to affect the original internal variable.
1907 Do not do this for INTERNALVAR_MAKE_VALUE variables, as those have
1908 no underlying modifyable state in the internal variable.
1910 Likewise, if the variable's value is a computed lvalue, we want
1911 references to it to produce another computed lvalue, where
1912 references and assignments actually operate through the
1913 computed value's functions.
1915 This means that internal variables with computed values
1916 behave a little differently from other internal variables:
1917 assignments to them don't just replace the previous value
1918 altogether. At the moment, this seems like the behavior we
1919 want. */
1923 {
1926 }
1929 }
1931 int
1933 {
1935 {
1938 }
1941 {
1945 {
1948 }
1949 }
1952 }
1954 static int
1957 {
1959 {
1966 }
1967 }
1969 void
1972 {
1976 {
1983 else
1989 /* We can never get a component of any other kind. */
1991 }
1992 }
1994 void
1996 {
2003 /* Prepare new contents. */
2005 {
2015 /* Copies created here are never canonical. */
2023 /* Force the value to be fetched from the target now, to avoid problems
2024 later when this internalvar is referenced and the target is gone or
2025 has changed. */
2029 /* Release the value from the value chain to prevent it from being
2030 deleted by free_all_values. From here on this function should not
2031 call error () until new_data is installed into the var->u to avoid
2032 leaking memory. */
2035 }
2037 /* Clean up old contents. */
2040 /* Switch over. */
2043 /* End code which must not call error(). */
2044 }
2046 void
2048 {
2049 /* Clean up old contents. */
2055 }
2057 void
2059 {
2060 /* Clean up old contents. */
2065 }
2067 static void
2069 {
2070 /* Clean up old contents. */
2076 /* Variables installed here are always the canonical version. */
2077 }
2079 void
2081 {
2082 /* Clean up old contents. */
2084 {
2100 }
2102 /* Reset to void kind. */
2104 }
2108 {
2110 }
2115 {
2122 }
2126 {
2135 }
2141 {
2150 }
2152 /* The 'function' command. This does nothing -- it is just a
2153 placeholder to let "help function NAME" work. This is also used as
2154 the implementation of the sub-command that is created when
2155 registering an internal function. */
2156 static void
2158 {
2159 /* Do nothing. */
2160 }
2162 /* Clean up if an internal function's command is destroyed. */
2163 static void
2165 {
2168 }
2170 /* Add a new internal function. NAME is the name of the function; DOC
2171 is a documentation string describing the function. HANDLER is
2172 called when the function is invoked. COOKIE is an arbitrary
2173 pointer which is passed to HANDLER and is intended for "user
2174 data". */
2175 void
2178 {
2189 }
2191 /* Update VALUE before discarding OBJFILE. COPIED_TYPES is used to
2192 prevent cycles / duplicates. */
2194 void
2196 htab_t copied_types)
2197 {
2204 copied_types);
2205 }
2207 /* Likewise for internal variable VAR. */
2209 static void
2211 htab_t copied_types)
2212 {
2214 {
2224 }
2225 }
2227 /* Update the internal variables and value history when OBJFILE is
2228 discarded; we must copy the types out of the objfile. New global types
2229 will be created for every convenience variable which currently points to
2230 this objfile's types, and the convenience variables will be adjusted to
2231 use the new global types. */
2233 void
2235 {
2236 htab_t copied_types;
2241 /* Create the hash table. We allocate on the objfile's obstack, since
2242 it is soon to be deleted. */
2256 }
2258 static void
2260 {
2268 {
2272 {
2274 }
2278 {
2283 }
2287 }
2289 {
2290 /* This text does not mention convenience functions on purpose.
2291 The user can't create them except via Python, and if Python support
2292 is installed this message will never be printed ($_streq will
2293 exist). */
2295 "Convenience variables have "
2299 }
2300 }
2301 \f
2302 /* Extract a value as a C number (either long or double).
2303 Knows how to convert fixed values to double, or
2304 floating values to long.
2305 Does not deallocate the value. */
2307 LONGEST
2309 {
2310 /* This coerces arrays and functions, which is necessary (e.g.
2311 in disassemble_command). It also dereferences references, which
2312 I suspect is the most logical thing to do. */
2315 }
2317 DOUBLEST
2319 {
2320 DOUBLEST foo;
2327 }
2329 /* Extract a value as a C pointer. Does not deallocate the value.
2330 Note that val's type may not actually be a pointer; value_as_long
2331 handles all the cases. */
2332 CORE_ADDR
2334 {
2337 /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure
2338 whether we want this to be true eventually. */
2339 #if 0
2340 /* gdbarch_addr_bits_remove is wrong if we are being called for a
2341 non-address (e.g. argument to "signal", "info break", etc.), or
2342 for pointers to char, in which the low bits *are* significant. */
2344 #else
2346 /* There are several targets (IA-64, PowerPC, and others) which
2347 don't represent pointers to functions as simply the address of
2348 the function's entry point. For example, on the IA-64, a
2349 function pointer points to a two-word descriptor, generated by
2350 the linker, which contains the function's entry point, and the
2351 value the IA-64 "global pointer" register should have --- to
2352 support position-independent code. The linker generates
2353 descriptors only for those functions whose addresses are taken.
2355 On such targets, it's difficult for GDB to convert an arbitrary
2356 function address into a function pointer; it has to either find
2357 an existing descriptor for that function, or call malloc and
2358 build its own. On some targets, it is impossible for GDB to
2359 build a descriptor at all: the descriptor must contain a jump
2360 instruction; data memory cannot be executed; and code memory
2361 cannot be modified.
2363 Upon entry to this function, if VAL is a value of type `function'
2364 (that is, TYPE_CODE (VALUE_TYPE (val)) == TYPE_CODE_FUNC), then
2365 value_address (val) is the address of the function. This is what
2366 you'll get if you evaluate an expression like `main'. The call
2367 to COERCE_ARRAY below actually does all the usual unary
2368 conversions, which includes converting values of type `function'
2369 to `pointer to function'. This is the challenging conversion
2370 discussed above. Then, `unpack_long' will convert that pointer
2371 back into an address.
2373 So, suppose the user types `disassemble foo' on an architecture
2374 with a strange function pointer representation, on which GDB
2375 cannot build its own descriptors, and suppose further that `foo'
2376 has no linker-built descriptor. The address->pointer conversion
2377 will signal an error and prevent the command from running, even
2378 though the next step would have been to convert the pointer
2379 directly back into the same address.
2381 The following shortcut avoids this whole mess. If VAL is a
2382 function, just return its address directly. */
2389 /* Some architectures (e.g. Harvard), map instruction and data
2390 addresses onto a single large unified address space. For
2391 instance: An architecture may consider a large integer in the
2392 range 0x10000000 .. 0x1000ffff to already represent a data
2393 addresses (hence not need a pointer to address conversion) while
2394 a small integer would still need to be converted integer to
2395 pointer to address. Just assume such architectures handle all
2396 integer conversions in a single function. */
2398 /* JimB writes:
2400 I think INTEGER_TO_ADDRESS is a good idea as proposed --- but we
2401 must admonish GDB hackers to make sure its behavior matches the
2402 compiler's, whenever possible.
2404 In general, I think GDB should evaluate expressions the same way
2405 the compiler does. When the user copies an expression out of
2406 their source code and hands it to a `print' command, they should
2407 get the same value the compiler would have computed. Any
2408 deviation from this rule can cause major confusion and annoyance,
2409 and needs to be justified carefully. In other words, GDB doesn't
2410 really have the freedom to do these conversions in clever and
2411 useful ways.
2413 AndrewC pointed out that users aren't complaining about how GDB
2414 casts integers to pointers; they are complaining that they can't
2415 take an address from a disassembly listing and give it to `x/i'.
2416 This is certainly important.
2418 Adding an architecture method like integer_to_address() certainly
2419 makes it possible for GDB to "get it right" in all circumstances
2420 --- the target has complete control over how things get done, so
2421 people can Do The Right Thing for their target without breaking
2422 anyone else. The standard doesn't specify how integers get
2423 converted to pointers; usually, the ABI doesn't either, but
2424 ABI-specific code is a more reasonable place to handle it. */
2433 #endif
2434 }
2435 \f
2436 /* Unpack raw data (copied from debugee, target byte order) at VALADDR
2437 as a long, or as a double, assuming the raw data is described
2438 by type TYPE. Knows how to convert different sizes of values
2439 and can convert between fixed and floating point. We don't assume
2440 any alignment for the raw data. Return value is in host byte order.
2442 If you want functions and arrays to be coerced to pointers, and
2443 references to be dereferenced, call value_as_long() instead.
2445 C++: It is assumed that the front-end has taken care of
2446 all matters concerning pointers to members. A pointer
2447 to member which reaches here is considered to be equivalent
2448 to an INT (or some size). After all, it is only an offset. */
2450 LONGEST
2452 {
2459 {
2471 else
2478 /* libdecnumber has a function to convert from decimal to integer, but
2479 it doesn't work when the decimal number has a fractional part. */
2484 /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure
2485 whether we want this to be true eventually. */
2490 }
2492 }
2494 /* Return a double value from the specified type and address.
2495 INVP points to an int which is set to 0 for valid value,
2496 1 for invalid value (bad float format). In either case,
2497 the returned double is OK to use. Argument is in target
2498 format, result is in host format. */
2500 DOUBLEST
2502 {
2514 {
2515 /* NOTE: cagney/2002-02-19: There was a test here to see if the
2516 floating-point value was valid (using the macro
2517 INVALID_FLOAT). That test/macro have been removed.
2519 It turns out that only the VAX defined this macro and then
2520 only in a non-portable way. Fixing the portability problem
2521 wouldn't help since the VAX floating-point code is also badly
2522 bit-rotten. The target needs to add definitions for the
2523 methods gdbarch_float_format and gdbarch_double_format - these
2524 exactly describe the target floating-point format. The
2525 problem here is that the corresponding floatformat_vax_f and
2526 floatformat_vax_d values these methods should be set to are
2527 also not defined either. Oops!
2529 Hopefully someone will add both the missing floatformat
2530 definitions and the new cases for floatformat_is_valid (). */
2533 {
2536 }
2539 }
2543 {
2544 /* Unsigned -- be sure we compensate for signed LONGEST. */
2546 }
2547 else
2548 {
2549 /* Signed -- we are OK with unpack_long. */
2551 }
2552 }
2554 /* Unpack raw data (copied from debugee, target byte order) at VALADDR
2555 as a CORE_ADDR, assuming the raw data is described by type TYPE.
2556 We don't assume any alignment for the raw data. Return value is in
2557 host byte order.
2559 If you want functions and arrays to be coerced to pointers, and
2560 references to be dereferenced, call value_as_address() instead.
2562 C++: It is assumed that the front-end has taken care of
2563 all matters concerning pointers to members. A pointer
2564 to member which reaches here is considered to be equivalent
2565 to an INT (or some size). After all, it is only an offset. */
2567 CORE_ADDR
2569 {
2570 /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure
2571 whether we want this to be true eventually. */
2573 }
2575 \f
2576 /* Get the value of the FIELDNO'th field (which must be static) of
2577 TYPE. Return NULL if the field doesn't exist or has been
2578 optimized out. */
2582 {
2586 {
2592 {
2594 /* TYPE_FIELD_NAME (type, fieldno); */
2598 {
2599 /* With some compilers, e.g. HP aCC, static data members are
2600 reported as non-debuggable symbols. */
2606 else
2607 {
2610 }
2611 }
2612 else
2615 }
2618 }
2621 }
2623 /* Change the enclosing type of a value object VAL to NEW_ENCL_TYPE.
2624 You have to be careful here, since the size of the data area for the value
2625 is set by the length of the enclosing type. So if NEW_ENCL_TYPE is bigger
2626 than the old enclosing type, you have to allocate more space for the
2627 data. */
2629 void
2631 {
2637 }
2639 /* Given a value ARG1 (offset by OFFSET bytes)
2640 of a struct or union type ARG_TYPE,
2641 extract and return the value of one of its (non-static) fields.
2642 FIELDNO says which field. */
2647 {
2654 /* Call check_typedef on our type to make sure that, if TYPE
2655 is a TYPE_CODE_TYPEDEF, its length is set to the length
2656 of the target type instead of zero. However, we do not
2657 replace the typedef type by the target type, because we want
2658 to keep the typedef in order to be able to print the type
2659 description correctly. */
2663 {
2664 /* Handle packed fields.
2666 Create a new value for the bitfield, with bitpos and bitsize
2667 set. If possible, arrange offset and bitpos so that we can
2668 do a single aligned read of the size of the containing type.
2669 Otherwise, adjust offset to the byte containing the first
2670 bit. Assume that the address, offset, and embedded offset
2671 are sufficiently aligned. */
2678 else
2679 {
2685 else
2688 + offset
2693 }
2694 }
2696 {
2697 /* This field is actually a base subobject, so preserve the
2698 entire object's contents for later references to virtual
2699 bases, etc. */
2702 /* Lazy register values with offsets are not supported. */
2706 /* The optimized_out flag is only set correctly once a lazy value is
2707 loaded, having just loaded some lazy values we should check the
2708 optimized out case now. */
2711 else
2712 {
2713 /* We special case virtual inheritance here because this
2714 requires access to the contents, which we would rather avoid
2715 for references to ordinary fields of unavailable values. */
2721 arg1);
2722 else
2727 else
2728 {
2732 }
2736 }
2737 }
2738 else
2739 {
2740 /* Plain old data member */
2743 /* Lazy register values with offsets are not supported. */
2747 /* The optimized_out flag is only set correctly once a lazy value is
2748 loaded, having just loaded some lazy values we should check for
2749 the optimized out case now. */
2754 else
2755 {
2760 }
2763 }
2768 }
2770 /* Given a value ARG1 of a struct or union type,
2771 extract and return the value of one of its (non-static) fields.
2772 FIELDNO says which field. */
2776 {
2778 }
2780 /* Return a non-virtual function as a value.
2781 F is the list of member functions which contains the desired method.
2782 J is an index into F which provides the desired method.
2784 We only use the symbol for its address, so be happy with either a
2785 full symbol or a minimal symbol. */
2791 {
2800 {
2802 }
2803 else
2804 {
2809 }
2813 {
2815 }
2816 else
2817 {
2818 /* The minimal symbol might point to a function descriptor;
2819 resolve it to the actual code address instead. */
2824 gdbarch_convert_from_func_ptr_addr
2826 }
2829 {
2834 /* Move the `this' pointer according to the offset.
2835 VALUE_OFFSET (*arg1p) += offset; */
2836 }
2839 }
2841 \f
2843 /* Helper function for both unpack_value_bits_as_long and
2844 unpack_bits_as_long. See those functions for more details on the
2845 interface; the only difference is that this function accepts either
2846 a NULL or a non-NULL ORIGINAL_VALUE. */
2848 static int
2853 {
2855 ULONGEST val;
2856 ULONGEST valmask;
2861 /* Read the minimum number of bytes required; there may not be
2862 enough bytes to read an entire ULONGEST. */
2866 else
2873 bytes_read))
2879 /* Extract bits. See comment above. */
2883 else
2887 /* If the field does not entirely fill a LONGEST, then zero the sign bits.
2888 If the field is signed, and is negative, then sign extend. */
2891 {
2895 {
2897 {
2899 }
2900 }
2901 }
2905 }
2907 /* Unpack a bitfield of the specified FIELD_TYPE, from the object at
2908 VALADDR + EMBEDDED_OFFSET, and store the result in *RESULT.
2909 VALADDR points to the contents of ORIGINAL_VALUE, which must not be
2910 NULL. The bitfield starts at BITPOS bits and contains BITSIZE
2911 bits.
2913 Returns false if the value contents are unavailable, otherwise
2914 returns true, indicating a valid value has been stored in *RESULT.
2916 Extracting bits depends on endianness of the machine. Compute the
2917 number of least significant bits to discard. For big endian machines,
2918 we compute the total number of bits in the anonymous object, subtract
2919 off the bit count from the MSB of the object to the MSB of the
2920 bitfield, then the size of the bitfield, which leaves the LSB discard
2921 count. For little endian machines, the discard count is simply the
2922 number of bits from the LSB of the anonymous object to the LSB of the
2923 bitfield.
2925 If the field is signed, we also do sign extension. */
2927 int
2932 {
2938 }
2940 /* Unpack a field FIELDNO of the specified TYPE, from the object at
2941 VALADDR + EMBEDDED_OFFSET. VALADDR points to the contents of
2942 ORIGINAL_VALUE. See unpack_value_bits_as_long for more
2943 details. */
2945 static int
2949 {
2956 result);
2957 }
2959 /* Unpack a field FIELDNO of the specified TYPE, from the object at
2960 VALADDR + EMBEDDED_OFFSET. VALADDR points to the contents of
2961 ORIGINAL_VALUE, which must not be NULL. See
2962 unpack_value_bits_as_long for more details. */
2964 int
2968 {
2973 }
2975 /* Unpack a field FIELDNO of the specified TYPE, from the anonymous
2976 object at VALADDR. See unpack_value_bits_as_long for more details.
2977 This function differs from unpack_value_field_as_long in that it
2978 operates without a struct value object. */
2980 LONGEST
2982 {
2983 LONGEST result;
2987 }
2989 /* Return a new value with type TYPE, which is FIELDNO field of the
2990 object at VALADDR + EMBEDDEDOFFSET. VALADDR points to the contents
2991 of VAL. If the VAL's contents required to extract the bitfield
2992 from are unavailable, the new value is correspondingly marked as
2993 unavailable. */
2999 {
3000 LONGEST l;
3004 {
3009 }
3010 else
3011 {
3013 }
3014 }
3016 /* Modify the value of a bitfield. ADDR points to a block of memory in
3017 target byte order; the bitfield starts in the byte pointed to. FIELDVAL
3018 is the desired value of the field, in host byte order. BITPOS and BITSIZE
3019 indicate which bits (in target bit order) comprise the bitfield.
3020 Requires 0 < BITSIZE <= lbits, 0 <= BITPOS % 8 + BITSIZE <= lbits, and
3021 0 <= BITPOS, where lbits is the size of a LONGEST in bits. */
3023 void
3026 {
3028 ULONGEST oword;
3032 /* Normalize BITPOS. */
3036 /* If a negative fieldval fits in the field in question, chop
3037 off the sign extension bits. */
3041 /* Warn if value is too big to fit in the field in question. */
3043 {
3044 /* FIXME: would like to include fieldval in the message, but
3045 we don't have a sprintf_longest. */
3048 /* Truncate it, otherwise adjoining fields may be corrupted. */
3050 }
3052 /* Ensure no bytes outside of the modified ones get accessed as it may cause
3053 false valgrind reports. */
3058 /* Shifting for bit field depends on endianness of the target machine. */
3066 }
3067 \f
3068 /* Pack NUM into BUF using a target format of TYPE. */
3070 void
3072 {
3080 {
3099 }
3100 }
3103 /* Pack NUM into BUF using a target format of TYPE. */
3105 static void
3107 {
3116 {
3136 }
3137 }
3140 /* Convert C numbers into newly allocated values. */
3144 {
3149 }
3152 /* Convert C unsigned numbers into newly allocated values. */
3156 {
3162 }
3165 /* Create a value representing a pointer of type TYPE to the address
3166 ADDR. */
3169 {
3174 }
3177 /* Create a value of type TYPE whose contents come from VALADDR, if it
3178 is non-null, and whose memory address (in the inferior) is
3179 ADDRESS. */
3184 CORE_ADDR address)
3185 {
3190 else
3195 }
3197 /* Create a value of type TYPE holding the contents CONTENTS.
3198 The new value is `not_lval'. */
3202 {
3208 }
3212 {
3218 {
3220 }
3221 else
3225 }
3229 {
3234 }
3236 /* Extract a value from the history file. Input will be of the form
3237 $digits or $$digits. See block comment above 'write_dollar_variable'
3238 for details. */
3242 {
3247 else
3253 /* Find length of numeral string. */
3255 ;
3257 /* Make sure numeral string is not part of an identifier. */
3261 /* Now collect the index value. */
3263 {
3265 {
3266 /* For some bizarre reason, "$$" is equivalent to "$$1",
3267 rather than to "$$0" as it ought to be! */
3270 }
3271 else
3273 }
3274 else
3275 {
3277 {
3278 /* "$" is equivalent to "$0". */
3281 }
3282 else
3284 }
3287 }
3291 {
3305 }
3307 /* Look at value.h for description. */
3313 {
3314 /* Re-adjust type. */
3317 /* Add embedding info. */
3321 /* We may be pointing to an object of some derived type. */
3323 }
3327 {
3347 }
3351 {
3358 {
3366 }
3368 }
3369 \f
3371 /* Return the return value convention that will be used for the
3372 specified type. */
3374 enum return_value_convention
3377 {
3383 /* Probe the architecture for the return-value convention. */
3386 }
3388 /* Return true if the function returning the specified type is using
3389 the convention of returning structures in memory (passing in the
3390 address as a hidden first parameter). */
3392 int
3395 {
3397 /* A void return value is never in memory. See also corresponding
3398 code in "print_return_value". */
3403 }
3405 /* Set the initialized field in a value struct. */
3407 void
3409 {
3411 }
3413 /* Return the initialized field in a value struct. */
3415 int
3417 {
3419 }
3421 /* Called only from the value_contents and value_contents_all()
3422 macros, if the current data for a variable needs to be loaded into
3423 value_contents(VAL). Fetches the data from the user's process, and
3424 clears the lazy flag to indicate that the data in the buffer is
3425 valid.
3427 If the value is zero-length, we avoid calling read_memory, which
3428 would abort. We mark the value as fetched anyway -- all 0 bytes of
3429 it.
3431 This function returns a value because it is used in the
3432 value_contents macro as part of an expression, where a void would
3433 not work. The value is ignored. */
3435 int
3437 {
3441 {
3442 /* To read a lazy bitfield, read the entire enclosing value. This
3443 prevents reading the same block of (possibly volatile) memory once
3444 per bitfield. It would be even better to read only the containing
3445 word, but we have no way to record that just specific bits of a
3446 value have been fetched. */
3451 LONGEST num;
3462 offset,
3468 else
3471 }
3473 {
3481 }
3483 {
3489 /* Offsets are not supported here; lazy register values must
3490 refer to the entire register. */
3494 {
3500 /* Convertible register routines are used for multi-register
3501 values and for interpretation in different types
3502 (e.g. float or int from a double register). Lazy
3503 register values should have the register's natural type,
3504 so they do not apply. */
3509 }
3511 /* If it's still lazy (for instance, a saved register on the
3512 stack), fetch it. */
3516 /* If the register was not saved, mark it optimized out. */
3519 else
3520 {
3525 }
3528 {
3535 "{ value_fetch_lazy "
3543 else
3544 {
3555 else
3563 }
3566 }
3568 /* Dispose of the intermediate values. This prevents
3569 watchpoints from trying to watch the saved frame pointer. */
3571 }
3575 /* Don't call value_optimized_out on val, doing so would result in a
3576 recursive call back to value_fetch_lazy, instead check the
3577 optimized_out flag directly. */
3580 else
3585 }
3587 /* Implementation of the convenience function $_isvoid. */
3593 {
3602 }
3604 void
3606 {
3615 #ifdef HAVE_PYTHON
3617 Convenience functions are defined via the Python API."
3618 #endif
3642 }