Bump GDB's version number to 15.0.91.DATE-git.
[binutils-gdb.git] / gdb / f-lang.c
blob58f35bf0f3fd3510878c721869cebe9281922917
1 /* Fortran language support routines for GDB, the GNU debugger.
3 Copyright (C) 1993-2024 Free Software Foundation, Inc.
5 Contributed by Motorola. Adapted from the C parser by Farooq Butt
6 (fmbutt@engage.sps.mot.com).
8 This file is part of GDB.
10 This program is free software; you can redistribute it and/or modify
11 it under the terms of the GNU General Public License as published by
12 the Free Software Foundation; either version 3 of the License, or
13 (at your option) any later version.
15 This program is distributed in the hope that it will be useful,
16 but WITHOUT ANY WARRANTY; without even the implied warranty of
17 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 GNU General Public License for more details.
20 You should have received a copy of the GNU General Public License
21 along with this program. If not, see <http://www.gnu.org/licenses/>. */
23 #include "symtab.h"
24 #include "gdbtypes.h"
25 #include "expression.h"
26 #include "parser-defs.h"
27 #include "language.h"
28 #include "varobj.h"
29 #include "gdbcore.h"
30 #include "f-lang.h"
31 #include "valprint.h"
32 #include "value.h"
33 #include "cp-support.h"
34 #include "charset.h"
35 #include "c-lang.h"
36 #include "target-float.h"
37 #include "gdbarch.h"
38 #include "cli/cli-cmds.h"
39 #include "f-array-walker.h"
40 #include "f-exp.h"
42 #include <math.h>
44 /* Whether GDB should repack array slices created by the user. */
45 static bool repack_array_slices = false;
47 /* Implement 'show fortran repack-array-slices'. */
48 static void
49 show_repack_array_slices (struct ui_file *file, int from_tty,
50 struct cmd_list_element *c, const char *value)
52 gdb_printf (file, _("Repacking of Fortran array slices is %s.\n"),
53 value);
56 /* Debugging of Fortran's array slicing. */
57 static bool fortran_array_slicing_debug = false;
59 /* Implement 'show debug fortran-array-slicing'. */
60 static void
61 show_fortran_array_slicing_debug (struct ui_file *file, int from_tty,
62 struct cmd_list_element *c,
63 const char *value)
65 gdb_printf (file, _("Debugging of Fortran array slicing is %s.\n"),
66 value);
69 /* Local functions */
71 static value *fortran_prepare_argument (struct expression *exp,
72 expr::operation *subexp,
73 int arg_num, bool is_internal_call_p,
74 struct type *func_type, enum noside noside);
76 /* Return the encoding that should be used for the character type
77 TYPE. */
79 const char *
80 f_language::get_encoding (struct type *type)
82 const char *encoding;
84 switch (type->length ())
86 case 1:
87 encoding = target_charset (type->arch ());
88 break;
89 case 4:
90 if (type_byte_order (type) == BFD_ENDIAN_BIG)
91 encoding = "UTF-32BE";
92 else
93 encoding = "UTF-32LE";
94 break;
96 default:
97 error (_("unrecognized character type"));
100 return encoding;
103 /* See language.h. */
105 struct value *
106 f_language::value_string (struct gdbarch *gdbarch,
107 const char *ptr, ssize_t len) const
109 struct type *type = language_string_char_type (this, gdbarch);
110 return ::value_string (ptr, len, type);
113 /* A helper function for the "bound" intrinsics that checks that TYPE
114 is an array. LBOUND_P is true for lower bound; this is used for
115 the error message, if any. */
117 static void
118 fortran_require_array (struct type *type, bool lbound_p)
120 type = check_typedef (type);
121 if (type->code () != TYPE_CODE_ARRAY)
123 if (lbound_p)
124 error (_("LBOUND can only be applied to arrays"));
125 else
126 error (_("UBOUND can only be applied to arrays"));
130 /* Create an array containing the lower bounds (when LBOUND_P is true) or
131 the upper bounds (when LBOUND_P is false) of ARRAY (which must be of
132 array type). GDBARCH is the current architecture. */
134 static struct value *
135 fortran_bounds_all_dims (bool lbound_p,
136 struct gdbarch *gdbarch,
137 struct value *array)
139 type *array_type = check_typedef (array->type ());
140 int ndimensions = calc_f77_array_dims (array_type);
142 /* Allocate a result value of the correct type. */
143 type_allocator alloc (gdbarch);
144 struct type *range
145 = create_static_range_type (alloc,
146 builtin_f_type (gdbarch)->builtin_integer,
147 1, ndimensions);
148 struct type *elm_type = builtin_f_type (gdbarch)->builtin_integer;
149 struct type *result_type = create_array_type (alloc, elm_type, range);
150 struct value *result = value::allocate (result_type);
152 /* Walk the array dimensions backwards due to the way the array will be
153 laid out in memory, the first dimension will be the most inner. */
154 LONGEST elm_len = elm_type->length ();
155 for (LONGEST dst_offset = elm_len * (ndimensions - 1);
156 dst_offset >= 0;
157 dst_offset -= elm_len)
159 LONGEST b;
161 /* Grab the required bound. */
162 if (lbound_p)
163 b = f77_get_lowerbound (array_type);
164 else
165 b = f77_get_upperbound (array_type);
167 /* And copy the value into the result value. */
168 struct value *v = value_from_longest (elm_type, b);
169 gdb_assert (dst_offset + v->type ()->length ()
170 <= result->type ()->length ());
171 gdb_assert (v->type ()->length () == elm_len);
172 v->contents_copy (result, dst_offset, 0, elm_len);
174 /* Peel another dimension of the array. */
175 array_type = array_type->target_type ();
178 return result;
181 /* Return the lower bound (when LBOUND_P is true) or the upper bound (when
182 LBOUND_P is false) for dimension DIM_VAL (which must be an integer) of
183 ARRAY (which must be an array). RESULT_TYPE corresponds to the type kind
184 the function should be evaluated in. */
186 static value *
187 fortran_bounds_for_dimension (bool lbound_p, value *array, value *dim_val,
188 type* result_type)
190 /* Check the requested dimension is valid for this array. */
191 type *array_type = check_typedef (array->type ());
192 int ndimensions = calc_f77_array_dims (array_type);
193 long dim = value_as_long (dim_val);
194 if (dim < 1 || dim > ndimensions)
196 if (lbound_p)
197 error (_("LBOUND dimension must be from 1 to %d"), ndimensions);
198 else
199 error (_("UBOUND dimension must be from 1 to %d"), ndimensions);
202 /* Walk the dimensions backwards, due to the ordering in which arrays are
203 laid out the first dimension is the most inner. */
204 for (int i = ndimensions - 1; i >= 0; --i)
206 /* If this is the requested dimension then we're done. Grab the
207 bounds and return. */
208 if (i == dim - 1)
210 LONGEST b;
212 if (lbound_p)
213 b = f77_get_lowerbound (array_type);
214 else
215 b = f77_get_upperbound (array_type);
217 return value_from_longest (result_type, b);
220 /* Peel off another dimension of the array. */
221 array_type = array_type->target_type ();
224 gdb_assert_not_reached ("failed to find matching dimension");
227 /* Return the number of dimensions for a Fortran array or string. */
230 calc_f77_array_dims (struct type *array_type)
232 int ndimen = 1;
233 struct type *tmp_type;
235 if ((array_type->code () == TYPE_CODE_STRING))
236 return 1;
238 if ((array_type->code () != TYPE_CODE_ARRAY))
239 error (_("Can't get dimensions for a non-array type"));
241 tmp_type = array_type;
243 while ((tmp_type = tmp_type->target_type ()))
245 if (tmp_type->code () == TYPE_CODE_ARRAY)
246 ++ndimen;
248 return ndimen;
251 /* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
252 slices. This is a base class for two alternative repacking mechanisms,
253 one for when repacking from a lazy value, and one for repacking from a
254 non-lazy (already loaded) value. */
255 class fortran_array_repacker_base_impl
256 : public fortran_array_walker_base_impl
258 public:
259 /* Constructor, DEST is the value we are repacking into. */
260 fortran_array_repacker_base_impl (struct value *dest)
261 : m_dest (dest),
262 m_dest_offset (0)
263 { /* Nothing. */ }
265 /* When we start processing the inner most dimension, this is where we
266 will be creating values for each element as we load them and then copy
267 them into the M_DEST value. Set a value mark so we can free these
268 temporary values. */
269 void start_dimension (struct type *index_type, LONGEST nelts, bool inner_p)
271 if (inner_p)
273 gdb_assert (!m_mark.has_value ());
274 m_mark.emplace ();
278 /* When we finish processing the inner most dimension free all temporary
279 value that were created. */
280 void finish_dimension (bool inner_p, bool last_p)
282 if (inner_p)
284 gdb_assert (m_mark.has_value ());
285 m_mark.reset ();
289 protected:
290 /* Copy the contents of array element ELT into M_DEST at the next
291 available offset. */
292 void copy_element_to_dest (struct value *elt)
294 elt->contents_copy (m_dest, m_dest_offset, 0,
295 elt->type ()->length ());
296 m_dest_offset += elt->type ()->length ();
299 /* The value being written to. */
300 struct value *m_dest;
302 /* The byte offset in M_DEST at which the next element should be
303 written. */
304 LONGEST m_dest_offset;
306 /* Set and reset to handle removing intermediate values from the
307 value chain. */
308 std::optional<scoped_value_mark> m_mark;
311 /* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
312 slices. This class is specialised for repacking an array slice from a
313 lazy array value, as such it does not require the parent array value to
314 be loaded into GDB's memory; the parent value could be huge, while the
315 slice could be tiny. */
316 class fortran_lazy_array_repacker_impl
317 : public fortran_array_repacker_base_impl
319 public:
320 /* Constructor. TYPE is the type of the slice being loaded from the
321 parent value, so this type will correctly reflect the strides required
322 to find all of the elements from the parent value. ADDRESS is the
323 address in target memory of value matching TYPE, and DEST is the value
324 we are repacking into. */
325 explicit fortran_lazy_array_repacker_impl (struct type *type,
326 CORE_ADDR address,
327 struct value *dest)
328 : fortran_array_repacker_base_impl (dest),
329 m_addr (address)
330 { /* Nothing. */ }
332 /* Create a lazy value in target memory representing a single element,
333 then load the element into GDB's memory and copy the contents into the
334 destination value. */
335 void process_element (struct type *elt_type, LONGEST elt_off,
336 LONGEST index, bool last_p)
338 copy_element_to_dest (value_at_lazy (elt_type, m_addr + elt_off));
341 private:
342 /* The address in target memory where the parent value starts. */
343 CORE_ADDR m_addr;
346 /* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
347 slices. This class is specialised for repacking an array slice from a
348 previously loaded (non-lazy) array value, as such it fetches the
349 element values from the contents of the parent value. */
350 class fortran_array_repacker_impl
351 : public fortran_array_repacker_base_impl
353 public:
354 /* Constructor. TYPE is the type for the array slice within the parent
355 value, as such it has stride values as required to find the elements
356 within the original parent value. ADDRESS is the address in target
357 memory of the value matching TYPE. BASE_OFFSET is the offset from
358 the start of VAL's content buffer to the start of the object of TYPE,
359 VAL is the parent object from which we are loading the value, and
360 DEST is the value into which we are repacking. */
361 explicit fortran_array_repacker_impl (struct type *type, CORE_ADDR address,
362 LONGEST base_offset,
363 struct value *val, struct value *dest)
364 : fortran_array_repacker_base_impl (dest),
365 m_base_offset (base_offset),
366 m_val (val)
368 gdb_assert (!val->lazy ());
371 /* Extract an element of ELT_TYPE at offset (M_BASE_OFFSET + ELT_OFF)
372 from the content buffer of M_VAL then copy this extracted value into
373 the repacked destination value. */
374 void process_element (struct type *elt_type, LONGEST elt_off,
375 LONGEST index, bool last_p)
377 struct value *elt
378 = value_from_component (m_val, elt_type, (elt_off + m_base_offset));
379 copy_element_to_dest (elt);
382 private:
383 /* The offset into the content buffer of M_VAL to the start of the slice
384 being extracted. */
385 LONGEST m_base_offset;
387 /* The parent value from which we are extracting a slice. */
388 struct value *m_val;
392 /* Evaluate FORTRAN_ASSOCIATED expressions. Both GDBARCH and LANG are
393 extracted from the expression being evaluated. POINTER is the required
394 first argument to the 'associated' keyword, and TARGET is the optional
395 second argument, this will be nullptr if the user only passed one
396 argument to their use of 'associated'. */
398 static struct value *
399 fortran_associated (struct gdbarch *gdbarch, const language_defn *lang,
400 struct value *pointer, struct value *target = nullptr)
402 struct type *result_type = language_bool_type (lang, gdbarch);
404 /* All Fortran pointers should have the associated property, this is
405 how we know the pointer is pointing at something or not. */
406 struct type *pointer_type = check_typedef (pointer->type ());
407 if (TYPE_ASSOCIATED_PROP (pointer_type) == nullptr
408 && pointer_type->code () != TYPE_CODE_PTR)
409 error (_("ASSOCIATED can only be applied to pointers"));
411 /* Get an address from POINTER. Fortran (or at least gfortran) models
412 array pointers as arrays with a dynamic data address, so we need to
413 use two approaches here, for real pointers we take the contents of the
414 pointer as an address. For non-pointers we take the address of the
415 content. */
416 CORE_ADDR pointer_addr;
417 if (pointer_type->code () == TYPE_CODE_PTR)
418 pointer_addr = value_as_address (pointer);
419 else
420 pointer_addr = pointer->address ();
422 /* The single argument case, is POINTER associated with anything? */
423 if (target == nullptr)
425 bool is_associated = false;
427 /* If POINTER is an actual pointer and doesn't have an associated
428 property then we need to figure out whether this pointer is
429 associated by looking at the value of the pointer itself. We make
430 the assumption that a non-associated pointer will be set to 0.
431 This is probably true for most targets, but might not be true for
432 everyone. */
433 if (pointer_type->code () == TYPE_CODE_PTR
434 && TYPE_ASSOCIATED_PROP (pointer_type) == nullptr)
435 is_associated = (pointer_addr != 0);
436 else
437 is_associated = !type_not_associated (pointer_type);
438 return value_from_longest (result_type, is_associated ? 1 : 0);
441 /* The two argument case, is POINTER associated with TARGET? */
443 struct type *target_type = check_typedef (target->type ());
445 struct type *pointer_target_type;
446 if (pointer_type->code () == TYPE_CODE_PTR)
447 pointer_target_type = pointer_type->target_type ();
448 else
449 pointer_target_type = pointer_type;
451 struct type *target_target_type;
452 if (target_type->code () == TYPE_CODE_PTR)
453 target_target_type = target_type->target_type ();
454 else
455 target_target_type = target_type;
457 if (pointer_target_type->code () != target_target_type->code ()
458 || (pointer_target_type->code () != TYPE_CODE_ARRAY
459 && (pointer_target_type->length ()
460 != target_target_type->length ())))
461 error (_("arguments to associated must be of same type and kind"));
463 /* If TARGET is not in memory, or the original pointer is specifically
464 known to be not associated with anything, then the answer is obviously
465 false. Alternatively, if POINTER is an actual pointer and has no
466 associated property, then we have to check if its associated by
467 looking the value of the pointer itself. We make the assumption that
468 a non-associated pointer will be set to 0. This is probably true for
469 most targets, but might not be true for everyone. */
470 if (target->lval () != lval_memory
471 || type_not_associated (pointer_type)
472 || (TYPE_ASSOCIATED_PROP (pointer_type) == nullptr
473 && pointer_type->code () == TYPE_CODE_PTR
474 && pointer_addr == 0))
475 return value_from_longest (result_type, 0);
477 /* See the comment for POINTER_ADDR above. */
478 CORE_ADDR target_addr;
479 if (target_type->code () == TYPE_CODE_PTR)
480 target_addr = value_as_address (target);
481 else
482 target_addr = target->address ();
484 /* Wrap the following checks inside a do { ... } while (false) loop so
485 that we can use `break' to jump out of the loop. */
486 bool is_associated = false;
489 /* If the addresses are different then POINTER is definitely not
490 pointing at TARGET. */
491 if (pointer_addr != target_addr)
492 break;
494 /* If POINTER is a real pointer (i.e. not an array pointer, which are
495 implemented as arrays with a dynamic content address), then this
496 is all the checking that is needed. */
497 if (pointer_type->code () == TYPE_CODE_PTR)
499 is_associated = true;
500 break;
503 /* We have an array pointer. Check the number of dimensions. */
504 int pointer_dims = calc_f77_array_dims (pointer_type);
505 int target_dims = calc_f77_array_dims (target_type);
506 if (pointer_dims != target_dims)
507 break;
509 /* Now check that every dimension has the same upper bound, lower
510 bound, and stride value. */
511 int dim = 0;
512 while (dim < pointer_dims)
514 LONGEST pointer_lowerbound, pointer_upperbound, pointer_stride;
515 LONGEST target_lowerbound, target_upperbound, target_stride;
517 pointer_type = check_typedef (pointer_type);
518 target_type = check_typedef (target_type);
520 struct type *pointer_range = pointer_type->index_type ();
521 struct type *target_range = target_type->index_type ();
523 if (!get_discrete_bounds (pointer_range, &pointer_lowerbound,
524 &pointer_upperbound))
525 break;
527 if (!get_discrete_bounds (target_range, &target_lowerbound,
528 &target_upperbound))
529 break;
531 if (pointer_lowerbound != target_lowerbound
532 || pointer_upperbound != target_upperbound)
533 break;
535 /* Figure out the stride (in bits) for both pointer and target.
536 If either doesn't have a stride then we take the element size,
537 but we need to convert to bits (hence the * 8). */
538 pointer_stride = pointer_range->bounds ()->bit_stride ();
539 if (pointer_stride == 0)
540 pointer_stride
541 = type_length_units (check_typedef
542 (pointer_type->target_type ())) * 8;
543 target_stride = target_range->bounds ()->bit_stride ();
544 if (target_stride == 0)
545 target_stride
546 = type_length_units (check_typedef
547 (target_type->target_type ())) * 8;
548 if (pointer_stride != target_stride)
549 break;
551 ++dim;
554 if (dim < pointer_dims)
555 break;
557 is_associated = true;
559 while (false);
561 return value_from_longest (result_type, is_associated ? 1 : 0);
564 struct value *
565 eval_op_f_associated (struct type *expect_type,
566 struct expression *exp,
567 enum noside noside,
568 enum exp_opcode opcode,
569 struct value *arg1)
571 return fortran_associated (exp->gdbarch, exp->language_defn, arg1);
574 struct value *
575 eval_op_f_associated (struct type *expect_type,
576 struct expression *exp,
577 enum noside noside,
578 enum exp_opcode opcode,
579 struct value *arg1,
580 struct value *arg2)
582 return fortran_associated (exp->gdbarch, exp->language_defn, arg1, arg2);
585 /* Implement FORTRAN_ARRAY_SIZE expression, this corresponds to the 'SIZE'
586 keyword. RESULT_TYPE corresponds to the type kind the function should be
587 evaluated in, ARRAY is the value that should be an array, though this will
588 not have been checked before calling this function. DIM is optional, if
589 present then it should be an integer identifying a dimension of the
590 array to ask about. As with ARRAY the validity of DIM is not checked
591 before calling this function.
593 Return either the total number of elements in ARRAY (when DIM is
594 nullptr), or the number of elements in dimension DIM. */
596 static value *
597 fortran_array_size (value *array, value *dim_val, type *result_type)
599 /* Check that ARRAY is the correct type. */
600 struct type *array_type = check_typedef (array->type ());
601 if (array_type->code () != TYPE_CODE_ARRAY)
602 error (_("SIZE can only be applied to arrays"));
603 if (type_not_allocated (array_type) || type_not_associated (array_type))
604 error (_("SIZE can only be used on allocated/associated arrays"));
606 int ndimensions = calc_f77_array_dims (array_type);
607 int dim = -1;
608 LONGEST result = 0;
610 if (dim_val != nullptr)
612 if (check_typedef (dim_val->type ())->code () != TYPE_CODE_INT)
613 error (_("DIM argument to SIZE must be an integer"));
614 dim = (int) value_as_long (dim_val);
616 if (dim < 1 || dim > ndimensions)
617 error (_("DIM argument to SIZE must be between 1 and %d"),
618 ndimensions);
621 /* Now walk over all the dimensions of the array totalling up the
622 elements in each dimension. */
623 for (int i = ndimensions - 1; i >= 0; --i)
625 /* If this is the requested dimension then we're done. Grab the
626 bounds and return. */
627 if (i == dim - 1 || dim == -1)
629 LONGEST lbound, ubound;
630 struct type *range = array_type->index_type ();
632 if (!get_discrete_bounds (range, &lbound, &ubound))
633 error (_("failed to find array bounds"));
635 LONGEST dim_size = (ubound - lbound + 1);
636 if (result == 0)
637 result = dim_size;
638 else
639 result *= dim_size;
641 if (dim != -1)
642 break;
645 /* Peel off another dimension of the array. */
646 array_type = array_type->target_type ();
649 return value_from_longest (result_type, result);
652 /* See f-exp.h. */
654 struct value *
655 eval_op_f_array_size (struct type *expect_type,
656 struct expression *exp,
657 enum noside noside,
658 enum exp_opcode opcode,
659 struct value *arg1)
661 gdb_assert (opcode == FORTRAN_ARRAY_SIZE);
663 type *result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
664 return fortran_array_size (arg1, nullptr, result_type);
667 /* See f-exp.h. */
669 struct value *
670 eval_op_f_array_size (struct type *expect_type,
671 struct expression *exp,
672 enum noside noside,
673 enum exp_opcode opcode,
674 struct value *arg1,
675 struct value *arg2)
677 gdb_assert (opcode == FORTRAN_ARRAY_SIZE);
679 type *result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
680 return fortran_array_size (arg1, arg2, result_type);
683 /* See f-exp.h. */
685 value *eval_op_f_array_size (type *expect_type, expression *exp, noside noside,
686 exp_opcode opcode, value *arg1, value *arg2,
687 type *kind_arg)
689 gdb_assert (opcode == FORTRAN_ARRAY_SIZE);
690 gdb_assert (kind_arg->code () == TYPE_CODE_INT);
692 return fortran_array_size (arg1, arg2, kind_arg);
695 /* Implement UNOP_FORTRAN_SHAPE expression. Both GDBARCH and LANG are
696 extracted from the expression being evaluated. VAL is the value on
697 which 'shape' was used, this can be any type.
699 Return an array of integers. If VAL is not an array then the returned
700 array should have zero elements. If VAL is an array then the returned
701 array should have one element per dimension, with the element
702 containing the extent of that dimension from VAL. */
704 static struct value *
705 fortran_array_shape (struct gdbarch *gdbarch, const language_defn *lang,
706 struct value *val)
708 struct type *val_type = check_typedef (val->type ());
710 /* If we are passed an array that is either not allocated, or not
711 associated, then this is explicitly not allowed according to the
712 Fortran specification. */
713 if (val_type->code () == TYPE_CODE_ARRAY
714 && (type_not_associated (val_type) || type_not_allocated (val_type)))
715 error (_("The array passed to SHAPE must be allocated or associated"));
717 /* The Fortran specification allows non-array types to be passed to this
718 function, in which case we get back an empty array.
720 Calculate the number of dimensions for the resulting array. */
721 int ndimensions = 0;
722 if (val_type->code () == TYPE_CODE_ARRAY)
723 ndimensions = calc_f77_array_dims (val_type);
725 /* Allocate a result value of the correct type. */
726 type_allocator alloc (gdbarch);
727 struct type *range
728 = create_static_range_type (alloc,
729 builtin_type (gdbarch)->builtin_int,
730 1, ndimensions);
731 struct type *elm_type = builtin_f_type (gdbarch)->builtin_integer;
732 struct type *result_type = create_array_type (alloc, elm_type, range);
733 struct value *result = value::allocate (result_type);
734 LONGEST elm_len = elm_type->length ();
736 /* Walk the array dimensions backwards due to the way the array will be
737 laid out in memory, the first dimension will be the most inner.
739 If VAL was not an array then ndimensions will be 0, in which case we
740 will never go around this loop. */
741 for (LONGEST dst_offset = elm_len * (ndimensions - 1);
742 dst_offset >= 0;
743 dst_offset -= elm_len)
745 LONGEST lbound, ubound;
747 if (!get_discrete_bounds (val_type->index_type (), &lbound, &ubound))
748 error (_("failed to find array bounds"));
750 LONGEST dim_size = (ubound - lbound + 1);
752 /* And copy the value into the result value. */
753 struct value *v = value_from_longest (elm_type, dim_size);
754 gdb_assert (dst_offset + v->type ()->length ()
755 <= result->type ()->length ());
756 gdb_assert (v->type ()->length () == elm_len);
757 v->contents_copy (result, dst_offset, 0, elm_len);
759 /* Peel another dimension of the array. */
760 val_type = val_type->target_type ();
763 return result;
766 /* See f-exp.h. */
768 struct value *
769 eval_op_f_array_shape (struct type *expect_type, struct expression *exp,
770 enum noside noside, enum exp_opcode opcode,
771 struct value *arg1)
773 gdb_assert (opcode == UNOP_FORTRAN_SHAPE);
774 return fortran_array_shape (exp->gdbarch, exp->language_defn, arg1);
777 /* A helper function for UNOP_ABS. */
779 struct value *
780 eval_op_f_abs (struct type *expect_type, struct expression *exp,
781 enum noside noside,
782 enum exp_opcode opcode,
783 struct value *arg1)
785 struct type *type = arg1->type ();
786 switch (type->code ())
788 case TYPE_CODE_FLT:
790 double d
791 = fabs (target_float_to_host_double (arg1->contents ().data (),
792 arg1->type ()));
793 return value_from_host_double (type, d);
795 case TYPE_CODE_INT:
797 LONGEST l = value_as_long (arg1);
798 l = llabs (l);
799 return value_from_longest (type, l);
802 error (_("ABS of type %s not supported"), TYPE_SAFE_NAME (type));
805 /* A helper function for BINOP_MOD. */
807 struct value *
808 eval_op_f_mod (struct type *expect_type, struct expression *exp,
809 enum noside noside,
810 enum exp_opcode opcode,
811 struct value *arg1, struct value *arg2)
813 struct type *type = arg1->type ();
814 if (type->code () != arg2->type ()->code ())
815 error (_("non-matching types for parameters to MOD ()"));
816 switch (type->code ())
818 case TYPE_CODE_FLT:
820 double d1
821 = target_float_to_host_double (arg1->contents ().data (),
822 arg1->type ());
823 double d2
824 = target_float_to_host_double (arg2->contents ().data (),
825 arg2->type ());
826 double d3 = fmod (d1, d2);
827 return value_from_host_double (type, d3);
829 case TYPE_CODE_INT:
831 LONGEST v1 = value_as_long (arg1);
832 LONGEST v2 = value_as_long (arg2);
833 if (v2 == 0)
834 error (_("calling MOD (N, 0) is undefined"));
835 LONGEST v3 = v1 - (v1 / v2) * v2;
836 return value_from_longest (arg1->type (), v3);
839 error (_("MOD of type %s not supported"), TYPE_SAFE_NAME (type));
842 /* A helper function for the different FORTRAN_CEILING overloads. Calculates
843 CEILING for ARG1 (a float type) and returns it in the requested kind type
844 RESULT_TYPE. */
846 static value *
847 fortran_ceil_operation (value *arg1, type *result_type)
849 if (arg1->type ()->code () != TYPE_CODE_FLT)
850 error (_("argument to CEILING must be of type float"));
851 double val = target_float_to_host_double (arg1->contents ().data (),
852 arg1->type ());
853 val = ceil (val);
854 return value_from_longest (result_type, val);
857 /* A helper function for FORTRAN_CEILING. */
859 struct value *
860 eval_op_f_ceil (struct type *expect_type, struct expression *exp,
861 enum noside noside,
862 enum exp_opcode opcode,
863 struct value *arg1)
865 gdb_assert (opcode == FORTRAN_CEILING);
866 type *result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
867 return fortran_ceil_operation (arg1, result_type);
870 /* A helper function for FORTRAN_CEILING. */
872 value *
873 eval_op_f_ceil (type *expect_type, expression *exp, noside noside,
874 exp_opcode opcode, value *arg1, type *kind_arg)
876 gdb_assert (opcode == FORTRAN_CEILING);
877 gdb_assert (kind_arg->code () == TYPE_CODE_INT);
878 return fortran_ceil_operation (arg1, kind_arg);
881 /* A helper function for the different FORTRAN_FLOOR overloads. Calculates
882 FLOOR for ARG1 (a float type) and returns it in the requested kind type
883 RESULT_TYPE. */
885 static value *
886 fortran_floor_operation (value *arg1, type *result_type)
888 if (arg1->type ()->code () != TYPE_CODE_FLT)
889 error (_("argument to FLOOR must be of type float"));
890 double val = target_float_to_host_double (arg1->contents ().data (),
891 arg1->type ());
892 val = floor (val);
893 return value_from_longest (result_type, val);
896 /* A helper function for FORTRAN_FLOOR. */
898 struct value *
899 eval_op_f_floor (struct type *expect_type, struct expression *exp,
900 enum noside noside,
901 enum exp_opcode opcode,
902 struct value *arg1)
904 gdb_assert (opcode == FORTRAN_FLOOR);
905 type *result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
906 return fortran_floor_operation (arg1, result_type);
909 /* A helper function for FORTRAN_FLOOR. */
911 struct value *
912 eval_op_f_floor (type *expect_type, expression *exp, noside noside,
913 exp_opcode opcode, value *arg1, type *kind_arg)
915 gdb_assert (opcode == FORTRAN_FLOOR);
916 gdb_assert (kind_arg->code () == TYPE_CODE_INT);
917 return fortran_floor_operation (arg1, kind_arg);
920 /* A helper function for BINOP_FORTRAN_MODULO. */
922 struct value *
923 eval_op_f_modulo (struct type *expect_type, struct expression *exp,
924 enum noside noside,
925 enum exp_opcode opcode,
926 struct value *arg1, struct value *arg2)
928 struct type *type = arg1->type ();
929 if (type->code () != arg2->type ()->code ())
930 error (_("non-matching types for parameters to MODULO ()"));
931 /* MODULO(A, P) = A - FLOOR (A / P) * P */
932 switch (type->code ())
934 case TYPE_CODE_INT:
936 LONGEST a = value_as_long (arg1);
937 LONGEST p = value_as_long (arg2);
938 LONGEST result = a - (a / p) * p;
939 if (result != 0 && (a < 0) != (p < 0))
940 result += p;
941 return value_from_longest (arg1->type (), result);
943 case TYPE_CODE_FLT:
945 double a
946 = target_float_to_host_double (arg1->contents ().data (),
947 arg1->type ());
948 double p
949 = target_float_to_host_double (arg2->contents ().data (),
950 arg2->type ());
951 double result = fmod (a, p);
952 if (result != 0 && (a < 0.0) != (p < 0.0))
953 result += p;
954 return value_from_host_double (type, result);
957 error (_("MODULO of type %s not supported"), TYPE_SAFE_NAME (type));
960 /* A helper function for FORTRAN_CMPLX. */
962 value *
963 eval_op_f_cmplx (type *expect_type, expression *exp, noside noside,
964 exp_opcode opcode, value *arg1)
966 gdb_assert (opcode == FORTRAN_CMPLX);
968 type *result_type = builtin_f_type (exp->gdbarch)->builtin_complex;
970 if (arg1->type ()->code () == TYPE_CODE_COMPLEX)
971 return value_cast (result_type, arg1);
972 else
973 return value_literal_complex (arg1,
974 value::zero (arg1->type (), not_lval),
975 result_type);
978 /* A helper function for FORTRAN_CMPLX. */
980 struct value *
981 eval_op_f_cmplx (struct type *expect_type, struct expression *exp,
982 enum noside noside,
983 enum exp_opcode opcode,
984 struct value *arg1, struct value *arg2)
986 if (arg1->type ()->code () == TYPE_CODE_COMPLEX
987 || arg2->type ()->code () == TYPE_CODE_COMPLEX)
988 error (_("Types of arguments for CMPLX called with more then one argument "
989 "must be REAL or INTEGER"));
991 type *result_type = builtin_f_type (exp->gdbarch)->builtin_complex;
992 return value_literal_complex (arg1, arg2, result_type);
995 /* A helper function for FORTRAN_CMPLX. */
997 value *
998 eval_op_f_cmplx (type *expect_type, expression *exp, noside noside,
999 exp_opcode opcode, value *arg1, value *arg2, type *kind_arg)
1001 gdb_assert (kind_arg->code () == TYPE_CODE_COMPLEX);
1002 if (arg1->type ()->code () == TYPE_CODE_COMPLEX
1003 || arg2->type ()->code () == TYPE_CODE_COMPLEX)
1004 error (_("Types of arguments for CMPLX called with more then one argument "
1005 "must be REAL or INTEGER"));
1007 return value_literal_complex (arg1, arg2, kind_arg);
1010 /* A helper function for UNOP_FORTRAN_KIND. */
1012 struct value *
1013 eval_op_f_kind (struct type *expect_type, struct expression *exp,
1014 enum noside noside,
1015 enum exp_opcode opcode,
1016 struct value *arg1)
1018 struct type *type = arg1->type ();
1020 switch (type->code ())
1022 case TYPE_CODE_STRUCT:
1023 case TYPE_CODE_UNION:
1024 case TYPE_CODE_MODULE:
1025 case TYPE_CODE_FUNC:
1026 error (_("argument to kind must be an intrinsic type"));
1029 if (!type->target_type ())
1030 return value_from_longest (builtin_type (exp->gdbarch)->builtin_int,
1031 type->length ());
1032 return value_from_longest (builtin_type (exp->gdbarch)->builtin_int,
1033 type->target_type ()->length ());
1036 /* A helper function for UNOP_FORTRAN_ALLOCATED. */
1038 struct value *
1039 eval_op_f_allocated (struct type *expect_type, struct expression *exp,
1040 enum noside noside, enum exp_opcode op,
1041 struct value *arg1)
1043 struct type *type = check_typedef (arg1->type ());
1044 if (type->code () != TYPE_CODE_ARRAY)
1045 error (_("ALLOCATED can only be applied to arrays"));
1046 struct type *result_type
1047 = builtin_f_type (exp->gdbarch)->builtin_logical;
1048 LONGEST result_value = type_not_allocated (type) ? 0 : 1;
1049 return value_from_longest (result_type, result_value);
1052 /* See f-exp.h. */
1054 struct value *
1055 eval_op_f_rank (struct type *expect_type,
1056 struct expression *exp,
1057 enum noside noside,
1058 enum exp_opcode op,
1059 struct value *arg1)
1061 gdb_assert (op == UNOP_FORTRAN_RANK);
1063 struct type *result_type
1064 = builtin_f_type (exp->gdbarch)->builtin_integer;
1065 struct type *type = check_typedef (arg1->type ());
1066 if (type->code () != TYPE_CODE_ARRAY)
1067 return value_from_longest (result_type, 0);
1068 LONGEST ndim = calc_f77_array_dims (type);
1069 return value_from_longest (result_type, ndim);
1072 /* A helper function for UNOP_FORTRAN_LOC. */
1074 struct value *
1075 eval_op_f_loc (struct type *expect_type, struct expression *exp,
1076 enum noside noside, enum exp_opcode op,
1077 struct value *arg1)
1079 struct type *result_type;
1080 if (gdbarch_ptr_bit (exp->gdbarch) == 16)
1081 result_type = builtin_f_type (exp->gdbarch)->builtin_integer_s2;
1082 else if (gdbarch_ptr_bit (exp->gdbarch) == 32)
1083 result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
1084 else
1085 result_type = builtin_f_type (exp->gdbarch)->builtin_integer_s8;
1087 LONGEST result_value = arg1->address ();
1088 return value_from_longest (result_type, result_value);
1091 namespace expr
1094 /* Called from evaluate to perform array indexing, and sub-range
1095 extraction, for Fortran. As well as arrays this function also
1096 handles strings as they can be treated like arrays of characters.
1097 ARRAY is the array or string being accessed. EXP and NOSIDE are as
1098 for evaluate. */
1100 value *
1101 fortran_undetermined::value_subarray (value *array,
1102 struct expression *exp,
1103 enum noside noside)
1105 type *original_array_type = check_typedef (array->type ());
1106 bool is_string_p = original_array_type->code () == TYPE_CODE_STRING;
1107 const std::vector<operation_up> &ops = std::get<1> (m_storage);
1108 int nargs = ops.size ();
1110 /* Perform checks for ARRAY not being available. The somewhat overly
1111 complex logic here is just to keep backward compatibility with the
1112 errors that we used to get before FORTRAN_VALUE_SUBARRAY was
1113 rewritten. Maybe a future task would streamline the error messages we
1114 get here, and update all the expected test results. */
1115 if (ops[0]->opcode () != OP_RANGE)
1117 if (type_not_associated (original_array_type))
1118 error (_("no such vector element (vector not associated)"));
1119 else if (type_not_allocated (original_array_type))
1120 error (_("no such vector element (vector not allocated)"));
1122 else
1124 if (type_not_associated (original_array_type))
1125 error (_("array not associated"));
1126 else if (type_not_allocated (original_array_type))
1127 error (_("array not allocated"));
1130 /* First check that the number of dimensions in the type we are slicing
1131 matches the number of arguments we were passed. */
1132 int ndimensions = calc_f77_array_dims (original_array_type);
1133 if (nargs != ndimensions)
1134 error (_("Wrong number of subscripts"));
1136 /* This will be initialised below with the type of the elements held in
1137 ARRAY. */
1138 struct type *inner_element_type;
1140 /* Extract the types of each array dimension from the original array
1141 type. We need these available so we can fill in the default upper and
1142 lower bounds if the user requested slice doesn't provide that
1143 information. Additionally unpacking the dimensions like this gives us
1144 the inner element type. */
1145 std::vector<struct type *> dim_types;
1147 dim_types.reserve (ndimensions);
1148 struct type *type = original_array_type;
1149 for (int i = 0; i < ndimensions; ++i)
1151 dim_types.push_back (type);
1152 type = type->target_type ();
1154 /* TYPE is now the inner element type of the array, we start the new
1155 array slice off as this type, then as we process the requested slice
1156 (from the user) we wrap new types around this to build up the final
1157 slice type. */
1158 inner_element_type = type;
1161 /* As we analyse the new slice type we need to understand if the data
1162 being referenced is contiguous. Do decide this we must track the size
1163 of an element at each dimension of the new slice array. Initially the
1164 elements of the inner most dimension of the array are the same inner
1165 most elements as the original ARRAY. */
1166 LONGEST slice_element_size = inner_element_type->length ();
1168 /* Start off assuming all data is contiguous, this will be set to false
1169 if access to any dimension results in non-contiguous data. */
1170 bool is_all_contiguous = true;
1172 /* The TOTAL_OFFSET is the distance in bytes from the start of the
1173 original ARRAY to the start of the new slice. This is calculated as
1174 we process the information from the user. */
1175 LONGEST total_offset = 0;
1177 /* A structure representing information about each dimension of the
1178 resulting slice. */
1179 struct slice_dim
1181 /* Constructor. */
1182 slice_dim (LONGEST l, LONGEST h, LONGEST s, struct type *idx)
1183 : low (l),
1184 high (h),
1185 stride (s),
1186 index (idx)
1187 { /* Nothing. */ }
1189 /* The low bound for this dimension of the slice. */
1190 LONGEST low;
1192 /* The high bound for this dimension of the slice. */
1193 LONGEST high;
1195 /* The byte stride for this dimension of the slice. */
1196 LONGEST stride;
1198 struct type *index;
1201 /* The dimensions of the resulting slice. */
1202 std::vector<slice_dim> slice_dims;
1204 /* Process the incoming arguments. These arguments are in the reverse
1205 order to the array dimensions, that is the first argument refers to
1206 the last array dimension. */
1207 if (fortran_array_slicing_debug)
1208 debug_printf ("Processing array access:\n");
1209 for (int i = 0; i < nargs; ++i)
1211 /* For each dimension of the array the user will have either provided
1212 a ranged access with optional lower bound, upper bound, and
1213 stride, or the user will have supplied a single index. */
1214 struct type *dim_type = dim_types[ndimensions - (i + 1)];
1215 fortran_range_operation *range_op
1216 = dynamic_cast<fortran_range_operation *> (ops[i].get ());
1217 if (range_op != nullptr)
1219 enum range_flag range_flag = range_op->get_flags ();
1221 LONGEST low, high, stride;
1222 low = high = stride = 0;
1224 if ((range_flag & RANGE_LOW_BOUND_DEFAULT) == 0)
1225 low = value_as_long (range_op->evaluate0 (exp, noside));
1226 else
1227 low = f77_get_lowerbound (dim_type);
1228 if ((range_flag & RANGE_HIGH_BOUND_DEFAULT) == 0)
1229 high = value_as_long (range_op->evaluate1 (exp, noside));
1230 else
1231 high = f77_get_upperbound (dim_type);
1232 if ((range_flag & RANGE_HAS_STRIDE) == RANGE_HAS_STRIDE)
1233 stride = value_as_long (range_op->evaluate2 (exp, noside));
1234 else
1235 stride = 1;
1237 if (stride == 0)
1238 error (_("stride must not be 0"));
1240 /* Get information about this dimension in the original ARRAY. */
1241 struct type *target_type = dim_type->target_type ();
1242 struct type *index_type = dim_type->index_type ();
1243 LONGEST lb = f77_get_lowerbound (dim_type);
1244 LONGEST ub = f77_get_upperbound (dim_type);
1245 LONGEST sd = index_type->bit_stride ();
1246 if (sd == 0)
1247 sd = target_type->length () * 8;
1249 if (fortran_array_slicing_debug)
1251 debug_printf ("|-> Range access\n");
1252 std::string str = type_to_string (dim_type);
1253 debug_printf ("| |-> Type: %s\n", str.c_str ());
1254 debug_printf ("| |-> Array:\n");
1255 debug_printf ("| | |-> Low bound: %s\n", plongest (lb));
1256 debug_printf ("| | |-> High bound: %s\n", plongest (ub));
1257 debug_printf ("| | |-> Bit stride: %s\n", plongest (sd));
1258 debug_printf ("| | |-> Byte stride: %s\n", plongest (sd / 8));
1259 debug_printf ("| | |-> Type size: %s\n",
1260 pulongest (dim_type->length ()));
1261 debug_printf ("| | '-> Target type size: %s\n",
1262 pulongest (target_type->length ()));
1263 debug_printf ("| |-> Accessing:\n");
1264 debug_printf ("| | |-> Low bound: %s\n",
1265 plongest (low));
1266 debug_printf ("| | |-> High bound: %s\n",
1267 plongest (high));
1268 debug_printf ("| | '-> Element stride: %s\n",
1269 plongest (stride));
1272 /* Check the user hasn't asked for something invalid. */
1273 if (high > ub || low < lb)
1274 error (_("array subscript out of bounds"));
1276 /* Calculate what this dimension of the new slice array will look
1277 like. OFFSET is the byte offset from the start of the
1278 previous (more outer) dimension to the start of this
1279 dimension. E_COUNT is the number of elements in this
1280 dimension. REMAINDER is the number of elements remaining
1281 between the last included element and the upper bound. For
1282 example an access '1:6:2' will include elements 1, 3, 5 and
1283 have a remainder of 1 (element #6). */
1284 LONGEST lowest = std::min (low, high);
1285 LONGEST offset = (sd / 8) * (lowest - lb);
1286 LONGEST e_count = std::abs (high - low) + 1;
1287 e_count = (e_count + (std::abs (stride) - 1)) / std::abs (stride);
1288 LONGEST new_low = 1;
1289 LONGEST new_high = new_low + e_count - 1;
1290 LONGEST new_stride = (sd * stride) / 8;
1291 LONGEST last_elem = low + ((e_count - 1) * stride);
1292 LONGEST remainder = high - last_elem;
1293 if (low > high)
1295 offset += std::abs (remainder) * target_type->length ();
1296 if (stride > 0)
1297 error (_("incorrect stride and boundary combination"));
1299 else if (stride < 0)
1300 error (_("incorrect stride and boundary combination"));
1302 /* Is the data within this dimension contiguous? It is if the
1303 newly computed stride is the same size as a single element of
1304 this dimension. */
1305 bool is_dim_contiguous = (new_stride == slice_element_size);
1306 is_all_contiguous &= is_dim_contiguous;
1308 if (fortran_array_slicing_debug)
1310 debug_printf ("| '-> Results:\n");
1311 debug_printf ("| |-> Offset = %s\n", plongest (offset));
1312 debug_printf ("| |-> Elements = %s\n", plongest (e_count));
1313 debug_printf ("| |-> Low bound = %s\n", plongest (new_low));
1314 debug_printf ("| |-> High bound = %s\n",
1315 plongest (new_high));
1316 debug_printf ("| |-> Byte stride = %s\n",
1317 plongest (new_stride));
1318 debug_printf ("| |-> Last element = %s\n",
1319 plongest (last_elem));
1320 debug_printf ("| |-> Remainder = %s\n",
1321 plongest (remainder));
1322 debug_printf ("| '-> Contiguous = %s\n",
1323 (is_dim_contiguous ? "Yes" : "No"));
1326 /* Figure out how big (in bytes) an element of this dimension of
1327 the new array slice will be. */
1328 slice_element_size = std::abs (new_stride * e_count);
1330 slice_dims.emplace_back (new_low, new_high, new_stride,
1331 index_type);
1333 /* Update the total offset. */
1334 total_offset += offset;
1336 else
1338 /* There is a single index for this dimension. */
1339 LONGEST index
1340 = value_as_long (ops[i]->evaluate_with_coercion (exp, noside));
1342 /* Get information about this dimension in the original ARRAY. */
1343 struct type *target_type = dim_type->target_type ();
1344 struct type *index_type = dim_type->index_type ();
1345 LONGEST lb = f77_get_lowerbound (dim_type);
1346 LONGEST ub = f77_get_upperbound (dim_type);
1347 LONGEST sd = index_type->bit_stride () / 8;
1348 if (sd == 0)
1349 sd = target_type->length ();
1351 if (fortran_array_slicing_debug)
1353 debug_printf ("|-> Index access\n");
1354 std::string str = type_to_string (dim_type);
1355 debug_printf ("| |-> Type: %s\n", str.c_str ());
1356 debug_printf ("| |-> Array:\n");
1357 debug_printf ("| | |-> Low bound: %s\n", plongest (lb));
1358 debug_printf ("| | |-> High bound: %s\n", plongest (ub));
1359 debug_printf ("| | |-> Byte stride: %s\n", plongest (sd));
1360 debug_printf ("| | |-> Type size: %s\n",
1361 pulongest (dim_type->length ()));
1362 debug_printf ("| | '-> Target type size: %s\n",
1363 pulongest (target_type->length ()));
1364 debug_printf ("| '-> Accessing:\n");
1365 debug_printf ("| '-> Index: %s\n",
1366 plongest (index));
1369 /* If the array has actual content then check the index is in
1370 bounds. An array without content (an unbound array) doesn't
1371 have a known upper bound, so don't error check in that
1372 situation. */
1373 if (index < lb
1374 || (dim_type->index_type ()->bounds ()->high.is_available ()
1375 && index > ub)
1376 || (array->lval () != lval_memory
1377 && dim_type->index_type ()->bounds ()->high.kind () == PROP_UNDEFINED))
1379 if (type_not_associated (dim_type))
1380 error (_("no such vector element (vector not associated)"));
1381 else if (type_not_allocated (dim_type))
1382 error (_("no such vector element (vector not allocated)"));
1383 else
1384 error (_("no such vector element"));
1387 /* Calculate using the type stride, not the target type size. */
1388 LONGEST offset = sd * (index - lb);
1389 total_offset += offset;
1393 /* Build a type that represents the new array slice in the target memory
1394 of the original ARRAY, this type makes use of strides to correctly
1395 find only those elements that are part of the new slice. */
1396 struct type *array_slice_type = inner_element_type;
1397 for (const auto &d : slice_dims)
1399 /* Create the range. */
1400 dynamic_prop p_low, p_high, p_stride;
1402 p_low.set_const_val (d.low);
1403 p_high.set_const_val (d.high);
1404 p_stride.set_const_val (d.stride);
1406 type_allocator alloc (d.index->target_type ());
1407 struct type *new_range
1408 = create_range_type_with_stride (alloc,
1409 d.index->target_type (),
1410 &p_low, &p_high, 0, &p_stride,
1411 true);
1412 array_slice_type
1413 = create_array_type (alloc, array_slice_type, new_range);
1416 if (fortran_array_slicing_debug)
1418 debug_printf ("'-> Final result:\n");
1419 debug_printf (" |-> Type: %s\n",
1420 type_to_string (array_slice_type).c_str ());
1421 debug_printf (" |-> Total offset: %s\n",
1422 plongest (total_offset));
1423 debug_printf (" |-> Base address: %s\n",
1424 core_addr_to_string (array->address ()));
1425 debug_printf (" '-> Contiguous = %s\n",
1426 (is_all_contiguous ? "Yes" : "No"));
1429 /* Should we repack this array slice? */
1430 if (!is_all_contiguous && (repack_array_slices || is_string_p))
1432 /* Build a type for the repacked slice. */
1433 struct type *repacked_array_type = inner_element_type;
1434 for (const auto &d : slice_dims)
1436 /* Create the range. */
1437 dynamic_prop p_low, p_high, p_stride;
1439 p_low.set_const_val (d.low);
1440 p_high.set_const_val (d.high);
1441 p_stride.set_const_val (repacked_array_type->length ());
1443 type_allocator alloc (d.index->target_type ());
1444 struct type *new_range
1445 = create_range_type_with_stride (alloc,
1446 d.index->target_type (),
1447 &p_low, &p_high, 0, &p_stride,
1448 true);
1449 repacked_array_type
1450 = create_array_type (alloc, repacked_array_type, new_range);
1453 /* Now copy the elements from the original ARRAY into the packed
1454 array value DEST. */
1455 struct value *dest = value::allocate (repacked_array_type);
1456 if (array->lazy ()
1457 || (total_offset + array_slice_type->length ()
1458 > check_typedef (array->type ())->length ()))
1460 fortran_array_walker<fortran_lazy_array_repacker_impl> p
1461 (array_slice_type, array->address () + total_offset, dest);
1462 p.walk ();
1464 else
1466 fortran_array_walker<fortran_array_repacker_impl> p
1467 (array_slice_type, array->address () + total_offset,
1468 total_offset, array, dest);
1469 p.walk ();
1471 array = dest;
1473 else
1475 if (array->lval () == lval_memory)
1477 /* If the value we're taking a slice from is not yet loaded, or
1478 the requested slice is outside the values content range then
1479 just create a new lazy value pointing at the memory where the
1480 contents we're looking for exist. */
1481 if (array->lazy ()
1482 || (total_offset + array_slice_type->length ()
1483 > check_typedef (array->type ())->length ()))
1484 array = value_at_lazy (array_slice_type,
1485 array->address () + total_offset);
1486 else
1487 array = value_from_contents_and_address
1488 (array_slice_type, array->contents ().data () + total_offset,
1489 array->address () + total_offset);
1491 else if (!array->lazy ())
1492 array = value_from_component (array, array_slice_type, total_offset);
1493 else
1494 error (_("cannot subscript arrays that are not in memory"));
1497 return array;
1500 value *
1501 fortran_undetermined::evaluate (struct type *expect_type,
1502 struct expression *exp,
1503 enum noside noside)
1505 value *callee = std::get<0> (m_storage)->evaluate (nullptr, exp, noside);
1506 if (noside == EVAL_AVOID_SIDE_EFFECTS
1507 && is_dynamic_type (callee->type ()))
1508 callee = std::get<0> (m_storage)->evaluate (nullptr, exp, EVAL_NORMAL);
1509 struct type *type = check_typedef (callee->type ());
1510 enum type_code code = type->code ();
1512 if (code == TYPE_CODE_PTR)
1514 /* Fortran always passes variable to subroutines as pointer.
1515 So we need to look into its target type to see if it is
1516 array, string or function. If it is, we need to switch
1517 to the target value the original one points to. */
1518 struct type *target_type = check_typedef (type->target_type ());
1520 if (target_type->code () == TYPE_CODE_ARRAY
1521 || target_type->code () == TYPE_CODE_STRING
1522 || target_type->code () == TYPE_CODE_FUNC)
1524 callee = value_ind (callee);
1525 type = check_typedef (callee->type ());
1526 code = type->code ();
1530 switch (code)
1532 case TYPE_CODE_ARRAY:
1533 case TYPE_CODE_STRING:
1534 return value_subarray (callee, exp, noside);
1536 case TYPE_CODE_PTR:
1537 case TYPE_CODE_FUNC:
1538 case TYPE_CODE_INTERNAL_FUNCTION:
1540 /* It's a function call. Allocate arg vector, including
1541 space for the function to be called in argvec[0] and a
1542 termination NULL. */
1543 const std::vector<operation_up> &actual (std::get<1> (m_storage));
1544 std::vector<value *> argvec (actual.size ());
1545 bool is_internal_func = (code == TYPE_CODE_INTERNAL_FUNCTION);
1546 for (int tem = 0; tem < argvec.size (); tem++)
1547 argvec[tem] = fortran_prepare_argument (exp, actual[tem].get (),
1548 tem, is_internal_func,
1549 callee->type (),
1550 noside);
1551 return evaluate_subexp_do_call (exp, noside, callee, argvec,
1552 nullptr, expect_type);
1555 default:
1556 error (_("Cannot perform substring on this type"));
1560 value *
1561 fortran_bound_1arg::evaluate (struct type *expect_type,
1562 struct expression *exp,
1563 enum noside noside)
1565 bool lbound_p = std::get<0> (m_storage) == FORTRAN_LBOUND;
1566 value *arg1 = std::get<1> (m_storage)->evaluate (nullptr, exp, noside);
1567 fortran_require_array (arg1->type (), lbound_p);
1568 return fortran_bounds_all_dims (lbound_p, exp->gdbarch, arg1);
1571 value *
1572 fortran_bound_2arg::evaluate (struct type *expect_type,
1573 struct expression *exp,
1574 enum noside noside)
1576 bool lbound_p = std::get<0> (m_storage) == FORTRAN_LBOUND;
1577 value *arg1 = std::get<1> (m_storage)->evaluate (nullptr, exp, noside);
1578 fortran_require_array (arg1->type (), lbound_p);
1580 /* User asked for the bounds of a specific dimension of the array. */
1581 value *arg2 = std::get<2> (m_storage)->evaluate (nullptr, exp, noside);
1582 type *type_arg2 = check_typedef (arg2->type ());
1583 if (type_arg2->code () != TYPE_CODE_INT)
1585 if (lbound_p)
1586 error (_("LBOUND second argument should be an integer"));
1587 else
1588 error (_("UBOUND second argument should be an integer"));
1591 type *result_type = builtin_f_type (exp->gdbarch)->builtin_integer;
1592 return fortran_bounds_for_dimension (lbound_p, arg1, arg2, result_type);
1595 value *
1596 fortran_bound_3arg::evaluate (type *expect_type,
1597 expression *exp,
1598 noside noside)
1600 const bool lbound_p = std::get<0> (m_storage) == FORTRAN_LBOUND;
1601 value *arg1 = std::get<1> (m_storage)->evaluate (nullptr, exp, noside);
1602 fortran_require_array (arg1->type (), lbound_p);
1604 /* User asked for the bounds of a specific dimension of the array. */
1605 value *arg2 = std::get<2> (m_storage)->evaluate (nullptr, exp, noside);
1606 type *type_arg2 = check_typedef (arg2->type ());
1607 if (type_arg2->code () != TYPE_CODE_INT)
1609 if (lbound_p)
1610 error (_("LBOUND second argument should be an integer"));
1611 else
1612 error (_("UBOUND second argument should be an integer"));
1615 type *kind_arg = std::get<3> (m_storage);
1616 gdb_assert (kind_arg->code () == TYPE_CODE_INT);
1618 return fortran_bounds_for_dimension (lbound_p, arg1, arg2, kind_arg);
1621 /* Implement STRUCTOP_STRUCT for Fortran. See operation::evaluate in
1622 expression.h for argument descriptions. */
1624 value *
1625 fortran_structop_operation::evaluate (struct type *expect_type,
1626 struct expression *exp,
1627 enum noside noside)
1629 value *arg1 = std::get<0> (m_storage)->evaluate (nullptr, exp, noside);
1630 const char *str = std::get<1> (m_storage).c_str ();
1631 if (noside == EVAL_AVOID_SIDE_EFFECTS)
1633 struct type *type = lookup_struct_elt_type (arg1->type (), str, 1);
1635 if (type != nullptr && is_dynamic_type (type))
1636 arg1 = std::get<0> (m_storage)->evaluate (nullptr, exp, EVAL_NORMAL);
1639 value *elt = value_struct_elt (&arg1, {}, str, NULL, "structure");
1641 if (noside == EVAL_AVOID_SIDE_EFFECTS)
1643 struct type *elt_type = elt->type ();
1644 if (is_dynamic_type (elt_type))
1646 const gdb_byte *valaddr = elt->contents_for_printing ().data ();
1647 CORE_ADDR address = elt->address ();
1648 gdb::array_view<const gdb_byte> view
1649 = gdb::make_array_view (valaddr, elt_type->length ());
1650 elt_type = resolve_dynamic_type (elt_type, view, address);
1652 elt = value::zero (elt_type, elt->lval ());
1655 return elt;
1658 } /* namespace expr */
1660 /* See language.h. */
1662 void
1663 f_language::print_array_index (struct type *index_type, LONGEST index,
1664 struct ui_file *stream,
1665 const value_print_options *options) const
1667 struct value *index_value = value_from_longest (index_type, index);
1669 gdb_printf (stream, "(");
1670 value_print (index_value, stream, options);
1671 gdb_printf (stream, ") = ");
1674 /* See language.h. */
1676 void
1677 f_language::language_arch_info (struct gdbarch *gdbarch,
1678 struct language_arch_info *lai) const
1680 const struct builtin_f_type *builtin = builtin_f_type (gdbarch);
1682 /* Helper function to allow shorter lines below. */
1683 auto add = [&] (struct type * t)
1685 lai->add_primitive_type (t);
1688 add (builtin->builtin_character);
1689 add (builtin->builtin_logical);
1690 add (builtin->builtin_logical_s1);
1691 add (builtin->builtin_logical_s2);
1692 add (builtin->builtin_logical_s8);
1693 add (builtin->builtin_real);
1694 add (builtin->builtin_real_s8);
1695 add (builtin->builtin_real_s16);
1696 add (builtin->builtin_complex);
1697 add (builtin->builtin_complex_s8);
1698 add (builtin->builtin_void);
1700 lai->set_string_char_type (builtin->builtin_character);
1701 lai->set_bool_type (builtin->builtin_logical, "logical");
1704 /* See language.h. */
1706 unsigned int
1707 f_language::search_name_hash (const char *name) const
1709 return cp_search_name_hash (name);
1712 /* See language.h. */
1714 struct block_symbol
1715 f_language::lookup_symbol_nonlocal (const char *name,
1716 const struct block *block,
1717 const domain_search_flags domain) const
1719 return cp_lookup_symbol_nonlocal (this, name, block, domain);
1722 /* See language.h. */
1724 symbol_name_matcher_ftype *
1725 f_language::get_symbol_name_matcher_inner
1726 (const lookup_name_info &lookup_name) const
1728 return cp_get_symbol_name_matcher (lookup_name);
1731 /* Single instance of the Fortran language class. */
1733 static f_language f_language_defn;
1735 static struct builtin_f_type *
1736 build_fortran_types (struct gdbarch *gdbarch)
1738 struct builtin_f_type *builtin_f_type = new struct builtin_f_type;
1740 builtin_f_type->builtin_void = builtin_type (gdbarch)->builtin_void;
1742 type_allocator alloc (gdbarch);
1744 builtin_f_type->builtin_character
1745 = alloc.new_type (TYPE_CODE_CHAR, TARGET_CHAR_BIT, "character");
1747 builtin_f_type->builtin_logical_s1
1748 = init_boolean_type (alloc, TARGET_CHAR_BIT, 1, "logical*1");
1750 builtin_f_type->builtin_logical_s2
1751 = init_boolean_type (alloc, gdbarch_short_bit (gdbarch), 1, "logical*2");
1753 builtin_f_type->builtin_logical
1754 = init_boolean_type (alloc, gdbarch_int_bit (gdbarch), 1, "logical*4");
1756 builtin_f_type->builtin_logical_s8
1757 = init_boolean_type (alloc, gdbarch_long_long_bit (gdbarch), 1,
1758 "logical*8");
1760 builtin_f_type->builtin_integer_s1
1761 = init_integer_type (alloc, TARGET_CHAR_BIT, 0, "integer*1");
1763 builtin_f_type->builtin_integer_s2
1764 = init_integer_type (alloc, gdbarch_short_bit (gdbarch), 0, "integer*2");
1766 builtin_f_type->builtin_integer
1767 = init_integer_type (alloc, gdbarch_int_bit (gdbarch), 0, "integer*4");
1769 builtin_f_type->builtin_integer_s8
1770 = init_integer_type (alloc, gdbarch_long_long_bit (gdbarch), 0,
1771 "integer*8");
1773 builtin_f_type->builtin_real
1774 = init_float_type (alloc, gdbarch_float_bit (gdbarch),
1775 "real*4", gdbarch_float_format (gdbarch));
1777 builtin_f_type->builtin_real_s8
1778 = init_float_type (alloc, gdbarch_double_bit (gdbarch),
1779 "real*8", gdbarch_double_format (gdbarch));
1781 auto fmt = gdbarch_floatformat_for_type (gdbarch, "real(kind=16)", 128);
1782 if (fmt != nullptr)
1783 builtin_f_type->builtin_real_s16
1784 = init_float_type (alloc, 128, "real*16", fmt);
1785 else if (gdbarch_long_double_bit (gdbarch) == 128)
1786 builtin_f_type->builtin_real_s16
1787 = init_float_type (alloc, gdbarch_long_double_bit (gdbarch),
1788 "real*16", gdbarch_long_double_format (gdbarch));
1789 else
1790 builtin_f_type->builtin_real_s16
1791 = alloc.new_type (TYPE_CODE_ERROR, 128, "real*16");
1793 builtin_f_type->builtin_complex
1794 = init_complex_type ("complex*4", builtin_f_type->builtin_real);
1796 builtin_f_type->builtin_complex_s8
1797 = init_complex_type ("complex*8", builtin_f_type->builtin_real_s8);
1799 if (builtin_f_type->builtin_real_s16->code () == TYPE_CODE_ERROR)
1800 builtin_f_type->builtin_complex_s16
1801 = alloc.new_type (TYPE_CODE_ERROR, 256, "complex*16");
1802 else
1803 builtin_f_type->builtin_complex_s16
1804 = init_complex_type ("complex*16", builtin_f_type->builtin_real_s16);
1806 return builtin_f_type;
1809 static const registry<gdbarch>::key<struct builtin_f_type> f_type_data;
1811 const struct builtin_f_type *
1812 builtin_f_type (struct gdbarch *gdbarch)
1814 struct builtin_f_type *result = f_type_data.get (gdbarch);
1815 if (result == nullptr)
1817 result = build_fortran_types (gdbarch);
1818 f_type_data.set (gdbarch, result);
1821 return result;
1824 /* Command-list for the "set/show fortran" prefix command. */
1825 static struct cmd_list_element *set_fortran_list;
1826 static struct cmd_list_element *show_fortran_list;
1828 void _initialize_f_language ();
1829 void
1830 _initialize_f_language ()
1832 add_setshow_prefix_cmd
1833 ("fortran", no_class,
1834 _("Prefix command for changing Fortran-specific settings."),
1835 _("Generic command for showing Fortran-specific settings."),
1836 &set_fortran_list, &show_fortran_list,
1837 &setlist, &showlist);
1839 add_setshow_boolean_cmd ("repack-array-slices", class_vars,
1840 &repack_array_slices, _("\
1841 Enable or disable repacking of non-contiguous array slices."), _("\
1842 Show whether non-contiguous array slices are repacked."), _("\
1843 When the user requests a slice of a Fortran array then we can either return\n\
1844 a descriptor that describes the array in place (using the original array data\n\
1845 in its existing location) or the original data can be repacked (copied) to a\n\
1846 new location.\n\
1848 When the content of the array slice is contiguous within the original array\n\
1849 then the result will never be repacked, but when the data for the new array\n\
1850 is non-contiguous within the original array repacking will only be performed\n\
1851 when this setting is on."),
1852 NULL,
1853 show_repack_array_slices,
1854 &set_fortran_list, &show_fortran_list);
1856 /* Debug Fortran's array slicing logic. */
1857 add_setshow_boolean_cmd ("fortran-array-slicing", class_maintenance,
1858 &fortran_array_slicing_debug, _("\
1859 Set debugging of Fortran array slicing."), _("\
1860 Show debugging of Fortran array slicing."), _("\
1861 When on, debugging of Fortran array slicing is enabled."),
1862 NULL,
1863 show_fortran_array_slicing_debug,
1864 &setdebuglist, &showdebuglist);
1867 /* Ensures that function argument VALUE is in the appropriate form to
1868 pass to a Fortran function. Returns a possibly new value that should
1869 be used instead of VALUE.
1871 When IS_ARTIFICIAL is true this indicates an artificial argument,
1872 e.g. hidden string lengths which the GNU Fortran argument passing
1873 convention specifies as being passed by value.
1875 When IS_ARTIFICIAL is false, the argument is passed by pointer. If the
1876 value is already in target memory then return a value that is a pointer
1877 to VALUE. If VALUE is not in memory (e.g. an integer literal), allocate
1878 space in the target, copy VALUE in, and return a pointer to the in
1879 memory copy. */
1881 static struct value *
1882 fortran_argument_convert (struct value *value, bool is_artificial)
1884 if (!is_artificial)
1886 /* If the value is not in the inferior e.g. registers values,
1887 convenience variables and user input. */
1888 if (value->lval () != lval_memory)
1890 struct type *type = value->type ();
1891 const int length = type->length ();
1892 const CORE_ADDR addr
1893 = value_as_long (value_allocate_space_in_inferior (length));
1894 write_memory (addr, value->contents ().data (), length);
1895 struct value *val = value_from_contents_and_address
1896 (type, value->contents ().data (), addr);
1897 return value_addr (val);
1899 else
1900 return value_addr (value); /* Program variables, e.g. arrays. */
1902 return value;
1905 /* Prepare (and return) an argument value ready for an inferior function
1906 call to a Fortran function. EXP and POS are the expressions describing
1907 the argument to prepare. ARG_NUM is the argument number being
1908 prepared, with 0 being the first argument and so on. FUNC_TYPE is the
1909 type of the function being called.
1911 IS_INTERNAL_CALL_P is true if this is a call to a function of type
1912 TYPE_CODE_INTERNAL_FUNCTION, otherwise this parameter is false.
1914 NOSIDE has its usual meaning for expression parsing (see eval.c).
1916 Arguments in Fortran are normally passed by address, we coerce the
1917 arguments here rather than in value_arg_coerce as otherwise the call to
1918 malloc (to place the non-lvalue parameters in target memory) is hit by
1919 this Fortran specific logic. This results in malloc being called with a
1920 pointer to an integer followed by an attempt to malloc the arguments to
1921 malloc in target memory. Infinite recursion ensues. */
1923 static value *
1924 fortran_prepare_argument (struct expression *exp,
1925 expr::operation *subexp,
1926 int arg_num, bool is_internal_call_p,
1927 struct type *func_type, enum noside noside)
1929 if (is_internal_call_p)
1930 return subexp->evaluate_with_coercion (exp, noside);
1932 bool is_artificial = ((arg_num >= func_type->num_fields ())
1933 ? true
1934 : func_type->field (arg_num).is_artificial ());
1936 /* If this is an artificial argument, then either, this is an argument
1937 beyond the end of the known arguments, or possibly, there are no known
1938 arguments (maybe missing debug info).
1940 For these artificial arguments, if the user has prefixed it with '&'
1941 (for address-of), then lets always allow this to succeed, even if the
1942 argument is not actually in inferior memory. This will allow the user
1943 to pass arguments to a Fortran function even when there's no debug
1944 information.
1946 As we already pass the address of non-artificial arguments, all we
1947 need to do if skip the UNOP_ADDR operator in the expression and mark
1948 the argument as non-artificial. */
1949 if (is_artificial)
1951 expr::unop_addr_operation *addrop
1952 = dynamic_cast<expr::unop_addr_operation *> (subexp);
1953 if (addrop != nullptr)
1955 subexp = addrop->get_expression ().get ();
1956 is_artificial = false;
1960 struct value *arg_val = subexp->evaluate_with_coercion (exp, noside);
1961 return fortran_argument_convert (arg_val, is_artificial);
1964 /* See f-lang.h. */
1966 struct type *
1967 fortran_preserve_arg_pointer (struct value *arg, struct type *type)
1969 if (arg->type ()->code () == TYPE_CODE_PTR)
1970 return arg->type ();
1971 return type;
1974 /* See f-lang.h. */
1976 CORE_ADDR
1977 fortran_adjust_dynamic_array_base_address_hack (struct type *type,
1978 CORE_ADDR address)
1980 gdb_assert (type->code () == TYPE_CODE_ARRAY);
1982 /* We can't adjust the base address for arrays that have no content. */
1983 if (type_not_allocated (type) || type_not_associated (type))
1984 return address;
1986 int ndimensions = calc_f77_array_dims (type);
1987 LONGEST total_offset = 0;
1989 /* Walk through each of the dimensions of this array type and figure out
1990 if any of the dimensions are "backwards", that is the base address
1991 for this dimension points to the element at the highest memory
1992 address and the stride is negative. */
1993 struct type *tmp_type = type;
1994 for (int i = 0 ; i < ndimensions; ++i)
1996 /* Grab the range for this dimension and extract the lower and upper
1997 bounds. */
1998 tmp_type = check_typedef (tmp_type);
1999 struct type *range_type = tmp_type->index_type ();
2000 LONGEST lowerbound, upperbound, stride;
2001 if (!get_discrete_bounds (range_type, &lowerbound, &upperbound))
2002 error ("failed to get range bounds");
2004 /* Figure out the stride for this dimension. */
2005 struct type *elt_type = check_typedef (tmp_type->target_type ());
2006 stride = tmp_type->index_type ()->bounds ()->bit_stride ();
2007 if (stride == 0)
2008 stride = type_length_units (elt_type);
2009 else
2011 int unit_size
2012 = gdbarch_addressable_memory_unit_size (elt_type->arch ());
2013 stride /= (unit_size * 8);
2016 /* If this dimension is "backward" then figure out the offset
2017 adjustment required to point to the element at the lowest memory
2018 address, and add this to the total offset. */
2019 LONGEST offset = 0;
2020 if (stride < 0 && lowerbound < upperbound)
2021 offset = (upperbound - lowerbound) * stride;
2022 total_offset += offset;
2023 tmp_type = tmp_type->target_type ();
2026 /* Adjust the address of this object and return it. */
2027 address += total_offset;
2028 return address;