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1442 lines
46 KiB
C
1442 lines
46 KiB
C
/* Fortran language support routines for GDB, the GNU debugger.
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Copyright (C) 1993-2021 Free Software Foundation, Inc.
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Contributed by Motorola. Adapted from the C parser by Farooq Butt
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(fmbutt@engage.sps.mot.com).
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This file is part of GDB.
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>. */
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#include "defs.h"
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#include "symtab.h"
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#include "gdbtypes.h"
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#include "expression.h"
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#include "parser-defs.h"
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#include "language.h"
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#include "varobj.h"
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#include "gdbcore.h"
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#include "f-lang.h"
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#include "valprint.h"
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#include "value.h"
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#include "cp-support.h"
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#include "charset.h"
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#include "c-lang.h"
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#include "target-float.h"
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#include "gdbarch.h"
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#include "gdbcmd.h"
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#include "f-array-walker.h"
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#include <math.h>
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/* Whether GDB should repack array slices created by the user. */
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static bool repack_array_slices = false;
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/* Implement 'show fortran repack-array-slices'. */
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static void
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show_repack_array_slices (struct ui_file *file, int from_tty,
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struct cmd_list_element *c, const char *value)
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{
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fprintf_filtered (file, _("Repacking of Fortran array slices is %s.\n"),
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value);
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}
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/* Debugging of Fortran's array slicing. */
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static bool fortran_array_slicing_debug = false;
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/* Implement 'show debug fortran-array-slicing'. */
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static void
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show_fortran_array_slicing_debug (struct ui_file *file, int from_tty,
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struct cmd_list_element *c,
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const char *value)
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{
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fprintf_filtered (file, _("Debugging of Fortran array slicing is %s.\n"),
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value);
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}
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/* Local functions */
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static struct value *fortran_argument_convert (struct value *value,
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bool is_artificial);
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/* Return the encoding that should be used for the character type
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TYPE. */
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const char *
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f_language::get_encoding (struct type *type)
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{
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const char *encoding;
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switch (TYPE_LENGTH (type))
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{
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case 1:
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encoding = target_charset (get_type_arch (type));
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break;
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case 4:
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if (type_byte_order (type) == BFD_ENDIAN_BIG)
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encoding = "UTF-32BE";
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else
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encoding = "UTF-32LE";
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break;
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default:
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error (_("unrecognized character type"));
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}
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return encoding;
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}
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/* Table of operators and their precedences for printing expressions. */
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const struct op_print f_language::op_print_tab[] =
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{
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{"+", BINOP_ADD, PREC_ADD, 0},
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{"+", UNOP_PLUS, PREC_PREFIX, 0},
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{"-", BINOP_SUB, PREC_ADD, 0},
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{"-", UNOP_NEG, PREC_PREFIX, 0},
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{"*", BINOP_MUL, PREC_MUL, 0},
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{"/", BINOP_DIV, PREC_MUL, 0},
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{"DIV", BINOP_INTDIV, PREC_MUL, 0},
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{"MOD", BINOP_REM, PREC_MUL, 0},
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{"=", BINOP_ASSIGN, PREC_ASSIGN, 1},
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{".OR.", BINOP_LOGICAL_OR, PREC_LOGICAL_OR, 0},
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{".AND.", BINOP_LOGICAL_AND, PREC_LOGICAL_AND, 0},
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{".NOT.", UNOP_LOGICAL_NOT, PREC_PREFIX, 0},
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{".EQ.", BINOP_EQUAL, PREC_EQUAL, 0},
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{".NE.", BINOP_NOTEQUAL, PREC_EQUAL, 0},
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{".LE.", BINOP_LEQ, PREC_ORDER, 0},
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{".GE.", BINOP_GEQ, PREC_ORDER, 0},
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{".GT.", BINOP_GTR, PREC_ORDER, 0},
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{".LT.", BINOP_LESS, PREC_ORDER, 0},
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{"**", UNOP_IND, PREC_PREFIX, 0},
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{"@", BINOP_REPEAT, PREC_REPEAT, 0},
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{NULL, OP_NULL, PREC_REPEAT, 0}
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};
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/* Return the number of dimensions for a Fortran array or string. */
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int
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calc_f77_array_dims (struct type *array_type)
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{
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int ndimen = 1;
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struct type *tmp_type;
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if ((array_type->code () == TYPE_CODE_STRING))
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return 1;
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if ((array_type->code () != TYPE_CODE_ARRAY))
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error (_("Can't get dimensions for a non-array type"));
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tmp_type = array_type;
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while ((tmp_type = TYPE_TARGET_TYPE (tmp_type)))
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{
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if (tmp_type->code () == TYPE_CODE_ARRAY)
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++ndimen;
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}
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return ndimen;
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}
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/* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
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slices. This is a base class for two alternative repacking mechanisms,
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one for when repacking from a lazy value, and one for repacking from a
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non-lazy (already loaded) value. */
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class fortran_array_repacker_base_impl
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: public fortran_array_walker_base_impl
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{
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public:
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/* Constructor, DEST is the value we are repacking into. */
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fortran_array_repacker_base_impl (struct value *dest)
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: m_dest (dest),
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m_dest_offset (0)
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{ /* Nothing. */ }
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/* When we start processing the inner most dimension, this is where we
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will be creating values for each element as we load them and then copy
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them into the M_DEST value. Set a value mark so we can free these
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temporary values. */
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void start_dimension (bool inner_p)
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{
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if (inner_p)
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{
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gdb_assert (m_mark == nullptr);
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m_mark = value_mark ();
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}
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}
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/* When we finish processing the inner most dimension free all temporary
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value that were created. */
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void finish_dimension (bool inner_p, bool last_p)
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{
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if (inner_p)
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{
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gdb_assert (m_mark != nullptr);
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value_free_to_mark (m_mark);
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m_mark = nullptr;
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}
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}
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protected:
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/* Copy the contents of array element ELT into M_DEST at the next
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available offset. */
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void copy_element_to_dest (struct value *elt)
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{
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value_contents_copy (m_dest, m_dest_offset, elt, 0,
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TYPE_LENGTH (value_type (elt)));
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m_dest_offset += TYPE_LENGTH (value_type (elt));
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}
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/* The value being written to. */
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struct value *m_dest;
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/* The byte offset in M_DEST at which the next element should be
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written. */
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LONGEST m_dest_offset;
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/* Set with a call to VALUE_MARK, and then reset after calling
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VALUE_FREE_TO_MARK. */
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struct value *m_mark = nullptr;
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};
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/* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
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slices. This class is specialised for repacking an array slice from a
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lazy array value, as such it does not require the parent array value to
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be loaded into GDB's memory; the parent value could be huge, while the
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slice could be tiny. */
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class fortran_lazy_array_repacker_impl
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: public fortran_array_repacker_base_impl
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{
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public:
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/* Constructor. TYPE is the type of the slice being loaded from the
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parent value, so this type will correctly reflect the strides required
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to find all of the elements from the parent value. ADDRESS is the
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address in target memory of value matching TYPE, and DEST is the value
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we are repacking into. */
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explicit fortran_lazy_array_repacker_impl (struct type *type,
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CORE_ADDR address,
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struct value *dest)
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: fortran_array_repacker_base_impl (dest),
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m_addr (address)
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{ /* Nothing. */ }
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/* Create a lazy value in target memory representing a single element,
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then load the element into GDB's memory and copy the contents into the
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destination value. */
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void process_element (struct type *elt_type, LONGEST elt_off, bool last_p)
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{
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copy_element_to_dest (value_at_lazy (elt_type, m_addr + elt_off));
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}
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private:
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/* The address in target memory where the parent value starts. */
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CORE_ADDR m_addr;
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};
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/* A class used by FORTRAN_VALUE_SUBARRAY when repacking Fortran array
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slices. This class is specialised for repacking an array slice from a
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previously loaded (non-lazy) array value, as such it fetches the
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element values from the contents of the parent value. */
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class fortran_array_repacker_impl
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: public fortran_array_repacker_base_impl
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{
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public:
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/* Constructor. TYPE is the type for the array slice within the parent
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value, as such it has stride values as required to find the elements
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within the original parent value. ADDRESS is the address in target
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memory of the value matching TYPE. BASE_OFFSET is the offset from
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the start of VAL's content buffer to the start of the object of TYPE,
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VAL is the parent object from which we are loading the value, and
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DEST is the value into which we are repacking. */
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explicit fortran_array_repacker_impl (struct type *type, CORE_ADDR address,
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LONGEST base_offset,
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struct value *val, struct value *dest)
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: fortran_array_repacker_base_impl (dest),
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m_base_offset (base_offset),
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m_val (val)
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{
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gdb_assert (!value_lazy (val));
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}
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/* Extract an element of ELT_TYPE at offset (M_BASE_OFFSET + ELT_OFF)
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from the content buffer of M_VAL then copy this extracted value into
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the repacked destination value. */
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void process_element (struct type *elt_type, LONGEST elt_off, bool last_p)
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{
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struct value *elt
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= value_from_component (m_val, elt_type, (elt_off + m_base_offset));
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copy_element_to_dest (elt);
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}
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private:
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/* The offset into the content buffer of M_VAL to the start of the slice
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being extracted. */
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LONGEST m_base_offset;
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/* The parent value from which we are extracting a slice. */
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struct value *m_val;
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};
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/* Called from evaluate_subexp_standard to perform array indexing, and
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sub-range extraction, for Fortran. As well as arrays this function
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also handles strings as they can be treated like arrays of characters.
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ARRAY is the array or string being accessed. EXP, POS, and NOSIDE are
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as for evaluate_subexp_standard, and NARGS is the number of arguments
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in this access (e.g. 'array (1,2,3)' would be NARGS 3). */
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static struct value *
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fortran_value_subarray (struct value *array, struct expression *exp,
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int *pos, int nargs, enum noside noside)
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{
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type *original_array_type = check_typedef (value_type (array));
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bool is_string_p = original_array_type->code () == TYPE_CODE_STRING;
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/* Perform checks for ARRAY not being available. The somewhat overly
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complex logic here is just to keep backward compatibility with the
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errors that we used to get before FORTRAN_VALUE_SUBARRAY was
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rewritten. Maybe a future task would streamline the error messages we
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get here, and update all the expected test results. */
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if (exp->elts[*pos].opcode != OP_RANGE)
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{
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if (type_not_associated (original_array_type))
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error (_("no such vector element (vector not associated)"));
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else if (type_not_allocated (original_array_type))
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error (_("no such vector element (vector not allocated)"));
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}
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else
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{
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if (type_not_associated (original_array_type))
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error (_("array not associated"));
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else if (type_not_allocated (original_array_type))
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error (_("array not allocated"));
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}
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/* First check that the number of dimensions in the type we are slicing
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matches the number of arguments we were passed. */
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int ndimensions = calc_f77_array_dims (original_array_type);
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if (nargs != ndimensions)
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error (_("Wrong number of subscripts"));
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/* This will be initialised below with the type of the elements held in
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ARRAY. */
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struct type *inner_element_type;
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/* Extract the types of each array dimension from the original array
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type. We need these available so we can fill in the default upper and
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lower bounds if the user requested slice doesn't provide that
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information. Additionally unpacking the dimensions like this gives us
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the inner element type. */
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std::vector<struct type *> dim_types;
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{
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dim_types.reserve (ndimensions);
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struct type *type = original_array_type;
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for (int i = 0; i < ndimensions; ++i)
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{
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dim_types.push_back (type);
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type = TYPE_TARGET_TYPE (type);
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}
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/* TYPE is now the inner element type of the array, we start the new
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array slice off as this type, then as we process the requested slice
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(from the user) we wrap new types around this to build up the final
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slice type. */
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inner_element_type = type;
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}
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/* As we analyse the new slice type we need to understand if the data
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being referenced is contiguous. Do decide this we must track the size
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of an element at each dimension of the new slice array. Initially the
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elements of the inner most dimension of the array are the same inner
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most elements as the original ARRAY. */
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LONGEST slice_element_size = TYPE_LENGTH (inner_element_type);
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/* Start off assuming all data is contiguous, this will be set to false
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if access to any dimension results in non-contiguous data. */
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bool is_all_contiguous = true;
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/* The TOTAL_OFFSET is the distance in bytes from the start of the
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original ARRAY to the start of the new slice. This is calculated as
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we process the information from the user. */
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LONGEST total_offset = 0;
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/* A structure representing information about each dimension of the
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resulting slice. */
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struct slice_dim
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{
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/* Constructor. */
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slice_dim (LONGEST l, LONGEST h, LONGEST s, struct type *idx)
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: low (l),
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high (h),
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stride (s),
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index (idx)
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{ /* Nothing. */ }
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/* The low bound for this dimension of the slice. */
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LONGEST low;
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/* The high bound for this dimension of the slice. */
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LONGEST high;
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/* The byte stride for this dimension of the slice. */
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LONGEST stride;
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struct type *index;
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};
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/* The dimensions of the resulting slice. */
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std::vector<slice_dim> slice_dims;
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/* Process the incoming arguments. These arguments are in the reverse
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order to the array dimensions, that is the first argument refers to
|
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the last array dimension. */
|
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if (fortran_array_slicing_debug)
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debug_printf ("Processing array access:\n");
|
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for (int i = 0; i < nargs; ++i)
|
||
{
|
||
/* For each dimension of the array the user will have either provided
|
||
a ranged access with optional lower bound, upper bound, and
|
||
stride, or the user will have supplied a single index. */
|
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struct type *dim_type = dim_types[ndimensions - (i + 1)];
|
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if (exp->elts[*pos].opcode == OP_RANGE)
|
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{
|
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int pc = (*pos) + 1;
|
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enum range_flag range_flag = (enum range_flag) exp->elts[pc].longconst;
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*pos += 3;
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LONGEST low, high, stride;
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low = high = stride = 0;
|
||
|
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if ((range_flag & RANGE_LOW_BOUND_DEFAULT) == 0)
|
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low = value_as_long (evaluate_subexp (nullptr, exp, pos, noside));
|
||
else
|
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low = f77_get_lowerbound (dim_type);
|
||
if ((range_flag & RANGE_HIGH_BOUND_DEFAULT) == 0)
|
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high = value_as_long (evaluate_subexp (nullptr, exp, pos, noside));
|
||
else
|
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high = f77_get_upperbound (dim_type);
|
||
if ((range_flag & RANGE_HAS_STRIDE) == RANGE_HAS_STRIDE)
|
||
stride = value_as_long (evaluate_subexp (nullptr, exp, pos, noside));
|
||
else
|
||
stride = 1;
|
||
|
||
if (stride == 0)
|
||
error (_("stride must not be 0"));
|
||
|
||
/* Get information about this dimension in the original ARRAY. */
|
||
struct type *target_type = TYPE_TARGET_TYPE (dim_type);
|
||
struct type *index_type = dim_type->index_type ();
|
||
LONGEST lb = f77_get_lowerbound (dim_type);
|
||
LONGEST ub = f77_get_upperbound (dim_type);
|
||
LONGEST sd = index_type->bit_stride ();
|
||
if (sd == 0)
|
||
sd = TYPE_LENGTH (target_type) * 8;
|
||
|
||
if (fortran_array_slicing_debug)
|
||
{
|
||
debug_printf ("|-> Range access\n");
|
||
std::string str = type_to_string (dim_type);
|
||
debug_printf ("| |-> Type: %s\n", str.c_str ());
|
||
debug_printf ("| |-> Array:\n");
|
||
debug_printf ("| | |-> Low bound: %s\n", plongest (lb));
|
||
debug_printf ("| | |-> High bound: %s\n", plongest (ub));
|
||
debug_printf ("| | |-> Bit stride: %s\n", plongest (sd));
|
||
debug_printf ("| | |-> Byte stride: %s\n", plongest (sd / 8));
|
||
debug_printf ("| | |-> Type size: %s\n",
|
||
pulongest (TYPE_LENGTH (dim_type)));
|
||
debug_printf ("| | '-> Target type size: %s\n",
|
||
pulongest (TYPE_LENGTH (target_type)));
|
||
debug_printf ("| |-> Accessing:\n");
|
||
debug_printf ("| | |-> Low bound: %s\n",
|
||
plongest (low));
|
||
debug_printf ("| | |-> High bound: %s\n",
|
||
plongest (high));
|
||
debug_printf ("| | '-> Element stride: %s\n",
|
||
plongest (stride));
|
||
}
|
||
|
||
/* Check the user hasn't asked for something invalid. */
|
||
if (high > ub || low < lb)
|
||
error (_("array subscript out of bounds"));
|
||
|
||
/* Calculate what this dimension of the new slice array will look
|
||
like. OFFSET is the byte offset from the start of the
|
||
previous (more outer) dimension to the start of this
|
||
dimension. E_COUNT is the number of elements in this
|
||
dimension. REMAINDER is the number of elements remaining
|
||
between the last included element and the upper bound. For
|
||
example an access '1:6:2' will include elements 1, 3, 5 and
|
||
have a remainder of 1 (element #6). */
|
||
LONGEST lowest = std::min (low, high);
|
||
LONGEST offset = (sd / 8) * (lowest - lb);
|
||
LONGEST e_count = std::abs (high - low) + 1;
|
||
e_count = (e_count + (std::abs (stride) - 1)) / std::abs (stride);
|
||
LONGEST new_low = 1;
|
||
LONGEST new_high = new_low + e_count - 1;
|
||
LONGEST new_stride = (sd * stride) / 8;
|
||
LONGEST last_elem = low + ((e_count - 1) * stride);
|
||
LONGEST remainder = high - last_elem;
|
||
if (low > high)
|
||
{
|
||
offset += std::abs (remainder) * TYPE_LENGTH (target_type);
|
||
if (stride > 0)
|
||
error (_("incorrect stride and boundary combination"));
|
||
}
|
||
else if (stride < 0)
|
||
error (_("incorrect stride and boundary combination"));
|
||
|
||
/* Is the data within this dimension contiguous? It is if the
|
||
newly computed stride is the same size as a single element of
|
||
this dimension. */
|
||
bool is_dim_contiguous = (new_stride == slice_element_size);
|
||
is_all_contiguous &= is_dim_contiguous;
|
||
|
||
if (fortran_array_slicing_debug)
|
||
{
|
||
debug_printf ("| '-> Results:\n");
|
||
debug_printf ("| |-> Offset = %s\n", plongest (offset));
|
||
debug_printf ("| |-> Elements = %s\n", plongest (e_count));
|
||
debug_printf ("| |-> Low bound = %s\n", plongest (new_low));
|
||
debug_printf ("| |-> High bound = %s\n",
|
||
plongest (new_high));
|
||
debug_printf ("| |-> Byte stride = %s\n",
|
||
plongest (new_stride));
|
||
debug_printf ("| |-> Last element = %s\n",
|
||
plongest (last_elem));
|
||
debug_printf ("| |-> Remainder = %s\n",
|
||
plongest (remainder));
|
||
debug_printf ("| '-> Contiguous = %s\n",
|
||
(is_dim_contiguous ? "Yes" : "No"));
|
||
}
|
||
|
||
/* Figure out how big (in bytes) an element of this dimension of
|
||
the new array slice will be. */
|
||
slice_element_size = std::abs (new_stride * e_count);
|
||
|
||
slice_dims.emplace_back (new_low, new_high, new_stride,
|
||
index_type);
|
||
|
||
/* Update the total offset. */
|
||
total_offset += offset;
|
||
}
|
||
else
|
||
{
|
||
/* There is a single index for this dimension. */
|
||
LONGEST index
|
||
= value_as_long (evaluate_subexp_with_coercion (exp, pos, noside));
|
||
|
||
/* Get information about this dimension in the original ARRAY. */
|
||
struct type *target_type = TYPE_TARGET_TYPE (dim_type);
|
||
struct type *index_type = dim_type->index_type ();
|
||
LONGEST lb = f77_get_lowerbound (dim_type);
|
||
LONGEST ub = f77_get_upperbound (dim_type);
|
||
LONGEST sd = index_type->bit_stride () / 8;
|
||
if (sd == 0)
|
||
sd = TYPE_LENGTH (target_type);
|
||
|
||
if (fortran_array_slicing_debug)
|
||
{
|
||
debug_printf ("|-> Index access\n");
|
||
std::string str = type_to_string (dim_type);
|
||
debug_printf ("| |-> Type: %s\n", str.c_str ());
|
||
debug_printf ("| |-> Array:\n");
|
||
debug_printf ("| | |-> Low bound: %s\n", plongest (lb));
|
||
debug_printf ("| | |-> High bound: %s\n", plongest (ub));
|
||
debug_printf ("| | |-> Byte stride: %s\n", plongest (sd));
|
||
debug_printf ("| | |-> Type size: %s\n",
|
||
pulongest (TYPE_LENGTH (dim_type)));
|
||
debug_printf ("| | '-> Target type size: %s\n",
|
||
pulongest (TYPE_LENGTH (target_type)));
|
||
debug_printf ("| '-> Accessing:\n");
|
||
debug_printf ("| '-> Index: %s\n",
|
||
plongest (index));
|
||
}
|
||
|
||
/* If the array has actual content then check the index is in
|
||
bounds. An array without content (an unbound array) doesn't
|
||
have a known upper bound, so don't error check in that
|
||
situation. */
|
||
if (index < lb
|
||
|| (dim_type->index_type ()->bounds ()->high.kind () != PROP_UNDEFINED
|
||
&& index > ub)
|
||
|| (VALUE_LVAL (array) != lval_memory
|
||
&& dim_type->index_type ()->bounds ()->high.kind () == PROP_UNDEFINED))
|
||
{
|
||
if (type_not_associated (dim_type))
|
||
error (_("no such vector element (vector not associated)"));
|
||
else if (type_not_allocated (dim_type))
|
||
error (_("no such vector element (vector not allocated)"));
|
||
else
|
||
error (_("no such vector element"));
|
||
}
|
||
|
||
/* Calculate using the type stride, not the target type size. */
|
||
LONGEST offset = sd * (index - lb);
|
||
total_offset += offset;
|
||
}
|
||
}
|
||
|
||
if (noside == EVAL_SKIP)
|
||
return array;
|
||
|
||
/* Build a type that represents the new array slice in the target memory
|
||
of the original ARRAY, this type makes use of strides to correctly
|
||
find only those elements that are part of the new slice. */
|
||
struct type *array_slice_type = inner_element_type;
|
||
for (const auto &d : slice_dims)
|
||
{
|
||
/* Create the range. */
|
||
dynamic_prop p_low, p_high, p_stride;
|
||
|
||
p_low.set_const_val (d.low);
|
||
p_high.set_const_val (d.high);
|
||
p_stride.set_const_val (d.stride);
|
||
|
||
struct type *new_range
|
||
= create_range_type_with_stride ((struct type *) NULL,
|
||
TYPE_TARGET_TYPE (d.index),
|
||
&p_low, &p_high, 0, &p_stride,
|
||
true);
|
||
array_slice_type
|
||
= create_array_type (nullptr, array_slice_type, new_range);
|
||
}
|
||
|
||
if (fortran_array_slicing_debug)
|
||
{
|
||
debug_printf ("'-> Final result:\n");
|
||
debug_printf (" |-> Type: %s\n",
|
||
type_to_string (array_slice_type).c_str ());
|
||
debug_printf (" |-> Total offset: %s\n",
|
||
plongest (total_offset));
|
||
debug_printf (" |-> Base address: %s\n",
|
||
core_addr_to_string (value_address (array)));
|
||
debug_printf (" '-> Contiguous = %s\n",
|
||
(is_all_contiguous ? "Yes" : "No"));
|
||
}
|
||
|
||
/* Should we repack this array slice? */
|
||
if (!is_all_contiguous && (repack_array_slices || is_string_p))
|
||
{
|
||
/* Build a type for the repacked slice. */
|
||
struct type *repacked_array_type = inner_element_type;
|
||
for (const auto &d : slice_dims)
|
||
{
|
||
/* Create the range. */
|
||
dynamic_prop p_low, p_high, p_stride;
|
||
|
||
p_low.set_const_val (d.low);
|
||
p_high.set_const_val (d.high);
|
||
p_stride.set_const_val (TYPE_LENGTH (repacked_array_type));
|
||
|
||
struct type *new_range
|
||
= create_range_type_with_stride ((struct type *) NULL,
|
||
TYPE_TARGET_TYPE (d.index),
|
||
&p_low, &p_high, 0, &p_stride,
|
||
true);
|
||
repacked_array_type
|
||
= create_array_type (nullptr, repacked_array_type, new_range);
|
||
}
|
||
|
||
/* Now copy the elements from the original ARRAY into the packed
|
||
array value DEST. */
|
||
struct value *dest = allocate_value (repacked_array_type);
|
||
if (value_lazy (array)
|
||
|| (total_offset + TYPE_LENGTH (array_slice_type)
|
||
> TYPE_LENGTH (check_typedef (value_type (array)))))
|
||
{
|
||
fortran_array_walker<fortran_lazy_array_repacker_impl> p
|
||
(array_slice_type, value_address (array) + total_offset, dest);
|
||
p.walk ();
|
||
}
|
||
else
|
||
{
|
||
fortran_array_walker<fortran_array_repacker_impl> p
|
||
(array_slice_type, value_address (array) + total_offset,
|
||
total_offset, array, dest);
|
||
p.walk ();
|
||
}
|
||
array = dest;
|
||
}
|
||
else
|
||
{
|
||
if (VALUE_LVAL (array) == lval_memory)
|
||
{
|
||
/* If the value we're taking a slice from is not yet loaded, or
|
||
the requested slice is outside the values content range then
|
||
just create a new lazy value pointing at the memory where the
|
||
contents we're looking for exist. */
|
||
if (value_lazy (array)
|
||
|| (total_offset + TYPE_LENGTH (array_slice_type)
|
||
> TYPE_LENGTH (check_typedef (value_type (array)))))
|
||
array = value_at_lazy (array_slice_type,
|
||
value_address (array) + total_offset);
|
||
else
|
||
array = value_from_contents_and_address (array_slice_type,
|
||
(value_contents (array)
|
||
+ total_offset),
|
||
(value_address (array)
|
||
+ total_offset));
|
||
}
|
||
else if (!value_lazy (array))
|
||
{
|
||
const void *valaddr = value_contents (array) + total_offset;
|
||
array = allocate_value (array_slice_type);
|
||
memcpy (value_contents_raw (array), valaddr, TYPE_LENGTH (array_slice_type));
|
||
}
|
||
else
|
||
error (_("cannot subscript arrays that are not in memory"));
|
||
}
|
||
|
||
return array;
|
||
}
|
||
|
||
/* Special expression evaluation cases for Fortran. */
|
||
|
||
static struct value *
|
||
evaluate_subexp_f (struct type *expect_type, struct expression *exp,
|
||
int *pos, enum noside noside)
|
||
{
|
||
struct value *arg1 = NULL, *arg2 = NULL;
|
||
enum exp_opcode op;
|
||
int pc;
|
||
struct type *type;
|
||
|
||
pc = *pos;
|
||
*pos += 1;
|
||
op = exp->elts[pc].opcode;
|
||
|
||
switch (op)
|
||
{
|
||
default:
|
||
*pos -= 1;
|
||
return evaluate_subexp_standard (expect_type, exp, pos, noside);
|
||
|
||
case UNOP_ABS:
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = value_type (arg1);
|
||
switch (type->code ())
|
||
{
|
||
case TYPE_CODE_FLT:
|
||
{
|
||
double d
|
||
= fabs (target_float_to_host_double (value_contents (arg1),
|
||
value_type (arg1)));
|
||
return value_from_host_double (type, d);
|
||
}
|
||
case TYPE_CODE_INT:
|
||
{
|
||
LONGEST l = value_as_long (arg1);
|
||
l = llabs (l);
|
||
return value_from_longest (type, l);
|
||
}
|
||
}
|
||
error (_("ABS of type %s not supported"), TYPE_SAFE_NAME (type));
|
||
|
||
case BINOP_MOD:
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
arg2 = evaluate_subexp (value_type (arg1), exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = value_type (arg1);
|
||
if (type->code () != value_type (arg2)->code ())
|
||
error (_("non-matching types for parameters to MOD ()"));
|
||
switch (type->code ())
|
||
{
|
||
case TYPE_CODE_FLT:
|
||
{
|
||
double d1
|
||
= target_float_to_host_double (value_contents (arg1),
|
||
value_type (arg1));
|
||
double d2
|
||
= target_float_to_host_double (value_contents (arg2),
|
||
value_type (arg2));
|
||
double d3 = fmod (d1, d2);
|
||
return value_from_host_double (type, d3);
|
||
}
|
||
case TYPE_CODE_INT:
|
||
{
|
||
LONGEST v1 = value_as_long (arg1);
|
||
LONGEST v2 = value_as_long (arg2);
|
||
if (v2 == 0)
|
||
error (_("calling MOD (N, 0) is undefined"));
|
||
LONGEST v3 = v1 - (v1 / v2) * v2;
|
||
return value_from_longest (value_type (arg1), v3);
|
||
}
|
||
}
|
||
error (_("MOD of type %s not supported"), TYPE_SAFE_NAME (type));
|
||
|
||
case UNOP_FORTRAN_CEILING:
|
||
{
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = value_type (arg1);
|
||
if (type->code () != TYPE_CODE_FLT)
|
||
error (_("argument to CEILING must be of type float"));
|
||
double val
|
||
= target_float_to_host_double (value_contents (arg1),
|
||
value_type (arg1));
|
||
val = ceil (val);
|
||
return value_from_host_double (type, val);
|
||
}
|
||
|
||
case UNOP_FORTRAN_FLOOR:
|
||
{
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = value_type (arg1);
|
||
if (type->code () != TYPE_CODE_FLT)
|
||
error (_("argument to FLOOR must be of type float"));
|
||
double val
|
||
= target_float_to_host_double (value_contents (arg1),
|
||
value_type (arg1));
|
||
val = floor (val);
|
||
return value_from_host_double (type, val);
|
||
}
|
||
|
||
case BINOP_FORTRAN_MODULO:
|
||
{
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
arg2 = evaluate_subexp (value_type (arg1), exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = value_type (arg1);
|
||
if (type->code () != value_type (arg2)->code ())
|
||
error (_("non-matching types for parameters to MODULO ()"));
|
||
/* MODULO(A, P) = A - FLOOR (A / P) * P */
|
||
switch (type->code ())
|
||
{
|
||
case TYPE_CODE_INT:
|
||
{
|
||
LONGEST a = value_as_long (arg1);
|
||
LONGEST p = value_as_long (arg2);
|
||
LONGEST result = a - (a / p) * p;
|
||
if (result != 0 && (a < 0) != (p < 0))
|
||
result += p;
|
||
return value_from_longest (value_type (arg1), result);
|
||
}
|
||
case TYPE_CODE_FLT:
|
||
{
|
||
double a
|
||
= target_float_to_host_double (value_contents (arg1),
|
||
value_type (arg1));
|
||
double p
|
||
= target_float_to_host_double (value_contents (arg2),
|
||
value_type (arg2));
|
||
double result = fmod (a, p);
|
||
if (result != 0 && (a < 0.0) != (p < 0.0))
|
||
result += p;
|
||
return value_from_host_double (type, result);
|
||
}
|
||
}
|
||
error (_("MODULO of type %s not supported"), TYPE_SAFE_NAME (type));
|
||
}
|
||
|
||
case BINOP_FORTRAN_CMPLX:
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
arg2 = evaluate_subexp (value_type (arg1), exp, pos, noside);
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
type = builtin_f_type(exp->gdbarch)->builtin_complex_s16;
|
||
return value_literal_complex (arg1, arg2, type);
|
||
|
||
case UNOP_FORTRAN_KIND:
|
||
arg1 = evaluate_subexp (NULL, exp, pos, EVAL_AVOID_SIDE_EFFECTS);
|
||
type = value_type (arg1);
|
||
|
||
switch (type->code ())
|
||
{
|
||
case TYPE_CODE_STRUCT:
|
||
case TYPE_CODE_UNION:
|
||
case TYPE_CODE_MODULE:
|
||
case TYPE_CODE_FUNC:
|
||
error (_("argument to kind must be an intrinsic type"));
|
||
}
|
||
|
||
if (!TYPE_TARGET_TYPE (type))
|
||
return value_from_longest (builtin_type (exp->gdbarch)->builtin_int,
|
||
TYPE_LENGTH (type));
|
||
return value_from_longest (builtin_type (exp->gdbarch)->builtin_int,
|
||
TYPE_LENGTH (TYPE_TARGET_TYPE (type)));
|
||
|
||
|
||
case OP_F77_UNDETERMINED_ARGLIST:
|
||
/* Remember that in F77, functions, substring ops and array subscript
|
||
operations cannot be disambiguated at parse time. We have made
|
||
all array subscript operations, substring operations as well as
|
||
function calls come here and we now have to discover what the heck
|
||
this thing actually was. If it is a function, we process just as
|
||
if we got an OP_FUNCALL. */
|
||
int nargs = longest_to_int (exp->elts[pc + 1].longconst);
|
||
(*pos) += 2;
|
||
|
||
/* First determine the type code we are dealing with. */
|
||
arg1 = evaluate_subexp (nullptr, exp, pos, noside);
|
||
type = check_typedef (value_type (arg1));
|
||
enum type_code code = type->code ();
|
||
|
||
if (code == TYPE_CODE_PTR)
|
||
{
|
||
/* Fortran always passes variable to subroutines as pointer.
|
||
So we need to look into its target type to see if it is
|
||
array, string or function. If it is, we need to switch
|
||
to the target value the original one points to. */
|
||
struct type *target_type = check_typedef (TYPE_TARGET_TYPE (type));
|
||
|
||
if (target_type->code () == TYPE_CODE_ARRAY
|
||
|| target_type->code () == TYPE_CODE_STRING
|
||
|| target_type->code () == TYPE_CODE_FUNC)
|
||
{
|
||
arg1 = value_ind (arg1);
|
||
type = check_typedef (value_type (arg1));
|
||
code = type->code ();
|
||
}
|
||
}
|
||
|
||
switch (code)
|
||
{
|
||
case TYPE_CODE_ARRAY:
|
||
case TYPE_CODE_STRING:
|
||
return fortran_value_subarray (arg1, exp, pos, nargs, noside);
|
||
|
||
case TYPE_CODE_PTR:
|
||
case TYPE_CODE_FUNC:
|
||
case TYPE_CODE_INTERNAL_FUNCTION:
|
||
{
|
||
/* It's a function call. Allocate arg vector, including
|
||
space for the function to be called in argvec[0] and a
|
||
termination NULL. */
|
||
struct value **argvec = (struct value **)
|
||
alloca (sizeof (struct value *) * (nargs + 2));
|
||
argvec[0] = arg1;
|
||
int tem = 1;
|
||
for (; tem <= nargs; tem++)
|
||
{
|
||
argvec[tem] = evaluate_subexp_with_coercion (exp, pos, noside);
|
||
/* Arguments in Fortran are passed by address. Coerce the
|
||
arguments here rather than in value_arg_coerce as
|
||
otherwise the call to malloc to place the non-lvalue
|
||
parameters in target memory is hit by this Fortran
|
||
specific logic. This results in malloc being called
|
||
with a pointer to an integer followed by an attempt to
|
||
malloc the arguments to malloc in target memory.
|
||
Infinite recursion ensues. */
|
||
if (code == TYPE_CODE_PTR || code == TYPE_CODE_FUNC)
|
||
{
|
||
bool is_artificial
|
||
= TYPE_FIELD_ARTIFICIAL (value_type (arg1), tem - 1);
|
||
argvec[tem] = fortran_argument_convert (argvec[tem],
|
||
is_artificial);
|
||
}
|
||
}
|
||
argvec[tem] = 0; /* signal end of arglist */
|
||
if (noside == EVAL_SKIP)
|
||
return eval_skip_value (exp);
|
||
return evaluate_subexp_do_call (exp, noside, argvec[0],
|
||
gdb::make_array_view (argvec + 1,
|
||
nargs),
|
||
NULL, expect_type);
|
||
}
|
||
|
||
default:
|
||
error (_("Cannot perform substring on this type"));
|
||
}
|
||
}
|
||
|
||
/* Should be unreachable. */
|
||
return nullptr;
|
||
}
|
||
|
||
/* Special expression lengths for Fortran. */
|
||
|
||
static void
|
||
operator_length_f (const struct expression *exp, int pc, int *oplenp,
|
||
int *argsp)
|
||
{
|
||
int oplen = 1;
|
||
int args = 0;
|
||
|
||
switch (exp->elts[pc - 1].opcode)
|
||
{
|
||
default:
|
||
operator_length_standard (exp, pc, oplenp, argsp);
|
||
return;
|
||
|
||
case UNOP_FORTRAN_KIND:
|
||
case UNOP_FORTRAN_FLOOR:
|
||
case UNOP_FORTRAN_CEILING:
|
||
oplen = 1;
|
||
args = 1;
|
||
break;
|
||
|
||
case BINOP_FORTRAN_CMPLX:
|
||
case BINOP_FORTRAN_MODULO:
|
||
oplen = 1;
|
||
args = 2;
|
||
break;
|
||
|
||
case OP_F77_UNDETERMINED_ARGLIST:
|
||
oplen = 3;
|
||
args = 1 + longest_to_int (exp->elts[pc - 2].longconst);
|
||
break;
|
||
}
|
||
|
||
*oplenp = oplen;
|
||
*argsp = args;
|
||
}
|
||
|
||
/* Helper for PRINT_SUBEXP_F. Arguments are as for PRINT_SUBEXP_F, except
|
||
the extra argument NAME which is the text that should be printed as the
|
||
name of this operation. */
|
||
|
||
static void
|
||
print_unop_subexp_f (struct expression *exp, int *pos,
|
||
struct ui_file *stream, enum precedence prec,
|
||
const char *name)
|
||
{
|
||
(*pos)++;
|
||
fprintf_filtered (stream, "%s(", name);
|
||
print_subexp (exp, pos, stream, PREC_SUFFIX);
|
||
fputs_filtered (")", stream);
|
||
}
|
||
|
||
/* Helper for PRINT_SUBEXP_F. Arguments are as for PRINT_SUBEXP_F, except
|
||
the extra argument NAME which is the text that should be printed as the
|
||
name of this operation. */
|
||
|
||
static void
|
||
print_binop_subexp_f (struct expression *exp, int *pos,
|
||
struct ui_file *stream, enum precedence prec,
|
||
const char *name)
|
||
{
|
||
(*pos)++;
|
||
fprintf_filtered (stream, "%s(", name);
|
||
print_subexp (exp, pos, stream, PREC_SUFFIX);
|
||
fputs_filtered (",", stream);
|
||
print_subexp (exp, pos, stream, PREC_SUFFIX);
|
||
fputs_filtered (")", stream);
|
||
}
|
||
|
||
/* Special expression printing for Fortran. */
|
||
|
||
static void
|
||
print_subexp_f (struct expression *exp, int *pos,
|
||
struct ui_file *stream, enum precedence prec)
|
||
{
|
||
int pc = *pos;
|
||
enum exp_opcode op = exp->elts[pc].opcode;
|
||
|
||
switch (op)
|
||
{
|
||
default:
|
||
print_subexp_standard (exp, pos, stream, prec);
|
||
return;
|
||
|
||
case UNOP_FORTRAN_KIND:
|
||
print_unop_subexp_f (exp, pos, stream, prec, "KIND");
|
||
return;
|
||
|
||
case UNOP_FORTRAN_FLOOR:
|
||
print_unop_subexp_f (exp, pos, stream, prec, "FLOOR");
|
||
return;
|
||
|
||
case UNOP_FORTRAN_CEILING:
|
||
print_unop_subexp_f (exp, pos, stream, prec, "CEILING");
|
||
return;
|
||
|
||
case BINOP_FORTRAN_CMPLX:
|
||
print_binop_subexp_f (exp, pos, stream, prec, "CMPLX");
|
||
return;
|
||
|
||
case BINOP_FORTRAN_MODULO:
|
||
print_binop_subexp_f (exp, pos, stream, prec, "MODULO");
|
||
return;
|
||
|
||
case OP_F77_UNDETERMINED_ARGLIST:
|
||
(*pos)++;
|
||
print_subexp_funcall (exp, pos, stream);
|
||
return;
|
||
}
|
||
}
|
||
|
||
/* Special expression dumping for Fortran. */
|
||
|
||
static int
|
||
dump_subexp_body_f (struct expression *exp,
|
||
struct ui_file *stream, int elt)
|
||
{
|
||
int opcode = exp->elts[elt].opcode;
|
||
int oplen, nargs, i;
|
||
|
||
switch (opcode)
|
||
{
|
||
default:
|
||
return dump_subexp_body_standard (exp, stream, elt);
|
||
|
||
case UNOP_FORTRAN_KIND:
|
||
case UNOP_FORTRAN_FLOOR:
|
||
case UNOP_FORTRAN_CEILING:
|
||
case BINOP_FORTRAN_CMPLX:
|
||
case BINOP_FORTRAN_MODULO:
|
||
operator_length_f (exp, (elt + 1), &oplen, &nargs);
|
||
break;
|
||
|
||
case OP_F77_UNDETERMINED_ARGLIST:
|
||
return dump_subexp_body_funcall (exp, stream, elt + 1);
|
||
}
|
||
|
||
elt += oplen;
|
||
for (i = 0; i < nargs; i += 1)
|
||
elt = dump_subexp (exp, stream, elt);
|
||
|
||
return elt;
|
||
}
|
||
|
||
/* Special expression checking for Fortran. */
|
||
|
||
static int
|
||
operator_check_f (struct expression *exp, int pos,
|
||
int (*objfile_func) (struct objfile *objfile,
|
||
void *data),
|
||
void *data)
|
||
{
|
||
const union exp_element *const elts = exp->elts;
|
||
|
||
switch (elts[pos].opcode)
|
||
{
|
||
case UNOP_FORTRAN_KIND:
|
||
case UNOP_FORTRAN_FLOOR:
|
||
case UNOP_FORTRAN_CEILING:
|
||
case BINOP_FORTRAN_CMPLX:
|
||
case BINOP_FORTRAN_MODULO:
|
||
/* Any references to objfiles are held in the arguments to this
|
||
expression, not within the expression itself, so no additional
|
||
checking is required here, the outer expression iteration code
|
||
will take care of checking each argument. */
|
||
break;
|
||
|
||
default:
|
||
return operator_check_standard (exp, pos, objfile_func, data);
|
||
}
|
||
|
||
return 0;
|
||
}
|
||
|
||
/* Expression processing for Fortran. */
|
||
const struct exp_descriptor f_language::exp_descriptor_tab =
|
||
{
|
||
print_subexp_f,
|
||
operator_length_f,
|
||
operator_check_f,
|
||
dump_subexp_body_f,
|
||
evaluate_subexp_f
|
||
};
|
||
|
||
/* See language.h. */
|
||
|
||
void
|
||
f_language::language_arch_info (struct gdbarch *gdbarch,
|
||
struct language_arch_info *lai) const
|
||
{
|
||
const struct builtin_f_type *builtin = builtin_f_type (gdbarch);
|
||
|
||
/* Helper function to allow shorter lines below. */
|
||
auto add = [&] (struct type * t)
|
||
{
|
||
lai->add_primitive_type (t);
|
||
};
|
||
|
||
add (builtin->builtin_character);
|
||
add (builtin->builtin_logical);
|
||
add (builtin->builtin_logical_s1);
|
||
add (builtin->builtin_logical_s2);
|
||
add (builtin->builtin_logical_s8);
|
||
add (builtin->builtin_real);
|
||
add (builtin->builtin_real_s8);
|
||
add (builtin->builtin_real_s16);
|
||
add (builtin->builtin_complex_s8);
|
||
add (builtin->builtin_complex_s16);
|
||
add (builtin->builtin_void);
|
||
|
||
lai->set_string_char_type (builtin->builtin_character);
|
||
lai->set_bool_type (builtin->builtin_logical_s2, "logical");
|
||
}
|
||
|
||
/* See language.h. */
|
||
|
||
unsigned int
|
||
f_language::search_name_hash (const char *name) const
|
||
{
|
||
return cp_search_name_hash (name);
|
||
}
|
||
|
||
/* See language.h. */
|
||
|
||
struct block_symbol
|
||
f_language::lookup_symbol_nonlocal (const char *name,
|
||
const struct block *block,
|
||
const domain_enum domain) const
|
||
{
|
||
return cp_lookup_symbol_nonlocal (this, name, block, domain);
|
||
}
|
||
|
||
/* See language.h. */
|
||
|
||
symbol_name_matcher_ftype *
|
||
f_language::get_symbol_name_matcher_inner
|
||
(const lookup_name_info &lookup_name) const
|
||
{
|
||
return cp_get_symbol_name_matcher (lookup_name);
|
||
}
|
||
|
||
/* Single instance of the Fortran language class. */
|
||
|
||
static f_language f_language_defn;
|
||
|
||
static void *
|
||
build_fortran_types (struct gdbarch *gdbarch)
|
||
{
|
||
struct builtin_f_type *builtin_f_type
|
||
= GDBARCH_OBSTACK_ZALLOC (gdbarch, struct builtin_f_type);
|
||
|
||
builtin_f_type->builtin_void
|
||
= arch_type (gdbarch, TYPE_CODE_VOID, TARGET_CHAR_BIT, "void");
|
||
|
||
builtin_f_type->builtin_character
|
||
= arch_type (gdbarch, TYPE_CODE_CHAR, TARGET_CHAR_BIT, "character");
|
||
|
||
builtin_f_type->builtin_logical_s1
|
||
= arch_boolean_type (gdbarch, TARGET_CHAR_BIT, 1, "logical*1");
|
||
|
||
builtin_f_type->builtin_integer_s2
|
||
= arch_integer_type (gdbarch, gdbarch_short_bit (gdbarch), 0,
|
||
"integer*2");
|
||
|
||
builtin_f_type->builtin_integer_s8
|
||
= arch_integer_type (gdbarch, gdbarch_long_long_bit (gdbarch), 0,
|
||
"integer*8");
|
||
|
||
builtin_f_type->builtin_logical_s2
|
||
= arch_boolean_type (gdbarch, gdbarch_short_bit (gdbarch), 1,
|
||
"logical*2");
|
||
|
||
builtin_f_type->builtin_logical_s8
|
||
= arch_boolean_type (gdbarch, gdbarch_long_long_bit (gdbarch), 1,
|
||
"logical*8");
|
||
|
||
builtin_f_type->builtin_integer
|
||
= arch_integer_type (gdbarch, gdbarch_int_bit (gdbarch), 0,
|
||
"integer");
|
||
|
||
builtin_f_type->builtin_logical
|
||
= arch_boolean_type (gdbarch, gdbarch_int_bit (gdbarch), 1,
|
||
"logical*4");
|
||
|
||
builtin_f_type->builtin_real
|
||
= arch_float_type (gdbarch, gdbarch_float_bit (gdbarch),
|
||
"real", gdbarch_float_format (gdbarch));
|
||
builtin_f_type->builtin_real_s8
|
||
= arch_float_type (gdbarch, gdbarch_double_bit (gdbarch),
|
||
"real*8", gdbarch_double_format (gdbarch));
|
||
auto fmt = gdbarch_floatformat_for_type (gdbarch, "real(kind=16)", 128);
|
||
if (fmt != nullptr)
|
||
builtin_f_type->builtin_real_s16
|
||
= arch_float_type (gdbarch, 128, "real*16", fmt);
|
||
else if (gdbarch_long_double_bit (gdbarch) == 128)
|
||
builtin_f_type->builtin_real_s16
|
||
= arch_float_type (gdbarch, gdbarch_long_double_bit (gdbarch),
|
||
"real*16", gdbarch_long_double_format (gdbarch));
|
||
else
|
||
builtin_f_type->builtin_real_s16
|
||
= arch_type (gdbarch, TYPE_CODE_ERROR, 128, "real*16");
|
||
|
||
builtin_f_type->builtin_complex_s8
|
||
= init_complex_type ("complex*8", builtin_f_type->builtin_real);
|
||
builtin_f_type->builtin_complex_s16
|
||
= init_complex_type ("complex*16", builtin_f_type->builtin_real_s8);
|
||
|
||
if (builtin_f_type->builtin_real_s16->code () == TYPE_CODE_ERROR)
|
||
builtin_f_type->builtin_complex_s32
|
||
= arch_type (gdbarch, TYPE_CODE_ERROR, 256, "complex*32");
|
||
else
|
||
builtin_f_type->builtin_complex_s32
|
||
= init_complex_type ("complex*32", builtin_f_type->builtin_real_s16);
|
||
|
||
return builtin_f_type;
|
||
}
|
||
|
||
static struct gdbarch_data *f_type_data;
|
||
|
||
const struct builtin_f_type *
|
||
builtin_f_type (struct gdbarch *gdbarch)
|
||
{
|
||
return (const struct builtin_f_type *) gdbarch_data (gdbarch, f_type_data);
|
||
}
|
||
|
||
/* Command-list for the "set/show fortran" prefix command. */
|
||
static struct cmd_list_element *set_fortran_list;
|
||
static struct cmd_list_element *show_fortran_list;
|
||
|
||
void _initialize_f_language ();
|
||
void
|
||
_initialize_f_language ()
|
||
{
|
||
f_type_data = gdbarch_data_register_post_init (build_fortran_types);
|
||
|
||
add_basic_prefix_cmd ("fortran", no_class,
|
||
_("Prefix command for changing Fortran-specific settings."),
|
||
&set_fortran_list, "set fortran ", 0, &setlist);
|
||
|
||
add_show_prefix_cmd ("fortran", no_class,
|
||
_("Generic command for showing Fortran-specific settings."),
|
||
&show_fortran_list, "show fortran ", 0, &showlist);
|
||
|
||
add_setshow_boolean_cmd ("repack-array-slices", class_vars,
|
||
&repack_array_slices, _("\
|
||
Enable or disable repacking of non-contiguous array slices."), _("\
|
||
Show whether non-contiguous array slices are repacked."), _("\
|
||
When the user requests a slice of a Fortran array then we can either return\n\
|
||
a descriptor that describes the array in place (using the original array data\n\
|
||
in its existing location) or the original data can be repacked (copied) to a\n\
|
||
new location.\n\
|
||
\n\
|
||
When the content of the array slice is contiguous within the original array\n\
|
||
then the result will never be repacked, but when the data for the new array\n\
|
||
is non-contiguous within the original array repacking will only be performed\n\
|
||
when this setting is on."),
|
||
NULL,
|
||
show_repack_array_slices,
|
||
&set_fortran_list, &show_fortran_list);
|
||
|
||
/* Debug Fortran's array slicing logic. */
|
||
add_setshow_boolean_cmd ("fortran-array-slicing", class_maintenance,
|
||
&fortran_array_slicing_debug, _("\
|
||
Set debugging of Fortran array slicing."), _("\
|
||
Show debugging of Fortran array slicing."), _("\
|
||
When on, debugging of Fortran array slicing is enabled."),
|
||
NULL,
|
||
show_fortran_array_slicing_debug,
|
||
&setdebuglist, &showdebuglist);
|
||
}
|
||
|
||
/* Ensures that function argument VALUE is in the appropriate form to
|
||
pass to a Fortran function. Returns a possibly new value that should
|
||
be used instead of VALUE.
|
||
|
||
When IS_ARTIFICIAL is true this indicates an artificial argument,
|
||
e.g. hidden string lengths which the GNU Fortran argument passing
|
||
convention specifies as being passed by value.
|
||
|
||
When IS_ARTIFICIAL is false, the argument is passed by pointer. If the
|
||
value is already in target memory then return a value that is a pointer
|
||
to VALUE. If VALUE is not in memory (e.g. an integer literal), allocate
|
||
space in the target, copy VALUE in, and return a pointer to the in
|
||
memory copy. */
|
||
|
||
static struct value *
|
||
fortran_argument_convert (struct value *value, bool is_artificial)
|
||
{
|
||
if (!is_artificial)
|
||
{
|
||
/* If the value is not in the inferior e.g. registers values,
|
||
convenience variables and user input. */
|
||
if (VALUE_LVAL (value) != lval_memory)
|
||
{
|
||
struct type *type = value_type (value);
|
||
const int length = TYPE_LENGTH (type);
|
||
const CORE_ADDR addr
|
||
= value_as_long (value_allocate_space_in_inferior (length));
|
||
write_memory (addr, value_contents (value), length);
|
||
struct value *val
|
||
= value_from_contents_and_address (type, value_contents (value),
|
||
addr);
|
||
return value_addr (val);
|
||
}
|
||
else
|
||
return value_addr (value); /* Program variables, e.g. arrays. */
|
||
}
|
||
return value;
|
||
}
|
||
|
||
/* See f-lang.h. */
|
||
|
||
struct type *
|
||
fortran_preserve_arg_pointer (struct value *arg, struct type *type)
|
||
{
|
||
if (value_type (arg)->code () == TYPE_CODE_PTR)
|
||
return value_type (arg);
|
||
return type;
|
||
}
|
||
|
||
/* See f-lang.h. */
|
||
|
||
CORE_ADDR
|
||
fortran_adjust_dynamic_array_base_address_hack (struct type *type,
|
||
CORE_ADDR address)
|
||
{
|
||
gdb_assert (type->code () == TYPE_CODE_ARRAY);
|
||
|
||
/* We can't adjust the base address for arrays that have no content. */
|
||
if (type_not_allocated (type) || type_not_associated (type))
|
||
return address;
|
||
|
||
int ndimensions = calc_f77_array_dims (type);
|
||
LONGEST total_offset = 0;
|
||
|
||
/* Walk through each of the dimensions of this array type and figure out
|
||
if any of the dimensions are "backwards", that is the base address
|
||
for this dimension points to the element at the highest memory
|
||
address and the stride is negative. */
|
||
struct type *tmp_type = type;
|
||
for (int i = 0 ; i < ndimensions; ++i)
|
||
{
|
||
/* Grab the range for this dimension and extract the lower and upper
|
||
bounds. */
|
||
tmp_type = check_typedef (tmp_type);
|
||
struct type *range_type = tmp_type->index_type ();
|
||
LONGEST lowerbound, upperbound, stride;
|
||
if (!get_discrete_bounds (range_type, &lowerbound, &upperbound))
|
||
error ("failed to get range bounds");
|
||
|
||
/* Figure out the stride for this dimension. */
|
||
struct type *elt_type = check_typedef (TYPE_TARGET_TYPE (tmp_type));
|
||
stride = tmp_type->index_type ()->bounds ()->bit_stride ();
|
||
if (stride == 0)
|
||
stride = type_length_units (elt_type);
|
||
else
|
||
{
|
||
struct gdbarch *arch = get_type_arch (elt_type);
|
||
int unit_size = gdbarch_addressable_memory_unit_size (arch);
|
||
stride /= (unit_size * 8);
|
||
}
|
||
|
||
/* If this dimension is "backward" then figure out the offset
|
||
adjustment required to point to the element at the lowest memory
|
||
address, and add this to the total offset. */
|
||
LONGEST offset = 0;
|
||
if (stride < 0 && lowerbound < upperbound)
|
||
offset = (upperbound - lowerbound) * stride;
|
||
total_offset += offset;
|
||
tmp_type = TYPE_TARGET_TYPE (tmp_type);
|
||
}
|
||
|
||
/* Adjust the address of this object and return it. */
|
||
address += total_offset;
|
||
return address;
|
||
}
|