binutils-gdb/gdb/gdbtypes.h
rupothar df7a7bdd97 gdb: add support for Fortran's ASSUMED RANK arrays
This patch adds a new dynamic property DYN_PROP_RANK, this property is
read from the DW_AT_rank attribute and stored within the type just
like other dynamic properties.

As arrays with dynamic ranks make use of a single
DW_TAG_generic_subrange to represent all ranks of the array, support
for this tag has been added to dwarf2/read.c.

The final piece of this puzzle is to add support in gdbtypes.c so that
we can resolve an array type with dynamic rank.  To do this the
existing resolve_dynamic_array_or_string function is split into two,
there's a new resolve_dynamic_array_or_string_1 core that is
responsible for resolving each rank of the array, while the now outer
resolve_dynamic_array_or_string is responsible for figuring out the
array rank (which might require resolving a dynamic property) and then
calling the inner core.

The resolve_dynamic_range function now takes a rank, which is passed
on to the dwarf expression evaluator.  This rank will only be used in
the case where the array itself has dynamic rank, but we now pass the
rank in all cases, this should be harmless if the rank is not needed.

The only small nit is that resolve_dynamic_type_internal actually
handles resolving dynamic ranges itself, which now obviously requires
us to pass a rank value.  But what rank value to use?  In the end I
just passed '1' through here as a sane default, my thinking is that if
we are in resolve_dynamic_type_internal to resolve a range, then the
range isn't part of an array with dynamic rank, and so the range
should actually be using the rank value at all.

An alternative approach would be to make the rank value a
gdb::optional, however, this ends up adding a bunch of complexity to
the code (e.g. having to conditionally build the array to pass to
dwarf2_evaluate_property, and handling the 'rank - 1' in
resolve_dynamic_array_or_string_1) so I haven't done that, but could,
if people think that would be a better approach.

Finally, support for assumed rank arrays was only fixed very recently
in gcc, so you'll need the latest gcc in order to run the tests for
this.

Here's an example test program:

  PROGRAM arank
    REAL :: a1(10)
    CALL sub1(a1)

  CONTAINS

    SUBROUTINE sub1(a)
      REAL :: a(..)
      PRINT *, RANK(a)
    END SUBROUTINE sub1
  END PROGRAM arank

Compiler Version:
gcc (GCC) 12.0.0 20211122 (experimental)

Compilation command:
gfortran assumedrank.f90 -gdwarf-5 -o assumedrank

Without Patch:

  gdb -q assumedrank
  Reading symbols from assumedrank...
  (gdb) break sub1
  Breakpoint 1 at 0x4006ff: file assumedrank.f90, line 10.
  (gdb) run
  Starting program: /home/rupesh/STAGING-BUILD-2787/bin/assumedrank

  Breakpoint 1, arank::sub1 (a=<unknown type in /home/rupesh/STAGING-BUILD-2787
  /bin/assumedrank, CU 0x0, DIE 0xd5>) at assumedrank.f90:10
  10       PRINT *, RANK(a)
  (gdb) print RANK(a)
  'a' has unknown type; cast it to its declared type

With patch:

  gdb -q assumedrank
  Reading symbols from assumedrank...
  (gdb) break sub1
  Breakpoint 1 at 0x4006ff: file assumedrank.f90, line 10.
  (gdb) run
  Starting program: /home/rupesh/STAGING-BUILD-2787/bin/assumedrank

  Breakpoint 1, arank::sub1 (a=...) at assumedrank.f90:10
  10       PRINT *, RANK(a)
  (gdb) print RANK(a)
  $1 = 1
  (gdb) ptype a
  type = real(kind=4) (10)
  (gdb)

Co-Authored-By: Andrew Burgess <aburgess@redhat.com>
2022-04-03 17:18:20 +01:00

2925 lines
96 KiB
C++

/* Internal type definitions for GDB.
Copyright (C) 1992-2022 Free Software Foundation, Inc.
Contributed by Cygnus Support, using pieces from other GDB modules.
This file is part of GDB.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#if !defined (GDBTYPES_H)
#define GDBTYPES_H 1
/* * \page gdbtypes GDB Types
GDB represents all the different kinds of types in programming
languages using a common representation defined in gdbtypes.h.
The main data structure is main_type; it consists of a code (such
as #TYPE_CODE_ENUM for enumeration types), a number of
generally-useful fields such as the printable name, and finally a
field main_type::type_specific that is a union of info specific to
particular languages or other special cases (such as calling
convention).
The available type codes are defined in enum #type_code. The enum
includes codes both for types that are common across a variety
of languages, and for types that are language-specific.
Most accesses to type fields go through macros such as
#TYPE_CODE(thistype) and #TYPE_FN_FIELD_CONST(thisfn, n). These are
written such that they can be used as both rvalues and lvalues.
*/
#include "hashtab.h"
#include "gdbsupport/array-view.h"
#include "gdbsupport/gdb-hashtab.h"
#include "gdbsupport/gdb_optional.h"
#include "gdbsupport/offset-type.h"
#include "gdbsupport/enum-flags.h"
#include "gdbsupport/underlying.h"
#include "gdbsupport/print-utils.h"
#include "gdbsupport/function-view.h"
#include "dwarf2.h"
#include "gdbsupport/gdb_obstack.h"
#include "gmp-utils.h"
/* Forward declarations for prototypes. */
struct field;
struct block;
struct value_print_options;
struct language_defn;
struct dwarf2_per_cu_data;
struct dwarf2_per_objfile;
/* These declarations are DWARF-specific as some of the gdbtypes.h data types
are already DWARF-specific. */
/* * Offset relative to the start of its containing CU (compilation
unit). */
DEFINE_OFFSET_TYPE (cu_offset, unsigned int);
/* * Offset relative to the start of its .debug_info or .debug_types
section. */
DEFINE_OFFSET_TYPE (sect_offset, uint64_t);
static inline char *
sect_offset_str (sect_offset offset)
{
return hex_string (to_underlying (offset));
}
/* Some macros for char-based bitfields. */
#define B_SET(a,x) ((a)[(x)>>3] |= (1 << ((x)&7)))
#define B_CLR(a,x) ((a)[(x)>>3] &= ~(1 << ((x)&7)))
#define B_TST(a,x) ((a)[(x)>>3] & (1 << ((x)&7)))
#define B_TYPE unsigned char
#define B_BYTES(x) ( 1 + ((x)>>3) )
#define B_CLRALL(a,x) memset ((a), 0, B_BYTES(x))
/* * Different kinds of data types are distinguished by the `code'
field. */
enum type_code
{
TYPE_CODE_BITSTRING = -1, /**< Deprecated */
TYPE_CODE_UNDEF = 0, /**< Not used; catches errors */
TYPE_CODE_PTR, /**< Pointer type */
/* * Array type with lower & upper bounds.
Regardless of the language, GDB represents multidimensional
array types the way C does: as arrays of arrays. So an
instance of a GDB array type T can always be seen as a series
of instances of TYPE_TARGET_TYPE (T) laid out sequentially in
memory.
Row-major languages like C lay out multi-dimensional arrays so
that incrementing the rightmost index in a subscripting
expression results in the smallest change in the address of the
element referred to. Column-major languages like Fortran lay
them out so that incrementing the leftmost index results in the
smallest change.
This means that, in column-major languages, working our way
from type to target type corresponds to working through indices
from right to left, not left to right. */
TYPE_CODE_ARRAY,
TYPE_CODE_STRUCT, /**< C struct or Pascal record */
TYPE_CODE_UNION, /**< C union or Pascal variant part */
TYPE_CODE_ENUM, /**< Enumeration type */
TYPE_CODE_FLAGS, /**< Bit flags type */
TYPE_CODE_FUNC, /**< Function type */
TYPE_CODE_INT, /**< Integer type */
/* * Floating type. This is *NOT* a complex type. */
TYPE_CODE_FLT,
/* * Void type. The length field specifies the length (probably
always one) which is used in pointer arithmetic involving
pointers to this type, but actually dereferencing such a
pointer is invalid; a void type has no length and no actual
representation in memory or registers. A pointer to a void
type is a generic pointer. */
TYPE_CODE_VOID,
TYPE_CODE_SET, /**< Pascal sets */
TYPE_CODE_RANGE, /**< Range (integers within spec'd bounds). */
/* * A string type which is like an array of character but prints
differently. It does not contain a length field as Pascal
strings (for many Pascals, anyway) do; if we want to deal with
such strings, we should use a new type code. */
TYPE_CODE_STRING,
/* * Unknown type. The length field is valid if we were able to
deduce that much about the type, or 0 if we don't even know
that. */
TYPE_CODE_ERROR,
/* C++ */
TYPE_CODE_METHOD, /**< Method type */
/* * Pointer-to-member-function type. This describes how to access a
particular member function of a class (possibly a virtual
member function). The representation may vary between different
C++ ABIs. */
TYPE_CODE_METHODPTR,
/* * Pointer-to-member type. This is the offset within a class to
some particular data member. The only currently supported
representation uses an unbiased offset, with -1 representing
NULL; this is used by the Itanium C++ ABI (used by GCC on all
platforms). */
TYPE_CODE_MEMBERPTR,
TYPE_CODE_REF, /**< C++ Reference types */
TYPE_CODE_RVALUE_REF, /**< C++ rvalue reference types */
TYPE_CODE_CHAR, /**< *real* character type */
/* * Boolean type. 0 is false, 1 is true, and other values are
non-boolean (e.g. FORTRAN "logical" used as unsigned int). */
TYPE_CODE_BOOL,
/* Fortran */
TYPE_CODE_COMPLEX, /**< Complex float */
TYPE_CODE_TYPEDEF,
TYPE_CODE_NAMESPACE, /**< C++ namespace. */
TYPE_CODE_DECFLOAT, /**< Decimal floating point. */
TYPE_CODE_MODULE, /**< Fortran module. */
/* * Internal function type. */
TYPE_CODE_INTERNAL_FUNCTION,
/* * Methods implemented in extension languages. */
TYPE_CODE_XMETHOD,
/* * Fixed Point type. */
TYPE_CODE_FIXED_POINT,
/* * Fortran namelist is a group of variables or arrays that can be
read or written.
Namelist syntax: NAMELIST / groupname / namelist_items ...
NAMELIST statement assign a group name to a collection of variables
called as namelist items. The namelist items can be of any data type
and can be variables or arrays.
Compiler emit DW_TAG_namelist for group name and DW_TAG_namelist_item
for each of the namelist items. GDB process these namelist dies
and print namelist variables during print and ptype commands. */
TYPE_CODE_NAMELIST,
};
/* * Some bits for the type's instance_flags word. See the macros
below for documentation on each bit. */
enum type_instance_flag_value : unsigned
{
TYPE_INSTANCE_FLAG_CONST = (1 << 0),
TYPE_INSTANCE_FLAG_VOLATILE = (1 << 1),
TYPE_INSTANCE_FLAG_CODE_SPACE = (1 << 2),
TYPE_INSTANCE_FLAG_DATA_SPACE = (1 << 3),
TYPE_INSTANCE_FLAG_ADDRESS_CLASS_1 = (1 << 4),
TYPE_INSTANCE_FLAG_ADDRESS_CLASS_2 = (1 << 5),
TYPE_INSTANCE_FLAG_NOTTEXT = (1 << 6),
TYPE_INSTANCE_FLAG_RESTRICT = (1 << 7),
TYPE_INSTANCE_FLAG_ATOMIC = (1 << 8)
};
DEF_ENUM_FLAGS_TYPE (enum type_instance_flag_value, type_instance_flags);
/* * Not textual. By default, GDB treats all single byte integers as
characters (or elements of strings) unless this flag is set. */
#define TYPE_NOTTEXT(t) (((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_NOTTEXT)
/* * Constant type. If this is set, the corresponding type has a
const modifier. */
#define TYPE_CONST(t) ((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_CONST) != 0)
/* * Volatile type. If this is set, the corresponding type has a
volatile modifier. */
#define TYPE_VOLATILE(t) \
((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_VOLATILE) != 0)
/* * Restrict type. If this is set, the corresponding type has a
restrict modifier. */
#define TYPE_RESTRICT(t) \
((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_RESTRICT) != 0)
/* * Atomic type. If this is set, the corresponding type has an
_Atomic modifier. */
#define TYPE_ATOMIC(t) \
((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_ATOMIC) != 0)
/* * True if this type represents either an lvalue or lvalue reference type. */
#define TYPE_IS_REFERENCE(t) \
((t)->code () == TYPE_CODE_REF || (t)->code () == TYPE_CODE_RVALUE_REF)
/* * True if this type is allocatable. */
#define TYPE_IS_ALLOCATABLE(t) \
((t)->dyn_prop (DYN_PROP_ALLOCATED) != NULL)
/* * True if this type has variant parts. */
#define TYPE_HAS_VARIANT_PARTS(t) \
((t)->dyn_prop (DYN_PROP_VARIANT_PARTS) != nullptr)
/* * True if this type has a dynamic length. */
#define TYPE_HAS_DYNAMIC_LENGTH(t) \
((t)->dyn_prop (DYN_PROP_BYTE_SIZE) != nullptr)
/* * Instruction-space delimited type. This is for Harvard architectures
which have separate instruction and data address spaces (and perhaps
others).
GDB usually defines a flat address space that is a superset of the
architecture's two (or more) address spaces, but this is an extension
of the architecture's model.
If TYPE_INSTANCE_FLAG_CODE_SPACE is set, an object of the corresponding type
resides in instruction memory, even if its address (in the extended
flat address space) does not reflect this.
Similarly, if TYPE_INSTANCE_FLAG_DATA_SPACE is set, then an object of the
corresponding type resides in the data memory space, even if
this is not indicated by its (flat address space) address.
If neither flag is set, the default space for functions / methods
is instruction space, and for data objects is data memory. */
#define TYPE_CODE_SPACE(t) \
((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_CODE_SPACE) != 0)
#define TYPE_DATA_SPACE(t) \
((((t)->instance_flags ()) & TYPE_INSTANCE_FLAG_DATA_SPACE) != 0)
/* * Address class flags. Some environments provide for pointers
whose size is different from that of a normal pointer or address
types where the bits are interpreted differently than normal
addresses. The TYPE_INSTANCE_FLAG_ADDRESS_CLASS_n flags may be used in
target specific ways to represent these different types of address
classes. */
#define TYPE_ADDRESS_CLASS_1(t) (((t)->instance_flags ()) \
& TYPE_INSTANCE_FLAG_ADDRESS_CLASS_1)
#define TYPE_ADDRESS_CLASS_2(t) (((t)->instance_flags ()) \
& TYPE_INSTANCE_FLAG_ADDRESS_CLASS_2)
#define TYPE_INSTANCE_FLAG_ADDRESS_CLASS_ALL \
(TYPE_INSTANCE_FLAG_ADDRESS_CLASS_1 | TYPE_INSTANCE_FLAG_ADDRESS_CLASS_2)
#define TYPE_ADDRESS_CLASS_ALL(t) (((t)->instance_flags ()) \
& TYPE_INSTANCE_FLAG_ADDRESS_CLASS_ALL)
/* * Information about a single discriminant. */
struct discriminant_range
{
/* * The range of values for the variant. This is an inclusive
range. */
ULONGEST low, high;
/* * Return true if VALUE is contained in this range. IS_UNSIGNED
is true if this should be an unsigned comparison; false for
signed. */
bool contains (ULONGEST value, bool is_unsigned) const
{
if (is_unsigned)
return value >= low && value <= high;
LONGEST valuel = (LONGEST) value;
return valuel >= (LONGEST) low && valuel <= (LONGEST) high;
}
};
struct variant_part;
/* * A single variant. A variant has a list of discriminant values.
When the discriminator matches one of these, the variant is
enabled. Each variant controls zero or more fields; and may also
control other variant parts as well. This struct corresponds to
DW_TAG_variant in DWARF. */
struct variant : allocate_on_obstack
{
/* * The discriminant ranges for this variant. */
gdb::array_view<discriminant_range> discriminants;
/* * The fields controlled by this variant. This is inclusive on
the low end and exclusive on the high end. A variant may not
control any fields, in which case the two values will be equal.
These are indexes into the type's array of fields. */
int first_field;
int last_field;
/* * Variant parts controlled by this variant. */
gdb::array_view<variant_part> parts;
/* * Return true if this is the default variant. The default
variant can be recognized because it has no associated
discriminants. */
bool is_default () const
{
return discriminants.empty ();
}
/* * Return true if this variant matches VALUE. IS_UNSIGNED is true
if this should be an unsigned comparison; false for signed. */
bool matches (ULONGEST value, bool is_unsigned) const;
};
/* * A variant part. Each variant part has an optional discriminant
and holds an array of variants. This struct corresponds to
DW_TAG_variant_part in DWARF. */
struct variant_part : allocate_on_obstack
{
/* * The index of the discriminant field in the outer type. This is
an index into the type's array of fields. If this is -1, there
is no discriminant, and only the default variant can be
considered to be selected. */
int discriminant_index;
/* * True if this discriminant is unsigned; false if signed. This
comes from the type of the discriminant. */
bool is_unsigned;
/* * The variants that are controlled by this variant part. Note
that these will always be sorted by field number. */
gdb::array_view<variant> variants;
};
enum dynamic_prop_kind
{
PROP_UNDEFINED, /* Not defined. */
PROP_CONST, /* Constant. */
PROP_ADDR_OFFSET, /* Address offset. */
PROP_LOCEXPR, /* Location expression. */
PROP_LOCLIST, /* Location list. */
PROP_VARIANT_PARTS, /* Variant parts. */
PROP_TYPE, /* Type. */
PROP_VARIABLE_NAME, /* Variable name. */
};
union dynamic_prop_data
{
/* Storage for constant property. */
LONGEST const_val;
/* Storage for dynamic property. */
void *baton;
/* Storage of variant parts for a type. A type with variant parts
has all its fields "linearized" -- stored in a single field
array, just as if they had all been declared that way. The
variant parts are attached via a dynamic property, and then are
used to control which fields end up in the final type during
dynamic type resolution. */
const gdb::array_view<variant_part> *variant_parts;
/* Once a variant type is resolved, we may want to be able to go
from the resolved type to the original type. In this case we
rewrite the property's kind and set this field. */
struct type *original_type;
/* Name of a variable to look up; the variable holds the value of
this property. */
const char *variable_name;
};
/* * Used to store a dynamic property. */
struct dynamic_prop
{
dynamic_prop_kind kind () const
{
return m_kind;
}
void set_undefined ()
{
m_kind = PROP_UNDEFINED;
}
LONGEST const_val () const
{
gdb_assert (m_kind == PROP_CONST);
return m_data.const_val;
}
void set_const_val (LONGEST const_val)
{
m_kind = PROP_CONST;
m_data.const_val = const_val;
}
void *baton () const
{
gdb_assert (m_kind == PROP_LOCEXPR
|| m_kind == PROP_LOCLIST
|| m_kind == PROP_ADDR_OFFSET);
return m_data.baton;
}
void set_locexpr (void *baton)
{
m_kind = PROP_LOCEXPR;
m_data.baton = baton;
}
void set_loclist (void *baton)
{
m_kind = PROP_LOCLIST;
m_data.baton = baton;
}
void set_addr_offset (void *baton)
{
m_kind = PROP_ADDR_OFFSET;
m_data.baton = baton;
}
const gdb::array_view<variant_part> *variant_parts () const
{
gdb_assert (m_kind == PROP_VARIANT_PARTS);
return m_data.variant_parts;
}
void set_variant_parts (gdb::array_view<variant_part> *variant_parts)
{
m_kind = PROP_VARIANT_PARTS;
m_data.variant_parts = variant_parts;
}
struct type *original_type () const
{
gdb_assert (m_kind == PROP_TYPE);
return m_data.original_type;
}
void set_original_type (struct type *original_type)
{
m_kind = PROP_TYPE;
m_data.original_type = original_type;
}
/* Return the name of the variable that holds this property's value.
Only valid for PROP_VARIABLE_NAME. */
const char *variable_name () const
{
gdb_assert (m_kind == PROP_VARIABLE_NAME);
return m_data.variable_name;
}
/* Set the name of the variable that holds this property's value,
and set this property to be of kind PROP_VARIABLE_NAME. */
void set_variable_name (const char *name)
{
m_kind = PROP_VARIABLE_NAME;
m_data.variable_name = name;
}
/* Determine which field of the union dynamic_prop.data is used. */
enum dynamic_prop_kind m_kind;
/* Storage for dynamic or static value. */
union dynamic_prop_data m_data;
};
/* Compare two dynamic_prop objects for equality. dynamic_prop
instances are equal iff they have the same type and storage. */
extern bool operator== (const dynamic_prop &l, const dynamic_prop &r);
/* Compare two dynamic_prop objects for inequality. */
static inline bool operator!= (const dynamic_prop &l, const dynamic_prop &r)
{
return !(l == r);
}
/* * Define a type's dynamic property node kind. */
enum dynamic_prop_node_kind
{
/* A property providing a type's data location.
Evaluating this field yields to the location of an object's data. */
DYN_PROP_DATA_LOCATION,
/* A property representing DW_AT_allocated. The presence of this attribute
indicates that the object of the type can be allocated/deallocated. */
DYN_PROP_ALLOCATED,
/* A property representing DW_AT_associated. The presence of this attribute
indicated that the object of the type can be associated. */
DYN_PROP_ASSOCIATED,
/* A property providing an array's byte stride. */
DYN_PROP_BYTE_STRIDE,
/* A property holding variant parts. */
DYN_PROP_VARIANT_PARTS,
/* A property representing DW_AT_rank. The presence of this attribute
indicates that the object is of assumed rank array type. */
DYN_PROP_RANK,
/* A property holding the size of the type. */
DYN_PROP_BYTE_SIZE,
};
/* * List for dynamic type attributes. */
struct dynamic_prop_list
{
/* The kind of dynamic prop in this node. */
enum dynamic_prop_node_kind prop_kind;
/* The dynamic property itself. */
struct dynamic_prop prop;
/* A pointer to the next dynamic property. */
struct dynamic_prop_list *next;
};
/* * Determine which field of the union main_type.fields[x].loc is
used. */
enum field_loc_kind
{
FIELD_LOC_KIND_BITPOS, /**< bitpos */
FIELD_LOC_KIND_ENUMVAL, /**< enumval */
FIELD_LOC_KIND_PHYSADDR, /**< physaddr */
FIELD_LOC_KIND_PHYSNAME, /**< physname */
FIELD_LOC_KIND_DWARF_BLOCK /**< dwarf_block */
};
/* * A discriminant to determine which field in the
main_type.type_specific union is being used, if any.
For types such as TYPE_CODE_FLT, the use of this
discriminant is really redundant, as we know from the type code
which field is going to be used. As such, it would be possible to
reduce the size of this enum in order to save a bit or two for
other fields of struct main_type. But, since we still have extra
room , and for the sake of clarity and consistency, we treat all fields
of the union the same way. */
enum type_specific_kind
{
TYPE_SPECIFIC_NONE,
TYPE_SPECIFIC_CPLUS_STUFF,
TYPE_SPECIFIC_GNAT_STUFF,
TYPE_SPECIFIC_FLOATFORMAT,
/* Note: This is used by TYPE_CODE_FUNC and TYPE_CODE_METHOD. */
TYPE_SPECIFIC_FUNC,
TYPE_SPECIFIC_SELF_TYPE,
TYPE_SPECIFIC_INT,
TYPE_SPECIFIC_FIXED_POINT,
};
union type_owner
{
struct objfile *objfile;
struct gdbarch *gdbarch;
};
union field_location
{
/* * Position of this field, counting in bits from start of
containing structure. For big-endian targets, it is the bit
offset to the MSB. For little-endian targets, it is the bit
offset to the LSB. */
LONGEST bitpos;
/* * Enum value. */
LONGEST enumval;
/* * For a static field, if TYPE_FIELD_STATIC_HAS_ADDR then
physaddr is the location (in the target) of the static
field. Otherwise, physname is the mangled label of the
static field. */
CORE_ADDR physaddr;
const char *physname;
/* * The field location can be computed by evaluating the
following DWARF block. Its DATA is allocated on
objfile_obstack - no CU load is needed to access it. */
struct dwarf2_locexpr_baton *dwarf_block;
};
struct field
{
struct type *type () const
{
return this->m_type;
}
void set_type (struct type *type)
{
this->m_type = type;
}
const char *name () const
{
return m_name;
}
void set_name (const char *name)
{
m_name = name;
}
/* Location getters / setters. */
field_loc_kind loc_kind () const
{
return m_loc_kind;
}
LONGEST loc_bitpos () const
{
gdb_assert (m_loc_kind == FIELD_LOC_KIND_BITPOS);
return m_loc.bitpos;
}
void set_loc_bitpos (LONGEST bitpos)
{
m_loc_kind = FIELD_LOC_KIND_BITPOS;
m_loc.bitpos = bitpos;
}
LONGEST loc_enumval () const
{
gdb_assert (m_loc_kind == FIELD_LOC_KIND_ENUMVAL);
return m_loc.enumval;
}
void set_loc_enumval (LONGEST enumval)
{
m_loc_kind = FIELD_LOC_KIND_ENUMVAL;
m_loc.enumval = enumval;
}
CORE_ADDR loc_physaddr () const
{
gdb_assert (m_loc_kind == FIELD_LOC_KIND_PHYSADDR);
return m_loc.physaddr;
}
void set_loc_physaddr (CORE_ADDR physaddr)
{
m_loc_kind = FIELD_LOC_KIND_PHYSADDR;
m_loc.physaddr = physaddr;
}
const char *loc_physname () const
{
gdb_assert (m_loc_kind == FIELD_LOC_KIND_PHYSNAME);
return m_loc.physname;
}
void set_loc_physname (const char *physname)
{
m_loc_kind = FIELD_LOC_KIND_PHYSNAME;
m_loc.physname = physname;
}
dwarf2_locexpr_baton *loc_dwarf_block () const
{
gdb_assert (m_loc_kind == FIELD_LOC_KIND_DWARF_BLOCK);
return m_loc.dwarf_block;
}
void set_loc_dwarf_block (dwarf2_locexpr_baton *dwarf_block)
{
m_loc_kind = FIELD_LOC_KIND_DWARF_BLOCK;
m_loc.dwarf_block = dwarf_block;
}
union field_location m_loc;
/* * For a function or member type, this is 1 if the argument is
marked artificial. Artificial arguments should not be shown
to the user. For TYPE_CODE_RANGE it is set if the specific
bound is not defined. */
unsigned int artificial : 1;
/* * Discriminant for union field_location. */
ENUM_BITFIELD(field_loc_kind) m_loc_kind : 3;
/* * Size of this field, in bits, or zero if not packed.
If non-zero in an array type, indicates the element size in
bits (used only in Ada at the moment).
For an unpacked field, the field's type's length
says how many bytes the field occupies. */
unsigned int bitsize : 28;
/* * In a struct or union type, type of this field.
- In a function or member type, type of this argument.
- In an array type, the domain-type of the array. */
struct type *m_type;
/* * Name of field, value or argument.
NULL for range bounds, array domains, and member function
arguments. */
const char *m_name;
};
struct range_bounds
{
ULONGEST bit_stride () const
{
if (this->flag_is_byte_stride)
return this->stride.const_val () * 8;
else
return this->stride.const_val ();
}
/* * Low bound of range. */
struct dynamic_prop low;
/* * High bound of range. */
struct dynamic_prop high;
/* The stride value for this range. This can be stored in bits or bytes
based on the value of BYTE_STRIDE_P. It is optional to have a stride
value, if this range has no stride value defined then this will be set
to the constant zero. */
struct dynamic_prop stride;
/* * The bias. Sometimes a range value is biased before storage.
The bias is added to the stored bits to form the true value. */
LONGEST bias;
/* True if HIGH range bound contains the number of elements in the
subrange. This affects how the final high bound is computed. */
unsigned int flag_upper_bound_is_count : 1;
/* True if LOW or/and HIGH are resolved into a static bound from
a dynamic one. */
unsigned int flag_bound_evaluated : 1;
/* If this is true this STRIDE is in bytes, otherwise STRIDE is in bits. */
unsigned int flag_is_byte_stride : 1;
};
/* Compare two range_bounds objects for equality. Simply does
memberwise comparison. */
extern bool operator== (const range_bounds &l, const range_bounds &r);
/* Compare two range_bounds objects for inequality. */
static inline bool operator!= (const range_bounds &l, const range_bounds &r)
{
return !(l == r);
}
union type_specific
{
/* * CPLUS_STUFF is for TYPE_CODE_STRUCT. It is initialized to
point to cplus_struct_default, a default static instance of a
struct cplus_struct_type. */
struct cplus_struct_type *cplus_stuff;
/* * GNAT_STUFF is for types for which the GNAT Ada compiler
provides additional information. */
struct gnat_aux_type *gnat_stuff;
/* * FLOATFORMAT is for TYPE_CODE_FLT. It is a pointer to a
floatformat object that describes the floating-point value
that resides within the type. */
const struct floatformat *floatformat;
/* * For TYPE_CODE_FUNC and TYPE_CODE_METHOD types. */
struct func_type *func_stuff;
/* * For types that are pointer to member types (TYPE_CODE_METHODPTR,
TYPE_CODE_MEMBERPTR), SELF_TYPE is the type that this pointer
is a member of. */
struct type *self_type;
/* * For TYPE_CODE_FIXED_POINT types, the info necessary to decode
values of that type. */
struct fixed_point_type_info *fixed_point_info;
/* * An integer-like scalar type may be stored in just part of its
enclosing storage bytes. This structure describes this
situation. */
struct
{
/* * The bit size of the integer. This can be 0. For integers
that fill their storage (the ordinary case), this field holds
the byte size times 8. */
unsigned short bit_size;
/* * The bit offset of the integer. This is ordinarily 0, and can
only be non-zero if the bit size is less than the storage
size. */
unsigned short bit_offset;
} int_stuff;
};
/* * Main structure representing a type in GDB.
This structure is space-critical. Its layout has been tweaked to
reduce the space used. */
struct main_type
{
/* * Code for kind of type. */
ENUM_BITFIELD(type_code) code : 8;
/* * Flags about this type. These fields appear at this location
because they packs nicely here. See the TYPE_* macros for
documentation about these fields. */
unsigned int m_flag_unsigned : 1;
unsigned int m_flag_nosign : 1;
unsigned int m_flag_stub : 1;
unsigned int m_flag_target_stub : 1;
unsigned int m_flag_prototyped : 1;
unsigned int m_flag_varargs : 1;
unsigned int m_flag_vector : 1;
unsigned int m_flag_stub_supported : 1;
unsigned int m_flag_gnu_ifunc : 1;
unsigned int m_flag_fixed_instance : 1;
unsigned int m_flag_objfile_owned : 1;
unsigned int m_flag_endianity_not_default : 1;
/* * True if this type was declared with "class" rather than
"struct". */
unsigned int m_flag_declared_class : 1;
/* * True if this is an enum type with disjoint values. This
affects how the enum is printed. */
unsigned int m_flag_flag_enum : 1;
/* * A discriminant telling us which field of the type_specific
union is being used for this type, if any. */
ENUM_BITFIELD(type_specific_kind) type_specific_field : 3;
/* * Number of fields described for this type. This field appears
at this location because it packs nicely here. */
short nfields;
/* * Name of this type, or NULL if none.
This is used for printing only. For looking up a name, look for
a symbol in the VAR_DOMAIN. This is generally allocated in the
objfile's obstack. However coffread.c uses malloc. */
const char *name;
/* * Every type is now associated with a particular objfile, and the
type is allocated on the objfile_obstack for that objfile. One
problem however, is that there are times when gdb allocates new
types while it is not in the process of reading symbols from a
particular objfile. Fortunately, these happen when the type
being created is a derived type of an existing type, such as in
lookup_pointer_type(). So we can just allocate the new type
using the same objfile as the existing type, but to do this we
need a backpointer to the objfile from the existing type. Yes
this is somewhat ugly, but without major overhaul of the internal
type system, it can't be avoided for now. */
union type_owner m_owner;
/* * For a pointer type, describes the type of object pointed to.
- For an array type, describes the type of the elements.
- For a function or method type, describes the type of the return value.
- For a range type, describes the type of the full range.
- For a complex type, describes the type of each coordinate.
- For a special record or union type encoding a dynamic-sized type
in GNAT, a memoized pointer to a corresponding static version of
the type.
- Unused otherwise. */
struct type *target_type;
/* * For structure and union types, a description of each field.
For set and pascal array types, there is one "field",
whose type is the domain type of the set or array.
For range types, there are two "fields",
the minimum and maximum values (both inclusive).
For enum types, each possible value is described by one "field".
For a function or method type, a "field" for each parameter.
For C++ classes, there is one field for each base class (if it is
a derived class) plus one field for each class data member. Member
functions are recorded elsewhere.
Using a pointer to a separate array of fields
allows all types to have the same size, which is useful
because we can allocate the space for a type before
we know what to put in it. */
union
{
struct field *fields;
/* * Union member used for range types. */
struct range_bounds *bounds;
/* If this is a scalar type, then this is its corresponding
complex type. */
struct type *complex_type;
} flds_bnds;
/* * Slot to point to additional language-specific fields of this
type. */
union type_specific type_specific;
/* * Contains all dynamic type properties. */
struct dynamic_prop_list *dyn_prop_list;
};
/* * Number of bits allocated for alignment. */
#define TYPE_ALIGN_BITS 8
/* * A ``struct type'' describes a particular instance of a type, with
some particular qualification. */
struct type
{
/* Get the type code of this type.
Note that the code can be TYPE_CODE_TYPEDEF, so if you want the real
type, you need to do `check_typedef (type)->code ()`. */
type_code code () const
{
return this->main_type->code;
}
/* Set the type code of this type. */
void set_code (type_code code)
{
this->main_type->code = code;
}
/* Get the name of this type. */
const char *name () const
{
return this->main_type->name;
}
/* Set the name of this type. */
void set_name (const char *name)
{
this->main_type->name = name;
}
/* Get the number of fields of this type. */
int num_fields () const
{
return this->main_type->nfields;
}
/* Set the number of fields of this type. */
void set_num_fields (int num_fields)
{
this->main_type->nfields = num_fields;
}
/* Get the fields array of this type. */
struct field *fields () const
{
return this->main_type->flds_bnds.fields;
}
/* Get the field at index IDX. */
struct field &field (int idx) const
{
gdb_assert (idx >= 0 && idx < num_fields ());
return this->fields ()[idx];
}
/* Set the fields array of this type. */
void set_fields (struct field *fields)
{
this->main_type->flds_bnds.fields = fields;
}
type *index_type () const
{
return this->field (0).type ();
}
void set_index_type (type *index_type)
{
this->field (0).set_type (index_type);
}
/* Return the instance flags converted to the correct type. */
const type_instance_flags instance_flags () const
{
return (enum type_instance_flag_value) this->m_instance_flags;
}
/* Set the instance flags. */
void set_instance_flags (type_instance_flags flags)
{
this->m_instance_flags = flags;
}
/* Get the bounds bounds of this type. The type must be a range type. */
range_bounds *bounds () const
{
switch (this->code ())
{
case TYPE_CODE_RANGE:
return this->main_type->flds_bnds.bounds;
case TYPE_CODE_ARRAY:
case TYPE_CODE_STRING:
return this->index_type ()->bounds ();
default:
gdb_assert_not_reached
("type::bounds called on type with invalid code");
}
}
/* Set the bounds of this type. The type must be a range type. */
void set_bounds (range_bounds *bounds)
{
gdb_assert (this->code () == TYPE_CODE_RANGE);
this->main_type->flds_bnds.bounds = bounds;
}
ULONGEST bit_stride () const
{
if (this->code () == TYPE_CODE_ARRAY && this->field (0).bitsize != 0)
return this->field (0).bitsize;
return this->bounds ()->bit_stride ();
}
/* Unsigned integer type. If this is not set for a TYPE_CODE_INT,
the type is signed (unless TYPE_NOSIGN is set). */
bool is_unsigned () const
{
return this->main_type->m_flag_unsigned;
}
void set_is_unsigned (bool is_unsigned)
{
this->main_type->m_flag_unsigned = is_unsigned;
}
/* No sign for this type. In C++, "char", "signed char", and
"unsigned char" are distinct types; so we need an extra flag to
indicate the absence of a sign! */
bool has_no_signedness () const
{
return this->main_type->m_flag_nosign;
}
void set_has_no_signedness (bool has_no_signedness)
{
this->main_type->m_flag_nosign = has_no_signedness;
}
/* This appears in a type's flags word if it is a stub type (e.g.,
if someone referenced a type that wasn't defined in a source file
via (struct sir_not_appearing_in_this_film *)). */
bool is_stub () const
{
return this->main_type->m_flag_stub;
}
void set_is_stub (bool is_stub)
{
this->main_type->m_flag_stub = is_stub;
}
/* The target type of this type is a stub type, and this type needs
to be updated if it gets un-stubbed in check_typedef. Used for
arrays and ranges, in which TYPE_LENGTH of the array/range gets set
based on the TYPE_LENGTH of the target type. Also, set for
TYPE_CODE_TYPEDEF. */
bool target_is_stub () const
{
return this->main_type->m_flag_target_stub;
}
void set_target_is_stub (bool target_is_stub)
{
this->main_type->m_flag_target_stub = target_is_stub;
}
/* This is a function type which appears to have a prototype. We
need this for function calls in order to tell us if it's necessary
to coerce the args, or to just do the standard conversions. This
is used with a short field. */
bool is_prototyped () const
{
return this->main_type->m_flag_prototyped;
}
void set_is_prototyped (bool is_prototyped)
{
this->main_type->m_flag_prototyped = is_prototyped;
}
/* FIXME drow/2002-06-03: Only used for methods, but applies as well
to functions. */
bool has_varargs () const
{
return this->main_type->m_flag_varargs;
}
void set_has_varargs (bool has_varargs)
{
this->main_type->m_flag_varargs = has_varargs;
}
/* Identify a vector type. Gcc is handling this by adding an extra
attribute to the array type. We slurp that in as a new flag of a
type. This is used only in dwarf2read.c. */
bool is_vector () const
{
return this->main_type->m_flag_vector;
}
void set_is_vector (bool is_vector)
{
this->main_type->m_flag_vector = is_vector;
}
/* This debug target supports TYPE_STUB(t). In the unsupported case
we have to rely on NFIELDS to be zero etc., see TYPE_IS_OPAQUE().
TYPE_STUB(t) with !TYPE_STUB_SUPPORTED(t) may exist if we only
guessed the TYPE_STUB(t) value (see dwarfread.c). */
bool stub_is_supported () const
{
return this->main_type->m_flag_stub_supported;
}
void set_stub_is_supported (bool stub_is_supported)
{
this->main_type->m_flag_stub_supported = stub_is_supported;
}
/* Used only for TYPE_CODE_FUNC where it specifies the real function
address is returned by this function call. TYPE_TARGET_TYPE
determines the final returned function type to be presented to
user. */
bool is_gnu_ifunc () const
{
return this->main_type->m_flag_gnu_ifunc;
}
void set_is_gnu_ifunc (bool is_gnu_ifunc)
{
this->main_type->m_flag_gnu_ifunc = is_gnu_ifunc;
}
/* The debugging formats (especially STABS) do not contain enough
information to represent all Ada types---especially those whose
size depends on dynamic quantities. Therefore, the GNAT Ada
compiler includes extra information in the form of additional type
definitions connected by naming conventions. This flag indicates
that the type is an ordinary (unencoded) GDB type that has been
created from the necessary run-time information, and does not need
further interpretation. Optionally marks ordinary, fixed-size GDB
type. */
bool is_fixed_instance () const
{
return this->main_type->m_flag_fixed_instance;
}
void set_is_fixed_instance (bool is_fixed_instance)
{
this->main_type->m_flag_fixed_instance = is_fixed_instance;
}
/* A compiler may supply dwarf instrumentation that indicates the desired
endian interpretation of the variable differs from the native endian
representation. */
bool endianity_is_not_default () const
{
return this->main_type->m_flag_endianity_not_default;
}
void set_endianity_is_not_default (bool endianity_is_not_default)
{
this->main_type->m_flag_endianity_not_default = endianity_is_not_default;
}
/* True if this type was declared using the "class" keyword. This is
only valid for C++ structure and enum types. If false, a structure
was declared as a "struct"; if true it was declared "class". For
enum types, this is true when "enum class" or "enum struct" was
used to declare the type. */
bool is_declared_class () const
{
return this->main_type->m_flag_declared_class;
}
void set_is_declared_class (bool is_declared_class) const
{
this->main_type->m_flag_declared_class = is_declared_class;
}
/* True if this type is a "flag" enum. A flag enum is one where all
the values are pairwise disjoint when "and"ed together. This
affects how enum values are printed. */
bool is_flag_enum () const
{
return this->main_type->m_flag_flag_enum;
}
void set_is_flag_enum (bool is_flag_enum)
{
this->main_type->m_flag_flag_enum = is_flag_enum;
}
/* * Assuming that THIS is a TYPE_CODE_FIXED_POINT, return a reference
to this type's fixed_point_info. */
struct fixed_point_type_info &fixed_point_info () const
{
gdb_assert (this->code () == TYPE_CODE_FIXED_POINT);
gdb_assert (this->main_type->type_specific.fixed_point_info != nullptr);
return *this->main_type->type_specific.fixed_point_info;
}
/* * Assuming that THIS is a TYPE_CODE_FIXED_POINT, set this type's
fixed_point_info to INFO. */
void set_fixed_point_info (struct fixed_point_type_info *info) const
{
gdb_assert (this->code () == TYPE_CODE_FIXED_POINT);
this->main_type->type_specific.fixed_point_info = info;
}
/* * Assuming that THIS is a TYPE_CODE_FIXED_POINT, return its base type.
In other words, this returns the type after having peeled all
intermediate type layers (such as TYPE_CODE_RANGE, for instance).
The TYPE_CODE of the type returned is guaranteed to be
a TYPE_CODE_FIXED_POINT. */
struct type *fixed_point_type_base_type ();
/* * Assuming that THIS is a TYPE_CODE_FIXED_POINT, return its scaling
factor. */
const gdb_mpq &fixed_point_scaling_factor ();
/* * Return the dynamic property of the requested KIND from this type's
list of dynamic properties. */
dynamic_prop *dyn_prop (dynamic_prop_node_kind kind) const;
/* * Given a dynamic property PROP of a given KIND, add this dynamic
property to this type.
This function assumes that this type is objfile-owned. */
void add_dyn_prop (dynamic_prop_node_kind kind, dynamic_prop prop);
/* * Remove dynamic property of kind KIND from this type, if it exists. */
void remove_dyn_prop (dynamic_prop_node_kind kind);
/* Return true if this type is owned by an objfile. Return false if it is
owned by an architecture. */
bool is_objfile_owned () const
{
return this->main_type->m_flag_objfile_owned;
}
/* Set the owner of the type to be OBJFILE. */
void set_owner (objfile *objfile)
{
gdb_assert (objfile != nullptr);
this->main_type->m_owner.objfile = objfile;
this->main_type->m_flag_objfile_owned = true;
}
/* Set the owner of the type to be ARCH. */
void set_owner (gdbarch *arch)
{
gdb_assert (arch != nullptr);
this->main_type->m_owner.gdbarch = arch;
this->main_type->m_flag_objfile_owned = false;
}
/* Return the objfile owner of this type.
Return nullptr if this type is not objfile-owned. */
struct objfile *objfile_owner () const
{
if (!this->is_objfile_owned ())
return nullptr;
return this->main_type->m_owner.objfile;
}
/* Return the gdbarch owner of this type.
Return nullptr if this type is not gdbarch-owned. */
gdbarch *arch_owner () const
{
if (this->is_objfile_owned ())
return nullptr;
return this->main_type->m_owner.gdbarch;
}
/* Return the type's architecture. For types owned by an
architecture, that architecture is returned. For types owned by an
objfile, that objfile's architecture is returned.
The return value is always non-nullptr. */
gdbarch *arch () const;
/* * Return true if this is an integer type whose logical (bit) size
differs from its storage size; false otherwise. Always return
false for non-integer (i.e., non-TYPE_SPECIFIC_INT) types. */
bool bit_size_differs_p () const
{
return (main_type->type_specific_field == TYPE_SPECIFIC_INT
&& main_type->type_specific.int_stuff.bit_size != 8 * length);
}
/* * Return the logical (bit) size for this integer type. Only
valid for integer (TYPE_SPECIFIC_INT) types. */
unsigned short bit_size () const
{
gdb_assert (main_type->type_specific_field == TYPE_SPECIFIC_INT);
return main_type->type_specific.int_stuff.bit_size;
}
/* * Return the bit offset for this integer type. Only valid for
integer (TYPE_SPECIFIC_INT) types. */
unsigned short bit_offset () const
{
gdb_assert (main_type->type_specific_field == TYPE_SPECIFIC_INT);
return main_type->type_specific.int_stuff.bit_offset;
}
/* Return true if this is a pointer or reference type. */
bool is_pointer_or_reference () const
{
return this->code () == TYPE_CODE_PTR || TYPE_IS_REFERENCE (this);
}
/* * Type that is a pointer to this type.
NULL if no such pointer-to type is known yet.
The debugger may add the address of such a type
if it has to construct one later. */
struct type *pointer_type;
/* * C++: also need a reference type. */
struct type *reference_type;
/* * A C++ rvalue reference type added in C++11. */
struct type *rvalue_reference_type;
/* * Variant chain. This points to a type that differs from this
one only in qualifiers and length. Currently, the possible
qualifiers are const, volatile, code-space, data-space, and
address class. The length may differ only when one of the
address class flags are set. The variants are linked in a
circular ring and share MAIN_TYPE. */
struct type *chain;
/* * The alignment for this type. Zero means that the alignment was
not specified in the debug info. Note that this is stored in a
funny way: as the log base 2 (plus 1) of the alignment; so a
value of 1 means the alignment is 1, and a value of 9 means the
alignment is 256. */
unsigned align_log2 : TYPE_ALIGN_BITS;
/* * Flags specific to this instance of the type, indicating where
on the ring we are.
For TYPE_CODE_TYPEDEF the flags of the typedef type should be
binary or-ed with the target type, with a special case for
address class and space class. For example if this typedef does
not specify any new qualifiers, TYPE_INSTANCE_FLAGS is 0 and the
instance flags are completely inherited from the target type. No
qualifiers can be cleared by the typedef. See also
check_typedef. */
unsigned m_instance_flags : 9;
/* * Length of storage for a value of this type. The value is the
expression in host bytes of what sizeof(type) would return. This
size includes padding. For example, an i386 extended-precision
floating point value really only occupies ten bytes, but most
ABI's declare its size to be 12 bytes, to preserve alignment.
A `struct type' representing such a floating-point type would
have a `length' value of 12, even though the last two bytes are
unused.
Since this field is expressed in host bytes, its value is appropriate
to pass to memcpy and such (it is assumed that GDB itself always runs
on an 8-bits addressable architecture). However, when using it for
target address arithmetic (e.g. adding it to a target address), the
type_length_units function should be used in order to get the length
expressed in target addressable memory units. */
ULONGEST length;
/* * Core type, shared by a group of qualified types. */
struct main_type *main_type;
};
struct fn_fieldlist
{
/* * The overloaded name.
This is generally allocated in the objfile's obstack.
However stabsread.c sometimes uses malloc. */
const char *name;
/* * The number of methods with this name. */
int length;
/* * The list of methods. */
struct fn_field *fn_fields;
};
struct fn_field
{
/* * If is_stub is clear, this is the mangled name which we can look
up to find the address of the method (FIXME: it would be cleaner
to have a pointer to the struct symbol here instead).
If is_stub is set, this is the portion of the mangled name which
specifies the arguments. For example, "ii", if there are two int
arguments, or "" if there are no arguments. See gdb_mangle_name
for the conversion from this format to the one used if is_stub is
clear. */
const char *physname;
/* * The function type for the method.
(This comment used to say "The return value of the method", but
that's wrong. The function type is expected here, i.e. something
with TYPE_CODE_METHOD, and *not* the return-value type). */
struct type *type;
/* * For virtual functions. First baseclass that defines this
virtual function. */
struct type *fcontext;
/* Attributes. */
unsigned int is_const:1;
unsigned int is_volatile:1;
unsigned int is_private:1;
unsigned int is_protected:1;
unsigned int is_artificial:1;
/* * A stub method only has some fields valid (but they are enough
to reconstruct the rest of the fields). */
unsigned int is_stub:1;
/* * True if this function is a constructor, false otherwise. */
unsigned int is_constructor : 1;
/* * True if this function is deleted, false otherwise. */
unsigned int is_deleted : 1;
/* * DW_AT_defaulted attribute for this function. The value is one
of the DW_DEFAULTED constants. */
ENUM_BITFIELD (dwarf_defaulted_attribute) defaulted : 2;
/* * Unused. */
unsigned int dummy:6;
/* * Index into that baseclass's virtual function table, minus 2;
else if static: VOFFSET_STATIC; else: 0. */
unsigned int voffset:16;
#define VOFFSET_STATIC 1
};
struct decl_field
{
/* * Unqualified name to be prefixed by owning class qualified
name. */
const char *name;
/* * Type this typedef named NAME represents. */
struct type *type;
/* * True if this field was declared protected, false otherwise. */
unsigned int is_protected : 1;
/* * True if this field was declared private, false otherwise. */
unsigned int is_private : 1;
};
/* * C++ language-specific information for TYPE_CODE_STRUCT and
TYPE_CODE_UNION nodes. */
struct cplus_struct_type
{
/* * Number of base classes this type derives from. The
baseclasses are stored in the first N_BASECLASSES fields
(i.e. the `fields' field of the struct type). The only fields
of struct field that are used are: type, name, loc.bitpos. */
short n_baseclasses;
/* * Field number of the virtual function table pointer in VPTR_BASETYPE.
All access to this field must be through TYPE_VPTR_FIELDNO as one
thing it does is check whether the field has been initialized.
Initially TYPE_RAW_CPLUS_SPECIFIC has the value of cplus_struct_default,
which for portability reasons doesn't initialize this field.
TYPE_VPTR_FIELDNO returns -1 for this case.
If -1, we were unable to find the virtual function table pointer in
initial symbol reading, and get_vptr_fieldno should be called to find
it if possible. get_vptr_fieldno will update this field if possible.
Otherwise the value is left at -1.
Unused if this type does not have virtual functions. */
short vptr_fieldno;
/* * Number of methods with unique names. All overloaded methods
with the same name count only once. */
short nfn_fields;
/* * Number of template arguments. */
unsigned short n_template_arguments;
/* * One if this struct is a dynamic class, as defined by the
Itanium C++ ABI: if it requires a virtual table pointer,
because it or any of its base classes have one or more virtual
member functions or virtual base classes. Minus one if not
dynamic. Zero if not yet computed. */
int is_dynamic : 2;
/* * The calling convention for this type, fetched from the
DW_AT_calling_convention attribute. The value is one of the
DW_CC constants. */
ENUM_BITFIELD (dwarf_calling_convention) calling_convention : 8;
/* * The base class which defined the virtual function table pointer. */
struct type *vptr_basetype;
/* * For derived classes, the number of base classes is given by
n_baseclasses and virtual_field_bits is a bit vector containing
one bit per base class. If the base class is virtual, the
corresponding bit will be set.
I.E, given:
class A{};
class B{};
class C : public B, public virtual A {};
B is a baseclass of C; A is a virtual baseclass for C.
This is a C++ 2.0 language feature. */
B_TYPE *virtual_field_bits;
/* * For classes with private fields, the number of fields is
given by nfields and private_field_bits is a bit vector
containing one bit per field.
If the field is private, the corresponding bit will be set. */
B_TYPE *private_field_bits;
/* * For classes with protected fields, the number of fields is
given by nfields and protected_field_bits is a bit vector
containing one bit per field.
If the field is private, the corresponding bit will be set. */
B_TYPE *protected_field_bits;
/* * For classes with fields to be ignored, either this is
optimized out or this field has length 0. */
B_TYPE *ignore_field_bits;
/* * For classes, structures, and unions, a description of each
field, which consists of an overloaded name, followed by the
types of arguments that the method expects, and then the name
after it has been renamed to make it distinct.
fn_fieldlists points to an array of nfn_fields of these. */
struct fn_fieldlist *fn_fieldlists;
/* * typedefs defined inside this class. typedef_field points to
an array of typedef_field_count elements. */
struct decl_field *typedef_field;
unsigned typedef_field_count;
/* * The nested types defined by this type. nested_types points to
an array of nested_types_count elements. */
struct decl_field *nested_types;
unsigned nested_types_count;
/* * The template arguments. This is an array with
N_TEMPLATE_ARGUMENTS elements. This is NULL for non-template
classes. */
struct symbol **template_arguments;
};
/* * Struct used to store conversion rankings. */
struct rank
{
short rank;
/* * When two conversions are of the same type and therefore have
the same rank, subrank is used to differentiate the two.
Eg: Two derived-class-pointer to base-class-pointer conversions
would both have base pointer conversion rank, but the
conversion with the shorter distance to the ancestor is
preferable. 'subrank' would be used to reflect that. */
short subrank;
};
/* * Used for ranking a function for overload resolution. */
typedef std::vector<rank> badness_vector;
/* * GNAT Ada-specific information for various Ada types. */
struct gnat_aux_type
{
/* * Parallel type used to encode information about dynamic types
used in Ada (such as variant records, variable-size array,
etc). */
struct type* descriptive_type;
};
/* * For TYPE_CODE_FUNC and TYPE_CODE_METHOD types. */
struct func_type
{
/* * The calling convention for targets supporting multiple ABIs.
Right now this is only fetched from the Dwarf-2
DW_AT_calling_convention attribute. The value is one of the
DW_CC constants. */
ENUM_BITFIELD (dwarf_calling_convention) calling_convention : 8;
/* * Whether this function normally returns to its caller. It is
set from the DW_AT_noreturn attribute if set on the
DW_TAG_subprogram. */
unsigned int is_noreturn : 1;
/* * Only those DW_TAG_call_site's in this function that have
DW_AT_call_tail_call set are linked in this list. Function
without its tail call list complete
(DW_AT_call_all_tail_calls or its superset
DW_AT_call_all_calls) has TAIL_CALL_LIST NULL, even if some
DW_TAG_call_site's exist in such function. */
struct call_site *tail_call_list;
/* * For method types (TYPE_CODE_METHOD), the aggregate type that
contains the method. */
struct type *self_type;
};
/* struct call_site_parameter can be referenced in callees by several ways. */
enum call_site_parameter_kind
{
/* * Use field call_site_parameter.u.dwarf_reg. */
CALL_SITE_PARAMETER_DWARF_REG,
/* * Use field call_site_parameter.u.fb_offset. */
CALL_SITE_PARAMETER_FB_OFFSET,
/* * Use field call_site_parameter.u.param_offset. */
CALL_SITE_PARAMETER_PARAM_OFFSET
};
struct call_site_target
{
/* The kind of location held by this call site target. */
enum kind
{
/* An address. */
PHYSADDR,
/* A name. */
PHYSNAME,
/* A DWARF block. */
DWARF_BLOCK,
/* An array of addresses. */
ADDRESSES,
};
void set_loc_physaddr (CORE_ADDR physaddr)
{
m_loc_kind = PHYSADDR;
m_loc.physaddr = physaddr;
}
void set_loc_physname (const char *physname)
{
m_loc_kind = PHYSNAME;
m_loc.physname = physname;
}
void set_loc_dwarf_block (dwarf2_locexpr_baton *dwarf_block)
{
m_loc_kind = DWARF_BLOCK;
m_loc.dwarf_block = dwarf_block;
}
void set_loc_array (unsigned length, const CORE_ADDR *data)
{
m_loc_kind = ADDRESSES;
m_loc.addresses.length = length;
m_loc.addresses.values = data;
}
/* Callback type for iterate_over_addresses. */
using iterate_ftype = gdb::function_view<void (CORE_ADDR)>;
/* Call CALLBACK for each DW_TAG_call_site's DW_AT_call_target
address. CALLER_FRAME (for registers) can be NULL if it is not
known. This function always may throw NO_ENTRY_VALUE_ERROR. */
void iterate_over_addresses (struct gdbarch *call_site_gdbarch,
const struct call_site *call_site,
struct frame_info *caller_frame,
iterate_ftype callback) const;
private:
union
{
/* Address. */
CORE_ADDR physaddr;
/* Mangled name. */
const char *physname;
/* DWARF block. */
struct dwarf2_locexpr_baton *dwarf_block;
/* Array of addresses. */
struct
{
unsigned length;
const CORE_ADDR *values;
} addresses;
} m_loc;
/* * Discriminant for union field_location. */
enum kind m_loc_kind;
};
union call_site_parameter_u
{
/* * DW_TAG_formal_parameter's DW_AT_location's DW_OP_regX
as DWARF register number, for register passed
parameters. */
int dwarf_reg;
/* * Offset from the callee's frame base, for stack passed
parameters. This equals offset from the caller's stack
pointer. */
CORE_ADDR fb_offset;
/* * Offset relative to the start of this PER_CU to
DW_TAG_formal_parameter which is referenced by both
caller and the callee. */
cu_offset param_cu_off;
};
struct call_site_parameter
{
ENUM_BITFIELD (call_site_parameter_kind) kind : 2;
union call_site_parameter_u u;
/* * DW_TAG_formal_parameter's DW_AT_call_value. It is never NULL. */
const gdb_byte *value;
size_t value_size;
/* * DW_TAG_formal_parameter's DW_AT_call_data_value.
It may be NULL if not provided by DWARF. */
const gdb_byte *data_value;
size_t data_value_size;
};
/* * A place where a function gets called from, represented by
DW_TAG_call_site. It can be looked up from symtab->call_site_htab. */
struct call_site
{
call_site (CORE_ADDR pc, dwarf2_per_cu_data *per_cu,
dwarf2_per_objfile *per_objfile)
: per_cu (per_cu), per_objfile (per_objfile), m_unrelocated_pc (pc)
{}
static int
eq (const call_site *a, const call_site *b)
{
return a->m_unrelocated_pc == b->m_unrelocated_pc;
}
static hashval_t
hash (const call_site *a)
{
return a->m_unrelocated_pc;
}
static int
eq (const void *a, const void *b)
{
return eq ((const call_site *)a, (const call_site *)b);
}
static hashval_t
hash (const void *a)
{
return hash ((const call_site *)a);
}
/* Return the address of the first instruction after this call. */
CORE_ADDR pc () const;
/* Call CALLBACK for each target address. CALLER_FRAME (for
registers) can be NULL if it is not known. This function may
throw NO_ENTRY_VALUE_ERROR. */
void iterate_over_addresses (struct gdbarch *call_site_gdbarch,
struct frame_info *caller_frame,
call_site_target::iterate_ftype callback)
const
{
return target.iterate_over_addresses (call_site_gdbarch, this,
caller_frame, callback);
}
/* * List successor with head in FUNC_TYPE.TAIL_CALL_LIST. */
struct call_site *tail_call_next = nullptr;
/* * Describe DW_AT_call_target. Missing attribute uses
FIELD_LOC_KIND_DWARF_BLOCK with FIELD_DWARF_BLOCK == NULL. */
struct call_site_target target {};
/* * Size of the PARAMETER array. */
unsigned parameter_count = 0;
/* * CU of the function where the call is located. It gets used
for DWARF blocks execution in the parameter array below. */
dwarf2_per_cu_data *const per_cu = nullptr;
/* objfile of the function where the call is located. */
dwarf2_per_objfile *const per_objfile = nullptr;
private:
/* Unrelocated address of the first instruction after this call. */
const CORE_ADDR m_unrelocated_pc;
public:
/* * Describe DW_TAG_call_site's DW_TAG_formal_parameter. */
struct call_site_parameter parameter[];
};
/* The type-specific info for TYPE_CODE_FIXED_POINT types. */
struct fixed_point_type_info
{
/* The fixed point type's scaling factor. */
gdb_mpq scaling_factor;
};
/* * The default value of TYPE_CPLUS_SPECIFIC(T) points to this shared
static structure. */
extern const struct cplus_struct_type cplus_struct_default;
extern void allocate_cplus_struct_type (struct type *);
#define INIT_CPLUS_SPECIFIC(type) \
(TYPE_SPECIFIC_FIELD (type) = TYPE_SPECIFIC_CPLUS_STUFF, \
TYPE_RAW_CPLUS_SPECIFIC (type) = (struct cplus_struct_type*) \
&cplus_struct_default)
#define ALLOCATE_CPLUS_STRUCT_TYPE(type) allocate_cplus_struct_type (type)
#define HAVE_CPLUS_STRUCT(type) \
(TYPE_SPECIFIC_FIELD (type) == TYPE_SPECIFIC_CPLUS_STUFF \
&& TYPE_RAW_CPLUS_SPECIFIC (type) != &cplus_struct_default)
#define INIT_NONE_SPECIFIC(type) \
(TYPE_SPECIFIC_FIELD (type) = TYPE_SPECIFIC_NONE, \
TYPE_MAIN_TYPE (type)->type_specific = {})
extern const struct gnat_aux_type gnat_aux_default;
extern void allocate_gnat_aux_type (struct type *);
#define INIT_GNAT_SPECIFIC(type) \
(TYPE_SPECIFIC_FIELD (type) = TYPE_SPECIFIC_GNAT_STUFF, \
TYPE_GNAT_SPECIFIC (type) = (struct gnat_aux_type *) &gnat_aux_default)
#define ALLOCATE_GNAT_AUX_TYPE(type) allocate_gnat_aux_type (type)
/* * A macro that returns non-zero if the type-specific data should be
read as "gnat-stuff". */
#define HAVE_GNAT_AUX_INFO(type) \
(TYPE_SPECIFIC_FIELD (type) == TYPE_SPECIFIC_GNAT_STUFF)
/* * True if TYPE is known to be an Ada type of some kind. */
#define ADA_TYPE_P(type) \
(TYPE_SPECIFIC_FIELD (type) == TYPE_SPECIFIC_GNAT_STUFF \
|| (TYPE_SPECIFIC_FIELD (type) == TYPE_SPECIFIC_NONE \
&& (type)->is_fixed_instance ()))
#define INIT_FUNC_SPECIFIC(type) \
(TYPE_SPECIFIC_FIELD (type) = TYPE_SPECIFIC_FUNC, \
TYPE_MAIN_TYPE (type)->type_specific.func_stuff = (struct func_type *) \
TYPE_ZALLOC (type, \
sizeof (*TYPE_MAIN_TYPE (type)->type_specific.func_stuff)))
/* "struct fixed_point_type_info" has a field that has a destructor.
See allocate_fixed_point_type_info to understand how this is
handled. */
#define INIT_FIXED_POINT_SPECIFIC(type) \
(TYPE_SPECIFIC_FIELD (type) = TYPE_SPECIFIC_FIXED_POINT, \
allocate_fixed_point_type_info (type))
#define TYPE_MAIN_TYPE(thistype) (thistype)->main_type
#define TYPE_TARGET_TYPE(thistype) TYPE_MAIN_TYPE(thistype)->target_type
#define TYPE_POINTER_TYPE(thistype) (thistype)->pointer_type
#define TYPE_REFERENCE_TYPE(thistype) (thistype)->reference_type
#define TYPE_RVALUE_REFERENCE_TYPE(thistype) (thistype)->rvalue_reference_type
#define TYPE_CHAIN(thistype) (thistype)->chain
#define TYPE_DYN_PROP(thistype) TYPE_MAIN_TYPE(thistype)->dyn_prop_list
/* * Note that if thistype is a TYPEDEF type, you have to call check_typedef.
But check_typedef does set the TYPE_LENGTH of the TYPEDEF type,
so you only have to call check_typedef once. Since allocate_value
calls check_typedef, TYPE_LENGTH (VALUE_TYPE (X)) is safe. */
#define TYPE_LENGTH(thistype) (thistype)->length
/* * Return the alignment of the type in target addressable memory
units, or 0 if no alignment was specified. */
#define TYPE_RAW_ALIGN(thistype) type_raw_align (thistype)
/* * Return the alignment of the type in target addressable memory
units, or 0 if no alignment was specified. */
extern unsigned type_raw_align (struct type *);
/* * Return the alignment of the type in target addressable memory
units. Return 0 if the alignment cannot be determined; but note
that this makes an effort to compute the alignment even it it was
not specified in the debug info. */
extern unsigned type_align (struct type *);
/* * Set the alignment of the type. The alignment must be a power of
2. Returns false if the given value does not fit in the available
space in struct type. */
extern bool set_type_align (struct type *, ULONGEST);
/* Property accessors for the type data location. */
#define TYPE_DATA_LOCATION(thistype) \
((thistype)->dyn_prop (DYN_PROP_DATA_LOCATION))
#define TYPE_DATA_LOCATION_BATON(thistype) \
TYPE_DATA_LOCATION (thistype)->data.baton
#define TYPE_DATA_LOCATION_ADDR(thistype) \
(TYPE_DATA_LOCATION (thistype)->const_val ())
#define TYPE_DATA_LOCATION_KIND(thistype) \
(TYPE_DATA_LOCATION (thistype)->kind ())
#define TYPE_DYNAMIC_LENGTH(thistype) \
((thistype)->dyn_prop (DYN_PROP_BYTE_SIZE))
/* Property accessors for the type allocated/associated. */
#define TYPE_ALLOCATED_PROP(thistype) \
((thistype)->dyn_prop (DYN_PROP_ALLOCATED))
#define TYPE_ASSOCIATED_PROP(thistype) \
((thistype)->dyn_prop (DYN_PROP_ASSOCIATED))
#define TYPE_RANK_PROP(thistype) \
((thistype)->dyn_prop (DYN_PROP_RANK))
/* C++ */
#define TYPE_SELF_TYPE(thistype) internal_type_self_type (thistype)
/* Do not call this, use TYPE_SELF_TYPE. */
extern struct type *internal_type_self_type (struct type *);
extern void set_type_self_type (struct type *, struct type *);
extern int internal_type_vptr_fieldno (struct type *);
extern void set_type_vptr_fieldno (struct type *, int);
extern struct type *internal_type_vptr_basetype (struct type *);
extern void set_type_vptr_basetype (struct type *, struct type *);
#define TYPE_VPTR_FIELDNO(thistype) internal_type_vptr_fieldno (thistype)
#define TYPE_VPTR_BASETYPE(thistype) internal_type_vptr_basetype (thistype)
#define TYPE_NFN_FIELDS(thistype) TYPE_CPLUS_SPECIFIC(thistype)->nfn_fields
#define TYPE_SPECIFIC_FIELD(thistype) \
TYPE_MAIN_TYPE(thistype)->type_specific_field
/* We need this tap-dance with the TYPE_RAW_SPECIFIC because of the case
where we're trying to print an Ada array using the C language.
In that case, there is no "cplus_stuff", but the C language assumes
that there is. What we do, in that case, is pretend that there is
an implicit one which is the default cplus stuff. */
#define TYPE_CPLUS_SPECIFIC(thistype) \
(!HAVE_CPLUS_STRUCT(thistype) \
? (struct cplus_struct_type*)&cplus_struct_default \
: TYPE_RAW_CPLUS_SPECIFIC(thistype))
#define TYPE_RAW_CPLUS_SPECIFIC(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.cplus_stuff
#define TYPE_CPLUS_CALLING_CONVENTION(thistype) \
TYPE_MAIN_TYPE(thistype)->type_specific.cplus_stuff->calling_convention
#define TYPE_FLOATFORMAT(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.floatformat
#define TYPE_GNAT_SPECIFIC(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.gnat_stuff
#define TYPE_DESCRIPTIVE_TYPE(thistype) TYPE_GNAT_SPECIFIC(thistype)->descriptive_type
#define TYPE_CALLING_CONVENTION(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.func_stuff->calling_convention
#define TYPE_NO_RETURN(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.func_stuff->is_noreturn
#define TYPE_TAIL_CALL_LIST(thistype) TYPE_MAIN_TYPE(thistype)->type_specific.func_stuff->tail_call_list
#define TYPE_BASECLASS(thistype,index) ((thistype)->field (index).type ())
#define TYPE_N_BASECLASSES(thistype) TYPE_CPLUS_SPECIFIC(thistype)->n_baseclasses
#define TYPE_BASECLASS_NAME(thistype,index) (thistype->field (index).name ())
#define TYPE_BASECLASS_BITPOS(thistype,index) (thistype->field (index).loc_bitpos ())
#define BASETYPE_VIA_PUBLIC(thistype, index) \
((!TYPE_FIELD_PRIVATE(thistype, index)) && (!TYPE_FIELD_PROTECTED(thistype, index)))
#define TYPE_CPLUS_DYNAMIC(thistype) TYPE_CPLUS_SPECIFIC (thistype)->is_dynamic
#define BASETYPE_VIA_VIRTUAL(thistype, index) \
(TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits == NULL ? 0 \
: B_TST(TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits, (index)))
#define FIELD_ARTIFICIAL(thisfld) ((thisfld).artificial)
#define FIELD_BITSIZE(thisfld) ((thisfld).bitsize)
#define TYPE_FIELD_ARTIFICIAL(thistype, n) FIELD_ARTIFICIAL((thistype)->field (n))
#define TYPE_FIELD_BITSIZE(thistype, n) FIELD_BITSIZE((thistype)->field (n))
#define TYPE_FIELD_PACKED(thistype, n) (FIELD_BITSIZE((thistype)->field (n))!=0)
#define TYPE_FIELD_PRIVATE_BITS(thistype) \
TYPE_CPLUS_SPECIFIC(thistype)->private_field_bits
#define TYPE_FIELD_PROTECTED_BITS(thistype) \
TYPE_CPLUS_SPECIFIC(thistype)->protected_field_bits
#define TYPE_FIELD_IGNORE_BITS(thistype) \
TYPE_CPLUS_SPECIFIC(thistype)->ignore_field_bits
#define TYPE_FIELD_VIRTUAL_BITS(thistype) \
TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits
#define SET_TYPE_FIELD_PRIVATE(thistype, n) \
B_SET (TYPE_CPLUS_SPECIFIC(thistype)->private_field_bits, (n))
#define SET_TYPE_FIELD_PROTECTED(thistype, n) \
B_SET (TYPE_CPLUS_SPECIFIC(thistype)->protected_field_bits, (n))
#define SET_TYPE_FIELD_IGNORE(thistype, n) \
B_SET (TYPE_CPLUS_SPECIFIC(thistype)->ignore_field_bits, (n))
#define SET_TYPE_FIELD_VIRTUAL(thistype, n) \
B_SET (TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits, (n))
#define TYPE_FIELD_PRIVATE(thistype, n) \
(TYPE_CPLUS_SPECIFIC(thistype)->private_field_bits == NULL ? 0 \
: B_TST(TYPE_CPLUS_SPECIFIC(thistype)->private_field_bits, (n)))
#define TYPE_FIELD_PROTECTED(thistype, n) \
(TYPE_CPLUS_SPECIFIC(thistype)->protected_field_bits == NULL ? 0 \
: B_TST(TYPE_CPLUS_SPECIFIC(thistype)->protected_field_bits, (n)))
#define TYPE_FIELD_IGNORE(thistype, n) \
(TYPE_CPLUS_SPECIFIC(thistype)->ignore_field_bits == NULL ? 0 \
: B_TST(TYPE_CPLUS_SPECIFIC(thistype)->ignore_field_bits, (n)))
#define TYPE_FIELD_VIRTUAL(thistype, n) \
(TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits == NULL ? 0 \
: B_TST(TYPE_CPLUS_SPECIFIC(thistype)->virtual_field_bits, (n)))
#define TYPE_FN_FIELDLISTS(thistype) TYPE_CPLUS_SPECIFIC(thistype)->fn_fieldlists
#define TYPE_FN_FIELDLIST(thistype, n) TYPE_CPLUS_SPECIFIC(thistype)->fn_fieldlists[n]
#define TYPE_FN_FIELDLIST1(thistype, n) TYPE_CPLUS_SPECIFIC(thistype)->fn_fieldlists[n].fn_fields
#define TYPE_FN_FIELDLIST_NAME(thistype, n) TYPE_CPLUS_SPECIFIC(thistype)->fn_fieldlists[n].name
#define TYPE_FN_FIELDLIST_LENGTH(thistype, n) TYPE_CPLUS_SPECIFIC(thistype)->fn_fieldlists[n].length
#define TYPE_N_TEMPLATE_ARGUMENTS(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->n_template_arguments
#define TYPE_TEMPLATE_ARGUMENTS(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->template_arguments
#define TYPE_TEMPLATE_ARGUMENT(thistype, n) \
TYPE_CPLUS_SPECIFIC (thistype)->template_arguments[n]
#define TYPE_FN_FIELD(thisfn, n) (thisfn)[n]
#define TYPE_FN_FIELD_PHYSNAME(thisfn, n) (thisfn)[n].physname
#define TYPE_FN_FIELD_TYPE(thisfn, n) (thisfn)[n].type
#define TYPE_FN_FIELD_ARGS(thisfn, n) (((thisfn)[n].type)->fields ())
#define TYPE_FN_FIELD_CONST(thisfn, n) ((thisfn)[n].is_const)
#define TYPE_FN_FIELD_VOLATILE(thisfn, n) ((thisfn)[n].is_volatile)
#define TYPE_FN_FIELD_PRIVATE(thisfn, n) ((thisfn)[n].is_private)
#define TYPE_FN_FIELD_PROTECTED(thisfn, n) ((thisfn)[n].is_protected)
#define TYPE_FN_FIELD_ARTIFICIAL(thisfn, n) ((thisfn)[n].is_artificial)
#define TYPE_FN_FIELD_STUB(thisfn, n) ((thisfn)[n].is_stub)
#define TYPE_FN_FIELD_CONSTRUCTOR(thisfn, n) ((thisfn)[n].is_constructor)
#define TYPE_FN_FIELD_FCONTEXT(thisfn, n) ((thisfn)[n].fcontext)
#define TYPE_FN_FIELD_VOFFSET(thisfn, n) ((thisfn)[n].voffset-2)
#define TYPE_FN_FIELD_VIRTUAL_P(thisfn, n) ((thisfn)[n].voffset > 1)
#define TYPE_FN_FIELD_STATIC_P(thisfn, n) ((thisfn)[n].voffset == VOFFSET_STATIC)
#define TYPE_FN_FIELD_DEFAULTED(thisfn, n) ((thisfn)[n].defaulted)
#define TYPE_FN_FIELD_DELETED(thisfn, n) ((thisfn)[n].is_deleted)
/* Accessors for typedefs defined by a class. */
#define TYPE_TYPEDEF_FIELD_ARRAY(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->typedef_field
#define TYPE_TYPEDEF_FIELD(thistype, n) \
TYPE_CPLUS_SPECIFIC (thistype)->typedef_field[n]
#define TYPE_TYPEDEF_FIELD_NAME(thistype, n) \
TYPE_TYPEDEF_FIELD (thistype, n).name
#define TYPE_TYPEDEF_FIELD_TYPE(thistype, n) \
TYPE_TYPEDEF_FIELD (thistype, n).type
#define TYPE_TYPEDEF_FIELD_COUNT(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->typedef_field_count
#define TYPE_TYPEDEF_FIELD_PROTECTED(thistype, n) \
TYPE_TYPEDEF_FIELD (thistype, n).is_protected
#define TYPE_TYPEDEF_FIELD_PRIVATE(thistype, n) \
TYPE_TYPEDEF_FIELD (thistype, n).is_private
#define TYPE_NESTED_TYPES_ARRAY(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->nested_types
#define TYPE_NESTED_TYPES_FIELD(thistype, n) \
TYPE_CPLUS_SPECIFIC (thistype)->nested_types[n]
#define TYPE_NESTED_TYPES_FIELD_NAME(thistype, n) \
TYPE_NESTED_TYPES_FIELD (thistype, n).name
#define TYPE_NESTED_TYPES_FIELD_TYPE(thistype, n) \
TYPE_NESTED_TYPES_FIELD (thistype, n).type
#define TYPE_NESTED_TYPES_COUNT(thistype) \
TYPE_CPLUS_SPECIFIC (thistype)->nested_types_count
#define TYPE_NESTED_TYPES_FIELD_PROTECTED(thistype, n) \
TYPE_NESTED_TYPES_FIELD (thistype, n).is_protected
#define TYPE_NESTED_TYPES_FIELD_PRIVATE(thistype, n) \
TYPE_NESTED_TYPES_FIELD (thistype, n).is_private
#define TYPE_IS_OPAQUE(thistype) \
((((thistype)->code () == TYPE_CODE_STRUCT) \
|| ((thistype)->code () == TYPE_CODE_UNION)) \
&& ((thistype)->num_fields () == 0) \
&& (!HAVE_CPLUS_STRUCT (thistype) \
|| TYPE_NFN_FIELDS (thistype) == 0) \
&& ((thistype)->is_stub () || !(thistype)->stub_is_supported ()))
/* * A helper macro that returns the name of a type or "unnamed type"
if the type has no name. */
#define TYPE_SAFE_NAME(type) \
(type->name () != nullptr ? type->name () : _("<unnamed type>"))
/* * A helper macro that returns the name of an error type. If the
type has a name, it is used; otherwise, a default is used. */
#define TYPE_ERROR_NAME(type) \
(type->name () ? type->name () : _("<error type>"))
/* Given TYPE, return its floatformat. */
const struct floatformat *floatformat_from_type (const struct type *type);
struct builtin_type
{
/* Integral types. */
/* Implicit size/sign (based on the architecture's ABI). */
struct type *builtin_void;
struct type *builtin_char;
struct type *builtin_short;
struct type *builtin_int;
struct type *builtin_long;
struct type *builtin_signed_char;
struct type *builtin_unsigned_char;
struct type *builtin_unsigned_short;
struct type *builtin_unsigned_int;
struct type *builtin_unsigned_long;
struct type *builtin_bfloat16;
struct type *builtin_half;
struct type *builtin_float;
struct type *builtin_double;
struct type *builtin_long_double;
struct type *builtin_complex;
struct type *builtin_double_complex;
struct type *builtin_string;
struct type *builtin_bool;
struct type *builtin_long_long;
struct type *builtin_unsigned_long_long;
struct type *builtin_decfloat;
struct type *builtin_decdouble;
struct type *builtin_declong;
/* "True" character types.
We use these for the '/c' print format, because c_char is just a
one-byte integral type, which languages less laid back than C
will print as ... well, a one-byte integral type. */
struct type *builtin_true_char;
struct type *builtin_true_unsigned_char;
/* Explicit sizes - see C9X <intypes.h> for naming scheme. The "int0"
is for when an architecture needs to describe a register that has
no size. */
struct type *builtin_int0;
struct type *builtin_int8;
struct type *builtin_uint8;
struct type *builtin_int16;
struct type *builtin_uint16;
struct type *builtin_int24;
struct type *builtin_uint24;
struct type *builtin_int32;
struct type *builtin_uint32;
struct type *builtin_int64;
struct type *builtin_uint64;
struct type *builtin_int128;
struct type *builtin_uint128;
/* Wide character types. */
struct type *builtin_char16;
struct type *builtin_char32;
struct type *builtin_wchar;
/* Pointer types. */
/* * `pointer to data' type. Some target platforms use an implicitly
{sign,zero} -extended 32-bit ABI pointer on a 64-bit ISA. */
struct type *builtin_data_ptr;
/* * `pointer to function (returning void)' type. Harvard
architectures mean that ABI function and code pointers are not
interconvertible. Similarly, since ANSI, C standards have
explicitly said that pointers to functions and pointers to data
are not interconvertible --- that is, you can't cast a function
pointer to void * and back, and expect to get the same value.
However, all function pointer types are interconvertible, so void
(*) () can server as a generic function pointer. */
struct type *builtin_func_ptr;
/* * `function returning pointer to function (returning void)' type.
The final void return type is not significant for it. */
struct type *builtin_func_func;
/* Special-purpose types. */
/* * This type is used to represent a GDB internal function. */
struct type *internal_fn;
/* * This type is used to represent an xmethod. */
struct type *xmethod;
};
/* * Return the type table for the specified architecture. */
extern const struct builtin_type *builtin_type (struct gdbarch *gdbarch);
/* * Per-objfile types used by symbol readers. */
struct objfile_type
{
/* Basic types based on the objfile architecture. */
struct type *builtin_void;
struct type *builtin_char;
struct type *builtin_short;
struct type *builtin_int;
struct type *builtin_long;
struct type *builtin_long_long;
struct type *builtin_signed_char;
struct type *builtin_unsigned_char;
struct type *builtin_unsigned_short;
struct type *builtin_unsigned_int;
struct type *builtin_unsigned_long;
struct type *builtin_unsigned_long_long;
struct type *builtin_half;
struct type *builtin_float;
struct type *builtin_double;
struct type *builtin_long_double;
/* * This type is used to represent symbol addresses. */
struct type *builtin_core_addr;
/* * This type represents a type that was unrecognized in symbol
read-in. */
struct type *builtin_error;
/* * Types used for symbols with no debug information. */
struct type *nodebug_text_symbol;
struct type *nodebug_text_gnu_ifunc_symbol;
struct type *nodebug_got_plt_symbol;
struct type *nodebug_data_symbol;
struct type *nodebug_unknown_symbol;
struct type *nodebug_tls_symbol;
};
/* * Return the type table for the specified objfile. */
extern const struct objfile_type *objfile_type (struct objfile *objfile);
/* Explicit floating-point formats. See "floatformat.h". */
extern const struct floatformat *floatformats_ieee_half[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ieee_single[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ieee_double[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ieee_quad[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ieee_double_littlebyte_bigword[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_i387_ext[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_m68881_ext[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_arm_ext[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ia64_spill[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_vax_f[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_vax_d[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_ibm_long_double[BFD_ENDIAN_UNKNOWN];
extern const struct floatformat *floatformats_bfloat16[BFD_ENDIAN_UNKNOWN];
/* Allocate space for storing data associated with a particular
type. We ensure that the space is allocated using the same
mechanism that was used to allocate the space for the type
structure itself. I.e. if the type is on an objfile's
objfile_obstack, then the space for data associated with that type
will also be allocated on the objfile_obstack. If the type is
associated with a gdbarch, then the space for data associated with that
type will also be allocated on the gdbarch_obstack.
If a type is not associated with neither an objfile or a gdbarch then
you should not use this macro to allocate space for data, instead you
should call xmalloc directly, and ensure the memory is correctly freed
when it is no longer needed. */
#define TYPE_ALLOC(t,size) \
(obstack_alloc (((t)->is_objfile_owned () \
? &((t)->objfile_owner ()->objfile_obstack) \
: gdbarch_obstack ((t)->arch_owner ())), \
size))
/* See comment on TYPE_ALLOC. */
#define TYPE_ZALLOC(t,size) (memset (TYPE_ALLOC (t, size), 0, size))
/* Use alloc_type to allocate a type owned by an objfile. Use
alloc_type_arch to allocate a type owned by an architecture. Use
alloc_type_copy to allocate a type with the same owner as a
pre-existing template type, no matter whether objfile or
gdbarch. */
extern struct type *alloc_type (struct objfile *);
extern struct type *alloc_type_arch (struct gdbarch *);
extern struct type *alloc_type_copy (const struct type *);
/* * This returns the target type (or NULL) of TYPE, also skipping
past typedefs. */
extern struct type *get_target_type (struct type *type);
/* Return the equivalent of TYPE_LENGTH, but in number of target
addressable memory units of the associated gdbarch instead of bytes. */
extern unsigned int type_length_units (struct type *type);
/* * Helper function to construct objfile-owned types. */
extern struct type *init_type (struct objfile *, enum type_code, int,
const char *);
extern struct type *init_integer_type (struct objfile *, int, int,
const char *);
extern struct type *init_character_type (struct objfile *, int, int,
const char *);
extern struct type *init_boolean_type (struct objfile *, int, int,
const char *);
extern struct type *init_float_type (struct objfile *, int, const char *,
const struct floatformat **,
enum bfd_endian = BFD_ENDIAN_UNKNOWN);
extern struct type *init_decfloat_type (struct objfile *, int, const char *);
extern bool can_create_complex_type (struct type *);
extern struct type *init_complex_type (const char *, struct type *);
extern struct type *init_pointer_type (struct objfile *, int, const char *,
struct type *);
extern struct type *init_fixed_point_type (struct objfile *, int, int,
const char *);
/* Helper functions to construct architecture-owned types. */
extern struct type *arch_type (struct gdbarch *, enum type_code, int,
const char *);
extern struct type *arch_integer_type (struct gdbarch *, int, int,
const char *);
extern struct type *arch_character_type (struct gdbarch *, int, int,
const char *);
extern struct type *arch_boolean_type (struct gdbarch *, int, int,
const char *);
extern struct type *arch_float_type (struct gdbarch *, int, const char *,
const struct floatformat **);
extern struct type *arch_decfloat_type (struct gdbarch *, int, const char *);
extern struct type *arch_pointer_type (struct gdbarch *, int, const char *,
struct type *);
/* Helper functions to construct a struct or record type. An
initially empty type is created using arch_composite_type().
Fields are then added using append_composite_type_field*(). A union
type has its size set to the largest field. A struct type has each
field packed against the previous. */
extern struct type *arch_composite_type (struct gdbarch *gdbarch,
const char *name, enum type_code code);
extern void append_composite_type_field (struct type *t, const char *name,
struct type *field);
extern void append_composite_type_field_aligned (struct type *t,
const char *name,
struct type *field,
int alignment);
struct field *append_composite_type_field_raw (struct type *t, const char *name,
struct type *field);
/* Helper functions to construct a bit flags type. An initially empty
type is created using arch_flag_type(). Flags are then added using
append_flag_type_field() and append_flag_type_flag(). */
extern struct type *arch_flags_type (struct gdbarch *gdbarch,
const char *name, int bit);
extern void append_flags_type_field (struct type *type,
int start_bitpos, int nr_bits,
struct type *field_type, const char *name);
extern void append_flags_type_flag (struct type *type, int bitpos,
const char *name);
extern void make_vector_type (struct type *array_type);
extern struct type *init_vector_type (struct type *elt_type, int n);
extern struct type *lookup_reference_type (struct type *, enum type_code);
extern struct type *lookup_lvalue_reference_type (struct type *);
extern struct type *lookup_rvalue_reference_type (struct type *);
extern struct type *make_reference_type (struct type *, struct type **,
enum type_code);
extern struct type *make_cv_type (int, int, struct type *, struct type **);
extern struct type *make_restrict_type (struct type *);
extern struct type *make_unqualified_type (struct type *);
extern struct type *make_atomic_type (struct type *);
extern void replace_type (struct type *, struct type *);
extern type_instance_flags address_space_name_to_type_instance_flags
(struct gdbarch *, const char *);
extern const char *address_space_type_instance_flags_to_name
(struct gdbarch *, type_instance_flags);
extern struct type *make_type_with_address_space
(struct type *type, type_instance_flags space_identifier);
extern struct type *lookup_memberptr_type (struct type *, struct type *);
extern struct type *lookup_methodptr_type (struct type *);
extern void smash_to_method_type (struct type *type, struct type *self_type,
struct type *to_type, struct field *args,
int nargs, int varargs);
extern void smash_to_memberptr_type (struct type *, struct type *,
struct type *);
extern void smash_to_methodptr_type (struct type *, struct type *);
extern struct type *allocate_stub_method (struct type *);
extern const char *type_name_or_error (struct type *type);
struct struct_elt
{
/* The field of the element, or NULL if no element was found. */
struct field *field;
/* The bit offset of the element in the parent structure. */
LONGEST offset;
};
/* Given a type TYPE, lookup the field and offset of the component named
NAME.
TYPE can be either a struct or union, or a pointer or reference to
a struct or union. If it is a pointer or reference, its target
type is automatically used. Thus '.' and '->' are interchangable,
as specified for the definitions of the expression element types
STRUCTOP_STRUCT and STRUCTOP_PTR.
If NOERR is nonzero, the returned structure will have field set to
NULL if there is no component named NAME.
If the component NAME is a field in an anonymous substructure of
TYPE, the returned offset is a "global" offset relative to TYPE
rather than an offset within the substructure. */
extern struct_elt lookup_struct_elt (struct type *, const char *, int);
/* Given a type TYPE, lookup the type of the component named NAME.
TYPE can be either a struct or union, or a pointer or reference to
a struct or union. If it is a pointer or reference, its target
type is automatically used. Thus '.' and '->' are interchangable,
as specified for the definitions of the expression element types
STRUCTOP_STRUCT and STRUCTOP_PTR.
If NOERR is nonzero, return NULL if there is no component named
NAME. */
extern struct type *lookup_struct_elt_type (struct type *, const char *, int);
extern struct type *make_pointer_type (struct type *, struct type **);
extern struct type *lookup_pointer_type (struct type *);
extern struct type *make_function_type (struct type *, struct type **);
extern struct type *lookup_function_type (struct type *);
extern struct type *lookup_function_type_with_arguments (struct type *,
int,
struct type **);
extern struct type *create_static_range_type (struct type *, struct type *,
LONGEST, LONGEST);
extern struct type *create_array_type_with_stride
(struct type *, struct type *, struct type *,
struct dynamic_prop *, unsigned int);
extern struct type *create_range_type (struct type *, struct type *,
const struct dynamic_prop *,
const struct dynamic_prop *,
LONGEST);
/* Like CREATE_RANGE_TYPE but also sets up a stride. When BYTE_STRIDE_P
is true the value in STRIDE is a byte stride, otherwise STRIDE is a bit
stride. */
extern struct type * create_range_type_with_stride
(struct type *result_type, struct type *index_type,
const struct dynamic_prop *low_bound,
const struct dynamic_prop *high_bound, LONGEST bias,
const struct dynamic_prop *stride, bool byte_stride_p);
extern struct type *create_array_type (struct type *, struct type *,
struct type *);
extern struct type *lookup_array_range_type (struct type *, LONGEST, LONGEST);
extern struct type *create_string_type (struct type *, struct type *,
struct type *);
extern struct type *lookup_string_range_type (struct type *, LONGEST, LONGEST);
extern struct type *create_set_type (struct type *, struct type *);
extern struct type *lookup_unsigned_typename (const struct language_defn *,
const char *);
extern struct type *lookup_signed_typename (const struct language_defn *,
const char *);
extern ULONGEST get_unsigned_type_max (struct type *);
extern void get_signed_type_minmax (struct type *, LONGEST *, LONGEST *);
extern CORE_ADDR get_pointer_type_max (struct type *);
/* * Resolve all dynamic values of a type e.g. array bounds to static values.
ADDR specifies the location of the variable the type is bound to.
If TYPE has no dynamic properties return TYPE; otherwise a new type with
static properties is returned.
For an array type, if the element type is dynamic, then that will
not be resolved. This is done because each individual element may
have a different type when resolved (depending on the contents of
memory). In this situation, 'is_dynamic_type' will still return
true for the return value of this function. */
extern struct type *resolve_dynamic_type
(struct type *type, gdb::array_view<const gdb_byte> valaddr,
CORE_ADDR addr);
/* * Predicate if the type has dynamic values, which are not resolved yet.
See the caveat in 'resolve_dynamic_type' to understand a scenario
where an apparently-resolved type may still be considered
"dynamic". */
extern int is_dynamic_type (struct type *type);
extern struct type *check_typedef (struct type *);
extern void check_stub_method_group (struct type *, int);
extern char *gdb_mangle_name (struct type *, int, int);
extern struct type *lookup_typename (const struct language_defn *,
const char *, const struct block *, int);
extern struct type *lookup_template_type (const char *, struct type *,
const struct block *);
extern int get_vptr_fieldno (struct type *, struct type **);
/* Set *LOWP and *HIGHP to the lower and upper bounds of discrete type
TYPE.
Return true if the two bounds are available, false otherwise. */
extern bool get_discrete_bounds (struct type *type, LONGEST *lowp,
LONGEST *highp);
/* If TYPE's low bound is a known constant, return it, else return nullopt. */
extern gdb::optional<LONGEST> get_discrete_low_bound (struct type *type);
/* If TYPE's high bound is a known constant, return it, else return nullopt. */
extern gdb::optional<LONGEST> get_discrete_high_bound (struct type *type);
/* Assuming TYPE is a simple, non-empty array type, compute its upper
and lower bound. Save the low bound into LOW_BOUND if not NULL.
Save the high bound into HIGH_BOUND if not NULL.
Return true if the operation was successful. Return false otherwise,
in which case the values of LOW_BOUND and HIGH_BOUNDS are unmodified. */
extern bool get_array_bounds (struct type *type, LONGEST *low_bound,
LONGEST *high_bound);
extern gdb::optional<LONGEST> discrete_position (struct type *type,
LONGEST val);
extern int class_types_same_p (const struct type *, const struct type *);
extern int is_ancestor (struct type *, struct type *);
extern int is_public_ancestor (struct type *, struct type *);
extern int is_unique_ancestor (struct type *, struct value *);
/* Overload resolution */
/* * Badness if parameter list length doesn't match arg list length. */
extern const struct rank LENGTH_MISMATCH_BADNESS;
/* * Dummy badness value for nonexistent parameter positions. */
extern const struct rank TOO_FEW_PARAMS_BADNESS;
/* * Badness if no conversion among types. */
extern const struct rank INCOMPATIBLE_TYPE_BADNESS;
/* * Badness of an exact match. */
extern const struct rank EXACT_MATCH_BADNESS;
/* * Badness of integral promotion. */
extern const struct rank INTEGER_PROMOTION_BADNESS;
/* * Badness of floating promotion. */
extern const struct rank FLOAT_PROMOTION_BADNESS;
/* * Badness of converting a derived class pointer
to a base class pointer. */
extern const struct rank BASE_PTR_CONVERSION_BADNESS;
/* * Badness of integral conversion. */
extern const struct rank INTEGER_CONVERSION_BADNESS;
/* * Badness of floating conversion. */
extern const struct rank FLOAT_CONVERSION_BADNESS;
/* * Badness of integer<->floating conversions. */
extern const struct rank INT_FLOAT_CONVERSION_BADNESS;
/* * Badness of conversion of pointer to void pointer. */
extern const struct rank VOID_PTR_CONVERSION_BADNESS;
/* * Badness of conversion to boolean. */
extern const struct rank BOOL_CONVERSION_BADNESS;
/* * Badness of converting derived to base class. */
extern const struct rank BASE_CONVERSION_BADNESS;
/* * Badness of converting from non-reference to reference. Subrank
is the type of reference conversion being done. */
extern const struct rank REFERENCE_CONVERSION_BADNESS;
extern const struct rank REFERENCE_SEE_THROUGH_BADNESS;
/* * Conversion to rvalue reference. */
#define REFERENCE_CONVERSION_RVALUE 1
/* * Conversion to const lvalue reference. */
#define REFERENCE_CONVERSION_CONST_LVALUE 2
/* * Badness of converting integer 0 to NULL pointer. */
extern const struct rank NULL_POINTER_CONVERSION;
/* * Badness of cv-conversion. Subrank is a flag describing the conversions
being done. */
extern const struct rank CV_CONVERSION_BADNESS;
#define CV_CONVERSION_CONST 1
#define CV_CONVERSION_VOLATILE 2
/* Non-standard conversions allowed by the debugger */
/* * Converting a pointer to an int is usually OK. */
extern const struct rank NS_POINTER_CONVERSION_BADNESS;
/* * Badness of converting a (non-zero) integer constant
to a pointer. */
extern const struct rank NS_INTEGER_POINTER_CONVERSION_BADNESS;
extern struct rank sum_ranks (struct rank a, struct rank b);
extern int compare_ranks (struct rank a, struct rank b);
extern int compare_badness (const badness_vector &,
const badness_vector &);
extern badness_vector rank_function (gdb::array_view<type *> parms,
gdb::array_view<value *> args);
extern struct rank rank_one_type (struct type *, struct type *,
struct value *);
extern void recursive_dump_type (struct type *, int);
extern int field_is_static (struct field *);
/* printcmd.c */
extern void print_scalar_formatted (const gdb_byte *, struct type *,
const struct value_print_options *,
int, struct ui_file *);
extern int can_dereference (struct type *);
extern int is_integral_type (struct type *);
extern int is_floating_type (struct type *);
extern int is_scalar_type (struct type *type);
extern int is_scalar_type_recursive (struct type *);
extern int class_or_union_p (const struct type *);
extern void maintenance_print_type (const char *, int);
extern htab_up create_copied_types_hash (struct objfile *objfile);
extern struct type *copy_type_recursive (struct objfile *objfile,
struct type *type,
htab_t copied_types);
extern struct type *copy_type (const struct type *type);
extern bool types_equal (struct type *, struct type *);
extern bool types_deeply_equal (struct type *, struct type *);
extern int type_not_allocated (const struct type *type);
extern int type_not_associated (const struct type *type);
/* Return True if TYPE is a TYPE_CODE_FIXED_POINT or if TYPE is
a range type whose base type is a TYPE_CODE_FIXED_POINT. */
extern bool is_fixed_point_type (struct type *type);
/* Allocate a fixed-point type info for TYPE. This should only be
called by INIT_FIXED_POINT_SPECIFIC. */
extern void allocate_fixed_point_type_info (struct type *type);
/* * When the type includes explicit byte ordering, return that.
Otherwise, the byte ordering from gdbarch_byte_order for
the type's arch is returned. */
extern enum bfd_endian type_byte_order (const struct type *type);
/* A flag to enable printing of debugging information of C++
overloading. */
extern unsigned int overload_debug;
/* Return whether the function type represented by TYPE is marked as unsafe
to call by the debugger.
This usually indicates that the function does not follow the target's
standard calling convention.
The TYPE argument must be of code TYPE_CODE_FUNC or TYPE_CODE_METHOD. */
extern bool is_nocall_function (const struct type *type);
#endif /* GDBTYPES_H */