binutils-gdb/gdb/dwarf2/expr.c
Simon Marchi e5dc0d5d04 gdb: move a bunch of quit-related things to event-top.{c,h}
Move some declarations related to the "quit" machinery from defs.h to
event-top.h.  Most of the definitions associated to these declarations
are in event-top.c.  The exceptions are `quit()` and `maybe_quit()`,
that are defined in utils.c.  For consistency, move these two
definitions to event-top.c.

Include "event-top.h" in many files that use these things.

Change-Id: I6594f6df9047a9a480e7b9934275d186afb14378
Approved-By: Tom Tromey <tom@tromey.com>
2024-04-23 11:26:14 -04:00

2397 lines
65 KiB
C
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/* DWARF 2 Expression Evaluator.
Copyright (C) 2001-2024 Free Software Foundation, Inc.
Contributed by Daniel Berlin (dan@dberlin.org)
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/>. */
#include "block.h"
#include "event-top.h"
#include "symtab.h"
#include "gdbtypes.h"
#include "value.h"
#include "gdbcore.h"
#include "dwarf2.h"
#include "dwarf2/expr.h"
#include "dwarf2/loc.h"
#include "dwarf2/read.h"
#include "frame.h"
#include "gdbsupport/underlying.h"
#include "gdbarch.h"
#include "objfiles.h"
/* This holds gdbarch-specific types used by the DWARF expression
evaluator. See comments in execute_stack_op. */
struct dwarf_gdbarch_types
{
struct type *dw_types[3] {};
};
/* Cookie for gdbarch data. */
static const registry<gdbarch>::key<dwarf_gdbarch_types> dwarf_arch_cookie;
/* Ensure that a FRAME is defined, throw an exception otherwise. */
static void
ensure_have_frame (const frame_info_ptr &frame, const char *op_name)
{
if (frame == nullptr)
throw_error (GENERIC_ERROR,
_("%s evaluation requires a frame."), op_name);
}
/* Ensure that a PER_CU is defined and throw an exception otherwise. */
static void
ensure_have_per_cu (dwarf2_per_cu_data *per_cu, const char* op_name)
{
if (per_cu == nullptr)
throw_error (GENERIC_ERROR,
_("%s evaluation requires a compilation unit."), op_name);
}
/* Return the number of bytes overlapping a contiguous chunk of N_BITS
bits whose first bit is located at bit offset START. */
static size_t
bits_to_bytes (ULONGEST start, ULONGEST n_bits)
{
return (start % HOST_CHAR_BIT + n_bits + HOST_CHAR_BIT - 1) / HOST_CHAR_BIT;
}
/* See expr.h. */
CORE_ADDR
read_addr_from_reg (const frame_info_ptr &frame, int reg)
{
struct gdbarch *gdbarch = get_frame_arch (frame);
int regnum = dwarf_reg_to_regnum_or_error (gdbarch, reg);
return address_from_register (regnum, frame);
}
struct piece_closure
{
/* Reference count. */
int refc = 0;
/* The objfile from which this closure's expression came. */
dwarf2_per_objfile *per_objfile = nullptr;
/* The CU from which this closure's expression came. */
dwarf2_per_cu_data *per_cu = nullptr;
/* The pieces describing this variable. */
std::vector<dwarf_expr_piece> pieces;
/* Frame ID of frame to which a register value is relative, used
only by DWARF_VALUE_REGISTER. */
struct frame_id frame_id;
};
/* Allocate a closure for a value formed from separately-described
PIECES. */
static piece_closure *
allocate_piece_closure (dwarf2_per_cu_data *per_cu,
dwarf2_per_objfile *per_objfile,
std::vector<dwarf_expr_piece> &&pieces,
const frame_info_ptr &frame)
{
piece_closure *c = new piece_closure;
c->refc = 1;
/* We must capture this here due to sharing of DWARF state. */
c->per_objfile = per_objfile;
c->per_cu = per_cu;
c->pieces = std::move (pieces);
if (frame == nullptr)
c->frame_id = null_frame_id;
else
c->frame_id = get_frame_id (frame);
for (dwarf_expr_piece &piece : c->pieces)
if (piece.location == DWARF_VALUE_STACK)
piece.v.value->incref ();
return c;
}
/* Read or write a pieced value V. If FROM != NULL, operate in "write
mode": copy FROM into the pieces comprising V. If FROM == NULL,
operate in "read mode": fetch the contents of the (lazy) value V by
composing it from its pieces. If CHECK_OPTIMIZED is true, then no
reading or writing is done; instead the return value of this
function is true if any piece is optimized out. When
CHECK_OPTIMIZED is true, FROM must be nullptr. */
static bool
rw_pieced_value (value *v, value *from, bool check_optimized)
{
int i;
LONGEST offset = 0, max_offset;
gdb_byte *v_contents;
const gdb_byte *from_contents;
piece_closure *c
= (piece_closure *) v->computed_closure ();
gdb::byte_vector buffer;
bool bits_big_endian = type_byte_order (v->type ()) == BFD_ENDIAN_BIG;
gdb_assert (!check_optimized || from == nullptr);
if (from != nullptr)
{
from_contents = from->contents ().data ();
v_contents = nullptr;
}
else
{
if (check_optimized)
v_contents = nullptr;
else
v_contents = v->contents_raw ().data ();
from_contents = nullptr;
}
ULONGEST bits_to_skip = 8 * v->offset ();
if (v->bitsize ())
{
bits_to_skip += (8 * v->parent ()->offset ()
+ v->bitpos ());
if (from != nullptr
&& (type_byte_order (from->type ())
== BFD_ENDIAN_BIG))
{
/* Use the least significant bits of FROM. */
max_offset = 8 * from->type ()->length ();
offset = max_offset - v->bitsize ();
}
else
max_offset = v->bitsize ();
}
else
max_offset = 8 * v->type ()->length ();
/* Advance to the first non-skipped piece. */
for (i = 0; i < c->pieces.size () && bits_to_skip >= c->pieces[i].size; i++)
bits_to_skip -= c->pieces[i].size;
for (; i < c->pieces.size () && offset < max_offset; i++)
{
dwarf_expr_piece *p = &c->pieces[i];
size_t this_size_bits, this_size;
this_size_bits = p->size - bits_to_skip;
if (this_size_bits > max_offset - offset)
this_size_bits = max_offset - offset;
switch (p->location)
{
case DWARF_VALUE_REGISTER:
{
frame_info_ptr next_frame
= get_next_frame_sentinel_okay (frame_find_by_id (c->frame_id));
gdbarch *arch = frame_unwind_arch (next_frame);
int gdb_regnum = dwarf_reg_to_regnum_or_error (arch, p->v.regno);
ULONGEST reg_bits = 8 * register_size (arch, gdb_regnum);
int optim, unavail;
if (gdbarch_byte_order (arch) == BFD_ENDIAN_BIG
&& p->offset + p->size < reg_bits)
{
/* Big-endian, and we want less than full size. */
bits_to_skip += reg_bits - (p->offset + p->size);
}
else
bits_to_skip += p->offset;
this_size = bits_to_bytes (bits_to_skip, this_size_bits);
buffer.resize (this_size);
if (from == nullptr)
{
/* Read mode. */
if (!get_frame_register_bytes (next_frame, gdb_regnum,
bits_to_skip / 8, buffer,
&optim, &unavail))
{
if (optim)
{
if (check_optimized)
return true;
v->mark_bits_optimized_out (offset,
this_size_bits);
}
if (unavail && !check_optimized)
v->mark_bits_unavailable (offset,
this_size_bits);
break;
}
if (!check_optimized)
copy_bitwise (v_contents, offset,
buffer.data (), bits_to_skip % 8,
this_size_bits, bits_big_endian);
}
else
{
/* Write mode. */
if (bits_to_skip % 8 != 0 || this_size_bits % 8 != 0)
{
/* Data is copied non-byte-aligned into the register.
Need some bits from original register value. */
get_frame_register_bytes (next_frame, gdb_regnum,
bits_to_skip / 8, buffer, &optim,
&unavail);
if (optim)
throw_error (OPTIMIZED_OUT_ERROR,
_("Can't do read-modify-write to "
"update bitfield; containing word "
"has been optimized out"));
if (unavail)
throw_error (NOT_AVAILABLE_ERROR,
_("Can't do read-modify-write to "
"update bitfield; containing word "
"is unavailable"));
}
copy_bitwise (buffer.data (), bits_to_skip % 8,
from_contents, offset,
this_size_bits, bits_big_endian);
put_frame_register_bytes (next_frame, gdb_regnum,
bits_to_skip / 8, buffer);
}
}
break;
case DWARF_VALUE_MEMORY:
{
if (check_optimized)
break;
bits_to_skip += p->offset;
CORE_ADDR start_addr = p->v.mem.addr + bits_to_skip / 8;
if (bits_to_skip % 8 == 0 && this_size_bits % 8 == 0
&& offset % 8 == 0)
{
/* Everything is byte-aligned; no buffer needed. */
if (from != nullptr)
write_memory_with_notification (start_addr,
(from_contents
+ offset / 8),
this_size_bits / 8);
else
read_value_memory (v, offset,
p->v.mem.in_stack_memory,
p->v.mem.addr + bits_to_skip / 8,
v_contents + offset / 8,
this_size_bits / 8);
break;
}
this_size = bits_to_bytes (bits_to_skip, this_size_bits);
buffer.resize (this_size);
if (from == nullptr)
{
/* Read mode. */
read_value_memory (v, offset,
p->v.mem.in_stack_memory,
p->v.mem.addr + bits_to_skip / 8,
buffer.data (), this_size);
copy_bitwise (v_contents, offset,
buffer.data (), bits_to_skip % 8,
this_size_bits, bits_big_endian);
}
else
{
/* Write mode. */
if (bits_to_skip % 8 != 0 || this_size_bits % 8 != 0)
{
if (this_size <= 8)
{
/* Perform a single read for small sizes. */
read_memory (start_addr, buffer.data (),
this_size);
}
else
{
/* Only the first and last bytes can possibly have
any bits reused. */
read_memory (start_addr, buffer.data (), 1);
read_memory (start_addr + this_size - 1,
&buffer[this_size - 1], 1);
}
}
copy_bitwise (buffer.data (), bits_to_skip % 8,
from_contents, offset,
this_size_bits, bits_big_endian);
write_memory_with_notification (start_addr,
buffer.data (),
this_size);
}
}
break;
case DWARF_VALUE_STACK:
{
if (check_optimized)
break;
if (from != nullptr)
{
v->mark_bits_optimized_out (offset, this_size_bits);
break;
}
gdbarch *objfile_gdbarch = c->per_objfile->objfile->arch ();
ULONGEST stack_value_size_bits
= 8 * p->v.value->type ()->length ();
/* Use zeroes if piece reaches beyond stack value. */
if (p->offset + p->size > stack_value_size_bits)
break;
/* Piece is anchored at least significant bit end. */
if (gdbarch_byte_order (objfile_gdbarch) == BFD_ENDIAN_BIG)
bits_to_skip += stack_value_size_bits - p->offset - p->size;
else
bits_to_skip += p->offset;
copy_bitwise (v_contents, offset,
p->v.value->contents_all ().data (),
bits_to_skip,
this_size_bits, bits_big_endian);
}
break;
case DWARF_VALUE_LITERAL:
{
if (check_optimized)
break;
if (from != nullptr)
{
v->mark_bits_optimized_out (offset, this_size_bits);
break;
}
ULONGEST literal_size_bits = 8 * p->v.literal.length;
size_t n = this_size_bits;
/* Cut off at the end of the implicit value. */
bits_to_skip += p->offset;
if (bits_to_skip >= literal_size_bits)
break;
if (n > literal_size_bits - bits_to_skip)
n = literal_size_bits - bits_to_skip;
copy_bitwise (v_contents, offset,
p->v.literal.data, bits_to_skip,
n, bits_big_endian);
}
break;
case DWARF_VALUE_IMPLICIT_POINTER:
if (from != nullptr)
{
v->mark_bits_optimized_out (offset, this_size_bits);
break;
}
/* These bits show up as zeros -- but do not cause the value to
be considered optimized-out. */
break;
case DWARF_VALUE_OPTIMIZED_OUT:
if (check_optimized)
return true;
v->mark_bits_optimized_out (offset, this_size_bits);
break;
default:
internal_error (_("invalid location type"));
}
offset += this_size_bits;
bits_to_skip = 0;
}
if (offset < max_offset)
{
if (check_optimized)
return true;
v->mark_bits_optimized_out (offset, max_offset - offset);
}
return false;
}
static void
read_pieced_value (value *v)
{
rw_pieced_value (v, nullptr, false);
}
static void
write_pieced_value (value *to, value *from)
{
rw_pieced_value (to, from, false);
}
static bool
is_optimized_out_pieced_value (value *v)
{
return rw_pieced_value (v, nullptr, true);
}
/* An implementation of an lval_funcs method to see whether a value is
a synthetic pointer. */
static bool
check_pieced_synthetic_pointer (const value *value, LONGEST bit_offset,
int bit_length)
{
piece_closure *c = (piece_closure *) value->computed_closure ();
int i;
bit_offset += 8 * value->offset ();
if (value->bitsize ())
bit_offset += value->bitpos ();
for (i = 0; i < c->pieces.size () && bit_length > 0; i++)
{
dwarf_expr_piece *p = &c->pieces[i];
size_t this_size_bits = p->size;
if (bit_offset > 0)
{
if (bit_offset >= this_size_bits)
{
bit_offset -= this_size_bits;
continue;
}
bit_length -= this_size_bits - bit_offset;
bit_offset = 0;
}
else
bit_length -= this_size_bits;
if (p->location != DWARF_VALUE_IMPLICIT_POINTER)
return false;
}
return bit_length == 0;
}
/* An implementation of an lval_funcs method to indirect through a
pointer. This handles the synthetic pointer case when needed. */
static value *
indirect_pieced_value (value *value)
{
piece_closure *c
= (piece_closure *) value->computed_closure ();
int i;
dwarf_expr_piece *piece = NULL;
struct type *type = check_typedef (value->type ());
if (type->code () != TYPE_CODE_PTR)
return NULL;
int bit_length = 8 * type->length ();
LONGEST bit_offset = 8 * value->offset ();
if (value->bitsize ())
bit_offset += value->bitpos ();
for (i = 0; i < c->pieces.size () && bit_length > 0; i++)
{
dwarf_expr_piece *p = &c->pieces[i];
size_t this_size_bits = p->size;
if (bit_offset > 0)
{
if (bit_offset >= this_size_bits)
{
bit_offset -= this_size_bits;
continue;
}
bit_length -= this_size_bits - bit_offset;
bit_offset = 0;
}
else
bit_length -= this_size_bits;
if (p->location != DWARF_VALUE_IMPLICIT_POINTER)
return NULL;
if (bit_length != 0)
error (_("Invalid use of DW_OP_implicit_pointer"));
piece = p;
break;
}
gdb_assert (piece != NULL && c->per_cu != nullptr);
frame_info_ptr frame = get_selected_frame (_("No frame selected."));
/* This is an offset requested by GDB, such as value subscripts.
However, due to how synthetic pointers are implemented, this is
always presented to us as a pointer type. This means we have to
sign-extend it manually as appropriate. Use raw
extract_signed_integer directly rather than value_as_address and
sign extend afterwards on architectures that would need it
(mostly everywhere except MIPS, which has signed addresses) as
the later would go through gdbarch_pointer_to_address and thus
return a CORE_ADDR with high bits set on architectures that
encode address spaces and other things in CORE_ADDR. */
bfd_endian byte_order = gdbarch_byte_order (get_frame_arch (frame));
LONGEST byte_offset
= extract_signed_integer (value->contents (), byte_order);
byte_offset += piece->v.ptr.offset;
return indirect_synthetic_pointer (piece->v.ptr.die_sect_off,
byte_offset, c->per_cu,
c->per_objfile, frame, type);
}
/* Implementation of the coerce_ref method of lval_funcs for synthetic C++
references. */
static value *
coerce_pieced_ref (const value *value)
{
struct type *type = check_typedef (value->type ());
if (value->bits_synthetic_pointer (value->embedded_offset (),
TARGET_CHAR_BIT * type->length ()))
{
const piece_closure *closure
= (piece_closure *) value->computed_closure ();
frame_info_ptr frame
= get_selected_frame (_("No frame selected."));
/* gdb represents synthetic pointers as pieced values with a single
piece. */
gdb_assert (closure != NULL);
gdb_assert (closure->pieces.size () == 1);
return indirect_synthetic_pointer
(closure->pieces[0].v.ptr.die_sect_off,
closure->pieces[0].v.ptr.offset,
closure->per_cu, closure->per_objfile, frame, type);
}
else
{
/* Else: not a synthetic reference; do nothing. */
return NULL;
}
}
static void *
copy_pieced_value_closure (const value *v)
{
piece_closure *c = (piece_closure *) v->computed_closure ();
++c->refc;
return c;
}
static void
free_pieced_value_closure (value *v)
{
piece_closure *c = (piece_closure *) v->computed_closure ();
--c->refc;
if (c->refc == 0)
{
for (dwarf_expr_piece &p : c->pieces)
if (p.location == DWARF_VALUE_STACK)
p.v.value->decref ();
delete c;
}
}
/* Functions for accessing a variable described by DW_OP_piece. */
static const struct lval_funcs pieced_value_funcs = {
read_pieced_value,
write_pieced_value,
is_optimized_out_pieced_value,
indirect_pieced_value,
coerce_pieced_ref,
check_pieced_synthetic_pointer,
copy_pieced_value_closure,
free_pieced_value_closure
};
/* Given context CTX, section offset SECT_OFF, and compilation unit
data PER_CU, execute the "variable value" operation on the DIE
found at SECT_OFF. */
static value *
sect_variable_value (sect_offset sect_off,
dwarf2_per_cu_data *per_cu,
dwarf2_per_objfile *per_objfile)
{
const char *var_name = nullptr;
struct type *die_type
= dwarf2_fetch_die_type_sect_off (sect_off, per_cu, per_objfile,
&var_name);
if (die_type == NULL)
error (_("Bad DW_OP_GNU_variable_value DIE."));
/* Note: Things still work when the following test is removed. This
test and error is here to conform to the proposed specification. */
if (die_type->code () != TYPE_CODE_INT
&& die_type->code () != TYPE_CODE_ENUM
&& die_type->code () != TYPE_CODE_RANGE
&& die_type->code () != TYPE_CODE_PTR)
error (_("Type of DW_OP_GNU_variable_value DIE must be an integer or pointer."));
if (var_name != nullptr)
{
value *result = compute_var_value (var_name);
if (result != nullptr)
return result;
}
struct type *type = lookup_pointer_type (die_type);
frame_info_ptr frame = get_selected_frame (_("No frame selected."));
return indirect_synthetic_pointer (sect_off, 0, per_cu, per_objfile, frame,
type, true);
}
/* Return the type used for DWARF operations where the type is
unspecified in the DWARF spec. Only certain sizes are
supported. */
struct type *
dwarf_expr_context::address_type () const
{
gdbarch *arch = this->m_per_objfile->objfile->arch ();
dwarf_gdbarch_types *types = dwarf_arch_cookie.get (arch);
if (types == nullptr)
types = dwarf_arch_cookie.emplace (arch);
int ndx;
if (this->m_addr_size == 2)
ndx = 0;
else if (this->m_addr_size == 4)
ndx = 1;
else if (this->m_addr_size == 8)
ndx = 2;
else
error (_("Unsupported address size in DWARF expressions: %d bits"),
8 * this->m_addr_size);
if (types->dw_types[ndx] == NULL)
{
type_allocator alloc (arch);
types->dw_types[ndx]
= init_integer_type (alloc, 8 * this->m_addr_size,
0, "<signed DWARF address type>");
}
return types->dw_types[ndx];
}
/* Create a new context for the expression evaluator. */
dwarf_expr_context::dwarf_expr_context (dwarf2_per_objfile *per_objfile,
int addr_size)
: m_addr_size (addr_size),
m_per_objfile (per_objfile)
{
}
/* Push VALUE onto the stack. */
void
dwarf_expr_context::push (struct value *value, bool in_stack_memory)
{
this->m_stack.emplace_back (value, in_stack_memory);
}
/* Push VALUE onto the stack. */
void
dwarf_expr_context::push_address (CORE_ADDR value, bool in_stack_memory)
{
push (value_from_ulongest (address_type (), value), in_stack_memory);
}
/* Pop the top item off of the stack. */
void
dwarf_expr_context::pop ()
{
if (this->m_stack.empty ())
error (_("dwarf expression stack underflow"));
this->m_stack.pop_back ();
}
/* Retrieve the N'th item on the stack. */
struct value *
dwarf_expr_context::fetch (int n)
{
if (this->m_stack.size () <= n)
error (_("Asked for position %d of stack, "
"stack only has %zu elements on it."),
n, this->m_stack.size ());
return this->m_stack[this->m_stack.size () - (1 + n)].value;
}
/* See expr.h. */
void
dwarf_expr_context::get_frame_base (const gdb_byte **start,
size_t * length)
{
ensure_have_frame (this->m_frame, "DW_OP_fbreg");
const block *bl = get_frame_block (this->m_frame, NULL);
if (bl == NULL)
error (_("frame address is not available."));
/* Use block_linkage_function, which returns a real (not inlined)
function, instead of get_frame_function, which may return an
inlined function. */
symbol *framefunc = bl->linkage_function ();
/* If we found a frame-relative symbol then it was certainly within
some function associated with a frame. If we can't find the frame,
something has gone wrong. */
gdb_assert (framefunc != NULL);
func_get_frame_base_dwarf_block (framefunc,
get_frame_address_in_block (this->m_frame),
start, length);
}
/* See expr.h. */
struct type *
dwarf_expr_context::get_base_type (cu_offset die_cu_off)
{
if (this->m_per_cu == nullptr)
return builtin_type (this->m_per_objfile->objfile->arch ())->builtin_int;
struct type *result = dwarf2_get_die_type (die_cu_off, this->m_per_cu,
this->m_per_objfile);
if (result == nullptr)
error (_("Could not find type for operation"));
return result;
}
/* See expr.h. */
void
dwarf_expr_context::dwarf_call (cu_offset die_cu_off)
{
ensure_have_per_cu (this->m_per_cu, "DW_OP_call");
frame_info_ptr frame = this->m_frame;
auto get_pc_from_frame = [frame] ()
{
ensure_have_frame (frame, "DW_OP_call");
return get_frame_address_in_block (frame);
};
dwarf2_locexpr_baton block
= dwarf2_fetch_die_loc_cu_off (die_cu_off, this->m_per_cu,
this->m_per_objfile, get_pc_from_frame);
/* DW_OP_call_ref is currently not supported. */
gdb_assert (block.per_cu == this->m_per_cu);
this->eval (block.data, block.size);
}
/* See expr.h. */
void
dwarf_expr_context::read_mem (gdb_byte *buf, CORE_ADDR addr,
size_t length)
{
if (length == 0)
return;
/* Prefer the passed-in memory, if it exists. */
if (this->m_addr_info != nullptr)
{
CORE_ADDR offset = addr - this->m_addr_info->addr;
if (offset < this->m_addr_info->valaddr.size ()
&& offset + length <= this->m_addr_info->valaddr.size ())
{
memcpy (buf, this->m_addr_info->valaddr.data (), length);
return;
}
}
read_memory (addr, buf, length);
}
/* See expr.h. */
void
dwarf_expr_context::push_dwarf_reg_entry_value (call_site_parameter_kind kind,
call_site_parameter_u kind_u,
int deref_size)
{
ensure_have_per_cu (this->m_per_cu, "DW_OP_entry_value");
ensure_have_frame (this->m_frame, "DW_OP_entry_value");
dwarf2_per_cu_data *caller_per_cu;
dwarf2_per_objfile *caller_per_objfile;
frame_info_ptr caller_frame = get_prev_frame (this->m_frame);
call_site_parameter *parameter
= dwarf_expr_reg_to_entry_parameter (this->m_frame, kind, kind_u,
&caller_per_cu,
&caller_per_objfile);
const gdb_byte *data_src
= deref_size == -1 ? parameter->value : parameter->data_value;
size_t size
= deref_size == -1 ? parameter->value_size : parameter->data_value_size;
/* DEREF_SIZE size is not verified here. */
if (data_src == nullptr)
throw_error (NO_ENTRY_VALUE_ERROR,
_("Cannot resolve DW_AT_call_data_value"));
/* We are about to evaluate an expression in the context of the caller
of the current frame. This evaluation context may be different from
the current (callee's) context), so temporarily set the caller's context.
It is possible for the caller to be from a different objfile from the
callee if the call is made through a function pointer. */
scoped_restore save_frame = make_scoped_restore (&this->m_frame,
caller_frame);
scoped_restore save_per_cu = make_scoped_restore (&this->m_per_cu,
caller_per_cu);
scoped_restore save_addr_info = make_scoped_restore (&this->m_addr_info,
nullptr);
scoped_restore save_per_objfile = make_scoped_restore (&this->m_per_objfile,
caller_per_objfile);
scoped_restore save_addr_size = make_scoped_restore (&this->m_addr_size);
this->m_addr_size = this->m_per_cu->addr_size ();
this->eval (data_src, size);
}
/* See expr.h. */
value *
dwarf_expr_context::fetch_result (struct type *type, struct type *subobj_type,
LONGEST subobj_offset, bool as_lval)
{
value *retval = nullptr;
gdbarch *arch = this->m_per_objfile->objfile->arch ();
if (type == nullptr)
type = address_type ();
if (subobj_type == nullptr)
subobj_type = type;
/* Ensure that, if TYPE or SUBOBJ_TYPE are typedefs, their length is filled
in instead of being zero. */
check_typedef (type);
check_typedef (subobj_type);
if (this->m_pieces.size () > 0)
{
ULONGEST bit_size = 0;
for (dwarf_expr_piece &piece : this->m_pieces)
bit_size += piece.size;
/* Complain if the expression is larger than the size of the
outer type. */
if (bit_size > 8 * type->length ())
invalid_synthetic_pointer ();
piece_closure *c
= allocate_piece_closure (this->m_per_cu, this->m_per_objfile,
std::move (this->m_pieces), this->m_frame);
retval = value::allocate_computed (subobj_type,
&pieced_value_funcs, c);
retval->set_offset (subobj_offset);
}
else
{
/* If AS_LVAL is false, means that the implicit conversion
from a location description to value is expected. */
if (!as_lval)
this->m_location = DWARF_VALUE_STACK;
switch (this->m_location)
{
case DWARF_VALUE_REGISTER:
{
gdbarch *f_arch = get_frame_arch (this->m_frame);
int dwarf_regnum
= longest_to_int (value_as_long (this->fetch (0)));
int gdb_regnum = dwarf_reg_to_regnum_or_error (f_arch,
dwarf_regnum);
if (subobj_offset != 0)
error (_("cannot use offset on synthetic pointer to register"));
gdb_assert (this->m_frame != NULL);
retval = value_from_register (subobj_type, gdb_regnum,
this->m_frame);
if (retval->optimized_out ())
{
/* This means the register has undefined value / was
not saved. As we're computing the location of some
variable etc. in the program, not a value for
inspecting a register ($pc, $sp, etc.), return a
generic optimized out value instead, so that we show
<optimized out> instead of <not saved>. */
value *tmp = value::allocate (subobj_type);
retval->contents_copy (tmp, 0, 0,
subobj_type->length ());
retval = tmp;
}
}
break;
case DWARF_VALUE_MEMORY:
{
struct type *ptr_type;
CORE_ADDR address = this->fetch_address (0);
bool in_stack_memory = this->fetch_in_stack_memory (0);
/* DW_OP_deref_size (and possibly other operations too) may
create a pointer instead of an address. Ideally, the
pointer to address conversion would be performed as part
of those operations, but the type of the object to
which the address refers is not known at the time of
the operation. Therefore, we do the conversion here
since the type is readily available. */
switch (subobj_type->code ())
{
case TYPE_CODE_FUNC:
case TYPE_CODE_METHOD:
ptr_type = builtin_type (arch)->builtin_func_ptr;
break;
default:
ptr_type = builtin_type (arch)->builtin_data_ptr;
break;
}
address = value_as_address (value_from_pointer (ptr_type, address));
retval = value_at_lazy (subobj_type, address + subobj_offset,
m_frame);
if (in_stack_memory)
retval->set_stack (true);
}
break;
case DWARF_VALUE_STACK:
{
value *val = this->fetch (0);
size_t n = val->type ()->length ();
size_t len = subobj_type->length ();
size_t max = type->length ();
if (subobj_offset + len > max)
invalid_synthetic_pointer ();
retval = value::allocate (subobj_type);
/* The given offset is relative to the actual object. */
if (gdbarch_byte_order (arch) == BFD_ENDIAN_BIG)
subobj_offset += n - max;
copy (val->contents_all ().slice (subobj_offset, len),
retval->contents_raw ());
}
break;
case DWARF_VALUE_LITERAL:
{
size_t n = subobj_type->length ();
if (subobj_offset + n > this->m_len)
invalid_synthetic_pointer ();
retval = value::allocate (subobj_type);
bfd_byte *contents = retval->contents_raw ().data ();
memcpy (contents, this->m_data + subobj_offset, n);
}
break;
case DWARF_VALUE_OPTIMIZED_OUT:
retval = value::allocate_optimized_out (subobj_type);
break;
/* DWARF_VALUE_IMPLICIT_POINTER was converted to a pieced
operation by execute_stack_op. */
case DWARF_VALUE_IMPLICIT_POINTER:
/* DWARF_VALUE_OPTIMIZED_OUT can't occur in this context --
it can only be encountered when making a piece. */
default:
internal_error (_("invalid location type"));
}
}
retval->set_initialized (this->m_initialized);
return retval;
}
/* See expr.h. */
value *
dwarf_expr_context::evaluate (const gdb_byte *addr, size_t len, bool as_lval,
dwarf2_per_cu_data *per_cu, const frame_info_ptr &frame,
const struct property_addr_info *addr_info,
struct type *type, struct type *subobj_type,
LONGEST subobj_offset)
{
this->m_per_cu = per_cu;
this->m_frame = frame;
this->m_addr_info = addr_info;
eval (addr, len);
return fetch_result (type, subobj_type, subobj_offset, as_lval);
}
/* Require that TYPE be an integral type; throw an exception if not. */
static void
dwarf_require_integral (struct type *type)
{
if (type->code () != TYPE_CODE_INT
&& type->code () != TYPE_CODE_CHAR
&& type->code () != TYPE_CODE_BOOL)
error (_("integral type expected in DWARF expression"));
}
/* Return the unsigned form of TYPE. TYPE is necessarily an integral
type. */
static struct type *
get_unsigned_type (struct gdbarch *gdbarch, struct type *type)
{
switch (type->length ())
{
case 1:
return builtin_type (gdbarch)->builtin_uint8;
case 2:
return builtin_type (gdbarch)->builtin_uint16;
case 4:
return builtin_type (gdbarch)->builtin_uint32;
case 8:
return builtin_type (gdbarch)->builtin_uint64;
default:
error (_("no unsigned variant found for type, while evaluating "
"DWARF expression"));
}
}
/* Return the signed form of TYPE. TYPE is necessarily an integral
type. */
static struct type *
get_signed_type (struct gdbarch *gdbarch, struct type *type)
{
switch (type->length ())
{
case 1:
return builtin_type (gdbarch)->builtin_int8;
case 2:
return builtin_type (gdbarch)->builtin_int16;
case 4:
return builtin_type (gdbarch)->builtin_int32;
case 8:
return builtin_type (gdbarch)->builtin_int64;
default:
error (_("no signed variant found for type, while evaluating "
"DWARF expression"));
}
}
/* Retrieve the N'th item on the stack, converted to an address. */
CORE_ADDR
dwarf_expr_context::fetch_address (int n)
{
gdbarch *arch = this->m_per_objfile->objfile->arch ();
value *result_val = fetch (n);
bfd_endian byte_order = gdbarch_byte_order (arch);
ULONGEST result;
dwarf_require_integral (result_val->type ());
result = extract_unsigned_integer (result_val->contents (), byte_order);
/* For most architectures, calling extract_unsigned_integer() alone
is sufficient for extracting an address. However, some
architectures (e.g. MIPS) use signed addresses and using
extract_unsigned_integer() will not produce a correct
result. Make sure we invoke gdbarch_integer_to_address()
for those architectures which require it. */
if (gdbarch_integer_to_address_p (arch))
{
gdb_byte *buf = (gdb_byte *) alloca (this->m_addr_size);
type *int_type = get_unsigned_type (arch,
result_val->type ());
store_unsigned_integer (buf, this->m_addr_size, byte_order, result);
return gdbarch_integer_to_address (arch, int_type, buf);
}
return (CORE_ADDR) result;
}
/* Retrieve the in_stack_memory flag of the N'th item on the stack. */
bool
dwarf_expr_context::fetch_in_stack_memory (int n)
{
if (this->m_stack.size () <= n)
error (_("Asked for position %d of stack, "
"stack only has %zu elements on it."),
n, this->m_stack.size ());
return this->m_stack[this->m_stack.size () - (1 + n)].in_stack_memory;
}
/* Return true if the expression stack is empty. */
bool
dwarf_expr_context::stack_empty_p () const
{
return m_stack.empty ();
}
/* Add a new piece to the dwarf_expr_context's piece list. */
void
dwarf_expr_context::add_piece (ULONGEST size, ULONGEST offset)
{
dwarf_expr_piece &p = this->m_pieces.emplace_back ();
p.location = this->m_location;
p.size = size;
p.offset = offset;
if (p.location == DWARF_VALUE_LITERAL)
{
p.v.literal.data = this->m_data;
p.v.literal.length = this->m_len;
}
else if (stack_empty_p ())
{
p.location = DWARF_VALUE_OPTIMIZED_OUT;
/* Also reset the context's location, for our callers. This is
a somewhat strange approach, but this lets us avoid setting
the location to DWARF_VALUE_MEMORY in all the individual
cases in the evaluator. */
this->m_location = DWARF_VALUE_OPTIMIZED_OUT;
}
else if (p.location == DWARF_VALUE_MEMORY)
{
p.v.mem.addr = fetch_address (0);
p.v.mem.in_stack_memory = fetch_in_stack_memory (0);
}
else if (p.location == DWARF_VALUE_IMPLICIT_POINTER)
{
p.v.ptr.die_sect_off = (sect_offset) this->m_len;
p.v.ptr.offset = value_as_long (fetch (0));
}
else if (p.location == DWARF_VALUE_REGISTER)
p.v.regno = value_as_long (fetch (0));
else
{
p.v.value = fetch (0);
}
}
/* Evaluate the expression at ADDR (LEN bytes long). */
void
dwarf_expr_context::eval (const gdb_byte *addr, size_t len)
{
int old_recursion_depth = this->m_recursion_depth;
execute_stack_op (addr, addr + len);
/* RECURSION_DEPTH becomes invalid if an exception was thrown here. */
gdb_assert (this->m_recursion_depth == old_recursion_depth);
}
/* Helper to read a uleb128 value or throw an error. */
const gdb_byte *
safe_read_uleb128 (const gdb_byte *buf, const gdb_byte *buf_end,
uint64_t *r)
{
buf = gdb_read_uleb128 (buf, buf_end, r);
if (buf == NULL)
error (_("DWARF expression error: ran off end of buffer reading uleb128 value"));
return buf;
}
/* Helper to read a sleb128 value or throw an error. */
const gdb_byte *
safe_read_sleb128 (const gdb_byte *buf, const gdb_byte *buf_end,
int64_t *r)
{
buf = gdb_read_sleb128 (buf, buf_end, r);
if (buf == NULL)
error (_("DWARF expression error: ran off end of buffer reading sleb128 value"));
return buf;
}
const gdb_byte *
safe_skip_leb128 (const gdb_byte *buf, const gdb_byte *buf_end)
{
buf = gdb_skip_leb128 (buf, buf_end);
if (buf == NULL)
error (_("DWARF expression error: ran off end of buffer reading leb128 value"));
return buf;
}
/* Check that the current operator is either at the end of an
expression, or that it is followed by a composition operator or by
DW_OP_GNU_uninit (which should terminate the expression). */
void
dwarf_expr_require_composition (const gdb_byte *op_ptr, const gdb_byte *op_end,
const char *op_name)
{
if (op_ptr != op_end && *op_ptr != DW_OP_piece && *op_ptr != DW_OP_bit_piece
&& *op_ptr != DW_OP_GNU_uninit)
error (_("DWARF-2 expression error: `%s' operations must be "
"used either alone or in conjunction with DW_OP_piece "
"or DW_OP_bit_piece."),
op_name);
}
/* Return true iff the types T1 and T2 are "the same". This only does
checks that might reasonably be needed to compare DWARF base
types. */
static int
base_types_equal_p (struct type *t1, struct type *t2)
{
if (t1->code () != t2->code ())
return 0;
if (t1->is_unsigned () != t2->is_unsigned ())
return 0;
return t1->length () == t2->length ();
}
/* If <BUF..BUF_END] contains DW_FORM_block* with single DW_OP_reg* return the
DWARF register number. Otherwise return -1. */
int
dwarf_block_to_dwarf_reg (const gdb_byte *buf, const gdb_byte *buf_end)
{
uint64_t dwarf_reg;
if (buf_end <= buf)
return -1;
if (*buf >= DW_OP_reg0 && *buf <= DW_OP_reg31)
{
if (buf_end - buf != 1)
return -1;
return *buf - DW_OP_reg0;
}
if (*buf == DW_OP_regval_type || *buf == DW_OP_GNU_regval_type)
{
buf++;
buf = gdb_read_uleb128 (buf, buf_end, &dwarf_reg);
if (buf == NULL)
return -1;
buf = gdb_skip_leb128 (buf, buf_end);
if (buf == NULL)
return -1;
}
else if (*buf == DW_OP_regx)
{
buf++;
buf = gdb_read_uleb128 (buf, buf_end, &dwarf_reg);
if (buf == NULL)
return -1;
}
else
return -1;
if (buf != buf_end || (int) dwarf_reg != dwarf_reg)
return -1;
return dwarf_reg;
}
/* If <BUF..BUF_END] contains DW_FORM_block* with just DW_OP_breg*(0) and
DW_OP_deref* return the DWARF register number. Otherwise return -1.
DEREF_SIZE_RETURN contains -1 for DW_OP_deref; otherwise it contains the
size from DW_OP_deref_size. */
int
dwarf_block_to_dwarf_reg_deref (const gdb_byte *buf, const gdb_byte *buf_end,
CORE_ADDR *deref_size_return)
{
uint64_t dwarf_reg;
int64_t offset;
if (buf_end <= buf)
return -1;
if (*buf >= DW_OP_breg0 && *buf <= DW_OP_breg31)
{
dwarf_reg = *buf - DW_OP_breg0;
buf++;
if (buf >= buf_end)
return -1;
}
else if (*buf == DW_OP_bregx)
{
buf++;
buf = gdb_read_uleb128 (buf, buf_end, &dwarf_reg);
if (buf == NULL)
return -1;
if ((int) dwarf_reg != dwarf_reg)
return -1;
}
else
return -1;
buf = gdb_read_sleb128 (buf, buf_end, &offset);
if (buf == NULL)
return -1;
if (offset != 0)
return -1;
if (*buf == DW_OP_deref)
{
buf++;
*deref_size_return = -1;
}
else if (*buf == DW_OP_deref_size)
{
buf++;
if (buf >= buf_end)
return -1;
*deref_size_return = *buf++;
}
else
return -1;
if (buf != buf_end)
return -1;
return dwarf_reg;
}
/* If <BUF..BUF_END] contains DW_FORM_block* with single DW_OP_fbreg(X) fill
in FB_OFFSET_RETURN with the X offset and return 1. Otherwise return 0. */
int
dwarf_block_to_fb_offset (const gdb_byte *buf, const gdb_byte *buf_end,
CORE_ADDR *fb_offset_return)
{
int64_t fb_offset;
if (buf_end <= buf)
return 0;
if (*buf != DW_OP_fbreg)
return 0;
buf++;
buf = gdb_read_sleb128 (buf, buf_end, &fb_offset);
if (buf == NULL)
return 0;
*fb_offset_return = fb_offset;
if (buf != buf_end || fb_offset != (LONGEST) *fb_offset_return)
return 0;
return 1;
}
/* If <BUF..BUF_END] contains DW_FORM_block* with single DW_OP_bregSP(X) fill
in SP_OFFSET_RETURN with the X offset and return 1. Otherwise return 0.
The matched SP register number depends on GDBARCH. */
int
dwarf_block_to_sp_offset (struct gdbarch *gdbarch, const gdb_byte *buf,
const gdb_byte *buf_end, CORE_ADDR *sp_offset_return)
{
uint64_t dwarf_reg;
int64_t sp_offset;
if (buf_end <= buf)
return 0;
if (*buf >= DW_OP_breg0 && *buf <= DW_OP_breg31)
{
dwarf_reg = *buf - DW_OP_breg0;
buf++;
}
else
{
if (*buf != DW_OP_bregx)
return 0;
buf++;
buf = gdb_read_uleb128 (buf, buf_end, &dwarf_reg);
if (buf == NULL)
return 0;
}
if (dwarf_reg_to_regnum (gdbarch, dwarf_reg)
!= gdbarch_sp_regnum (gdbarch))
return 0;
buf = gdb_read_sleb128 (buf, buf_end, &sp_offset);
if (buf == NULL)
return 0;
*sp_offset_return = sp_offset;
if (buf != buf_end || sp_offset != (LONGEST) *sp_offset_return)
return 0;
return 1;
}
/* The engine for the expression evaluator. Using the context in this
object, evaluate the expression between OP_PTR and OP_END. */
void
dwarf_expr_context::execute_stack_op (const gdb_byte *op_ptr,
const gdb_byte *op_end)
{
gdbarch *arch = this->m_per_objfile->objfile->arch ();
bfd_endian byte_order = gdbarch_byte_order (arch);
/* Old-style "untyped" DWARF values need special treatment in a
couple of places, specifically DW_OP_mod and DW_OP_shr. We need
a special type for these values so we can distinguish them from
values that have an explicit type, because explicitly-typed
values do not need special treatment. This special type must be
different (in the `==' sense) from any base type coming from the
CU. */
type *address_type = this->address_type ();
this->m_location = DWARF_VALUE_MEMORY;
this->m_initialized = true; /* Default is initialized. */
if (this->m_recursion_depth > this->m_max_recursion_depth)
error (_("DWARF-2 expression error: Loop detected (%d)."),
this->m_recursion_depth);
this->m_recursion_depth++;
while (op_ptr < op_end)
{
dwarf_location_atom op = (dwarf_location_atom) *op_ptr++;
ULONGEST result;
/* Assume the value is not in stack memory.
Code that knows otherwise sets this to true.
Some arithmetic on stack addresses can probably be assumed to still
be a stack address, but we skip this complication for now.
This is just an optimization, so it's always ok to punt
and leave this as false. */
bool in_stack_memory = false;
uint64_t uoffset, reg;
int64_t offset;
value *result_val = NULL;
/* The DWARF expression might have a bug causing an infinite
loop. In that case, quitting is the only way out. */
QUIT;
switch (op)
{
case DW_OP_lit0:
case DW_OP_lit1:
case DW_OP_lit2:
case DW_OP_lit3:
case DW_OP_lit4:
case DW_OP_lit5:
case DW_OP_lit6:
case DW_OP_lit7:
case DW_OP_lit8:
case DW_OP_lit9:
case DW_OP_lit10:
case DW_OP_lit11:
case DW_OP_lit12:
case DW_OP_lit13:
case DW_OP_lit14:
case DW_OP_lit15:
case DW_OP_lit16:
case DW_OP_lit17:
case DW_OP_lit18:
case DW_OP_lit19:
case DW_OP_lit20:
case DW_OP_lit21:
case DW_OP_lit22:
case DW_OP_lit23:
case DW_OP_lit24:
case DW_OP_lit25:
case DW_OP_lit26:
case DW_OP_lit27:
case DW_OP_lit28:
case DW_OP_lit29:
case DW_OP_lit30:
case DW_OP_lit31:
result = op - DW_OP_lit0;
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_addr:
result = extract_unsigned_integer (op_ptr,
this->m_addr_size, byte_order);
op_ptr += this->m_addr_size;
/* Some versions of GCC emit DW_OP_addr before
DW_OP_GNU_push_tls_address. In this case the value is an
index, not an address. We don't support things like
branching between the address and the TLS op. */
if (op_ptr >= op_end || *op_ptr != DW_OP_GNU_push_tls_address)
result += this->m_per_objfile->objfile->text_section_offset ();
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_addrx:
case DW_OP_GNU_addr_index:
ensure_have_per_cu (this->m_per_cu, "DW_OP_addrx");
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
result = (m_per_objfile->relocate
(dwarf2_read_addr_index (this->m_per_cu,
this->m_per_objfile,
uoffset)));
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_GNU_const_index:
ensure_have_per_cu (this->m_per_cu, "DW_OP_GNU_const_index");
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
result = (ULONGEST) dwarf2_read_addr_index (this->m_per_cu,
this->m_per_objfile,
uoffset);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_const1u:
result = extract_unsigned_integer (op_ptr, 1, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 1;
break;
case DW_OP_const1s:
result = extract_signed_integer (op_ptr, 1, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 1;
break;
case DW_OP_const2u:
result = extract_unsigned_integer (op_ptr, 2, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 2;
break;
case DW_OP_const2s:
result = extract_signed_integer (op_ptr, 2, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 2;
break;
case DW_OP_const4u:
result = extract_unsigned_integer (op_ptr, 4, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 4;
break;
case DW_OP_const4s:
result = extract_signed_integer (op_ptr, 4, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 4;
break;
case DW_OP_const8u:
result = extract_unsigned_integer (op_ptr, 8, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 8;
break;
case DW_OP_const8s:
result = extract_signed_integer (op_ptr, 8, byte_order);
result_val = value_from_ulongest (address_type, result);
op_ptr += 8;
break;
case DW_OP_constu:
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
result = uoffset;
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_consts:
op_ptr = safe_read_sleb128 (op_ptr, op_end, &offset);
result = offset;
result_val = value_from_ulongest (address_type, result);
break;
/* The DW_OP_reg operations are required to occur alone in
location expressions. */
case DW_OP_reg0:
case DW_OP_reg1:
case DW_OP_reg2:
case DW_OP_reg3:
case DW_OP_reg4:
case DW_OP_reg5:
case DW_OP_reg6:
case DW_OP_reg7:
case DW_OP_reg8:
case DW_OP_reg9:
case DW_OP_reg10:
case DW_OP_reg11:
case DW_OP_reg12:
case DW_OP_reg13:
case DW_OP_reg14:
case DW_OP_reg15:
case DW_OP_reg16:
case DW_OP_reg17:
case DW_OP_reg18:
case DW_OP_reg19:
case DW_OP_reg20:
case DW_OP_reg21:
case DW_OP_reg22:
case DW_OP_reg23:
case DW_OP_reg24:
case DW_OP_reg25:
case DW_OP_reg26:
case DW_OP_reg27:
case DW_OP_reg28:
case DW_OP_reg29:
case DW_OP_reg30:
case DW_OP_reg31:
dwarf_expr_require_composition (op_ptr, op_end, "DW_OP_reg");
result = op - DW_OP_reg0;
result_val = value_from_ulongest (address_type, result);
this->m_location = DWARF_VALUE_REGISTER;
break;
case DW_OP_regx:
op_ptr = safe_read_uleb128 (op_ptr, op_end, &reg);
dwarf_expr_require_composition (op_ptr, op_end, "DW_OP_regx");
result = reg;
result_val = value_from_ulongest (address_type, result);
this->m_location = DWARF_VALUE_REGISTER;
break;
case DW_OP_implicit_value:
{
uint64_t len;
op_ptr = safe_read_uleb128 (op_ptr, op_end, &len);
if (op_ptr + len > op_end)
error (_("DW_OP_implicit_value: too few bytes available."));
this->m_len = len;
this->m_data = op_ptr;
this->m_location = DWARF_VALUE_LITERAL;
op_ptr += len;
dwarf_expr_require_composition (op_ptr, op_end,
"DW_OP_implicit_value");
}
goto no_push;
case DW_OP_stack_value:
this->m_location = DWARF_VALUE_STACK;
dwarf_expr_require_composition (op_ptr, op_end, "DW_OP_stack_value");
goto no_push;
case DW_OP_implicit_pointer:
case DW_OP_GNU_implicit_pointer:
{
int64_t len;
ensure_have_per_cu (this->m_per_cu, "DW_OP_implicit_pointer");
int ref_addr_size = this->m_per_cu->ref_addr_size ();
/* The referred-to DIE of sect_offset kind. */
this->m_len = extract_unsigned_integer (op_ptr, ref_addr_size,
byte_order);
op_ptr += ref_addr_size;
/* The byte offset into the data. */
op_ptr = safe_read_sleb128 (op_ptr, op_end, &len);
result = (ULONGEST) len;
result_val = value_from_ulongest (address_type, result);
this->m_location = DWARF_VALUE_IMPLICIT_POINTER;
dwarf_expr_require_composition (op_ptr, op_end,
"DW_OP_implicit_pointer");
}
break;
case DW_OP_breg0:
case DW_OP_breg1:
case DW_OP_breg2:
case DW_OP_breg3:
case DW_OP_breg4:
case DW_OP_breg5:
case DW_OP_breg6:
case DW_OP_breg7:
case DW_OP_breg8:
case DW_OP_breg9:
case DW_OP_breg10:
case DW_OP_breg11:
case DW_OP_breg12:
case DW_OP_breg13:
case DW_OP_breg14:
case DW_OP_breg15:
case DW_OP_breg16:
case DW_OP_breg17:
case DW_OP_breg18:
case DW_OP_breg19:
case DW_OP_breg20:
case DW_OP_breg21:
case DW_OP_breg22:
case DW_OP_breg23:
case DW_OP_breg24:
case DW_OP_breg25:
case DW_OP_breg26:
case DW_OP_breg27:
case DW_OP_breg28:
case DW_OP_breg29:
case DW_OP_breg30:
case DW_OP_breg31:
{
op_ptr = safe_read_sleb128 (op_ptr, op_end, &offset);
ensure_have_frame (this->m_frame, "DW_OP_breg");
result = read_addr_from_reg (this->m_frame, op - DW_OP_breg0);
result += offset;
result_val = value_from_ulongest (address_type, result);
}
break;
case DW_OP_bregx:
{
op_ptr = safe_read_uleb128 (op_ptr, op_end, &reg);
op_ptr = safe_read_sleb128 (op_ptr, op_end, &offset);
ensure_have_frame (this->m_frame, "DW_OP_bregx");
result = read_addr_from_reg (this->m_frame, reg);
result += offset;
result_val = value_from_ulongest (address_type, result);
}
break;
case DW_OP_fbreg:
{
const gdb_byte *datastart;
size_t datalen;
op_ptr = safe_read_sleb128 (op_ptr, op_end, &offset);
/* Rather than create a whole new context, we simply
backup the current stack locally and install a new empty stack,
then reset it afterwards, effectively erasing whatever the
recursive call put there. */
std::vector<dwarf_stack_value> saved_stack = std::move (this->m_stack);
this->m_stack.clear ();
/* FIXME: cagney/2003-03-26: This code should be using
get_frame_base_address(), and then implement a dwarf2
specific this_base method. */
this->get_frame_base (&datastart, &datalen);
eval (datastart, datalen);
if (this->m_location == DWARF_VALUE_MEMORY)
result = fetch_address (0);
else if (this->m_location == DWARF_VALUE_REGISTER)
result
= read_addr_from_reg (this->m_frame, value_as_long (fetch (0)));
else
error (_("Not implemented: computing frame "
"base using explicit value operator"));
result = result + offset;
result_val = value_from_ulongest (address_type, result);
in_stack_memory = true;
/* Restore the content of the original stack. */
this->m_stack = std::move (saved_stack);
this->m_location = DWARF_VALUE_MEMORY;
}
break;
case DW_OP_dup:
result_val = fetch (0);
in_stack_memory = fetch_in_stack_memory (0);
break;
case DW_OP_drop:
pop ();
goto no_push;
case DW_OP_pick:
offset = *op_ptr++;
result_val = fetch (offset);
in_stack_memory = fetch_in_stack_memory (offset);
break;
case DW_OP_swap:
{
if (this->m_stack.size () < 2)
error (_("Not enough elements for "
"DW_OP_swap. Need 2, have %zu."),
this->m_stack.size ());
dwarf_stack_value &t1 = this->m_stack[this->m_stack.size () - 1];
dwarf_stack_value &t2 = this->m_stack[this->m_stack.size () - 2];
std::swap (t1, t2);
goto no_push;
}
case DW_OP_over:
result_val = fetch (1);
in_stack_memory = fetch_in_stack_memory (1);
break;
case DW_OP_rot:
{
if (this->m_stack.size () < 3)
error (_("Not enough elements for "
"DW_OP_rot. Need 3, have %zu."),
this->m_stack.size ());
dwarf_stack_value temp = this->m_stack[this->m_stack.size () - 1];
this->m_stack[this->m_stack.size () - 1]
= this->m_stack[this->m_stack.size () - 2];
this->m_stack[this->m_stack.size () - 2]
= this->m_stack[this->m_stack.size () - 3];
this->m_stack[this->m_stack.size () - 3] = temp;
goto no_push;
}
case DW_OP_deref:
case DW_OP_deref_size:
case DW_OP_deref_type:
case DW_OP_GNU_deref_type:
{
int addr_size = (op == DW_OP_deref ? this->m_addr_size : *op_ptr++);
gdb_byte *buf = (gdb_byte *) alloca (addr_size);
CORE_ADDR addr = fetch_address (0);
struct type *type;
pop ();
if (op == DW_OP_deref_type || op == DW_OP_GNU_deref_type)
{
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
cu_offset type_die_cu_off = (cu_offset) uoffset;
type = get_base_type (type_die_cu_off);
}
else
type = address_type;
this->read_mem (buf, addr, addr_size);
/* If the size of the object read from memory is different
from the type length, we need to zero-extend it. */
if (type->length () != addr_size)
{
ULONGEST datum =
extract_unsigned_integer (buf, addr_size, byte_order);
buf = (gdb_byte *) alloca (type->length ());
store_unsigned_integer (buf, type->length (),
byte_order, datum);
}
result_val = value_from_contents_and_address (type, buf, addr);
break;
}
case DW_OP_abs:
case DW_OP_neg:
case DW_OP_not:
case DW_OP_plus_uconst:
{
/* Unary operations. */
result_val = fetch (0);
pop ();
switch (op)
{
case DW_OP_abs:
if (value_less (result_val,
value::zero (result_val->type (), not_lval)))
result_val = value_neg (result_val);
break;
case DW_OP_neg:
result_val = value_neg (result_val);
break;
case DW_OP_not:
dwarf_require_integral (result_val->type ());
result_val = value_complement (result_val);
break;
case DW_OP_plus_uconst:
dwarf_require_integral (result_val->type ());
result = value_as_long (result_val);
op_ptr = safe_read_uleb128 (op_ptr, op_end, &reg);
result += reg;
result_val = value_from_ulongest (address_type, result);
break;
}
}
break;
case DW_OP_and:
case DW_OP_div:
case DW_OP_minus:
case DW_OP_mod:
case DW_OP_mul:
case DW_OP_or:
case DW_OP_plus:
case DW_OP_shl:
case DW_OP_shr:
case DW_OP_shra:
case DW_OP_xor:
case DW_OP_le:
case DW_OP_ge:
case DW_OP_eq:
case DW_OP_lt:
case DW_OP_gt:
case DW_OP_ne:
{
/* Binary operations. */
struct value *first, *second;
second = fetch (0);
pop ();
first = fetch (0);
pop ();
if (! base_types_equal_p (first->type (), second->type ()))
error (_("Incompatible types on DWARF stack"));
switch (op)
{
case DW_OP_and:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
result_val = value_binop (first, second, BINOP_BITWISE_AND);
break;
case DW_OP_div:
result_val = value_binop (first, second, BINOP_DIV);
break;
case DW_OP_minus:
result_val = value_binop (first, second, BINOP_SUB);
break;
case DW_OP_mod:
{
int cast_back = 0;
struct type *orig_type = first->type ();
/* We have to special-case "old-style" untyped values
-- these must have mod computed using unsigned
math. */
if (orig_type == address_type)
{
struct type *utype = get_unsigned_type (arch, orig_type);
cast_back = 1;
first = value_cast (utype, first);
second = value_cast (utype, second);
}
/* Note that value_binop doesn't handle float or
decimal float here. This seems unimportant. */
result_val = value_binop (first, second, BINOP_MOD);
if (cast_back)
result_val = value_cast (orig_type, result_val);
}
break;
case DW_OP_mul:
result_val = value_binop (first, second, BINOP_MUL);
break;
case DW_OP_or:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
result_val = value_binop (first, second, BINOP_BITWISE_IOR);
break;
case DW_OP_plus:
result_val = value_binop (first, second, BINOP_ADD);
break;
case DW_OP_shl:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
result_val = value_binop (first, second, BINOP_LSH);
break;
case DW_OP_shr:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
if (!first->type ()->is_unsigned ())
{
struct type *utype
= get_unsigned_type (arch, first->type ());
first = value_cast (utype, first);
}
result_val = value_binop (first, second, BINOP_RSH);
/* Make sure we wind up with the same type we started
with. */
if (result_val->type () != second->type ())
result_val = value_cast (second->type (), result_val);
break;
case DW_OP_shra:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
if (first->type ()->is_unsigned ())
{
struct type *stype
= get_signed_type (arch, first->type ());
first = value_cast (stype, first);
}
result_val = value_binop (first, second, BINOP_RSH);
/* Make sure we wind up with the same type we started
with. */
if (result_val->type () != second->type ())
result_val = value_cast (second->type (), result_val);
break;
case DW_OP_xor:
dwarf_require_integral (first->type ());
dwarf_require_integral (second->type ());
result_val = value_binop (first, second, BINOP_BITWISE_XOR);
break;
case DW_OP_le:
/* A <= B is !(B < A). */
result = ! value_less (second, first);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_ge:
/* A >= B is !(A < B). */
result = ! value_less (first, second);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_eq:
result = value_equal (first, second);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_lt:
result = value_less (first, second);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_gt:
/* A > B is B < A. */
result = value_less (second, first);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_ne:
result = ! value_equal (first, second);
result_val = value_from_ulongest (address_type, result);
break;
default:
internal_error (_("Can't be reached."));
}
}
break;
case DW_OP_call_frame_cfa:
ensure_have_frame (this->m_frame, "DW_OP_call_frame_cfa");
result = dwarf2_frame_cfa (this->m_frame);
result_val = value_from_ulongest (address_type, result);
in_stack_memory = true;
break;
case DW_OP_GNU_push_tls_address:
case DW_OP_form_tls_address:
/* Variable is at a constant offset in the thread-local
storage block into the objfile for the current thread and
the dynamic linker module containing this expression. Here
we return returns the offset from that base. The top of the
stack has the offset from the beginning of the thread
control block at which the variable is located. Nothing
should follow this operator, so the top of stack would be
returned. */
result = value_as_long (fetch (0));
pop ();
result = target_translate_tls_address (this->m_per_objfile->objfile,
result);
result_val = value_from_ulongest (address_type, result);
break;
case DW_OP_skip:
offset = extract_signed_integer (op_ptr, 2, byte_order);
op_ptr += 2;
op_ptr += offset;
goto no_push;
case DW_OP_bra:
{
struct value *val;
offset = extract_signed_integer (op_ptr, 2, byte_order);
op_ptr += 2;
val = fetch (0);
dwarf_require_integral (val->type ());
if (value_as_long (val) != 0)
op_ptr += offset;
pop ();
}
goto no_push;
case DW_OP_nop:
goto no_push;
case DW_OP_piece:
{
uint64_t size;
/* Record the piece. */
op_ptr = safe_read_uleb128 (op_ptr, op_end, &size);
add_piece (8 * size, 0);
/* Pop off the address/regnum, and reset the location
type. */
if (this->m_location != DWARF_VALUE_LITERAL
&& this->m_location != DWARF_VALUE_OPTIMIZED_OUT)
pop ();
this->m_location = DWARF_VALUE_MEMORY;
}
goto no_push;
case DW_OP_bit_piece:
{
uint64_t size, uleb_offset;
/* Record the piece. */
op_ptr = safe_read_uleb128 (op_ptr, op_end, &size);
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uleb_offset);
add_piece (size, uleb_offset);
/* Pop off the address/regnum, and reset the location
type. */
if (this->m_location != DWARF_VALUE_LITERAL
&& this->m_location != DWARF_VALUE_OPTIMIZED_OUT)
pop ();
this->m_location = DWARF_VALUE_MEMORY;
}
goto no_push;
case DW_OP_GNU_uninit:
dwarf_expr_require_composition (op_ptr, op_end, "DW_OP_GNU_uninit");
this->m_initialized = false;
goto no_push;
case DW_OP_call2:
{
cu_offset cu_off
= (cu_offset) extract_unsigned_integer (op_ptr, 2, byte_order);
op_ptr += 2;
this->dwarf_call (cu_off);
}
goto no_push;
case DW_OP_call4:
{
cu_offset cu_off
= (cu_offset) extract_unsigned_integer (op_ptr, 4, byte_order);
op_ptr += 4;
this->dwarf_call (cu_off);
}
goto no_push;
case DW_OP_GNU_variable_value:
{
ensure_have_per_cu (this->m_per_cu, "DW_OP_GNU_variable_value");
int ref_addr_size = this->m_per_cu->ref_addr_size ();
sect_offset sect_off
= (sect_offset) extract_unsigned_integer (op_ptr,
ref_addr_size,
byte_order);
op_ptr += ref_addr_size;
result_val = sect_variable_value (sect_off, this->m_per_cu,
this->m_per_objfile);
result_val = value_cast (address_type, result_val);
}
break;
case DW_OP_entry_value:
case DW_OP_GNU_entry_value:
{
uint64_t len;
CORE_ADDR deref_size;
union call_site_parameter_u kind_u;
op_ptr = safe_read_uleb128 (op_ptr, op_end, &len);
if (op_ptr + len > op_end)
error (_("DW_OP_entry_value: too few bytes available."));
kind_u.dwarf_reg = dwarf_block_to_dwarf_reg (op_ptr, op_ptr + len);
if (kind_u.dwarf_reg != -1)
{
op_ptr += len;
this->push_dwarf_reg_entry_value (CALL_SITE_PARAMETER_DWARF_REG,
kind_u,
-1 /* deref_size */);
goto no_push;
}
kind_u.dwarf_reg = dwarf_block_to_dwarf_reg_deref (op_ptr,
op_ptr + len,
&deref_size);
if (kind_u.dwarf_reg != -1)
{
if (deref_size == -1)
deref_size = this->m_addr_size;
op_ptr += len;
this->push_dwarf_reg_entry_value (CALL_SITE_PARAMETER_DWARF_REG,
kind_u, deref_size);
goto no_push;
}
error (_("DWARF-2 expression error: DW_OP_entry_value is "
"supported only for single DW_OP_reg* "
"or for DW_OP_breg*(0)+DW_OP_deref*"));
}
case DW_OP_GNU_parameter_ref:
{
union call_site_parameter_u kind_u;
kind_u.param_cu_off
= (cu_offset) extract_unsigned_integer (op_ptr, 4, byte_order);
op_ptr += 4;
this->push_dwarf_reg_entry_value (CALL_SITE_PARAMETER_PARAM_OFFSET,
kind_u,
-1 /* deref_size */);
}
goto no_push;
case DW_OP_const_type:
case DW_OP_GNU_const_type:
{
int n;
const gdb_byte *data;
struct type *type;
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
cu_offset type_die_cu_off = (cu_offset) uoffset;
n = *op_ptr++;
data = op_ptr;
op_ptr += n;
type = get_base_type (type_die_cu_off);
if (type->length () != n)
error (_("DW_OP_const_type has different sizes for type and data"));
result_val = value_from_contents (type, data);
}
break;
case DW_OP_regval_type:
case DW_OP_GNU_regval_type:
{
op_ptr = safe_read_uleb128 (op_ptr, op_end, &reg);
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
cu_offset type_die_cu_off = (cu_offset) uoffset;
ensure_have_frame (this->m_frame, "DW_OP_regval_type");
struct type *type = get_base_type (type_die_cu_off);
int regnum
= dwarf_reg_to_regnum_or_error (get_frame_arch (this->m_frame),
reg);
result_val = value_from_register (type, regnum, this->m_frame);
}
break;
case DW_OP_convert:
case DW_OP_GNU_convert:
case DW_OP_reinterpret:
case DW_OP_GNU_reinterpret:
{
struct type *type;
op_ptr = safe_read_uleb128 (op_ptr, op_end, &uoffset);
cu_offset type_die_cu_off = (cu_offset) uoffset;
if (to_underlying (type_die_cu_off) == 0)
type = address_type;
else
type = get_base_type (type_die_cu_off);
result_val = fetch (0);
pop ();
if (op == DW_OP_convert || op == DW_OP_GNU_convert)
result_val = value_cast (type, result_val);
else if (type == result_val->type ())
{
/* Nothing. */
}
else if (type->length ()
!= result_val->type ()->length ())
error (_("DW_OP_reinterpret has wrong size"));
else
result_val
= value_from_contents (type,
result_val->contents_all ().data ());
}
break;
case DW_OP_push_object_address:
/* Return the address of the object we are currently observing. */
if (this->m_addr_info == nullptr
|| (this->m_addr_info->valaddr.data () == nullptr
&& this->m_addr_info->addr == 0))
error (_("Location address is not set."));
result_val
= value_from_ulongest (address_type, this->m_addr_info->addr);
break;
default:
error (_("Unhandled dwarf expression opcode 0x%x"), op);
}
/* Most things push a result value. */
gdb_assert (result_val != NULL);
push (result_val, in_stack_memory);
no_push:
;
}
/* To simplify our main caller, if the result is an implicit
pointer, then make a pieced value. This is ok because we can't
have implicit pointers in contexts where pieces are invalid. */
if (this->m_location == DWARF_VALUE_IMPLICIT_POINTER)
add_piece (8 * this->m_addr_size, 0);
this->m_recursion_depth--;
gdb_assert (this->m_recursion_depth >= 0);
}