binutils-gdb/ld/ldexp.c
Maciej W. Rozycki d5c928c053 LD: Export relative-from-absolute symbol marking to BFD
It is usually possible to tell absolute and ordinary symbols apart in
BFD throughout the link, by checking whether the section that owns the
symbol is absolute or not.

That however does not work for ordinary symbols defined in a linker
script outside an output section statement.  Initially such symbols are
entered into to the link hash as absolute symbols, owned by the absolute
section.  A flag is set in the internal linker expression defining such
symbols to tell the linker to convert them to section-relative ones in
the final phase of the link.  That flag is however not accessible to BFD
linker code, including BFD target code in particular.

Add a flag to the link hash then to copy the information held in the
linker expression.  Define a macro, `bfd_is_abs_symbol', for BFD code to
use where determining whether a symbol is absolute or ordinary is
required before the final link phase.

This macro will correctly identify the special `__ehdr_start' symbol as
ordinary throughout link, for example, even though early on it will be
assigned to the absolute section.  Of course this does not let BFD code
identify what the symbol's ultimate section will be before the final
link phase has converted this symbol (in `update_definedness').

	include/
	* bfdlink.h (bfd_link_hash_entry): Add `rel_from_abs' member.

	bfd/
	* linker.c (bfd_is_abs_symbol): New macro.
	* bfd-in2.h: Regenerate.

	ld/
	* ldexp.c (exp_fold_tree_1) <etree_assign, etree_provide>
	<etree_provided>: Copy expression's `rel_from_abs' flag to the
	link hash.
2018-07-17 20:04:53 +01:00

1670 lines
44 KiB
C

/* This module handles expression trees.
Copyright (C) 1991-2018 Free Software Foundation, Inc.
Written by Steve Chamberlain of Cygnus Support <sac@cygnus.com>.
This file is part of the GNU Binutils.
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, write to the Free Software
Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston,
MA 02110-1301, USA. */
/* This module is in charge of working out the contents of expressions.
It has to keep track of the relative/absness of a symbol etc. This
is done by keeping all values in a struct (an etree_value_type)
which contains a value, a section to which it is relative and a
valid bit. */
#include "sysdep.h"
#include "bfd.h"
#include "bfdlink.h"
#include "ld.h"
#include "ldmain.h"
#include "ldmisc.h"
#include "ldexp.h"
#include "ldlex.h"
#include <ldgram.h>
#include "ldlang.h"
#include "libiberty.h"
#include "safe-ctype.h"
static void exp_fold_tree_1 (etree_type *);
static bfd_vma align_n (bfd_vma, bfd_vma);
segment_type *segments;
struct ldexp_control expld;
/* This structure records symbols for which we need to keep track of
definedness for use in the DEFINED () test. It is also used in
making absolute symbols section relative late in the link. */
struct definedness_hash_entry
{
struct bfd_hash_entry root;
/* If this symbol was assigned from "dot" outside of an output
section statement, the section we'd like it relative to. */
asection *final_sec;
/* Low bits of iteration count. Symbols with matching iteration have
been defined in this pass over the script. */
unsigned int iteration : 8;
/* Symbol was defined by an object file. */
unsigned int by_object : 1;
};
static struct bfd_hash_table definedness_table;
/* Print the string representation of the given token. Surround it
with spaces if INFIX_P is TRUE. */
static void
exp_print_token (token_code_type code, int infix_p)
{
static const struct
{
token_code_type code;
const char *name;
}
table[] =
{
{ INT, "int" },
{ NAME, "NAME" },
{ PLUSEQ, "+=" },
{ MINUSEQ, "-=" },
{ MULTEQ, "*=" },
{ DIVEQ, "/=" },
{ LSHIFTEQ, "<<=" },
{ RSHIFTEQ, ">>=" },
{ ANDEQ, "&=" },
{ OREQ, "|=" },
{ OROR, "||" },
{ ANDAND, "&&" },
{ EQ, "==" },
{ NE, "!=" },
{ LE, "<=" },
{ GE, ">=" },
{ LSHIFT, "<<" },
{ RSHIFT, ">>" },
{ LOG2CEIL, "LOG2CEIL" },
{ ALIGN_K, "ALIGN" },
{ BLOCK, "BLOCK" },
{ QUAD, "QUAD" },
{ SQUAD, "SQUAD" },
{ LONG, "LONG" },
{ SHORT, "SHORT" },
{ BYTE, "BYTE" },
{ SECTIONS, "SECTIONS" },
{ SIZEOF_HEADERS, "SIZEOF_HEADERS" },
{ MEMORY, "MEMORY" },
{ DEFINED, "DEFINED" },
{ TARGET_K, "TARGET" },
{ SEARCH_DIR, "SEARCH_DIR" },
{ MAP, "MAP" },
{ ENTRY, "ENTRY" },
{ NEXT, "NEXT" },
{ ALIGNOF, "ALIGNOF" },
{ SIZEOF, "SIZEOF" },
{ ADDR, "ADDR" },
{ LOADADDR, "LOADADDR" },
{ CONSTANT, "CONSTANT" },
{ ABSOLUTE, "ABSOLUTE" },
{ MAX_K, "MAX" },
{ MIN_K, "MIN" },
{ ASSERT_K, "ASSERT" },
{ REL, "relocatable" },
{ DATA_SEGMENT_ALIGN, "DATA_SEGMENT_ALIGN" },
{ DATA_SEGMENT_RELRO_END, "DATA_SEGMENT_RELRO_END" },
{ DATA_SEGMENT_END, "DATA_SEGMENT_END" },
{ ORIGIN, "ORIGIN" },
{ LENGTH, "LENGTH" },
{ SEGMENT_START, "SEGMENT_START" }
};
unsigned int idx;
for (idx = 0; idx < ARRAY_SIZE (table); idx++)
if (table[idx].code == code)
break;
if (infix_p)
fputc (' ', config.map_file);
if (idx < ARRAY_SIZE (table))
fputs (table[idx].name, config.map_file);
else if (code < 127)
fputc (code, config.map_file);
else
fprintf (config.map_file, "<code %d>", code);
if (infix_p)
fputc (' ', config.map_file);
}
static void
make_log2ceil (void)
{
bfd_vma value = expld.result.value;
bfd_vma result = -1;
bfd_boolean round_up = FALSE;
do
{
result++;
/* If more than one bit is set in the value we will need to round up. */
if ((value > 1) && (value & 1))
round_up = TRUE;
}
while (value >>= 1);
if (round_up)
result += 1;
expld.result.section = NULL;
expld.result.value = result;
}
static void
make_abs (void)
{
if (expld.result.section != NULL)
expld.result.value += expld.result.section->vma;
expld.result.section = bfd_abs_section_ptr;
expld.rel_from_abs = FALSE;
}
static void
new_abs (bfd_vma value)
{
expld.result.valid_p = TRUE;
expld.result.section = bfd_abs_section_ptr;
expld.result.value = value;
expld.result.str = NULL;
}
etree_type *
exp_intop (bfd_vma value)
{
etree_type *new_e = (etree_type *) stat_alloc (sizeof (new_e->value));
new_e->type.node_code = INT;
new_e->type.filename = ldlex_filename ();
new_e->type.lineno = lineno;
new_e->value.value = value;
new_e->value.str = NULL;
new_e->type.node_class = etree_value;
return new_e;
}
etree_type *
exp_bigintop (bfd_vma value, char *str)
{
etree_type *new_e = (etree_type *) stat_alloc (sizeof (new_e->value));
new_e->type.node_code = INT;
new_e->type.filename = ldlex_filename ();
new_e->type.lineno = lineno;
new_e->value.value = value;
new_e->value.str = str;
new_e->type.node_class = etree_value;
return new_e;
}
/* Build an expression representing an unnamed relocatable value. */
etree_type *
exp_relop (asection *section, bfd_vma value)
{
etree_type *new_e = (etree_type *) stat_alloc (sizeof (new_e->rel));
new_e->type.node_code = REL;
new_e->type.filename = ldlex_filename ();
new_e->type.lineno = lineno;
new_e->type.node_class = etree_rel;
new_e->rel.section = section;
new_e->rel.value = value;
return new_e;
}
static void
new_number (bfd_vma value)
{
expld.result.valid_p = TRUE;
expld.result.value = value;
expld.result.str = NULL;
expld.result.section = NULL;
}
static void
new_rel (bfd_vma value, asection *section)
{
expld.result.valid_p = TRUE;
expld.result.value = value;
expld.result.str = NULL;
expld.result.section = section;
}
static void
new_rel_from_abs (bfd_vma value)
{
asection *s = expld.section;
expld.rel_from_abs = TRUE;
expld.result.valid_p = TRUE;
expld.result.value = value - s->vma;
expld.result.str = NULL;
expld.result.section = s;
}
/* New-function for the definedness hash table. */
static struct bfd_hash_entry *
definedness_newfunc (struct bfd_hash_entry *entry,
struct bfd_hash_table *table ATTRIBUTE_UNUSED,
const char *name ATTRIBUTE_UNUSED)
{
struct definedness_hash_entry *ret = (struct definedness_hash_entry *) entry;
if (ret == NULL)
ret = (struct definedness_hash_entry *)
bfd_hash_allocate (table, sizeof (struct definedness_hash_entry));
if (ret == NULL)
einfo (_("%F%P: bfd_hash_allocate failed creating symbol %s\n"), name);
ret->by_object = 0;
ret->iteration = 0;
return &ret->root;
}
/* Called during processing of linker script script expressions.
For symbols assigned in a linker script, return a struct describing
where the symbol is defined relative to the current expression,
otherwise return NULL. */
static struct definedness_hash_entry *
symbol_defined (const char *name)
{
return ((struct definedness_hash_entry *)
bfd_hash_lookup (&definedness_table, name, FALSE, FALSE));
}
/* Update the definedness state of NAME. Return FALSE if script symbol
is multiply defining a strong symbol in an object. */
static bfd_boolean
update_definedness (const char *name, struct bfd_link_hash_entry *h)
{
bfd_boolean ret;
struct definedness_hash_entry *defentry
= (struct definedness_hash_entry *)
bfd_hash_lookup (&definedness_table, name, TRUE, FALSE);
if (defentry == NULL)
einfo (_("%F%P: bfd_hash_lookup failed creating symbol %s\n"), name);
/* If the symbol was already defined, and not by a script, then it
must be defined by an object file or by the linker target code. */
ret = TRUE;
if (!h->ldscript_def
&& (h->type == bfd_link_hash_defined
|| h->type == bfd_link_hash_defweak
|| h->type == bfd_link_hash_common))
{
defentry->by_object = 1;
if (h->type == bfd_link_hash_defined
&& h->u.def.section->output_section != NULL
&& !h->linker_def)
ret = FALSE;
}
defentry->iteration = lang_statement_iteration;
defentry->final_sec = bfd_abs_section_ptr;
if (expld.phase == lang_final_phase_enum
&& expld.rel_from_abs
&& expld.result.section == bfd_abs_section_ptr)
defentry->final_sec = section_for_dot ();
return ret;
}
static void
fold_segment_end (seg_align_type *seg)
{
if (expld.phase == lang_first_phase_enum
|| expld.section != bfd_abs_section_ptr)
{
expld.result.valid_p = FALSE;
}
else if (seg->phase == exp_seg_align_seen
|| seg->phase == exp_seg_relro_seen)
{
seg->phase = exp_seg_end_seen;
seg->end = expld.result.value;
}
else if (seg->phase == exp_seg_done
|| seg->phase == exp_seg_adjust
|| seg->phase == exp_seg_relro_adjust)
{
/* OK. */
}
else
expld.result.valid_p = FALSE;
}
static void
fold_unary (etree_type *tree)
{
exp_fold_tree_1 (tree->unary.child);
if (expld.result.valid_p)
{
switch (tree->type.node_code)
{
case ALIGN_K:
if (expld.phase != lang_first_phase_enum)
new_rel_from_abs (align_n (expld.dot, expld.result.value));
else
expld.result.valid_p = FALSE;
break;
case ABSOLUTE:
make_abs ();
break;
case LOG2CEIL:
make_log2ceil ();
break;
case '~':
expld.result.value = ~expld.result.value;
break;
case '!':
expld.result.value = !expld.result.value;
break;
case '-':
expld.result.value = -expld.result.value;
break;
case NEXT:
/* Return next place aligned to value. */
if (expld.phase != lang_first_phase_enum)
{
make_abs ();
expld.result.value = align_n (expld.dot, expld.result.value);
}
else
expld.result.valid_p = FALSE;
break;
case DATA_SEGMENT_END:
fold_segment_end (&expld.dataseg);
break;
default:
FAIL ();
break;
}
}
}
/* Arithmetic operators, bitwise AND, bitwise OR and XOR keep the
section of one of their operands only when the other operand is a
plain number. Losing the section when operating on two symbols,
ie. a result of a plain number, is required for subtraction and
XOR. It's justifiable for the other operations on the grounds that
adding, multiplying etc. two section relative values does not
really make sense unless they are just treated as numbers.
The same argument could be made for many expressions involving one
symbol and a number. For example, "1 << x" and "100 / x" probably
should not be given the section of x. The trouble is that if we
fuss about such things the rules become complex and it is onerous
to document ld expression evaluation. */
static void
arith_result_section (const etree_value_type *lhs)
{
if (expld.result.section == lhs->section)
{
if (expld.section == bfd_abs_section_ptr
&& !config.sane_expr)
/* Duplicate the insanity in exp_fold_tree_1 case etree_value. */
expld.result.section = bfd_abs_section_ptr;
else
expld.result.section = NULL;
}
}
static void
fold_segment_align (seg_align_type *seg, etree_value_type *lhs)
{
seg->relro = exp_seg_relro_start;
if (expld.phase == lang_first_phase_enum
|| expld.section != bfd_abs_section_ptr)
expld.result.valid_p = FALSE;
else
{
bfd_vma maxpage = lhs->value;
bfd_vma commonpage = expld.result.value;
expld.result.value = align_n (expld.dot, maxpage);
if (seg->phase == exp_seg_relro_adjust)
expld.result.value = seg->base;
else if (seg->phase == exp_seg_adjust)
{
if (commonpage < maxpage)
expld.result.value += ((expld.dot + commonpage - 1)
& (maxpage - commonpage));
}
else
{
expld.result.value += expld.dot & (maxpage - 1);
if (seg->phase == exp_seg_done)
{
/* OK. */
}
else if (seg->phase == exp_seg_none)
{
seg->phase = exp_seg_align_seen;
seg->base = expld.result.value;
seg->pagesize = commonpage;
seg->maxpagesize = maxpage;
seg->relro_end = 0;
}
else
expld.result.valid_p = FALSE;
}
}
}
static void
fold_segment_relro_end (seg_align_type *seg, etree_value_type *lhs)
{
/* Operands swapped! XXX_SEGMENT_RELRO_END(offset,exp) has offset
in expld.result and exp in lhs. */
seg->relro = exp_seg_relro_end;
seg->relro_offset = expld.result.value;
if (expld.phase == lang_first_phase_enum
|| expld.section != bfd_abs_section_ptr)
expld.result.valid_p = FALSE;
else if (seg->phase == exp_seg_align_seen
|| seg->phase == exp_seg_adjust
|| seg->phase == exp_seg_relro_adjust
|| seg->phase == exp_seg_done)
{
if (seg->phase == exp_seg_align_seen
|| seg->phase == exp_seg_relro_adjust)
seg->relro_end = lhs->value + expld.result.value;
if (seg->phase == exp_seg_relro_adjust
&& (seg->relro_end & (seg->pagesize - 1)))
{
seg->relro_end += seg->pagesize - 1;
seg->relro_end &= ~(seg->pagesize - 1);
expld.result.value = seg->relro_end - expld.result.value;
}
else
expld.result.value = lhs->value;
if (seg->phase == exp_seg_align_seen)
seg->phase = exp_seg_relro_seen;
}
else
expld.result.valid_p = FALSE;
}
static void
fold_binary (etree_type *tree)
{
etree_value_type lhs;
exp_fold_tree_1 (tree->binary.lhs);
/* The SEGMENT_START operator is special because its first
operand is a string, not the name of a symbol. Note that the
operands have been swapped, so binary.lhs is second (default)
operand, binary.rhs is first operand. */
if (expld.result.valid_p && tree->type.node_code == SEGMENT_START)
{
const char *segment_name;
segment_type *seg;
/* Check to see if the user has overridden the default
value. */
segment_name = tree->binary.rhs->name.name;
for (seg = segments; seg; seg = seg->next)
if (strcmp (seg->name, segment_name) == 0)
{
if (!seg->used
&& config.magic_demand_paged
&& (seg->value % config.maxpagesize) != 0)
einfo (_("%P: warning: address of `%s' "
"isn't multiple of maximum page size\n"),
segment_name);
seg->used = TRUE;
new_rel_from_abs (seg->value);
break;
}
return;
}
lhs = expld.result;
exp_fold_tree_1 (tree->binary.rhs);
expld.result.valid_p &= lhs.valid_p;
if (expld.result.valid_p)
{
if (lhs.section != expld.result.section)
{
/* If the values are from different sections, and neither is
just a number, make both the source arguments absolute. */
if (expld.result.section != NULL
&& lhs.section != NULL)
{
make_abs ();
lhs.value += lhs.section->vma;
lhs.section = bfd_abs_section_ptr;
}
/* If the rhs is just a number, keep the lhs section. */
else if (expld.result.section == NULL)
{
expld.result.section = lhs.section;
/* Make this NULL so that we know one of the operands
was just a number, for later tests. */
lhs.section = NULL;
}
}
/* At this point we know that both operands have the same
section, or at least one of them is a plain number. */
switch (tree->type.node_code)
{
#define BOP(x, y) \
case x: \
expld.result.value = lhs.value y expld.result.value; \
arith_result_section (&lhs); \
break;
/* Comparison operators, logical AND, and logical OR always
return a plain number. */
#define BOPN(x, y) \
case x: \
expld.result.value = lhs.value y expld.result.value; \
expld.result.section = NULL; \
break;
BOP ('+', +);
BOP ('*', *);
BOP ('-', -);
BOP (LSHIFT, <<);
BOP (RSHIFT, >>);
BOP ('&', &);
BOP ('^', ^);
BOP ('|', |);
BOPN (EQ, ==);
BOPN (NE, !=);
BOPN ('<', <);
BOPN ('>', >);
BOPN (LE, <=);
BOPN (GE, >=);
BOPN (ANDAND, &&);
BOPN (OROR, ||);
case '%':
if (expld.result.value != 0)
expld.result.value = ((bfd_signed_vma) lhs.value
% (bfd_signed_vma) expld.result.value);
else if (expld.phase != lang_mark_phase_enum)
einfo (_("%F%P:%pS %% by zero\n"), tree->binary.rhs);
arith_result_section (&lhs);
break;
case '/':
if (expld.result.value != 0)
expld.result.value = ((bfd_signed_vma) lhs.value
/ (bfd_signed_vma) expld.result.value);
else if (expld.phase != lang_mark_phase_enum)
einfo (_("%F%P:%pS / by zero\n"), tree->binary.rhs);
arith_result_section (&lhs);
break;
case MAX_K:
if (lhs.value > expld.result.value)
expld.result.value = lhs.value;
break;
case MIN_K:
if (lhs.value < expld.result.value)
expld.result.value = lhs.value;
break;
case ALIGN_K:
expld.result.value = align_n (lhs.value, expld.result.value);
break;
case DATA_SEGMENT_ALIGN:
fold_segment_align (&expld.dataseg, &lhs);
break;
case DATA_SEGMENT_RELRO_END:
fold_segment_relro_end (&expld.dataseg, &lhs);
break;
default:
FAIL ();
}
}
}
static void
fold_trinary (etree_type *tree)
{
struct bfd_link_hash_entry *save = expld.assign_src;
exp_fold_tree_1 (tree->trinary.cond);
expld.assign_src = save;
if (expld.result.valid_p)
exp_fold_tree_1 (expld.result.value
? tree->trinary.lhs
: tree->trinary.rhs);
}
static void
fold_name (etree_type *tree)
{
struct bfd_link_hash_entry *h;
struct definedness_hash_entry *def;
memset (&expld.result, 0, sizeof (expld.result));
switch (tree->type.node_code)
{
case SIZEOF_HEADERS:
if (expld.phase != lang_first_phase_enum)
{
bfd_vma hdr_size = 0;
/* Don't find the real header size if only marking sections;
The bfd function may cache incorrect data. */
if (expld.phase != lang_mark_phase_enum)
hdr_size = bfd_sizeof_headers (link_info.output_bfd, &link_info);
new_number (hdr_size);
}
break;
case DEFINED:
h = bfd_wrapped_link_hash_lookup (link_info.output_bfd,
&link_info,
tree->name.name,
FALSE, FALSE, TRUE);
new_number (h != NULL
&& (h->type == bfd_link_hash_defined
|| h->type == bfd_link_hash_defweak
|| h->type == bfd_link_hash_common)
&& (!h->ldscript_def
|| (def = symbol_defined (tree->name.name)) == NULL
|| def->by_object
|| def->iteration == (lang_statement_iteration & 255)));
break;
case NAME:
if (expld.assign_name != NULL
&& strcmp (expld.assign_name, tree->name.name) == 0)
{
/* Self-assignment is only allowed for absolute symbols
defined in a linker script. */
h = bfd_wrapped_link_hash_lookup (link_info.output_bfd,
&link_info,
tree->name.name,
FALSE, FALSE, TRUE);
if (!(h != NULL
&& (h->type == bfd_link_hash_defined
|| h->type == bfd_link_hash_defweak)
&& h->u.def.section == bfd_abs_section_ptr
&& (def = symbol_defined (tree->name.name)) != NULL
&& def->iteration == (lang_statement_iteration & 255)))
expld.assign_name = NULL;
}
if (tree->name.name[0] == '.' && tree->name.name[1] == 0)
new_rel_from_abs (expld.dot);
else
{
h = bfd_wrapped_link_hash_lookup (link_info.output_bfd,
&link_info,
tree->name.name,
TRUE, FALSE, TRUE);
if (!h)
einfo (_("%F%P: bfd_link_hash_lookup failed: %E\n"));
else if (h->type == bfd_link_hash_defined
|| h->type == bfd_link_hash_defweak)
{
asection *output_section;
output_section = h->u.def.section->output_section;
if (output_section == NULL)
{
if (expld.phase <= lang_mark_phase_enum)
new_rel (h->u.def.value, h->u.def.section);
else
einfo (_("%X%P:%pS: unresolvable symbol `%s'"
" referenced in expression\n"),
tree, tree->name.name);
}
else if (output_section == bfd_abs_section_ptr
&& (expld.section != bfd_abs_section_ptr
|| config.sane_expr))
new_number (h->u.def.value + h->u.def.section->output_offset);
else
new_rel (h->u.def.value + h->u.def.section->output_offset,
output_section);
}
else if (expld.phase == lang_final_phase_enum
|| (expld.phase != lang_mark_phase_enum
&& expld.assigning_to_dot))
einfo (_("%F%P:%pS: undefined symbol `%s'"
" referenced in expression\n"),
tree, tree->name.name);
else if (h->type == bfd_link_hash_new)
{
h->type = bfd_link_hash_undefined;
h->u.undef.abfd = NULL;
if (h->u.undef.next == NULL && h != link_info.hash->undefs_tail)
bfd_link_add_undef (link_info.hash, h);
}
if (expld.assign_src == NULL)
expld.assign_src = h;
else
expld.assign_src = (struct bfd_link_hash_entry *) - 1;
}
break;
case ADDR:
if (expld.phase != lang_first_phase_enum)
{
lang_output_section_statement_type *os;
os = lang_output_section_find (tree->name.name);
if (os == NULL)
{
if (expld.phase == lang_final_phase_enum)
einfo (_("%F%P:%pS: undefined section `%s'"
" referenced in expression\n"),
tree, tree->name.name);
}
else if (os->processed_vma)
new_rel (0, os->bfd_section);
}
break;
case LOADADDR:
if (expld.phase != lang_first_phase_enum)
{
lang_output_section_statement_type *os;
os = lang_output_section_find (tree->name.name);
if (os == NULL)
{
if (expld.phase == lang_final_phase_enum)
einfo (_("%F%P:%pS: undefined section `%s'"
" referenced in expression\n"),
tree, tree->name.name);
}
else if (os->processed_lma)
{
if (os->load_base == NULL)
new_abs (os->bfd_section->lma);
else
{
exp_fold_tree_1 (os->load_base);
if (expld.result.valid_p)
make_abs ();
}
}
}
break;
case SIZEOF:
case ALIGNOF:
if (expld.phase != lang_first_phase_enum)
{
lang_output_section_statement_type *os;
os = lang_output_section_find (tree->name.name);
if (os == NULL)
{
if (expld.phase == lang_final_phase_enum)
einfo (_("%F%P:%pS: undefined section `%s'"
" referenced in expression\n"),
tree, tree->name.name);
new_number (0);
}
else if (os->bfd_section != NULL)
{
bfd_vma val;
if (tree->type.node_code == SIZEOF)
val = (os->bfd_section->size
/ bfd_octets_per_byte (link_info.output_bfd));
else
val = (bfd_vma)1 << os->bfd_section->alignment_power;
new_number (val);
}
else
new_number (0);
}
break;
case LENGTH:
{
if (expld.phase != lang_first_phase_enum)
{
lang_memory_region_type *mem;
mem = lang_memory_region_lookup (tree->name.name, FALSE);
if (mem != NULL)
new_number (mem->length);
else
einfo (_("%F%P:%pS: undefined MEMORY region `%s'"
" referenced in expression\n"),
tree, tree->name.name);
}
}
break;
case ORIGIN:
if (expld.phase != lang_first_phase_enum)
{
lang_memory_region_type *mem;
mem = lang_memory_region_lookup (tree->name.name, FALSE);
if (mem != NULL)
new_rel_from_abs (mem->origin);
else
einfo (_("%F%P:%pS: undefined MEMORY region `%s'"
" referenced in expression\n"),
tree, tree->name.name);
}
break;
case CONSTANT:
if (strcmp (tree->name.name, "MAXPAGESIZE") == 0)
new_number (config.maxpagesize);
else if (strcmp (tree->name.name, "COMMONPAGESIZE") == 0)
new_number (config.commonpagesize);
else
einfo (_("%F%P:%pS: unknown constant `%s' referenced in expression\n"),
tree, tree->name.name);
break;
default:
FAIL ();
break;
}
}
/* Return true if TREE is '.'. */
static bfd_boolean
is_dot (const etree_type *tree)
{
return (tree->type.node_class == etree_name
&& tree->type.node_code == NAME
&& tree->name.name[0] == '.'
&& tree->name.name[1] == 0);
}
/* Return true if TREE is a constant equal to VAL. */
static bfd_boolean
is_value (const etree_type *tree, bfd_vma val)
{
return (tree->type.node_class == etree_value
&& tree->value.value == val);
}
/* Return true if TREE is an absolute symbol equal to VAL defined in
a linker script. */
static bfd_boolean
is_sym_value (const etree_type *tree, bfd_vma val)
{
struct bfd_link_hash_entry *h;
struct definedness_hash_entry *def;
return (tree->type.node_class == etree_name
&& tree->type.node_code == NAME
&& (def = symbol_defined (tree->name.name)) != NULL
&& def->iteration == (lang_statement_iteration & 255)
&& (h = bfd_wrapped_link_hash_lookup (link_info.output_bfd,
&link_info,
tree->name.name,
FALSE, FALSE, TRUE)) != NULL
&& h->ldscript_def
&& h->type == bfd_link_hash_defined
&& h->u.def.section == bfd_abs_section_ptr
&& h->u.def.value == val);
}
/* Return true if TREE is ". != 0". */
static bfd_boolean
is_dot_ne_0 (const etree_type *tree)
{
return (tree->type.node_class == etree_binary
&& tree->type.node_code == NE
&& is_dot (tree->binary.lhs)
&& is_value (tree->binary.rhs, 0));
}
/* Return true if TREE is ". = . + 0" or ". = . + sym" where sym is an
absolute constant with value 0 defined in a linker script. */
static bfd_boolean
is_dot_plus_0 (const etree_type *tree)
{
return (tree->type.node_class == etree_binary
&& tree->type.node_code == '+'
&& is_dot (tree->binary.lhs)
&& (is_value (tree->binary.rhs, 0)
|| is_sym_value (tree->binary.rhs, 0)));
}
/* Return true if TREE is "ALIGN (. != 0 ? some_expression : 1)". */
static bfd_boolean
is_align_conditional (const etree_type *tree)
{
if (tree->type.node_class == etree_unary
&& tree->type.node_code == ALIGN_K)
{
tree = tree->unary.child;
return (tree->type.node_class == etree_trinary
&& is_dot_ne_0 (tree->trinary.cond)
&& is_value (tree->trinary.rhs, 1));
}
return FALSE;
}
static void
exp_fold_tree_1 (etree_type *tree)
{
if (tree == NULL)
{
memset (&expld.result, 0, sizeof (expld.result));
return;
}
switch (tree->type.node_class)
{
case etree_value:
if (expld.section == bfd_abs_section_ptr
&& !config.sane_expr)
new_abs (tree->value.value);
else
new_number (tree->value.value);
expld.result.str = tree->value.str;
break;
case etree_rel:
if (expld.phase != lang_first_phase_enum)
{
asection *output_section = tree->rel.section->output_section;
new_rel (tree->rel.value + tree->rel.section->output_offset,
output_section);
}
else
memset (&expld.result, 0, sizeof (expld.result));
break;
case etree_assert:
exp_fold_tree_1 (tree->assert_s.child);
if (expld.phase == lang_final_phase_enum && !expld.result.value)
einfo ("%X%P: %s\n", tree->assert_s.message);
break;
case etree_unary:
fold_unary (tree);
break;
case etree_binary:
fold_binary (tree);
break;
case etree_trinary:
fold_trinary (tree);
break;
case etree_assign:
case etree_provide:
case etree_provided:
if (tree->assign.dst[0] == '.' && tree->assign.dst[1] == 0)
{
if (tree->type.node_class != etree_assign)
einfo (_("%F%P:%pS can not PROVIDE assignment to"
" location counter\n"), tree);
if (expld.phase != lang_first_phase_enum)
{
/* Notify the folder that this is an assignment to dot. */
expld.assigning_to_dot = TRUE;
exp_fold_tree_1 (tree->assign.src);
expld.assigning_to_dot = FALSE;
/* If we are assigning to dot inside an output section
arrange to keep the section, except for certain
expressions that evaluate to zero. We ignore . = 0,
. = . + 0, and . = ALIGN (. != 0 ? expr : 1).
We can't ignore all expressions that evaluate to zero
because an otherwise empty section might have padding
added by an alignment expression that changes with
relaxation. Such a section might have zero size
before relaxation and so be stripped incorrectly. */
if (expld.phase == lang_mark_phase_enum
&& expld.section != bfd_abs_section_ptr
&& expld.section != bfd_und_section_ptr
&& !(expld.result.valid_p
&& expld.result.value == 0
&& (is_value (tree->assign.src, 0)
|| is_sym_value (tree->assign.src, 0)
|| is_dot_plus_0 (tree->assign.src)
|| is_align_conditional (tree->assign.src))))
expld.section->flags |= SEC_KEEP;
if (!expld.result.valid_p
|| expld.section == bfd_und_section_ptr)
{
if (expld.phase != lang_mark_phase_enum)
einfo (_("%F%P:%pS invalid assignment to"
" location counter\n"), tree);
}
else if (expld.dotp == NULL)
einfo (_("%F%P:%pS assignment to location counter"
" invalid outside of SECTIONS\n"), tree);
/* After allocation, assignment to dot should not be
done inside an output section since allocation adds a
padding statement that effectively duplicates the
assignment. */
else if (expld.phase <= lang_allocating_phase_enum
|| expld.section == bfd_abs_section_ptr)
{
bfd_vma nextdot;
nextdot = expld.result.value;
if (expld.result.section != NULL)
nextdot += expld.result.section->vma;
else
nextdot += expld.section->vma;
if (nextdot < expld.dot
&& expld.section != bfd_abs_section_ptr)
einfo (_("%F%P:%pS cannot move location counter backwards"
" (from %V to %V)\n"),
tree, expld.dot, nextdot);
else
{
expld.dot = nextdot;
*expld.dotp = nextdot;
}
}
}
else
memset (&expld.result, 0, sizeof (expld.result));
}
else
{
struct bfd_link_hash_entry *h = NULL;
if (tree->type.node_class == etree_provide)
{
h = bfd_link_hash_lookup (link_info.hash, tree->assign.dst,
FALSE, FALSE, TRUE);
if (h == NULL
|| !(h->type == bfd_link_hash_new
|| h->type == bfd_link_hash_undefined
|| h->type == bfd_link_hash_undefweak
|| h->linker_def))
{
/* Do nothing. The symbol was never referenced, or
was defined in some object file. Note that
undefweak symbols are defined by PROVIDE. This
is to support glibc use of __rela_iplt_start and
similar weak references. */
break;
}
}
expld.assign_name = tree->assign.dst;
expld.assign_src = NULL;
exp_fold_tree_1 (tree->assign.src);
/* expld.assign_name remaining equal to tree->assign.dst
below indicates the evaluation of tree->assign.src did
not use the value of tree->assign.dst. We don't allow
self assignment until the final phase for two reasons:
1) Expressions are evaluated multiple times. With
relaxation, the number of times may vary.
2) Section relative symbol values cannot be correctly
converted to absolute values, as is required by many
expressions, until final section sizing is complete. */
if (expld.phase == lang_final_phase_enum
|| expld.assign_name != NULL)
{
if (tree->type.node_class == etree_provide)
tree->type.node_class = etree_provided;
if (h == NULL)
{
h = bfd_link_hash_lookup (link_info.hash, tree->assign.dst,
TRUE, FALSE, TRUE);
if (h == NULL)
einfo (_("%F%P:%s: hash creation failed\n"),
tree->assign.dst);
}
/* If the expression is not valid then fake a zero value. In
the final phase any errors will already have been raised,
in earlier phases we want to create this definition so
that it can be seen by other expressions. */
if (!expld.result.valid_p
&& h->type == bfd_link_hash_new)
{
expld.result.value = 0;
expld.result.section = NULL;
expld.result.valid_p = TRUE;
}
if (expld.result.valid_p)
{
if (expld.result.section == NULL)
expld.result.section = expld.section;
if (!update_definedness (tree->assign.dst, h) && 0)
{
/* Symbol was already defined. For now this error
is disabled because it causes failures in the ld
testsuite: ld-elf/var1, ld-scripts/defined5, and
ld-scripts/pr14962. Some of these no doubt
reflect scripts used in the wild. */
(*link_info.callbacks->multiple_definition)
(&link_info, h, link_info.output_bfd,
expld.result.section, expld.result.value);
}
h->type = bfd_link_hash_defined;
h->u.def.value = expld.result.value;
h->u.def.section = expld.result.section;
h->linker_def = ! tree->assign.type.lineno;
h->ldscript_def = 1;
h->rel_from_abs = expld.rel_from_abs;
if (tree->assign.hidden)
bfd_link_hide_symbol (link_info.output_bfd,
&link_info, h);
/* Copy the symbol type if this is an expression only
referencing a single symbol. (If the expression
contains ternary conditions, ignoring symbols on
false branches.) */
if (expld.assign_src != NULL
&& (expld.assign_src
!= (struct bfd_link_hash_entry *) -1))
bfd_copy_link_hash_symbol_type (link_info.output_bfd, h,
expld.assign_src);
}
}
expld.assign_name = NULL;
}
break;
case etree_name:
fold_name (tree);
break;
default:
FAIL ();
memset (&expld.result, 0, sizeof (expld.result));
break;
}
}
void
exp_fold_tree (etree_type *tree, asection *current_section, bfd_vma *dotp)
{
expld.rel_from_abs = FALSE;
expld.dot = *dotp;
expld.dotp = dotp;
expld.section = current_section;
exp_fold_tree_1 (tree);
}
void
exp_fold_tree_no_dot (etree_type *tree)
{
expld.rel_from_abs = FALSE;
expld.dot = 0;
expld.dotp = NULL;
expld.section = bfd_abs_section_ptr;
exp_fold_tree_1 (tree);
}
static void
exp_value_fold (etree_type *tree)
{
exp_fold_tree_no_dot (tree);
if (expld.result.valid_p)
{
tree->type.node_code = INT;
tree->value.value = expld.result.value;
tree->value.str = NULL;
tree->type.node_class = etree_value;
}
}
#define MAX(a, b) ((a) > (b) ? (a) : (b))
etree_type *
exp_binop (int code, etree_type *lhs, etree_type *rhs)
{
etree_type *new_e = (etree_type *) stat_alloc (MAX (sizeof (new_e->binary),
sizeof (new_e->value)));
new_e->type.node_code = code;
new_e->type.filename = lhs->type.filename;
new_e->type.lineno = lhs->type.lineno;
new_e->binary.lhs = lhs;
new_e->binary.rhs = rhs;
new_e->type.node_class = etree_binary;
if (lhs->type.node_class == etree_value
&& rhs->type.node_class == etree_value
&& code != ALIGN_K
&& code != DATA_SEGMENT_ALIGN
&& code != DATA_SEGMENT_RELRO_END)
exp_value_fold (new_e);
return new_e;
}
etree_type *
exp_trinop (int code, etree_type *cond, etree_type *lhs, etree_type *rhs)
{
etree_type *new_e = (etree_type *) stat_alloc (MAX (sizeof (new_e->trinary),
sizeof (new_e->value)));
new_e->type.node_code = code;
new_e->type.filename = cond->type.filename;
new_e->type.lineno = cond->type.lineno;
new_e->trinary.lhs = lhs;
new_e->trinary.cond = cond;
new_e->trinary.rhs = rhs;
new_e->type.node_class = etree_trinary;
if (cond->type.node_class == etree_value
&& lhs->type.node_class == etree_value
&& rhs->type.node_class == etree_value)
exp_value_fold (new_e);
return new_e;
}
etree_type *
exp_unop (int code, etree_type *child)
{
etree_type *new_e = (etree_type *) stat_alloc (MAX (sizeof (new_e->unary),
sizeof (new_e->value)));
new_e->unary.type.node_code = code;
new_e->unary.type.filename = child->type.filename;
new_e->unary.type.lineno = child->type.lineno;
new_e->unary.child = child;
new_e->unary.type.node_class = etree_unary;
if (child->type.node_class == etree_value
&& code != ALIGN_K
&& code != ABSOLUTE
&& code != NEXT
&& code != DATA_SEGMENT_END)
exp_value_fold (new_e);
return new_e;
}
etree_type *
exp_nameop (int code, const char *name)
{
etree_type *new_e = (etree_type *) stat_alloc (sizeof (new_e->name));
new_e->name.type.node_code = code;
new_e->name.type.filename = ldlex_filename ();
new_e->name.type.lineno = lineno;
new_e->name.name = name;
new_e->name.type.node_class = etree_name;
return new_e;
}
static etree_type *
exp_assop (const char *dst,
etree_type *src,
enum node_tree_enum class,
bfd_boolean hidden)
{
etree_type *n;
n = (etree_type *) stat_alloc (sizeof (n->assign));
n->assign.type.node_code = '=';
n->assign.type.filename = src->type.filename;
n->assign.type.lineno = src->type.lineno;
n->assign.type.node_class = class;
n->assign.src = src;
n->assign.dst = dst;
n->assign.hidden = hidden;
return n;
}
/* Handle linker script assignments and HIDDEN. */
etree_type *
exp_assign (const char *dst, etree_type *src, bfd_boolean hidden)
{
return exp_assop (dst, src, etree_assign, hidden);
}
/* Handle --defsym command-line option. */
etree_type *
exp_defsym (const char *dst, etree_type *src)
{
return exp_assop (dst, src, etree_assign, FALSE);
}
/* Handle PROVIDE. */
etree_type *
exp_provide (const char *dst, etree_type *src, bfd_boolean hidden)
{
return exp_assop (dst, src, etree_provide, hidden);
}
/* Handle ASSERT. */
etree_type *
exp_assert (etree_type *exp, const char *message)
{
etree_type *n;
n = (etree_type *) stat_alloc (sizeof (n->assert_s));
n->assert_s.type.node_code = '!';
n->assert_s.type.filename = exp->type.filename;
n->assert_s.type.lineno = exp->type.lineno;
n->assert_s.type.node_class = etree_assert;
n->assert_s.child = exp;
n->assert_s.message = message;
return n;
}
void
exp_print_tree (etree_type *tree)
{
bfd_boolean function_like;
if (config.map_file == NULL)
config.map_file = stderr;
if (tree == NULL)
{
minfo ("NULL TREE\n");
return;
}
switch (tree->type.node_class)
{
case etree_value:
minfo ("0x%v", tree->value.value);
return;
case etree_rel:
if (tree->rel.section->owner != NULL)
minfo ("%pB:", tree->rel.section->owner);
minfo ("%s+0x%v", tree->rel.section->name, tree->rel.value);
return;
case etree_assign:
fputs (tree->assign.dst, config.map_file);
exp_print_token (tree->type.node_code, TRUE);
exp_print_tree (tree->assign.src);
break;
case etree_provide:
case etree_provided:
fprintf (config.map_file, "PROVIDE (%s = ", tree->assign.dst);
exp_print_tree (tree->assign.src);
fputc (')', config.map_file);
break;
case etree_binary:
function_like = FALSE;
switch (tree->type.node_code)
{
case MAX_K:
case MIN_K:
case ALIGN_K:
case DATA_SEGMENT_ALIGN:
case DATA_SEGMENT_RELRO_END:
function_like = TRUE;
break;
case SEGMENT_START:
/* Special handling because arguments are in reverse order and
the segment name is quoted. */
exp_print_token (tree->type.node_code, FALSE);
fputs (" (\"", config.map_file);
exp_print_tree (tree->binary.rhs);
fputs ("\", ", config.map_file);
exp_print_tree (tree->binary.lhs);
fputc (')', config.map_file);
return;
}
if (function_like)
{
exp_print_token (tree->type.node_code, FALSE);
fputc (' ', config.map_file);
}
fputc ('(', config.map_file);
exp_print_tree (tree->binary.lhs);
if (function_like)
fprintf (config.map_file, ", ");
else
exp_print_token (tree->type.node_code, TRUE);
exp_print_tree (tree->binary.rhs);
fputc (')', config.map_file);
break;
case etree_trinary:
exp_print_tree (tree->trinary.cond);
fputc ('?', config.map_file);
exp_print_tree (tree->trinary.lhs);
fputc (':', config.map_file);
exp_print_tree (tree->trinary.rhs);
break;
case etree_unary:
exp_print_token (tree->unary.type.node_code, FALSE);
if (tree->unary.child)
{
fprintf (config.map_file, " (");
exp_print_tree (tree->unary.child);
fputc (')', config.map_file);
}
break;
case etree_assert:
fprintf (config.map_file, "ASSERT (");
exp_print_tree (tree->assert_s.child);
fprintf (config.map_file, ", %s)", tree->assert_s.message);
break;
case etree_name:
if (tree->type.node_code == NAME)
fputs (tree->name.name, config.map_file);
else
{
exp_print_token (tree->type.node_code, FALSE);
if (tree->name.name)
fprintf (config.map_file, " (%s)", tree->name.name);
}
break;
default:
FAIL ();
break;
}
}
bfd_vma
exp_get_vma (etree_type *tree, bfd_vma def, char *name)
{
if (tree != NULL)
{
exp_fold_tree_no_dot (tree);
if (expld.result.valid_p)
return expld.result.value;
else if (name != NULL && expld.phase != lang_mark_phase_enum)
einfo (_("%F%P:%pS: nonconstant expression for %s\n"),
tree, name);
}
return def;
}
int
exp_get_value_int (etree_type *tree, int def, char *name)
{
return exp_get_vma (tree, def, name);
}
fill_type *
exp_get_fill (etree_type *tree, fill_type *def, char *name)
{
fill_type *fill;
size_t len;
unsigned int val;
if (tree == NULL)
return def;
exp_fold_tree_no_dot (tree);
if (!expld.result.valid_p)
{
if (name != NULL && expld.phase != lang_mark_phase_enum)
einfo (_("%F%P:%pS: nonconstant expression for %s\n"),
tree, name);
return def;
}
if (expld.result.str != NULL && (len = strlen (expld.result.str)) != 0)
{
unsigned char *dst;
unsigned char *s;
fill = (fill_type *) xmalloc ((len + 1) / 2 + sizeof (*fill) - 1);
fill->size = (len + 1) / 2;
dst = fill->data;
s = (unsigned char *) expld.result.str;
val = 0;
do
{
unsigned int digit;
digit = *s++ - '0';
if (digit > 9)
digit = (digit - 'A' + '0' + 10) & 0xf;
val <<= 4;
val += digit;
--len;
if ((len & 1) == 0)
{
*dst++ = val;
val = 0;
}
}
while (len != 0);
}
else
{
fill = (fill_type *) xmalloc (4 + sizeof (*fill) - 1);
val = expld.result.value;
fill->data[0] = (val >> 24) & 0xff;
fill->data[1] = (val >> 16) & 0xff;
fill->data[2] = (val >> 8) & 0xff;
fill->data[3] = (val >> 0) & 0xff;
fill->size = 4;
}
return fill;
}
bfd_vma
exp_get_abs_int (etree_type *tree, int def, char *name)
{
if (tree != NULL)
{
exp_fold_tree_no_dot (tree);
if (expld.result.valid_p)
{
if (expld.result.section != NULL)
expld.result.value += expld.result.section->vma;
return expld.result.value;
}
else if (name != NULL && expld.phase != lang_mark_phase_enum)
{
einfo (_("%F%P:%pS: nonconstant expression for %s\n"),
tree, name);
}
}
return def;
}
static bfd_vma
align_n (bfd_vma value, bfd_vma align)
{
if (align <= 1)
return value;
value = (value + align - 1) / align;
return value * align;
}
void
ldexp_init (void)
{
/* The value "13" is ad-hoc, somewhat related to the expected number of
assignments in a linker script. */
if (!bfd_hash_table_init_n (&definedness_table,
definedness_newfunc,
sizeof (struct definedness_hash_entry),
13))
einfo (_("%F%P: can not create hash table: %E\n"));
}
/* Convert absolute symbols defined by a script from "dot" (also
SEGMENT_START or ORIGIN) outside of an output section statement,
to section relative. */
static bfd_boolean
set_sym_sections (struct bfd_hash_entry *bh, void *inf ATTRIBUTE_UNUSED)
{
struct definedness_hash_entry *def = (struct definedness_hash_entry *) bh;
if (def->final_sec != bfd_abs_section_ptr)
{
struct bfd_link_hash_entry *h;
h = bfd_link_hash_lookup (link_info.hash, bh->string,
FALSE, FALSE, TRUE);
if (h != NULL
&& h->type == bfd_link_hash_defined
&& h->u.def.section == bfd_abs_section_ptr)
{
h->u.def.value -= def->final_sec->vma;
h->u.def.section = def->final_sec;
}
}
return TRUE;
}
void
ldexp_finalize_syms (void)
{
bfd_hash_traverse (&definedness_table, set_sym_sections, NULL);
}
void
ldexp_finish (void)
{
bfd_hash_table_free (&definedness_table);
}