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https://sourceware.org/git/binutils-gdb.git
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18d2988e5d
Now that defs.h, server.h and common-defs.h are included via the `-include` option, it is no longer necessary for source files to include them. Remove all the inclusions of these files I could find. Update the generation scripts where relevant. Change-Id: Ia026cff269c1b7ae7386dd3619bc9bb6a5332837 Approved-By: Pedro Alves <pedro@palves.net>
302 lines
11 KiB
C++
302 lines
11 KiB
C++
/* Copyright (C) 2020-2024 Free Software Foundation, Inc.
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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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/* Support classes to wrap up the process of iterating over a
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multi-dimensional Fortran array. */
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#ifndef F_ARRAY_WALKER_H
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#define F_ARRAY_WALKER_H
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#include "gdbtypes.h"
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#include "f-lang.h"
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/* Class for calculating the byte offset for elements within a single
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dimension of a Fortran array. */
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class fortran_array_offset_calculator
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{
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public:
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/* Create a new offset calculator for TYPE, which is either an array or a
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string. */
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explicit fortran_array_offset_calculator (struct type *type)
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{
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/* Validate the type. */
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type = check_typedef (type);
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if (type->code () != TYPE_CODE_ARRAY
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&& (type->code () != TYPE_CODE_STRING))
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error (_("can only compute offsets for arrays and strings"));
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/* Get the range, and extract the bounds. */
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struct type *range_type = type->index_type ();
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if (!get_discrete_bounds (range_type, &m_lowerbound, &m_upperbound))
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error ("unable to read array bounds");
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/* Figure out the stride for this array. */
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struct type *elt_type = check_typedef (type->target_type ());
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m_stride = type->index_type ()->bounds ()->bit_stride ();
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if (m_stride == 0)
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m_stride = type_length_units (elt_type);
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else
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{
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int unit_size
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= gdbarch_addressable_memory_unit_size (elt_type->arch ());
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m_stride /= (unit_size * 8);
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}
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};
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/* Get the byte offset for element INDEX within the type we are working
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on. There is no bounds checking done on INDEX. If the stride is
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negative then we still assume that the base address (for the array
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object) points to the element with the lowest memory address, we then
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calculate an offset assuming that index 0 will be the element at the
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highest address, index 1 the next highest, and so on. This is not
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quite how Fortran works in reality; in reality the base address of
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the object would point at the element with the highest address, and
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we would index backwards from there in the "normal" way, however,
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GDB's current value contents model doesn't support having the base
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address be near to the end of the value contents, so we currently
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adjust the base address of Fortran arrays with negative strides so
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their base address points at the lowest memory address. This code
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here is part of working around this weirdness. */
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LONGEST index_offset (LONGEST index)
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{
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LONGEST offset;
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if (m_stride < 0)
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offset = std::abs (m_stride) * (m_upperbound - index);
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else
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offset = std::abs (m_stride) * (index - m_lowerbound);
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return offset;
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}
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private:
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/* The stride for the type we are working with. */
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LONGEST m_stride;
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/* The upper bound for the type we are working with. */
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LONGEST m_upperbound;
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/* The lower bound for the type we are working with. */
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LONGEST m_lowerbound;
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};
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/* A base class used by fortran_array_walker. There's no virtual methods
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here, sub-classes should just override the functions they want in order
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to specialise the behaviour to their needs. The functionality
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provided in these default implementations will visit every array
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element, but do nothing for each element. */
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struct fortran_array_walker_base_impl
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{
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/* Called when iterating between the lower and upper bounds of each
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dimension of the array. Return true if GDB should continue iterating,
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otherwise, return false.
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SHOULD_CONTINUE indicates if GDB is going to stop anyway, and should
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be taken into consideration when deciding what to return. If
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SHOULD_CONTINUE is false then this function must also return false,
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the function is still called though in case extra work needs to be
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done as part of the stopping process. */
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bool continue_walking (bool should_continue)
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{ return should_continue; }
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/* Called when GDB starts iterating over a dimension of the array. The
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argument INDEX_TYPE is the type of the index used to address elements
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in the dimension, NELTS holds the number of the elements there, and
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INNER_P is true for the inner most dimension (the dimension containing
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the actual elements of the array), and false for more outer dimensions.
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For a concrete example of how this function is called see the comment
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on process_element below. */
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void start_dimension (struct type *index_type, LONGEST nelts, bool inner_p)
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{ /* Nothing. */ }
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/* Called when GDB finishes iterating over a dimension of the array. The
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argument INNER_P is true for the inner most dimension (the dimension
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containing the actual elements of the array), and false for more outer
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dimensions. LAST_P is true for the last call at a particular
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dimension. For a concrete example of how this function is called
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see the comment on process_element below. */
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void finish_dimension (bool inner_p, bool last_p)
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{ /* Nothing. */ }
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/* Called when processing dimensions of the array other than the
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innermost one. WALK_1 is the walker to normally call, ELT_TYPE is
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the type of the element being extracted, and ELT_OFF is the offset
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of the element from the start of array being walked. INDEX is the
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value of the index the current element is at in the upper dimension.
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Finally LAST_P is true only when this is the last element that will
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be processed in this dimension. */
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void process_dimension (gdb::function_view<void (struct type *,
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int, bool)> walk_1,
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struct type *elt_type, LONGEST elt_off,
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LONGEST index, bool last_p)
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{
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walk_1 (elt_type, elt_off, last_p);
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}
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/* Called when processing the inner most dimension of the array, for
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every element in the array. ELT_TYPE is the type of the element being
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extracted, and ELT_OFF is the offset of the element from the start of
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array being walked. INDEX is the value of the index the current
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element is at in the upper dimension. Finally LAST_P is true only
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when this is the last element that will be processed in this dimension.
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Given this two dimensional array ((1, 2) (3, 4) (5, 6)), the calls to
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start_dimension, process_element, and finish_dimension look like this:
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start_dimension (INDEX_TYPE, 3, false);
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start_dimension (INDEX_TYPE, 2, true);
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process_element (TYPE, OFFSET, false);
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process_element (TYPE, OFFSET, true);
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finish_dimension (true, false);
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start_dimension (INDEX_TYPE, 2, true);
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process_element (TYPE, OFFSET, false);
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process_element (TYPE, OFFSET, true);
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finish_dimension (true, true);
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start_dimension (INDEX_TYPE, 2, true);
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process_element (TYPE, OFFSET, false);
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process_element (TYPE, OFFSET, true);
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finish_dimension (true, true);
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finish_dimension (false, true); */
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void process_element (struct type *elt_type, LONGEST elt_off,
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LONGEST index, bool last_p)
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{ /* Nothing. */ }
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};
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/* A class to wrap up the process of iterating over a multi-dimensional
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Fortran array. IMPL is used to specialise what happens as we walk over
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the array. See class FORTRAN_ARRAY_WALKER_BASE_IMPL (above) for the
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methods than can be used to customise the array walk. */
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template<typename Impl>
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class fortran_array_walker
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{
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/* Ensure that Impl is derived from the required base class. This just
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ensures that all of the required API methods are available and have a
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sensible default implementation. */
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static_assert ((std::is_base_of<fortran_array_walker_base_impl,Impl>::value));
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public:
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/* Create a new array walker. TYPE is the type of the array being walked
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over, and ADDRESS is the base address for the object of TYPE in
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memory. All other arguments are forwarded to the constructor of the
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template parameter class IMPL. */
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template <typename ...Args>
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fortran_array_walker (struct type *type, CORE_ADDR address,
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Args... args)
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: m_type (type),
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m_address (address),
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m_impl (type, address, args...),
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m_ndimensions (calc_f77_array_dims (m_type)),
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m_nss (0)
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{ /* Nothing. */ }
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/* Walk the array. */
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void
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walk ()
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{
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walk_1 (m_type, 0, false);
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}
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private:
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/* The core of the array walking algorithm. TYPE is the type of
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the current dimension being processed and OFFSET is the offset
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(in bytes) for the start of this dimension. */
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void
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walk_1 (struct type *type, int offset, bool last_p)
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{
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/* Extract the range, and get lower and upper bounds. */
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struct type *range_type = check_typedef (type)->index_type ();
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LONGEST lowerbound, upperbound;
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if (!get_discrete_bounds (range_type, &lowerbound, &upperbound))
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error ("failed to get range bounds");
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/* CALC is used to calculate the offsets for each element in this
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dimension. */
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fortran_array_offset_calculator calc (type);
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m_nss++;
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gdb_assert (range_type->code () == TYPE_CODE_RANGE);
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m_impl.start_dimension (range_type->target_type (),
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upperbound - lowerbound + 1,
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m_nss == m_ndimensions);
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if (m_nss != m_ndimensions)
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{
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struct type *subarray_type = check_typedef (type)->target_type ();
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/* For dimensions other than the inner most, walk each element and
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recurse while peeling off one more dimension of the array. */
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for (LONGEST i = lowerbound;
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m_impl.continue_walking (i < upperbound + 1);
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i++)
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{
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/* Use the index and the stride to work out a new offset. */
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LONGEST new_offset = offset + calc.index_offset (i);
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/* Now print the lower dimension. */
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m_impl.process_dimension
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([this] (struct type *w_type, int w_offset, bool w_last_p) -> void
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{
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this->walk_1 (w_type, w_offset, w_last_p);
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},
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subarray_type, new_offset, i, i == upperbound);
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}
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}
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else
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{
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struct type *elt_type = check_typedef (type)->target_type ();
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/* For the inner most dimension of the array, process each element
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within this dimension. */
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for (LONGEST i = lowerbound;
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m_impl.continue_walking (i < upperbound + 1);
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i++)
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{
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LONGEST elt_off = offset + calc.index_offset (i);
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if (is_dynamic_type (elt_type))
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{
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CORE_ADDR e_address = m_address + elt_off;
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elt_type = resolve_dynamic_type (elt_type, {}, e_address);
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}
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m_impl.process_element (elt_type, elt_off, i, i == upperbound);
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}
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}
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m_impl.finish_dimension (m_nss == m_ndimensions, last_p || m_nss == 1);
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m_nss--;
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}
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/* The array type being processed. */
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struct type *m_type;
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/* The address in target memory for the object of M_TYPE being
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processed. This is required in order to resolve dynamic types. */
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CORE_ADDR m_address;
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/* An instance of the template specialisation class. */
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Impl m_impl;
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/* The total number of dimensions in M_TYPE. */
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int m_ndimensions;
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/* The current dimension number being processed. */
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int m_nss;
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};
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#endif /* F_ARRAY_WALKER_H */
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