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binutils-gdb/gdb/varobj.c

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/* Implementation of the GDB variable objects API.
Copyright (C) 1999-2022 Free Software Foundation, Inc.
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/>. */
#include "defs.h"
#include "value.h"
#include "expression.h"
#include "frame.h"
#include "language.h"
#include "gdbcmd.h"
#include "block.h"
#include "valprint.h"
#include "gdbsupport/gdb_regex.h"
#include "varobj.h"
#include "gdbthread.h"
#include "inferior.h"
#include "varobj-iter.h"
#include "parser-defs.h"
#include "gdbarch.h"
#include <algorithm>
#if HAVE_PYTHON
#include "python/python.h"
#include "python/python-internal.h"
#else
typedef int PyObject;
#endif
/* See varobj.h. */
unsigned int varobjdebug = 0;
static void
show_varobjdebug (struct ui_file *file, int from_tty,
struct cmd_list_element *c, const char *value)
{
fprintf_filtered (file, _("Varobj debugging is %s.\n"), value);
}
/* String representations of gdb's format codes. */
const char *varobj_format_string[] =
{ "natural", "binary", "decimal", "hexadecimal", "octal", "zero-hexadecimal" };
/* True if we want to allow Python-based pretty-printing. */
static bool pretty_printing = false;
void
varobj_enable_pretty_printing (void)
{
pretty_printing = true;
}
/* Data structures */
/* Every root variable has one of these structures saved in its
varobj. */
struct varobj_root
{
/* The expression for this parent. */
expression_up exp;
/* Block for which this expression is valid. */
const struct block *valid_block = NULL;
/* The frame for this expression. This field is set iff valid_block is
not NULL. */
struct frame_id frame = null_frame_id;
/* The global thread ID that this varobj_root belongs to. This field
is only valid if valid_block is not NULL.
When not 0, indicates which thread 'frame' belongs to.
When 0, indicates that the thread list was empty when the varobj_root
was created. */
int thread_id = 0;
/* If true, the -var-update always recomputes the value in the
current thread and frame. Otherwise, variable object is
always updated in the specific scope/thread/frame. */
bool floating = false;
/* Flag that indicates validity: set to false when this varobj_root refers
to symbols that do not exist anymore. */
bool is_valid = true;
/* Language-related operations for this variable and its
children. */
const struct lang_varobj_ops *lang_ops = NULL;
/* The varobj for this root node. */
struct varobj *rootvar = NULL;
};
/* Dynamic part of varobj. */
struct varobj_dynamic
{
/* Whether the children of this varobj were requested. This field is
used to decide if dynamic varobj should recompute their children.
In the event that the frontend never asked for the children, we
can avoid that. */
bool children_requested = false;
/* The pretty-printer constructor. If NULL, then the default
pretty-printer will be looked up. If None, then no
pretty-printer will be installed. */
PyObject *constructor = NULL;
/* The pretty-printer that has been constructed. If NULL, then a
new printer object is needed, and one will be constructed. */
PyObject *pretty_printer = NULL;
/* The iterator returned by the printer's 'children' method, or NULL
if not available. */
std::unique_ptr<varobj_iter> child_iter;
/* We request one extra item from the iterator, so that we can
report to the caller whether there are more items than we have
already reported. However, we don't want to install this value
when we read it, because that will mess up future updates. So,
we stash it here instead. */
std::unique_ptr<varobj_item> saved_item;
};
/* Private function prototypes */
/* Helper functions for the above subcommands. */
static int delete_variable (struct varobj *, bool);
static void delete_variable_1 (int *, struct varobj *, bool, bool);
static void install_variable (struct varobj *);
static void uninstall_variable (struct varobj *);
static struct varobj *create_child (struct varobj *, int, std::string &);
static struct varobj *
create_child_with_value (struct varobj *parent, int index,
struct varobj_item *item);
/* Utility routines */
static enum varobj_display_formats variable_default_display (struct varobj *);
static bool update_type_if_necessary (struct varobj *var,
struct value *new_value);
static bool install_new_value (struct varobj *var, struct value *value,
bool initial);
/* Language-specific routines. */
static int number_of_children (const struct varobj *);
static std::string name_of_variable (const struct varobj *);
static std::string name_of_child (struct varobj *, int);
static struct value *value_of_root (struct varobj **var_handle, bool *);
static struct value *value_of_child (const struct varobj *parent, int index);
static std::string my_value_of_variable (struct varobj *var,
enum varobj_display_formats format);
static bool is_root_p (const struct varobj *var);
static struct varobj *varobj_add_child (struct varobj *var,
struct varobj_item *item);
/* Private data */
/* Mappings of varobj_display_formats enums to gdb's format codes. */
static int format_code[] = { 0, 't', 'd', 'x', 'o', 'z' };
/* List of root variable objects. */
static std::list<struct varobj_root *> rootlist;
/* Pointer to the varobj hash table (built at run time). */
static htab_t varobj_table;
/* API Implementation */
static bool
is_root_p (const struct varobj *var)
{
return (var->root->rootvar == var);
}
#ifdef HAVE_PYTHON
/* See python-internal.h. */
gdbpy_enter_varobj::gdbpy_enter_varobj (const struct varobj *var)
: gdbpy_enter (var->root->exp->gdbarch, var->root->exp->language_defn)
{
}
#endif
/* Return the full FRAME which corresponds to the given CORE_ADDR
or NULL if no FRAME on the chain corresponds to CORE_ADDR. */
static struct frame_info *
find_frame_addr_in_frame_chain (CORE_ADDR frame_addr)
{
struct frame_info *frame = NULL;
if (frame_addr == (CORE_ADDR) 0)
return NULL;
for (frame = get_current_frame ();
frame != NULL;
frame = get_prev_frame (frame))
{
/* The CORE_ADDR we get as argument was parsed from a string GDB
output as $fp. This output got truncated to gdbarch_addr_bit.
Truncate the frame base address in the same manner before
comparing it against our argument. */
CORE_ADDR frame_base = get_frame_base_address (frame);
int addr_bit = gdbarch_addr_bit (get_frame_arch (frame));
if (addr_bit < (sizeof (CORE_ADDR) * HOST_CHAR_BIT))
frame_base &= ((CORE_ADDR) 1 << addr_bit) - 1;
if (frame_base == frame_addr)
return frame;
}
return NULL;
}
/* Creates a varobj (not its children). */
struct varobj *
varobj_create (const char *objname,
const char *expression, CORE_ADDR frame, enum varobj_type type)
{
/* Fill out a varobj structure for the (root) variable being constructed. */
std::unique_ptr<varobj> var (new varobj (new varobj_root));
if (expression != NULL)
{
struct frame_info *fi;
struct frame_id old_id = null_frame_id;
const struct block *block;
const char *p;
struct value *value = NULL;
CORE_ADDR pc;
/* Parse and evaluate the expression, filling in as much of the
variable's data as possible. */
if (has_stack_frames ())
{
/* Allow creator to specify context of variable. */
if ((type == USE_CURRENT_FRAME) || (type == USE_SELECTED_FRAME))
fi = get_selected_frame (NULL);
else
/* FIXME: cagney/2002-11-23: This code should be doing a
lookup using the frame ID and not just the frame's
``address''. This, of course, means an interface
change. However, with out that interface change ISAs,
such as the ia64 with its two stacks, won't work.
Similar goes for the case where there is a frameless
function. */
fi = find_frame_addr_in_frame_chain (frame);
}
else
fi = NULL;
if (type == USE_SELECTED_FRAME)
var->root->floating = true;
pc = 0;
block = NULL;
if (fi != NULL)
{
block = get_frame_block (fi, 0);
pc = get_frame_pc (fi);
}
p = expression;
innermost_block_tracker tracker (INNERMOST_BLOCK_FOR_SYMBOLS
| INNERMOST_BLOCK_FOR_REGISTERS);
/* Wrap the call to parse expression, so we can
return a sensible error. */
try
{
var->root->exp = parse_exp_1 (&p, pc, block, 0, &tracker);
}
catch (const gdb_exception_error &except)
{
return NULL;
}
/* Don't allow variables to be created for types. */
enum exp_opcode opcode = var->root->exp->first_opcode ();
if (opcode == OP_TYPE
|| opcode == OP_TYPEOF
|| opcode == OP_DECLTYPE)
{
fprintf_unfiltered (gdb_stderr, "Attempt to use a type name"
" as an expression.\n");
return NULL;
}
var->format = variable_default_display (var.get ());
var->root->valid_block =
var->root->floating ? NULL : tracker.block ();
var->name = expression;
/* For a root var, the name and the expr are the same. */
var->path_expr = expression;
/* When the frame is different from the current frame,
we must select the appropriate frame before parsing
the expression, otherwise the value will not be current.
Since select_frame is so benign, just call it for all cases. */
if (var->root->valid_block)
{
/* User could specify explicit FRAME-ADDR which was not found but
EXPRESSION is frame specific and we would not be able to evaluate
it correctly next time. With VALID_BLOCK set we must also set
FRAME and THREAD_ID. */
if (fi == NULL)
error (_("Failed to find the specified frame"));
var->root->frame = get_frame_id (fi);
var->root->thread_id = inferior_thread ()->global_num;
old_id = get_frame_id (get_selected_frame (NULL));
select_frame (fi);
}
/* We definitely need to catch errors here.
If evaluate_expression succeeds we got the value we wanted.
But if it fails, we still go on with a call to evaluate_type(). */
try
{
value = evaluate_expression (var->root->exp.get ());
}
catch (const gdb_exception_error &except)
{
/* Error getting the value. Try to at least get the
right type. */
struct value *type_only_value = evaluate_type (var->root->exp.get ());
var->type = value_type (type_only_value);
}
if (value != NULL)
{
int real_type_found = 0;
var->type = value_actual_type (value, 0, &real_type_found);
if (real_type_found)
value = value_cast (var->type, value);
}
/* Set language info */
var->root->lang_ops = var->root->exp->language_defn->varobj_ops ();
install_new_value (var.get (), value, 1 /* Initial assignment */);
/* Set ourselves as our root. */
var->root->rootvar = var.get ();
/* Reset the selected frame. */
if (frame_id_p (old_id))
select_frame (frame_find_by_id (old_id));
}
/* If the variable object name is null, that means this
is a temporary variable, so don't install it. */
if ((var != NULL) && (objname != NULL))
{
var->obj_name = objname;
install_variable (var.get ());
}
return var.release ();
}
/* Generates an unique name that can be used for a varobj. */
std::string
varobj_gen_name (void)
{
static int id = 0;
/* Generate a name for this object. */
id++;
return string_printf ("var%d", id);
}
/* Given an OBJNAME, returns the pointer to the corresponding varobj. Call
error if OBJNAME cannot be found. */
struct varobj *
varobj_get_handle (const char *objname)
{
varobj *var = (varobj *) htab_find_with_hash (varobj_table, objname,
htab_hash_string (objname));
if (var == NULL)
error (_("Variable object not found"));
return var;
}
/* Given the handle, return the name of the object. */
const char *
varobj_get_objname (const struct varobj *var)
{
return var->obj_name.c_str ();
}
/* Given the handle, return the expression represented by the
object. */
std::string
varobj_get_expression (const struct varobj *var)
{
return name_of_variable (var);
}
/* See varobj.h. */
int
varobj_delete (struct varobj *var, bool only_children)
{
return delete_variable (var, only_children);
}
#if HAVE_PYTHON
/* Convenience function for varobj_set_visualizer. Instantiate a
pretty-printer for a given value. */
static PyObject *
instantiate_pretty_printer (PyObject *constructor, struct value *value)
{
gdbpy_ref<> val_obj (value_to_value_object (value));
if (val_obj == nullptr)
return NULL;
return PyObject_CallFunctionObjArgs (constructor, val_obj.get (), NULL);
}
#endif
/* Set/Get variable object display format. */
enum varobj_display_formats
varobj_set_display_format (struct varobj *var,
enum varobj_display_formats format)
{
switch (format)
{
case FORMAT_NATURAL:
case FORMAT_BINARY:
case FORMAT_DECIMAL:
case FORMAT_HEXADECIMAL:
case FORMAT_OCTAL:
case FORMAT_ZHEXADECIMAL:
var->format = format;
break;
default:
var->format = variable_default_display (var);
}
if (varobj_value_is_changeable_p (var)
&& var->value != nullptr && !value_lazy (var->value.get ()))
{
var->print_value = varobj_value_get_print_value (var->value.get (),
var->format, var);
}
return var->format;
}
enum varobj_display_formats
varobj_get_display_format (const struct varobj *var)
{
return var->format;
}
gdb::unique_xmalloc_ptr<char>
varobj_get_display_hint (const struct varobj *var)
{
gdb::unique_xmalloc_ptr<char> result;
#if HAVE_PYTHON
if (!gdb_python_initialized)
return NULL;
gdbpy_enter_varobj enter_py (var);
if (var->dynamic->pretty_printer != NULL)
result = gdbpy_get_display_hint (var->dynamic->pretty_printer);
#endif
return result;
}
/* Return true if the varobj has items after TO, false otherwise. */
bool
varobj_has_more (const struct varobj *var, int to)
{
if (var->children.size () > to)
return true;
return ((to == -1 || var->children.size () == to)
&& (var->dynamic->saved_item != NULL));
}
/* If the variable object is bound to a specific thread, that
is its evaluation can always be done in context of a frame
inside that thread, returns GDB id of the thread -- which
is always positive. Otherwise, returns -1. */
int
varobj_get_thread_id (const struct varobj *var)
{
if (var->root->valid_block && var->root->thread_id > 0)
return var->root->thread_id;
else
return -1;
}
void
varobj_set_frozen (struct varobj *var, bool frozen)
{
/* When a variable is unfrozen, we don't fetch its value.
The 'not_fetched' flag remains set, so next -var-update
won't complain.
We don't fetch the value, because for structures the client
should do -var-update anyway. It would be bad to have different
client-size logic for structure and other types. */
var->frozen = frozen;
}
bool
varobj_get_frozen (const struct varobj *var)
{
return var->frozen;
}
/* A helper function that updates the contents of FROM and TO based on the
size of the vector CHILDREN. If the contents of either FROM or TO are
negative the entire range is used. */
void
varobj_restrict_range (const std::vector<varobj *> &children,
int *from, int *to)
{
int len = children.size ();
if (*from < 0 || *to < 0)
{
*from = 0;
*to = len;
}
else
{
if (*from > len)
*from = len;
if (*to > len)
*to = len;
if (*from > *to)
*from = *to;
}
}
/* A helper for update_dynamic_varobj_children that installs a new
child when needed. */
static void
install_dynamic_child (struct varobj *var,
std::vector<varobj *> *changed,
std::vector<varobj *> *type_changed,
std::vector<varobj *> *newobj,
std::vector<varobj *> *unchanged,
bool *cchanged,
int index,
struct varobj_item *item)
{
if (var->children.size () < index + 1)
{
/* There's no child yet. */
struct varobj *child = varobj_add_child (var, item);
if (newobj != NULL)
{
newobj->push_back (child);
*cchanged = true;
}
}
else
{
varobj *existing = var->children[index];
bool type_updated = update_type_if_necessary (existing,
item->value.get ());
if (type_updated)
{
if (type_changed != NULL)
type_changed->push_back (existing);
}
if (install_new_value (existing, item->value.get (), 0))
{
if (!type_updated && changed != NULL)
changed->push_back (existing);
}
else if (!type_updated && unchanged != NULL)
unchanged->push_back (existing);
}
}
#if HAVE_PYTHON
static bool
dynamic_varobj_has_child_method (const struct varobj *var)
{
PyObject *printer = var->dynamic->pretty_printer;
if (!gdb_python_initialized)
return false;
gdbpy_enter_varobj enter_py (var);
return PyObject_HasAttr (printer, gdbpy_children_cst);
}
#endif
/* A factory for creating dynamic varobj's iterators. Returns an
iterator object suitable for iterating over VAR's children. */
static std::unique_ptr<varobj_iter>
varobj_get_iterator (struct varobj *var)
{
#if HAVE_PYTHON
if (var->dynamic->pretty_printer)
return py_varobj_get_iterator (var, var->dynamic->pretty_printer);
#endif
gdb_assert_not_reached ("requested an iterator from a non-dynamic varobj");
}
static bool
update_dynamic_varobj_children (struct varobj *var,
std::vector<varobj *> *changed,
std::vector<varobj *> *type_changed,
std::vector<varobj *> *newobj,
std::vector<varobj *> *unchanged,
bool *cchanged,
bool update_children,
int from,
int to)
{
int i;
*cchanged = false;
if (update_children || var->dynamic->child_iter == NULL)
{
var->dynamic->child_iter = varobj_get_iterator (var);
var->dynamic->saved_item.reset (nullptr);
i = 0;
if (var->dynamic->child_iter == NULL)
return false;
}
else
i = var->children.size ();
/* We ask for one extra child, so that MI can report whether there
are more children. */
for (; to < 0 || i < to + 1; ++i)
{
std::unique_ptr<varobj_item> item;
/* See if there was a leftover from last time. */
if (var->dynamic->saved_item != NULL)
item = std::move (var->dynamic->saved_item);
else
item = var->dynamic->child_iter->next ();
if (item == NULL)
{
/* Iteration is done. Remove iterator from VAR. */
var->dynamic->child_iter.reset (nullptr);
break;
}
/* We don't want to push the extra child on any report list. */
if (to < 0 || i < to)
{
bool can_mention = from < 0 || i >= from;
install_dynamic_child (var, can_mention ? changed : NULL,
can_mention ? type_changed : NULL,
can_mention ? newobj : NULL,
can_mention ? unchanged : NULL,
can_mention ? cchanged : NULL, i,
item.get ());
}
else
{
var->dynamic->saved_item = std::move (item);
/* We want to truncate the child list just before this
element. */
break;
}
}
if (i < var->children.size ())
{
*cchanged = true;
for (int j = i; j < var->children.size (); ++j)
varobj_delete (var->children[j], 0);
var->children.resize (i);
}
/* If there are fewer children than requested, note that the list of
children changed. */
if (to >= 0 && var->children.size () < to)
*cchanged = true;
var->num_children = var->children.size ();
return true;
}
int
varobj_get_num_children (struct varobj *var)
{
if (var->num_children == -1)
{
if (varobj_is_dynamic_p (var))
{
bool dummy;
/* If we have a dynamic varobj, don't report -1 children.
So, try to fetch some children first. */
update_dynamic_varobj_children (var, NULL, NULL, NULL, NULL, &dummy,
false, 0, 0);
}
else
var->num_children = number_of_children (var);
}
return var->num_children >= 0 ? var->num_children : 0;
}
/* Creates a list of the immediate children of a variable object;
the return code is the number of such children or -1 on error. */
const std::vector<varobj *> &
varobj_list_children (struct varobj *var, int *from, int *to)
{
var->dynamic->children_requested = true;
if (varobj_is_dynamic_p (var))
{
bool children_changed;
/* This, in theory, can result in the number of children changing without
frontend noticing. But well, calling -var-list-children on the same
varobj twice is not something a sane frontend would do. */
update_dynamic_varobj_children (var, NULL, NULL, NULL, NULL,
&children_changed, false, 0, *to);
varobj_restrict_range (var->children, from, to);
return var->children;
}
if (var->num_children == -1)
var->num_children = number_of_children (var);
/* If that failed, give up. */
if (var->num_children == -1)
return var->children;
/* If we're called when the list of children is not yet initialized,
allocate enough elements in it. */
while (var->children.size () < var->num_children)
var->children.push_back (NULL);
for (int i = 0; i < var->num_children; i++)
{
if (var->children[i] == NULL)
{
/* Either it's the first call to varobj_list_children for
this variable object, and the child was never created,
or it was explicitly deleted by the client. */
std::string name = name_of_child (var, i);
var->children[i] = create_child (var, i, name);
}
}
varobj_restrict_range (var->children, from, to);
return var->children;
}
static struct varobj *
varobj_add_child (struct varobj *var, struct varobj_item *item)
{
varobj *v = create_child_with_value (var, var->children.size (), item);
var->children.push_back (v);
return v;
}
/* Obtain the type of an object Variable as a string similar to the one gdb
prints on the console. The caller is responsible for freeing the string.
*/
std::string
varobj_get_type (struct varobj *var)
{
/* For the "fake" variables, do not return a type. (Its type is
NULL, too.)
Do not return a type for invalid variables as well. */
if (CPLUS_FAKE_CHILD (var) || !var->root->is_valid)
return std::string ();
return type_to_string (var->type);
}
/* Obtain the type of an object variable. */
struct type *
varobj_get_gdb_type (const struct varobj *var)
{
return var->type;
}
/* Is VAR a path expression parent, i.e., can it be used to construct
a valid path expression? */
static bool
is_path_expr_parent (const struct varobj *var)
{
gdb_assert (var->root->lang_ops->is_path_expr_parent != NULL);
return var->root->lang_ops->is_path_expr_parent (var);
}
/* Is VAR a path expression parent, i.e., can it be used to construct
a valid path expression? By default we assume any VAR can be a path
parent. */
bool
varobj_default_is_path_expr_parent (const struct varobj *var)
{
return true;
}
/* Return the path expression parent for VAR. */
const struct varobj *
varobj_get_path_expr_parent (const struct varobj *var)
{
const struct varobj *parent = var;
while (!is_root_p (parent) && !is_path_expr_parent (parent))
parent = parent->parent;
/* Computation of full rooted expression for children of dynamic
varobjs is not supported. */
if (varobj_is_dynamic_p (parent))
error (_("Invalid variable object (child of a dynamic varobj)"));
return parent;
}
/* Return a pointer to the full rooted expression of varobj VAR.
If it has not been computed yet, compute it. */
const char *
varobj_get_path_expr (const struct varobj *var)
{
if (var->path_expr.empty ())
{
/* For root varobjs, we initialize path_expr
when creating varobj, so here it should be
child varobj. */
struct varobj *mutable_var = (struct varobj *) var;
gdb_assert (!is_root_p (var));
mutable_var->path_expr = (*var->root->lang_ops->path_expr_of_child) (var);
}
return var->path_expr.c_str ();
}
const struct language_defn *
varobj_get_language (const struct varobj *var)
{
return var->root->exp->language_defn;
}
int
varobj_get_attributes (const struct varobj *var)
{
int attributes = 0;
if (varobj_editable_p (var))
/* FIXME: define masks for attributes. */
attributes |= 0x00000001; /* Editable */
return attributes;
}
/* Return true if VAR is a dynamic varobj. */
bool
varobj_is_dynamic_p (const struct varobj *var)
{
return var->dynamic->pretty_printer != NULL;
}
std::string
varobj_get_formatted_value (struct varobj *var,
enum varobj_display_formats format)
{
return my_value_of_variable (var, format);
}
std::string
varobj_get_value (struct varobj *var)
{
return my_value_of_variable (var, var->format);
}
/* Set the value of an object variable (if it is editable) to the
value of the given expression. */
/* Note: Invokes functions that can call error(). */
bool
varobj_set_value (struct varobj *var, const char *expression)
{
struct value *val = NULL; /* Initialize to keep gcc happy. */
/* The argument "expression" contains the variable's new value.
We need to first construct a legal expression for this -- ugh! */
/* Does this cover all the bases? */
struct value *value = NULL; /* Initialize to keep gcc happy. */
int saved_input_radix = input_radix;
const char *s = expression;
gdb_assert (varobj_editable_p (var));
input_radix = 10; /* ALWAYS reset to decimal temporarily. */
expression_up exp = parse_exp_1 (&s, 0, 0, 0);
try
{
value = evaluate_expression (exp.get ());
}
catch (const gdb_exception_error &except)
{
/* We cannot proceed without a valid expression. */
return false;
}
/* All types that are editable must also be changeable. */
gdb_assert (varobj_value_is_changeable_p (var));
/* The value of a changeable variable object must not be lazy. */
gdb_assert (!value_lazy (var->value.get ()));
/* Need to coerce the input. We want to check if the
value of the variable object will be different
after assignment, and the first thing value_assign
does is coerce the input.
For example, if we are assigning an array to a pointer variable we
should compare the pointer with the array's address, not with the
array's content. */
value = coerce_array (value);
/* The new value may be lazy. value_assign, or
rather value_contents, will take care of this. */
try
{
val = value_assign (var->value.get (), value);
}
catch (const gdb_exception_error &except)
{
return false;
}
/* If the value has changed, record it, so that next -var-update can
report this change. If a variable had a value of '1', we've set it
to '333' and then set again to '1', when -var-update will report this
variable as changed -- because the first assignment has set the
'updated' flag. There's no need to optimize that, because return value
of -var-update should be considered an approximation. */
var->updated = install_new_value (var, val, false /* Compare values. */);
input_radix = saved_input_radix;
return true;
}
#if HAVE_PYTHON
/* A helper function to install a constructor function and visualizer
in a varobj_dynamic. */
static void
install_visualizer (struct varobj_dynamic *var, PyObject *constructor,
PyObject *visualizer)
{
Py_XDECREF (var->constructor);
var->constructor = constructor;
Py_XDECREF (var->pretty_printer);
var->pretty_printer = visualizer;
var->child_iter.reset (nullptr);
}
/* Install the default visualizer for VAR. */
static void
install_default_visualizer (struct varobj *var)
{
/* Do not install a visualizer on a CPLUS_FAKE_CHILD. */
if (CPLUS_FAKE_CHILD (var))
return;
if (pretty_printing)
{
gdbpy_ref<> pretty_printer;
if (var->value != nullptr)
{
pretty_printer = gdbpy_get_varobj_pretty_printer (var->value.get ());
if (pretty_printer == nullptr)
{
gdbpy_print_stack ();
error (_("Cannot instantiate printer for default visualizer"));
}
}
if (pretty_printer == Py_None)
pretty_printer.reset (nullptr);
install_visualizer (var->dynamic, NULL, pretty_printer.release ());
}
}
/* Instantiate and install a visualizer for VAR using CONSTRUCTOR to
make a new object. */
static void
construct_visualizer (struct varobj *var, PyObject *constructor)
{
PyObject *pretty_printer;
/* Do not install a visualizer on a CPLUS_FAKE_CHILD. */
if (CPLUS_FAKE_CHILD (var))
return;
Py_INCREF (constructor);
if (constructor == Py_None)
pretty_printer = NULL;
else
{
pretty_printer = instantiate_pretty_printer (constructor,
var->value.get ());
if (! pretty_printer)
{
gdbpy_print_stack ();
Py_DECREF (constructor);
constructor = Py_None;
Py_INCREF (constructor);
}
if (pretty_printer == Py_None)
{
Py_DECREF (pretty_printer);
pretty_printer = NULL;
}
}
install_visualizer (var->dynamic, constructor, pretty_printer);
}
#endif /* HAVE_PYTHON */
/* A helper function for install_new_value. This creates and installs
a visualizer for VAR, if appropriate. */
static void
install_new_value_visualizer (struct varobj *var)
{
#if HAVE_PYTHON
/* If the constructor is None, then we want the raw value. If VAR
does not have a value, just skip this. */
if (!gdb_python_initialized)
return;
if (var->dynamic->constructor != Py_None && var->value != NULL)
{
gdbpy_enter_varobj enter_py (var);
if (var->dynamic->constructor == NULL)
install_default_visualizer (var);
else
construct_visualizer (var, var->dynamic->constructor);
}
#else
/* Do nothing. */
#endif
}
/* When using RTTI to determine variable type it may be changed in runtime when
the variable value is changed. This function checks whether type of varobj
VAR will change when a new value NEW_VALUE is assigned and if it is so
updates the type of VAR. */
static bool
update_type_if_necessary (struct varobj *var, struct value *new_value)
{
if (new_value)
{
struct value_print_options opts;
get_user_print_options (&opts);
if (opts.objectprint)
{
struct type *new_type = value_actual_type (new_value, 0, 0);
std::string new_type_str = type_to_string (new_type);
std::string curr_type_str = varobj_get_type (var);
/* Did the type name change? */
if (curr_type_str != new_type_str)
{
var->type = new_type;
/* This information may be not valid for a new type. */
varobj_delete (var, 1);
var->children.clear ();
var->num_children = -1;
return true;
}
}
}
return false;
}
/* Assign a new value to a variable object. If INITIAL is true,
this is the first assignment after the variable object was just
created, or changed type. In that case, just assign the value
and return false.
Otherwise, assign the new value, and return true if the value is
different from the current one, false otherwise. The comparison is
done on textual representation of value. Therefore, some types
need not be compared. E.g. for structures the reported value is
always "{...}", so no comparison is necessary here. If the old
value was NULL and new one is not, or vice versa, we always return true.
The VALUE parameter should not be released -- the function will
take care of releasing it when needed. */
static bool
install_new_value (struct varobj *var, struct value *value, bool initial)
{
bool changeable;
bool need_to_fetch;
bool changed = false;
bool intentionally_not_fetched = false;
/* We need to know the varobj's type to decide if the value should
be fetched or not. C++ fake children (public/protected/private)
don't have a type. */
gdb_assert (var->type || CPLUS_FAKE_CHILD (var));
changeable = varobj_value_is_changeable_p (var);
/* If the type has custom visualizer, we consider it to be always
changeable. FIXME: need to make sure this behaviour will not
mess up read-sensitive values. */
if (var->dynamic->pretty_printer != NULL)
changeable = true;
need_to_fetch = changeable;
/* We are not interested in the address of references, and given
that in C++ a reference is not rebindable, it cannot
meaningfully change. So, get hold of the real value. */
if (value)
value = coerce_ref (value);
if (var->type && var->type->code () == TYPE_CODE_UNION)
/* For unions, we need to fetch the value implicitly because
of implementation of union member fetch. When gdb
creates a value for a field and the value of the enclosing
structure is not lazy, it immediately copies the necessary
bytes from the enclosing values. If the enclosing value is
lazy, the call to value_fetch_lazy on the field will read
the data from memory. For unions, that means we'll read the
same memory more than once, which is not desirable. So
fetch now. */
need_to_fetch = true;
/* The new value might be lazy. If the type is changeable,
that is we'll be comparing values of this type, fetch the
value now. Otherwise, on the next update the old value
will be lazy, which means we've lost that old value. */
if (need_to_fetch && value && value_lazy (value))
{
const struct varobj *parent = var->parent;
bool frozen = var->frozen;
for (; !frozen && parent; parent = parent->parent)
frozen |= parent->frozen;
if (frozen && initial)
{
/* For variables that are frozen, or are children of frozen
variables, we don't do fetch on initial assignment.
For non-initial assignment we do the fetch, since it means we're
explicitly asked to compare the new value with the old one. */
intentionally_not_fetched = true;
}
else
{
try
{
value_fetch_lazy (value);
}
catch (const gdb_exception_error &except)
{
/* Set the value to NULL, so that for the next -var-update,
we don't try to compare the new value with this value,
that we couldn't even read. */
value = NULL;
}
}
}
/* Get a reference now, before possibly passing it to any Python
code that might release it. */
value_ref_ptr value_holder;
if (value != NULL)
value_holder = value_ref_ptr::new_reference (value);
/* Below, we'll be comparing string rendering of old and new
values. Don't get string rendering if the value is
lazy -- if it is, the code above has decided that the value
should not be fetched. */
std::string print_value;
if (value != NULL && !value_lazy (value)
&& var->dynamic->pretty_printer == NULL)
print_value = varobj_value_get_print_value (value, var->format, var);
/* If the type is changeable, compare the old and the new values.
If this is the initial assignment, we don't have any old value
to compare with. */
if (!initial && changeable)
{
/* If the value of the varobj was changed by -var-set-value,
then the value in the varobj and in the target is the same.
However, that value is different from the value that the
varobj had after the previous -var-update. So need to the
varobj as changed. */
if (var->updated)
changed = true;
else if (var->dynamic->pretty_printer == NULL)
{
/* Try to compare the values. That requires that both
values are non-lazy. */
if (var->not_fetched && value_lazy (var->value.get ()))
{
/* This is a frozen varobj and the value was never read.
Presumably, UI shows some "never read" indicator.
Now that we've fetched the real value, we need to report
this varobj as changed so that UI can show the real
value. */
changed = true;
}
else if (var->value == NULL && value == NULL)
/* Equal. */
;
else if (var->value == NULL || value == NULL)
{
changed = true;
}
else
{
gdb_assert (!value_lazy (var->value.get ()));
gdb_assert (!value_lazy (value));
gdb_assert (!var->print_value.empty () && !print_value.empty ());
if (var->print_value != print_value)
changed = true;
}
}
}
if (!initial && !changeable)
{
/* For values that are not changeable, we don't compare the values.
However, we want to notice if a value was not NULL and now is NULL,
or vise versa, so that we report when top-level varobjs come in scope
and leave the scope. */
changed = (var->value != NULL) != (value != NULL);
}
/* We must always keep the new value, since children depend on it. */
var->value = value_holder;
if (value && value_lazy (value) && intentionally_not_fetched)
var->not_fetched = true;
else
var->not_fetched = false;
var->updated = false;
install_new_value_visualizer (var);
/* If we installed a pretty-printer, re-compare the printed version
to see if the variable changed. */
if (var->dynamic->pretty_printer != NULL)
{
print_value = varobj_value_get_print_value (var->value.get (),
var->format, var);
if ((var->print_value.empty () && !print_value.empty ())
|| (!var->print_value.empty () && print_value.empty ())
|| (!var->print_value.empty () && !print_value.empty ()
&& var->print_value != print_value))
changed = true;
}
var->print_value = print_value;
gdb_assert (var->value == nullptr || value_type (var->value.get ()));
return changed;
}
/* Return the requested range for a varobj. VAR is the varobj. FROM
and TO are out parameters; *FROM and *TO will be set to the
selected sub-range of VAR. If no range was selected using
-var-set-update-range, then both will be -1. */
void
varobj_get_child_range (const struct varobj *var, int *from, int *to)
{
*from = var->from;
*to = var->to;
}
/* Set the selected sub-range of children of VAR to start at index
FROM and end at index TO. If either FROM or TO is less than zero,
this is interpreted as a request for all children. */
void
varobj_set_child_range (struct varobj *var, int from, int to)
{
var->from = from;
var->to = to;
}
void
varobj_set_visualizer (struct varobj *var, const char *visualizer)
{
#if HAVE_PYTHON
PyObject *mainmod;
if (!gdb_python_initialized)
return;
gdbpy_enter_varobj enter_py (var);
mainmod = PyImport_AddModule ("__main__");
gdbpy_ref<> globals
= gdbpy_ref<>::new_reference (PyModule_GetDict (mainmod));
gdbpy_ref<> constructor (PyRun_String (visualizer, Py_eval_input,
globals.get (), globals.get ()));
if (constructor == NULL)
{
gdbpy_print_stack ();
error (_("Could not evaluate visualizer expression: %s"), visualizer);
}
construct_visualizer (var, constructor.get ());
/* If there are any children now, wipe them. */
varobj_delete (var, 1 /* children only */);
var->num_children = -1;
#else
error (_("Python support required"));
#endif
}
/* If NEW_VALUE is the new value of the given varobj (var), return
true if var has mutated. In other words, if the type of
the new value is different from the type of the varobj's old
value.
NEW_VALUE may be NULL, if the varobj is now out of scope. */
static bool
varobj_value_has_mutated (const struct varobj *var, struct value *new_value,
struct type *new_type)
{
/* If we haven't previously computed the number of children in var,
it does not matter from the front-end's perspective whether
the type has mutated or not. For all intents and purposes,
it has not mutated. */
if (var->num_children < 0)
return false;
if (var->root->lang_ops->value_has_mutated != NULL)
{
/* The varobj module, when installing new values, explicitly strips
references, saying that we're not interested in those addresses.
But detection of mutation happens before installing the new
value, so our value may be a reference that we need to strip
in order to remain consistent. */
if (new_value != NULL)
new_value = coerce_ref (new_value);
return var->root->lang_ops->value_has_mutated (var, new_value, new_type);
}
else
return false;
}
/* Update the values for a variable and its children. This is a
two-pronged attack. First, re-parse the value for the root's
expression to see if it's changed. Then go all the way
through its children, reconstructing them and noting if they've
changed.
The IS_EXPLICIT parameter specifies if this call is result
of MI request to update this specific variable, or
result of implicit -var-update *. For implicit request, we don't
update frozen variables.
NOTE: This function may delete the caller's varobj. If it
returns TYPE_CHANGED, then it has done this and VARP will be modified
to point to the new varobj. */
std::vector<varobj_update_result>
varobj_update (struct varobj **varp, bool is_explicit)
{
bool type_changed = false;
struct value *newobj;
std::vector<varobj_update_result> stack;
std::vector<varobj_update_result> result;
/* Frozen means frozen -- we don't check for any change in
this varobj, including its going out of scope, or
changing type. One use case for frozen varobjs is
retaining previously evaluated expressions, and we don't
want them to be reevaluated at all. */
if (!is_explicit && (*varp)->frozen)
return result;
if (!(*varp)->root->is_valid)
{
result.emplace_back (*varp, VAROBJ_INVALID);
return result;
}
if ((*varp)->root->rootvar == *varp)
{
varobj_update_result r (*varp);
/* Update the root variable. value_of_root can return NULL
if the variable is no longer around, i.e. we stepped out of
the frame in which a local existed. We are letting the
value_of_root variable dispose of the varobj if the type
has changed. */
newobj = value_of_root (varp, &type_changed);
if (update_type_if_necessary (*varp, newobj))
type_changed = true;
r.varobj = *varp;
r.type_changed = type_changed;
if (install_new_value ((*varp), newobj, type_changed))
r.changed = true;
if (newobj == NULL)
r.status = VAROBJ_NOT_IN_SCOPE;
r.value_installed = true;
if (r.status == VAROBJ_NOT_IN_SCOPE)
{
if (r.type_changed || r.changed)
result.push_back (std::move (r));
return result;
}
stack.push_back (std::move (r));
}
else
stack.emplace_back (*varp);
/* Walk through the children, reconstructing them all. */
while (!stack.empty ())
{
varobj_update_result r = std::move (stack.back ());
stack.pop_back ();
struct varobj *v = r.varobj;
/* Update this variable, unless it's a root, which is already
updated. */
if (!r.value_installed)
{
struct type *new_type;
newobj = value_of_child (v->parent, v->index);
if (update_type_if_necessary (v, newobj))
r.type_changed = true;
if (newobj)
new_type = value_type (newobj);
else
new_type = v->root->lang_ops->type_of_child (v->parent, v->index);
if (varobj_value_has_mutated (v, newobj, new_type))
{
/* The children are no longer valid; delete them now.
Report the fact that its type changed as well. */
varobj_delete (v, 1 /* only_children */);
v->num_children = -1;
v->to = -1;
v->from = -1;
v->type = new_type;
r.type_changed = true;
}
if (install_new_value (v, newobj, r.type_changed))
{
r.changed = true;
v->updated = false;
}
}
/* We probably should not get children of a dynamic varobj, but
for which -var-list-children was never invoked. */
if (varobj_is_dynamic_p (v))
{
std::vector<varobj *> changed, type_changed_vec, unchanged, newobj_vec;
bool children_changed = false;
if (v->frozen)
continue;
if (!v->dynamic->children_requested)
{
bool dummy;
/* If we initially did not have potential children, but
now we do, consider the varobj as changed.
Otherwise, if children were never requested, consider
it as unchanged -- presumably, such varobj is not yet
expanded in the UI, so we need not bother getting
it. */
if (!varobj_has_more (v, 0))
{
update_dynamic_varobj_children (v, NULL, NULL, NULL, NULL,
&dummy, false, 0, 0);
if (varobj_has_more (v, 0))
r.changed = true;
}
if (r.changed)
result.push_back (std::move (r));
continue;
}
/* If update_dynamic_varobj_children returns false, then we have
a non-conforming pretty-printer, so we skip it. */
if (update_dynamic_varobj_children (v, &changed, &type_changed_vec,
&newobj_vec,
&unchanged, &children_changed,
true, v->from, v->to))
{
if (children_changed || !newobj_vec.empty ())
{
r.children_changed = true;
r.newobj = std::move (newobj_vec);
}
/* Push in reverse order so that the first child is
popped from the work stack first, and so will be
added to result first. This does not affect
correctness, just "nicer". */
for (int i = type_changed_vec.size () - 1; i >= 0; --i)
{
varobj_update_result item (type_changed_vec[i]);
/* Type may change only if value was changed. */
item.changed = true;
item.type_changed = true;
item.value_installed = true;
stack.push_back (std::move (item));
}
for (int i = changed.size () - 1; i >= 0; --i)
{
varobj_update_result item (changed[i]);
item.changed = true;
item.value_installed = true;
stack.push_back (std::move (item));
}
for (int i = unchanged.size () - 1; i >= 0; --i)
{
if (!unchanged[i]->frozen)
{
varobj_update_result item (unchanged[i]);
item.value_installed = true;
stack.push_back (std::move (item));
}
}
if (r.changed || r.children_changed)
result.push_back (std::move (r));
continue;
}
}
/* Push any children. Use reverse order so that the first
child is popped from the work stack first, and so
will be added to result first. This does not
affect correctness, just "nicer". */
for (int i = v->children.size () - 1; i >= 0; --i)
{
varobj *c = v->children[i];
/* Child may be NULL if explicitly deleted by -var-delete. */
if (c != NULL && !c->frozen)
stack.emplace_back (c);
}
if (r.changed || r.type_changed)
result.push_back (std::move (r));
}
return result;
}
/* Helper functions */
/*
* Variable object construction/destruction
*/
static int
delete_variable (struct varobj *var, bool only_children_p)
{
int delcount = 0;
delete_variable_1 (&delcount, var, only_children_p,
true /* remove_from_parent_p */ );
return delcount;
}
/* Delete the variable object VAR and its children. */
/* IMPORTANT NOTE: If we delete a variable which is a child
and the parent is not removed we dump core. It must be always
initially called with remove_from_parent_p set. */
static void
delete_variable_1 (int *delcountp, struct varobj *var, bool only_children_p,
bool remove_from_parent_p)
{
/* Delete any children of this variable, too. */
for (varobj *child : var->children)
{
if (!child)
continue;
if (!remove_from_parent_p)
child->parent = NULL;
delete_variable_1 (delcountp, child, false, only_children_p);
}
var->children.clear ();
/* if we were called to delete only the children we are done here. */
if (only_children_p)
return;
/* Otherwise, add it to the list of deleted ones and proceed to do so. */
/* If the name is empty, this is a temporary variable, that has not
yet been installed, don't report it, it belongs to the caller... */
if (!var->obj_name.empty ())
{
*delcountp = *delcountp + 1;
}
/* If this variable has a parent, remove it from its parent's list. */
/* OPTIMIZATION: if the parent of this variable is also being deleted,
(as indicated by remove_from_parent_p) we don't bother doing an
expensive list search to find the element to remove when we are
discarding the list afterwards. */
if ((remove_from_parent_p) && (var->parent != NULL))
var->parent->children[var->index] = NULL;
if (!var->obj_name.empty ())
uninstall_variable (var);
/* Free memory associated with this variable. */
delete var;
}
/* Install the given variable VAR with the object name VAR->OBJ_NAME. */
static void
install_variable (struct varobj *var)
{
hashval_t hash = htab_hash_string (var->obj_name.c_str ());
void **slot = htab_find_slot_with_hash (varobj_table,
var->obj_name.c_str (),
hash, INSERT);
if (*slot != nullptr)
error (_("Duplicate variable object name"));
/* Add varobj to hash table. */
*slot = var;
/* If root, add varobj to root list. */
if (is_root_p (var))
rootlist.push_front (var->root);
}
/* Uninstall the object VAR. */
static void
uninstall_variable (struct varobj *var)
{
hashval_t hash = htab_hash_string (var->obj_name.c_str ());
htab_remove_elt_with_hash (varobj_table, var->obj_name.c_str (), hash);
if (varobjdebug)
fprintf_unfiltered (gdb_stdlog, "Deleting %s\n", var->obj_name.c_str ());
/* If root, remove varobj from root list. */
if (is_root_p (var))
{
auto iter = std::find (rootlist.begin (), rootlist.end (), var->root);
rootlist.erase (iter);
}
}
/* Create and install a child of the parent of the given name.
The created VAROBJ takes ownership of the allocated NAME. */
static struct varobj *
create_child (struct varobj *parent, int index, std::string &name)
{
struct varobj_item item;
std::swap (item.name, name);
item.value = release_value (value_of_child (parent, index));
return create_child_with_value (parent, index, &item);
}
static struct varobj *
create_child_with_value (struct varobj *parent, int index,
struct varobj_item *item)
{
varobj *child = new varobj (parent->root);
/* NAME is allocated by caller. */
std::swap (child->name, item->name);
child->index = index;
child->parent = parent;
if (varobj_is_anonymous_child (child))
child->obj_name = string_printf ("%s.%d_anonymous",
parent->obj_name.c_str (), index);
else
child->obj_name = string_printf ("%s.%s",
parent->obj_name.c_str (),
child->name.c_str ());
install_variable (child);
/* Compute the type of the child. Must do this before
calling install_new_value. */
if (item->value != NULL)
/* If the child had no evaluation errors, var->value
will be non-NULL and contain a valid type. */
child->type = value_actual_type (item->value.get (), 0, NULL);
else
/* Otherwise, we must compute the type. */
child->type = (*child->root->lang_ops->type_of_child) (child->parent,
child->index);
install_new_value (child, item->value.get (), 1);
return child;
}
/*
* Miscellaneous utility functions.
*/
/* Allocate memory and initialize a new variable. */
varobj::varobj (varobj_root *root_)
: root (root_), dynamic (new varobj_dynamic)
{
}
/* Free any allocated memory associated with VAR. */
varobj::~varobj ()
{
varobj *var = this;
#if HAVE_PYTHON
if (var->dynamic->pretty_printer != NULL)
{
gdbpy_enter_varobj enter_py (var);
Py_XDECREF (var->dynamic->constructor);
Py_XDECREF (var->dynamic->pretty_printer);
}
#endif
/* This must be deleted before the root object, because Python-based
destructors need access to some components. */
delete var->dynamic;
if (is_root_p (var))
delete var->root;
}
/* Return the type of the value that's stored in VAR,
or that would have being stored there if the
value were accessible.
This differs from VAR->type in that VAR->type is always
the true type of the expression in the source language.
The return value of this function is the type we're
actually storing in varobj, and using for displaying
the values and for comparing previous and new values.
For example, top-level references are always stripped. */
struct type *
varobj_get_value_type (const struct varobj *var)
{
struct type *type;
if (var->value != nullptr)
type = value_type (var->value.get ());
else
type = var->type;
type = check_typedef (type);
if (TYPE_IS_REFERENCE (type))
type = get_target_type (type);
type = check_typedef (type);
return type;
}
/* What is the default display for this variable? We assume that
everything is "natural". Any exceptions? */
static enum varobj_display_formats
variable_default_display (struct varobj *var)
{
return FORMAT_NATURAL;
}
/*
* Language-dependencies
*/
/* Common entry points */
/* Return the number of children for a given variable.
The result of this function is defined by the language
implementation. The number of children returned by this function
is the number of children that the user will see in the variable
display. */
static int
number_of_children (const struct varobj *var)
{
return (*var->root->lang_ops->number_of_children) (var);
}
/* What is the expression for the root varobj VAR? */
static std::string
name_of_variable (const struct varobj *var)
{
return (*var->root->lang_ops->name_of_variable) (var);
}
/* What is the name of the INDEX'th child of VAR? */
static std::string
name_of_child (struct varobj *var, int index)
{
return (*var->root->lang_ops->name_of_child) (var, index);
}
/* If frame associated with VAR can be found, switch
to it and return true. Otherwise, return false. */
static bool
check_scope (const struct varobj *var)
{
struct frame_info *fi;
bool scope;
fi = frame_find_by_id (var->root->frame);
scope = fi != NULL;
if (fi)
{
CORE_ADDR pc = get_frame_pc (fi);
if (pc < BLOCK_START (var->root->valid_block) ||
pc >= BLOCK_END (var->root->valid_block))
scope = false;
else
select_frame (fi);
}
return scope;
}
/* Helper function to value_of_root. */
static struct value *
value_of_root_1 (struct varobj **var_handle)
{
struct value *new_val = NULL;
struct varobj *var = *var_handle;
bool within_scope = false;
/* Only root variables can be updated... */
if (!is_root_p (var))
/* Not a root var. */
return NULL;
scoped_restore_current_thread restore_thread;
/* Determine whether the variable is still around. */
if (var->root->valid_block == NULL || var->root->floating)
within_scope = true;
else if (var->root->thread_id == 0)
{
/* The program was single-threaded when the variable object was
created. Technically, it's possible that the program became
multi-threaded since then, but we don't support such
scenario yet. */
within_scope = check_scope (var);
}
else
{
thread_info *thread = find_thread_global_id (var->root->thread_id);
if (thread != NULL)
{
switch_to_thread (thread);
within_scope = check_scope (var);
}
}
if (within_scope)
{
/* We need to catch errors here, because if evaluate
expression fails we want to just return NULL. */
try
{
new_val = evaluate_expression (var->root->exp.get ());
}
catch (const gdb_exception_error &except)
{
}
}
return new_val;
}
/* What is the ``struct value *'' of the root variable VAR?
For floating variable object, evaluation can get us a value
of different type from what is stored in varobj already. In
that case:
- *type_changed will be set to 1
- old varobj will be freed, and new one will be
created, with the same name.
- *var_handle will be set to the new varobj
Otherwise, *type_changed will be set to 0. */
static struct value *
value_of_root (struct varobj **var_handle, bool *type_changed)
{
struct varobj *var;
if (var_handle == NULL)
return NULL;
var = *var_handle;
/* This should really be an exception, since this should
only get called with a root variable. */
if (!is_root_p (var))
return NULL;
if (var->root->floating)
{
struct varobj *tmp_var;
tmp_var = varobj_create (NULL, var->name.c_str (), (CORE_ADDR) 0,
USE_SELECTED_FRAME);
if (tmp_var == NULL)
{
return NULL;
}
std::string old_type = varobj_get_type (var);
std::string new_type = varobj_get_type (tmp_var);
if (old_type == new_type)
{
/* The expression presently stored inside var->root->exp
remembers the locations of local variables relatively to
the frame where the expression was created (in DWARF location
button, for example). Naturally, those locations are not
correct in other frames, so update the expression. */
std::swap (var->root->exp, tmp_var->root->exp);
varobj_delete (tmp_var, 0);
*type_changed = 0;
}
else
{
tmp_var->obj_name = var->obj_name;
tmp_var->from = var->from;
tmp_var->to = var->to;
varobj_delete (var, 0);
install_variable (tmp_var);
*var_handle = tmp_var;
var = *var_handle;
*type_changed = true;
}
}
else
{
*type_changed = 0;
}
{
struct value *value;
value = value_of_root_1 (var_handle);
if (var->value == NULL || value == NULL)
{
/* For root varobj-s, a NULL value indicates a scoping issue.
So, nothing to do in terms of checking for mutations. */
}
else if (varobj_value_has_mutated (var, value, value_type (value)))
{
/* The type has mutated, so the children are no longer valid.
Just delete them, and tell our caller that the type has
changed. */
varobj_delete (var, 1 /* only_children */);
var->num_children = -1;
var->to = -1;
var->from = -1;
*type_changed = true;
}
return value;
}
}
/* What is the ``struct value *'' for the INDEX'th child of PARENT? */
static struct value *
value_of_child (const struct varobj *parent, int index)
{
struct value *value;
value = (*parent->root->lang_ops->value_of_child) (parent, index);
return value;
}
/* GDB already has a command called "value_of_variable". Sigh. */
static std::string
my_value_of_variable (struct varobj *var, enum varobj_display_formats format)
{
if (var->root->is_valid)
{
if (var->dynamic->pretty_printer != NULL)
return varobj_value_get_print_value (var->value.get (), var->format,
var);
return (*var->root->lang_ops->value_of_variable) (var, format);
}
else
return std::string ();
}
void
varobj_formatted_print_options (struct value_print_options *opts,
enum varobj_display_formats format)
{
get_formatted_print_options (opts, format_code[(int) format]);
opts->deref_ref = 0;
opts->raw = !pretty_printing;
}
std::string
varobj_value_get_print_value (struct value *value,
enum varobj_display_formats format,
const struct varobj *var)
{
struct value_print_options opts;
struct type *type = NULL;
long len = 0;
gdb::unique_xmalloc_ptr<char> encoding;
/* Initialize it just to avoid a GCC false warning. */
CORE_ADDR str_addr = 0;
bool string_print = false;
if (value == NULL)
return std::string ();
string_file stb;
std::string thevalue;
#if HAVE_PYTHON
if (gdb_python_initialized)
{
PyObject *value_formatter = var->dynamic->pretty_printer;
gdbpy_enter_varobj enter_py (var);
if (value_formatter)
{
/* First check to see if we have any children at all. If so,
we simply return {...}. */
if (dynamic_varobj_has_child_method (var))
return "{...}";
if (PyObject_HasAttr (value_formatter, gdbpy_to_string_cst))
{
struct value *replacement;
gdbpy_ref<> output = apply_varobj_pretty_printer (value_formatter,
&replacement,
&stb);
/* If we have string like output ... */
if (output != NULL)
{
/* If this is a lazy string, extract it. For lazy
strings we always print as a string, so set
string_print. */
if (gdbpy_is_lazy_string (output.get ()))
{
gdbpy_extract_lazy_string (output.get (), &str_addr,
&type, &len, &encoding);
string_print = true;
}
else
{
/* If it is a regular (non-lazy) string, extract
it and copy the contents into THEVALUE. If the
hint says to print it as a string, set
string_print. Otherwise just return the extracted
string as a value. */
gdb::unique_xmalloc_ptr<char> s
= python_string_to_target_string (output.get ());
if (s)
{
struct gdbarch *gdbarch;
gdb::unique_xmalloc_ptr<char> hint
= gdbpy_get_display_hint (value_formatter);
if (hint)
{
if (!strcmp (hint.get (), "string"))
string_print = true;
}
thevalue = std::string (s.get ());
len = thevalue.size ();
gdbarch = value_type (value)->arch ();
type = builtin_type (gdbarch)->builtin_char;
if (!string_print)
return thevalue;
}
else
gdbpy_print_stack ();
}
}
/* If the printer returned a replacement value, set VALUE
to REPLACEMENT. If there is not a replacement value,
just use the value passed to this function. */
if (replacement)
value = replacement;
}
}
}
#endif
varobj_formatted_print_options (&opts, format);
/* If the THEVALUE has contents, it is a regular string. */
if (!thevalue.empty ())
LA_PRINT_STRING (&stb, type, (gdb_byte *) thevalue.c_str (),
len, encoding.get (), 0, &opts);
else if (string_print)
/* Otherwise, if string_print is set, and it is not a regular
string, it is a lazy string. */
val_print_string (type, encoding.get (), str_addr, len, &stb, &opts);
else
/* All other cases. */
common_val_print (value, &stb, 0, &opts, current_language);
return std::move (stb.string ());
}
bool
varobj_editable_p (const struct varobj *var)
{
struct type *type;
if (!(var->root->is_valid && var->value != nullptr
&& VALUE_LVAL (var->value.get ())))
return false;
type = varobj_get_value_type (var);
switch (type->code ())
{
case TYPE_CODE_STRUCT:
case TYPE_CODE_UNION:
case TYPE_CODE_ARRAY:
case TYPE_CODE_FUNC:
case TYPE_CODE_METHOD:
return false;
break;
default:
return true;
break;
}
}
/* Call VAR's value_is_changeable_p language-specific callback. */
bool
varobj_value_is_changeable_p (const struct varobj *var)
{
return var->root->lang_ops->value_is_changeable_p (var);
}
/* Return true if that varobj is floating, that is is always evaluated in the
selected frame, and not bound to thread/frame. Such variable objects
are created using '@' as frame specifier to -var-create. */
bool
varobj_floating_p (const struct varobj *var)
{
return var->root->floating;
}
/* Implement the "value_is_changeable_p" varobj callback for most
languages. */
bool
varobj_default_value_is_changeable_p (const struct varobj *var)
{
bool r;
struct type *type;
if (CPLUS_FAKE_CHILD (var))
return false;
type = varobj_get_value_type (var);
switch (type->code ())
{
case TYPE_CODE_STRUCT:
case TYPE_CODE_UNION:
case TYPE_CODE_ARRAY:
r = false;
break;
default:
r = true;
}
return r;
}
/* Iterate all the existing _root_ VAROBJs and call the FUNC callback
for each one. */
void
all_root_varobjs (gdb::function_view<void (struct varobj *var)> func)
{
/* Iterate "safely" - handle if the callee deletes its passed VAROBJ. */
auto iter = rootlist.begin ();
auto end = rootlist.end ();
while (iter != end)
{
auto self = iter++;
func ((*self)->rootvar);
}
}
/* Invalidate varobj VAR if it is tied to locals and re-create it if it is
defined on globals. It is a helper for varobj_invalidate.
This function is called after changing the symbol file, in this case the
pointers to "struct type" stored by the varobj are no longer valid. All
varobj must be either re-evaluated, or marked as invalid here. */
static void
varobj_invalidate_iter (struct varobj *var)
{
/* global and floating var must be re-evaluated. */
if (var->root->floating || var->root->valid_block == NULL)
{
struct varobj *tmp_var;
/* Try to create a varobj with same expression. If we succeed
replace the old varobj, otherwise invalidate it. */
tmp_var = varobj_create (NULL, var->name.c_str (), (CORE_ADDR) 0,
USE_CURRENT_FRAME);
if (tmp_var != NULL)
{
tmp_var->obj_name = var->obj_name;
varobj_delete (var, 0);
install_variable (tmp_var);
}
else
var->root->is_valid = false;
}
else /* locals must be invalidated. */
var->root->is_valid = false;
}
/* Invalidate the varobjs that are tied to locals and re-create the ones that
are defined on globals.
Invalidated varobjs will be always printed in_scope="invalid". */
void
varobj_invalidate (void)
{
all_root_varobjs (varobj_invalidate_iter);
}
/* A hash function for a varobj. */
static hashval_t
hash_varobj (const void *a)
{
const varobj *obj = (const varobj *) a;
return htab_hash_string (obj->obj_name.c_str ());
}
/* A hash table equality function for varobjs. */
static int
eq_varobj_and_string (const void *a, const void *b)
{
const varobj *obj = (const varobj *) a;
const char *name = (const char *) b;
return obj->obj_name == name;
}
void _initialize_varobj ();
void
_initialize_varobj ()
{
varobj_table = htab_create_alloc (5, hash_varobj, eq_varobj_and_string,
nullptr, xcalloc, xfree);
add_setshow_zuinteger_cmd ("varobj", class_maintenance,
&varobjdebug,
_("Set varobj debugging."),
_("Show varobj debugging."),
_("When non-zero, varobj debugging is enabled."),
NULL, show_varobjdebug,
&setdebuglist, &showdebuglist);
}