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c6cfcb7f7d
* mpw-elfmips.c: Rename from mpw-emipself.c. * mpw-config.in: Update accordingly.
1471 lines
47 KiB
C
1471 lines
47 KiB
C
/* This file is is generated by a shell script. DO NOT EDIT! */
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/* 32 bit ELF emulation code for elf32ebmip
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Copyright (C) 1991, 93, 94, 95, 1996 Free Software Foundation, Inc.
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Written by Steve Chamberlain <sac@cygnus.com>
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ELF support by Ian Lance Taylor <ian@cygnus.com>
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This file is part of GLD, the Gnu Linker.
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 2 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
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#define TARGET_IS_elf32ebmip
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#include "bfd.h"
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#include "sysdep.h"
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#include <ctype.h>
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#include "bfdlink.h"
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#include "ld.h"
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#include "ldmain.h"
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#include "ldemul.h"
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#include "ldfile.h"
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#include "ldmisc.h"
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#include "ldexp.h"
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#include "ldlang.h"
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#include "ldgram.h"
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static void gldelf32ebmip_before_parse PARAMS ((void));
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static boolean gldelf32ebmip_open_dynamic_archive
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PARAMS ((const char *, search_dirs_type *, lang_input_statement_type *));
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static void gldelf32ebmip_after_open PARAMS ((void));
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static void gldelf32ebmip_check_needed
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PARAMS ((lang_input_statement_type *));
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static void gldelf32ebmip_stat_needed
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PARAMS ((lang_input_statement_type *));
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static boolean gldelf32ebmip_search_needed
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PARAMS ((const char *, const char *));
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static boolean gldelf32ebmip_try_needed PARAMS ((const char *));
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static void gldelf32ebmip_before_allocation PARAMS ((void));
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static void gldelf32ebmip_find_statement_assignment
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PARAMS ((lang_statement_union_type *));
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static void gldelf32ebmip_find_exp_assignment PARAMS ((etree_type *));
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static boolean gldelf32ebmip_place_orphan
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PARAMS ((lang_input_statement_type *, asection *));
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static void gldelf32ebmip_place_section
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PARAMS ((lang_statement_union_type *));
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static char *gldelf32ebmip_get_script PARAMS ((int *isfile));
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static void
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gldelf32ebmip_before_parse()
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{
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ldfile_output_architecture = bfd_arch_mips;
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config.dynamic_link = true;
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}
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/* Try to open a dynamic archive. This is where we know that ELF
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dynamic libraries have an extension of .so. */
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static boolean
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gldelf32ebmip_open_dynamic_archive (arch, search, entry)
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const char *arch;
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search_dirs_type *search;
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lang_input_statement_type *entry;
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{
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const char *filename;
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char *string;
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if (! entry->is_archive)
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return false;
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filename = entry->filename;
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string = (char *) xmalloc (strlen (search->name)
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+ strlen (filename)
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+ strlen (arch)
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+ sizeof "/lib.so");
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sprintf (string, "%s/lib%s%s.so", search->name, filename, arch);
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if (! ldfile_try_open_bfd (string, entry))
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{
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free (string);
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return false;
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}
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entry->filename = string;
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/* We have found a dynamic object to include in the link. The ELF
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backend linker will create a DT_NEEDED entry in the .dynamic
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section naming this file. If this file includes a DT_SONAME
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entry, it will be used. Otherwise, the ELF linker will just use
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the name of the file. For an archive found by searching, like
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this one, the DT_NEEDED entry should consist of just the name of
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the file, without the path information used to find it. Note
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that we only need to do this if we have a dynamic object; an
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archive will never be referenced by a DT_NEEDED entry.
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FIXME: This approach--using bfd_elf_set_dt_needed_name--is not
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very pretty. I haven't been able to think of anything that is
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pretty, though. */
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if (bfd_check_format (entry->the_bfd, bfd_object)
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&& (entry->the_bfd->flags & DYNAMIC) != 0)
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{
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char *needed_name;
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ASSERT (entry->is_archive && entry->search_dirs_flag);
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needed_name = (char *) xmalloc (strlen (filename)
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+ strlen (arch)
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+ sizeof "lib.so");
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sprintf (needed_name, "lib%s%s.so", filename, arch);
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bfd_elf_set_dt_needed_name (entry->the_bfd, needed_name);
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}
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return true;
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}
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/* These variables are required to pass information back and forth
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between after_open and check_needed and stat_needed. */
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static struct bfd_link_needed_list *global_needed;
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static struct stat global_stat;
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static boolean global_found;
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/* This is called after all the input files have been opened. */
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static void
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gldelf32ebmip_after_open ()
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{
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struct bfd_link_needed_list *needed, *l;
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/* We only need to worry about this when doing a final link. */
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if (link_info.relocateable || link_info.shared)
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return;
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/* Get the list of files which appear in DT_NEEDED entries in
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dynamic objects included in the link (often there will be none).
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For each such file, we want to track down the corresponding
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library, and include the symbol table in the link. This is what
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the runtime dynamic linker will do. Tracking the files down here
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permits one dynamic object to include another without requiring
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special action by the person doing the link. Note that the
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needed list can actually grow while we are stepping through this
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loop. */
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needed = bfd_elf_get_needed_list (output_bfd, &link_info);
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for (l = needed; l != NULL; l = l->next)
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{
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struct bfd_link_needed_list *ll;
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const char *lib_path;
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size_t len;
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search_dirs_type *search;
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/* If we've already seen this file, skip it. */
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for (ll = needed; ll != l; ll = ll->next)
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if (strcmp (ll->name, l->name) == 0)
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break;
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if (ll != l)
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continue;
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/* See if this file was included in the link explicitly. */
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global_needed = l;
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global_found = false;
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lang_for_each_input_file (gldelf32ebmip_check_needed);
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if (global_found)
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continue;
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/* We need to find this file and include the symbol table. We
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want to search for the file in the same way that the dynamic
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linker will search. That means that we want to use
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rpath_link, rpath, then the environment variable
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LD_LIBRARY_PATH (native only), then the linker script
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LIB_SEARCH_DIRS. We do not search using the -L arguments. */
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if (gldelf32ebmip_search_needed (command_line.rpath_link,
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l->name))
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continue;
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if (gldelf32ebmip_search_needed (command_line.rpath, l->name))
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continue;
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if (command_line.rpath_link == NULL
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&& command_line.rpath == NULL)
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{
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lib_path = (const char *) getenv ("LD_RUN_PATH");
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if (gldelf32ebmip_search_needed (lib_path, l->name))
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continue;
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}
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len = strlen (l->name);
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for (search = search_head; search != NULL; search = search->next)
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{
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char *filename;
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if (search->cmdline)
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continue;
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filename = (char *) xmalloc (strlen (search->name) + len + 2);
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sprintf (filename, "%s/%s", search->name, l->name);
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if (gldelf32ebmip_try_needed (filename))
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break;
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free (filename);
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}
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if (search != NULL)
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continue;
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einfo ("%P: warning: %s, needed by %B, not found\n",
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l->name, l->by);
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}
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}
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/* Search for a needed file in a path. */
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static boolean
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gldelf32ebmip_search_needed (path, name)
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const char *path;
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const char *name;
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{
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const char *s;
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size_t len;
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if (path == NULL || *path == '\0')
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return false;
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len = strlen (name);
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while (1)
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{
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char *filename, *sset;
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s = strchr (path, ':');
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if (s == NULL)
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s = path + strlen (path);
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filename = (char *) xmalloc (s - path + len + 2);
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if (s == path)
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sset = filename;
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else
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{
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memcpy (filename, path, s - path);
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filename[s - path] = '/';
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sset = filename + (s - path) + 1;
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}
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strcpy (sset, name);
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if (gldelf32ebmip_try_needed (filename))
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return true;
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free (filename);
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if (*s == '\0')
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break;
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path = s + 1;
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}
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return false;
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}
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/* This function is called for each possible name for a dynamic object
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named by a DT_NEEDED entry. */
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static boolean
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gldelf32ebmip_try_needed (name)
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const char *name;
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{
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bfd *abfd;
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abfd = bfd_openr (name, bfd_get_target (output_bfd));
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if (abfd == NULL)
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return false;
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if (! bfd_check_format (abfd, bfd_object))
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{
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(void) bfd_close (abfd);
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return false;
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}
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if ((bfd_get_file_flags (abfd) & DYNAMIC) == 0)
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{
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(void) bfd_close (abfd);
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return false;
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}
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/* We've found a dynamic object matching the DT_NEEDED entry. */
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/* We have already checked that there is no other input file of the
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same name. We must now check again that we are not including the
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same file twice. We need to do this because on many systems
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libc.so is a symlink to, e.g., libc.so.1. The SONAME entry will
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reference libc.so.1. If we have already included libc.so, we
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don't want to include libc.so.1 if they are the same file, and we
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can only check that using stat. */
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if (bfd_stat (abfd, &global_stat) != 0)
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einfo ("%F%P:%B: bfd_stat failed: %E\n", abfd);
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global_found = false;
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lang_for_each_input_file (gldelf32ebmip_stat_needed);
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if (global_found)
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{
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/* Return true to indicate that we found the file, even though
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we aren't going to do anything with it. */
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return true;
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}
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/* Tell the ELF backend that don't want the output file to have a
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DT_NEEDED entry for this file. */
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bfd_elf_set_dt_needed_name (abfd, "");
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/* Add this file into the symbol table. */
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if (! bfd_link_add_symbols (abfd, &link_info))
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einfo ("%F%B: could not read symbols: %E\n", abfd);
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return true;
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}
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/* See if an input file matches a DT_NEEDED entry by name. */
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static void
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gldelf32ebmip_check_needed (s)
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lang_input_statement_type *s;
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{
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if (global_found)
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return;
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if (s->filename != NULL
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&& strcmp (s->filename, global_needed->name) == 0)
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{
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global_found = true;
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return;
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}
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if (s->the_bfd != NULL)
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{
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const char *soname;
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soname = bfd_elf_get_dt_soname (s->the_bfd);
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if (soname != NULL
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&& strcmp (soname, global_needed->name) == 0)
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{
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global_found = true;
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return;
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}
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}
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if (s->search_dirs_flag
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&& s->filename != NULL
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&& strchr (global_needed->name, '/') == NULL)
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{
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const char *f;
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f = strrchr (s->filename, '/');
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if (f != NULL
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&& strcmp (f + 1, global_needed->name) == 0)
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{
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global_found = true;
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return;
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}
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}
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}
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/* See if an input file matches a DT_NEEDED entry by running stat on
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the file. */
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static void
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gldelf32ebmip_stat_needed (s)
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lang_input_statement_type *s;
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{
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struct stat st;
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const char *suffix;
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const char *soname;
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const char *f;
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if (global_found)
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return;
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if (s->the_bfd == NULL)
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return;
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if (bfd_stat (s->the_bfd, &st) != 0)
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{
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einfo ("%P:%B: bfd_stat failed: %E\n", s->the_bfd);
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return;
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}
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if (st.st_dev == global_stat.st_dev
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&& st.st_ino == global_stat.st_ino)
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{
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global_found = true;
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return;
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}
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/* We issue a warning if it looks like we are including two
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different versions of the same shared library. For example,
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there may be a problem if -lc picks up libc.so.6 but some other
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shared library has a DT_NEEDED entry of libc.so.5. This is a
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hueristic test, and it will only work if the name looks like
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NAME.so.VERSION. FIXME: Depending on file names is error-prone.
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If we really want to issue warnings about mixing version numbers
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of shared libraries, we need to find a better way. */
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if (strchr (global_needed->name, '/') != NULL)
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return;
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suffix = strstr (global_needed->name, ".so.");
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if (suffix == NULL)
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return;
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suffix += sizeof ".so." - 1;
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soname = bfd_elf_get_dt_soname (s->the_bfd);
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if (soname == NULL)
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soname = s->filename;
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f = strrchr (soname, '/');
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if (f != NULL)
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++f;
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else
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f = soname;
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if (strncmp (f, global_needed->name, suffix - global_needed->name) == 0)
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einfo ("%P: warning: %s, needed by %B, may conflict with %s\n",
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global_needed->name, global_needed->by, f);
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}
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/* This is called after the sections have been attached to output
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sections, but before any sizes or addresses have been set. */
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static void
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gldelf32ebmip_before_allocation ()
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{
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const char *rpath;
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asection *sinterp;
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/* If we are going to make any variable assignments, we need to let
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the ELF backend know about them in case the variables are
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referred to by dynamic objects. */
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lang_for_each_statement (gldelf32ebmip_find_statement_assignment);
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/* Let the ELF backend work out the sizes of any sections required
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by dynamic linking. */
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rpath = command_line.rpath;
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if (rpath == NULL)
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rpath = (const char *) getenv ("LD_RUN_PATH");
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if (! bfd_elf32_size_dynamic_sections (output_bfd,
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command_line.soname,
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rpath,
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command_line.export_dynamic,
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&link_info,
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&sinterp))
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einfo ("%P%F: failed to set dynamic section sizes: %E\n");
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/* Let the user override the dynamic linker we are using. */
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if (command_line.interpreter != NULL
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&& sinterp != NULL)
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{
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sinterp->contents = (bfd_byte *) command_line.interpreter;
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sinterp->_raw_size = strlen (command_line.interpreter) + 1;
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}
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/* Look for any sections named .gnu.warning. As a GNU extensions,
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we treat such sections as containing warning messages. We print
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out the warning message, and then zero out the section size so
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that it does not get copied into the output file. */
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{
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LANG_FOR_EACH_INPUT_STATEMENT (is)
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{
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asection *s;
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bfd_size_type sz;
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char *msg;
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boolean ret;
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if (is->just_syms_flag)
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continue;
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s = bfd_get_section_by_name (is->the_bfd, ".gnu.warning");
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if (s == NULL)
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continue;
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sz = bfd_section_size (is->the_bfd, s);
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msg = xmalloc ((size_t) sz + 1);
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if (! bfd_get_section_contents (is->the_bfd, s, msg, (file_ptr) 0, sz))
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einfo ("%F%B: Can't read contents of section .gnu.warning: %E\n",
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is->the_bfd);
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msg[sz] = '\0';
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ret = link_info.callbacks->warning (&link_info, msg,
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(const char *) NULL,
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is->the_bfd, (asection *) NULL,
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(bfd_vma) 0);
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ASSERT (ret);
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free (msg);
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/* Clobber the section size, so that we don't waste copying the
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warning into the output file. */
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s->_raw_size = 0;
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}
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}
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#if defined (TARGET_IS_elf32bmip) || defined (TARGET_IS_elf32lmip)
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/* For MIPS ELF the .reginfo section requires special handling.
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Each input section is 24 bytes, and the final output section must
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also be 24 bytes. We handle this by clobbering all but the first
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input section size to 0. The .reginfo section is handled
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specially by the backend code anyhow. */
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{
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boolean found = false;
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LANG_FOR_EACH_INPUT_STATEMENT (is)
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{
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asection *s;
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if (is->just_syms_flag)
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continue;
|
|
|
|
s = bfd_get_section_by_name (is->the_bfd, ".reginfo");
|
|
if (s == NULL)
|
|
continue;
|
|
|
|
if (! found)
|
|
{
|
|
found = true;
|
|
continue;
|
|
}
|
|
|
|
s->_raw_size = 0;
|
|
s->_cooked_size = 0;
|
|
}
|
|
}
|
|
#endif
|
|
}
|
|
|
|
/* This is called by the before_allocation routine via
|
|
lang_for_each_statement. It locates any assignment statements, and
|
|
tells the ELF backend about them, in case they are assignments to
|
|
symbols which are referred to by dynamic objects. */
|
|
|
|
static void
|
|
gldelf32ebmip_find_statement_assignment (s)
|
|
lang_statement_union_type *s;
|
|
{
|
|
if (s->header.type == lang_assignment_statement_enum)
|
|
gldelf32ebmip_find_exp_assignment (s->assignment_statement.exp);
|
|
}
|
|
|
|
/* Look through an expression for an assignment statement. */
|
|
|
|
static void
|
|
gldelf32ebmip_find_exp_assignment (exp)
|
|
etree_type *exp;
|
|
{
|
|
struct bfd_link_hash_entry *h;
|
|
|
|
switch (exp->type.node_class)
|
|
{
|
|
case etree_provide:
|
|
h = bfd_link_hash_lookup (link_info.hash, exp->assign.dst,
|
|
false, false, false);
|
|
if (h == NULL)
|
|
break;
|
|
|
|
/* We call record_link_assignment even if the symbol is defined.
|
|
This is because if it is defined by a dynamic object, we
|
|
actually want to use the value defined by the linker script,
|
|
not the value from the dynamic object (because we are setting
|
|
symbols like etext). If the symbol is defined by a regular
|
|
object, then, as it happens, calling record_link_assignment
|
|
will do no harm. */
|
|
|
|
/* Fall through. */
|
|
case etree_assign:
|
|
if (strcmp (exp->assign.dst, ".") != 0)
|
|
{
|
|
if (! (bfd_elf32_record_link_assignment
|
|
(output_bfd, &link_info, exp->assign.dst,
|
|
exp->type.node_class == etree_provide ? true : false)))
|
|
einfo ("%P%F: failed to record assignment to %s: %E\n",
|
|
exp->assign.dst);
|
|
}
|
|
gldelf32ebmip_find_exp_assignment (exp->assign.src);
|
|
break;
|
|
|
|
case etree_binary:
|
|
gldelf32ebmip_find_exp_assignment (exp->binary.lhs);
|
|
gldelf32ebmip_find_exp_assignment (exp->binary.rhs);
|
|
break;
|
|
|
|
case etree_trinary:
|
|
gldelf32ebmip_find_exp_assignment (exp->trinary.cond);
|
|
gldelf32ebmip_find_exp_assignment (exp->trinary.lhs);
|
|
gldelf32ebmip_find_exp_assignment (exp->trinary.rhs);
|
|
break;
|
|
|
|
case etree_unary:
|
|
gldelf32ebmip_find_exp_assignment (exp->unary.child);
|
|
break;
|
|
|
|
default:
|
|
break;
|
|
}
|
|
}
|
|
|
|
/* Place an orphan section. We use this to put random SHF_ALLOC
|
|
sections in the right segment. */
|
|
|
|
static asection *hold_section;
|
|
static lang_output_section_statement_type *hold_use;
|
|
static lang_output_section_statement_type *hold_text;
|
|
static lang_output_section_statement_type *hold_rodata;
|
|
static lang_output_section_statement_type *hold_data;
|
|
static lang_output_section_statement_type *hold_bss;
|
|
static lang_output_section_statement_type *hold_rel;
|
|
|
|
/*ARGSUSED*/
|
|
static boolean
|
|
gldelf32ebmip_place_orphan (file, s)
|
|
lang_input_statement_type *file;
|
|
asection *s;
|
|
{
|
|
lang_output_section_statement_type *place;
|
|
asection *snew, **pps;
|
|
lang_statement_list_type *old;
|
|
lang_statement_list_type add;
|
|
etree_type *address;
|
|
const char *secname, *ps;
|
|
lang_output_section_statement_type *os;
|
|
|
|
if ((s->flags & SEC_ALLOC) == 0)
|
|
return false;
|
|
|
|
/* Look through the script to see where to place this section. */
|
|
hold_section = s;
|
|
hold_use = NULL;
|
|
lang_for_each_statement (gldelf32ebmip_place_section);
|
|
|
|
if (hold_use != NULL)
|
|
{
|
|
/* We have already placed a section with this name. */
|
|
wild_doit (&hold_use->children, s, hold_use, file);
|
|
return true;
|
|
}
|
|
|
|
secname = bfd_get_section_name (s->owner, s);
|
|
|
|
/* If this is a final link, then always put .gnu.warning.SYMBOL
|
|
sections into the .text section to get them out of the way. */
|
|
if (! link_info.shared
|
|
&& ! link_info.relocateable
|
|
&& strncmp (secname, ".gnu.warning.", sizeof ".gnu.warning." - 1) == 0
|
|
&& hold_text != NULL)
|
|
{
|
|
wild_doit (&hold_text->children, s, hold_text, file);
|
|
return true;
|
|
}
|
|
|
|
/* Decide which segment the section should go in based on the
|
|
section name and section flags. */
|
|
place = NULL;
|
|
if ((s->flags & SEC_HAS_CONTENTS) == 0
|
|
&& hold_bss != NULL)
|
|
place = hold_bss;
|
|
else if ((s->flags & SEC_READONLY) == 0
|
|
&& hold_data != NULL)
|
|
place = hold_data;
|
|
else if (strncmp (secname, ".rel", 4) == 0
|
|
&& hold_rel != NULL)
|
|
place = hold_rel;
|
|
else if ((s->flags & SEC_CODE) == 0
|
|
&& (s->flags & SEC_READONLY) != 0
|
|
&& hold_rodata != NULL)
|
|
place = hold_rodata;
|
|
else if ((s->flags & SEC_READONLY) != 0
|
|
&& hold_text != NULL)
|
|
place = hold_text;
|
|
if (place == NULL)
|
|
return false;
|
|
|
|
/* Create the section in the output file, and put it in the right
|
|
place. This shuffling is to make the output file look neater. */
|
|
snew = bfd_make_section (output_bfd, secname);
|
|
if (snew == NULL)
|
|
einfo ("%P%F: output format %s cannot represent section called %s\n",
|
|
output_bfd->xvec->name, secname);
|
|
if (place->bfd_section != NULL)
|
|
{
|
|
for (pps = &output_bfd->sections; *pps != snew; pps = &(*pps)->next)
|
|
;
|
|
*pps = snew->next;
|
|
snew->next = place->bfd_section->next;
|
|
place->bfd_section->next = snew;
|
|
}
|
|
|
|
/* Start building a list of statements for this section. */
|
|
old = stat_ptr;
|
|
stat_ptr = &add;
|
|
lang_list_init (stat_ptr);
|
|
|
|
/* If the name of the section is representable in C, then create
|
|
symbols to mark the start and the end of the section. */
|
|
for (ps = secname; *ps != '\0'; ps++)
|
|
if (! isalnum (*ps) && *ps != '_')
|
|
break;
|
|
if (*ps == '\0' && config.build_constructors)
|
|
{
|
|
char *symname;
|
|
|
|
symname = (char *) xmalloc (ps - secname + sizeof "__start_");
|
|
sprintf (symname, "__start_%s", secname);
|
|
lang_add_assignment (exp_assop ('=', symname,
|
|
exp_unop (ALIGN_K,
|
|
exp_intop ((bfd_vma) 1
|
|
<< s->alignment_power))));
|
|
}
|
|
|
|
if (! link_info.relocateable)
|
|
address = NULL;
|
|
else
|
|
address = exp_intop ((bfd_vma) 0);
|
|
|
|
lang_enter_output_section_statement (secname, address, 0,
|
|
(bfd_vma) 0,
|
|
(etree_type *) NULL,
|
|
(etree_type *) NULL,
|
|
(etree_type *) NULL);
|
|
|
|
os = lang_output_section_statement_lookup (secname);
|
|
wild_doit (&os->children, s, os, file);
|
|
|
|
lang_leave_output_section_statement ((bfd_vma) 0, "*default*");
|
|
stat_ptr = &add;
|
|
|
|
if (*ps == '\0' && config.build_constructors)
|
|
{
|
|
char *symname;
|
|
|
|
symname = (char *) xmalloc (ps - secname + sizeof "__stop_");
|
|
sprintf (symname, "__stop_%s", secname);
|
|
lang_add_assignment (exp_assop ('=', symname,
|
|
exp_nameop (NAME, ".")));
|
|
}
|
|
|
|
/* Now stick the new statement list right after PLACE. */
|
|
*add.tail = place->header.next;
|
|
place->header.next = add.head;
|
|
|
|
stat_ptr = old;
|
|
|
|
return true;
|
|
}
|
|
|
|
static void
|
|
gldelf32ebmip_place_section (s)
|
|
lang_statement_union_type *s;
|
|
{
|
|
lang_output_section_statement_type *os;
|
|
|
|
if (s->header.type != lang_output_section_statement_enum)
|
|
return;
|
|
|
|
os = &s->output_section_statement;
|
|
|
|
if (strcmp (os->name, hold_section->name) == 0)
|
|
hold_use = os;
|
|
|
|
if (strcmp (os->name, ".text") == 0)
|
|
hold_text = os;
|
|
else if (strcmp (os->name, ".rodata") == 0)
|
|
hold_rodata = os;
|
|
else if (strcmp (os->name, ".data") == 0)
|
|
hold_data = os;
|
|
else if (strcmp (os->name, ".bss") == 0)
|
|
hold_bss = os;
|
|
else if (hold_rel == NULL
|
|
&& os->bfd_section != NULL
|
|
&& strncmp (os->name, ".rel", 4) == 0)
|
|
hold_rel = os;
|
|
}
|
|
|
|
static char *
|
|
gldelf32ebmip_get_script(isfile)
|
|
int *isfile;
|
|
{
|
|
*isfile = 0;
|
|
|
|
if (link_info.relocateable == true && config.build_constructors == true)
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
/* For some reason, the Solaris linker makes bad executables\n\
|
|
if gld -r is used and the intermediate file has sections starting\n\
|
|
at non-zero addresses. Could be a Solaris ld bug, could be a GNU ld\n\
|
|
bug. But for now assigning the zero vmas works. */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
.interp 0 : { *(.interp) }\n\
|
|
.reginfo 0 : { *(.reginfo) }\n\
|
|
.dynamic 0 : { *(.dynamic) }\n\
|
|
.dynstr 0 : { *(.dynstr) }\n\
|
|
.dynsym 0 : { *(.dynsym) }\n\
|
|
.hash 0 : { *(.hash) }\n\
|
|
.rel.text 0 : { *(.rel.text) }\n\
|
|
.rela.text 0 : { *(.rela.text) }\n\
|
|
.rel.data 0 : { *(.rel.data) }\n\
|
|
.rela.data 0 : { *(.rela.data) }\n\
|
|
.rel.rodata 0 : { *(.rel.rodata) }\n\
|
|
.rela.rodata 0 : { *(.rela.rodata) }\n\
|
|
.rel.got 0 : { *(.rel.got) }\n\
|
|
.rela.got 0 : { *(.rela.got) }\n\
|
|
.rel.ctors 0 : { *(.rel.ctors) }\n\
|
|
.rela.ctors 0 : { *(.rela.ctors) }\n\
|
|
.rel.dtors 0 : { *(.rel.dtors) }\n\
|
|
.rela.dtors 0 : { *(.rela.dtors) }\n\
|
|
.rel.init 0 : { *(.rel.init) }\n\
|
|
.rela.init 0 : { *(.rela.init) }\n\
|
|
.rel.fini 0 : { *(.rel.fini) }\n\
|
|
.rela.fini 0 : { *(.rela.fini) }\n\
|
|
.rel.bss 0 : { *(.rel.bss) }\n\
|
|
.rela.bss 0 : { *(.rela.bss) }\n\
|
|
.rel.plt 0 : { *(.rel.plt) }\n\
|
|
.rela.plt 0 : { *(.rela.plt) }\n\
|
|
.rodata 0 : { *(.rodata) }\n\
|
|
.rodata1 0 : { *(.rodata1) }\n\
|
|
.init 0 : { *(.init) } =0\n\
|
|
.text 0 :\n\
|
|
{\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
.fini 0 : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
.data 0 :\n\
|
|
{\n\
|
|
*(.data)\n\
|
|
CONSTRUCTORS\n\
|
|
}\n\
|
|
.data1 0 : { *(.data1) }\n\
|
|
.ctors 0 : { *(.ctors) }\n\
|
|
.dtors 0 : { *(.dtors) }\n\
|
|
.got 0 :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata 0 : { *(.sdata) }\n\
|
|
.sbss 0 : { *(.sbss) *(.scommon) }\n\
|
|
.bss 0 :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
else if (link_info.relocateable == true)
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
/* For some reason, the Solaris linker makes bad executables\n\
|
|
if gld -r is used and the intermediate file has sections starting\n\
|
|
at non-zero addresses. Could be a Solaris ld bug, could be a GNU ld\n\
|
|
bug. But for now assigning the zero vmas works. */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
.interp 0 : { *(.interp) }\n\
|
|
.reginfo 0 : { *(.reginfo) }\n\
|
|
.dynamic 0 : { *(.dynamic) }\n\
|
|
.dynstr 0 : { *(.dynstr) }\n\
|
|
.dynsym 0 : { *(.dynsym) }\n\
|
|
.hash 0 : { *(.hash) }\n\
|
|
.rel.text 0 : { *(.rel.text) }\n\
|
|
.rela.text 0 : { *(.rela.text) }\n\
|
|
.rel.data 0 : { *(.rel.data) }\n\
|
|
.rela.data 0 : { *(.rela.data) }\n\
|
|
.rel.rodata 0 : { *(.rel.rodata) }\n\
|
|
.rela.rodata 0 : { *(.rela.rodata) }\n\
|
|
.rel.got 0 : { *(.rel.got) }\n\
|
|
.rela.got 0 : { *(.rela.got) }\n\
|
|
.rel.ctors 0 : { *(.rel.ctors) }\n\
|
|
.rela.ctors 0 : { *(.rela.ctors) }\n\
|
|
.rel.dtors 0 : { *(.rel.dtors) }\n\
|
|
.rela.dtors 0 : { *(.rela.dtors) }\n\
|
|
.rel.init 0 : { *(.rel.init) }\n\
|
|
.rela.init 0 : { *(.rela.init) }\n\
|
|
.rel.fini 0 : { *(.rel.fini) }\n\
|
|
.rela.fini 0 : { *(.rela.fini) }\n\
|
|
.rel.bss 0 : { *(.rel.bss) }\n\
|
|
.rela.bss 0 : { *(.rela.bss) }\n\
|
|
.rel.plt 0 : { *(.rel.plt) }\n\
|
|
.rela.plt 0 : { *(.rela.plt) }\n\
|
|
.rodata 0 : { *(.rodata) }\n\
|
|
.rodata1 0 : { *(.rodata1) }\n\
|
|
.init 0 : { *(.init) } =0\n\
|
|
.text 0 :\n\
|
|
{\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
.fini 0 : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
.data 0 :\n\
|
|
{\n\
|
|
*(.data)\n\
|
|
}\n\
|
|
.data1 0 : { *(.data1) }\n\
|
|
.ctors 0 : { *(.ctors) }\n\
|
|
.dtors 0 : { *(.dtors) }\n\
|
|
.got 0 :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata 0 : { *(.sdata) }\n\
|
|
.sbss 0 : { *(.sbss) *(.scommon) }\n\
|
|
.bss 0 :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
else if (!config.text_read_only)
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
SEARCH_DIR(/usr/local/mips-elf/lib);\n\
|
|
/* Do we need any of these for elf?\n\
|
|
__DYNAMIC = 0; */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
. = 0x0400000;\n\
|
|
.interp : { *(.interp) }\n\
|
|
.reginfo : { *(.reginfo) }\n\
|
|
.dynamic : { *(.dynamic) }\n\
|
|
.dynstr : { *(.dynstr) }\n\
|
|
.dynsym : { *(.dynsym) }\n\
|
|
.hash : { *(.hash) }\n\
|
|
.rel.text : { *(.rel.text) }\n\
|
|
.rela.text : { *(.rela.text) }\n\
|
|
.rel.data : { *(.rel.data) }\n\
|
|
.rela.data : { *(.rela.data) }\n\
|
|
.rel.rodata : { *(.rel.rodata) }\n\
|
|
.rela.rodata : { *(.rela.rodata) }\n\
|
|
.rel.got : { *(.rel.got) }\n\
|
|
.rela.got : { *(.rela.got) }\n\
|
|
.rel.ctors : { *(.rel.ctors) }\n\
|
|
.rela.ctors : { *(.rela.ctors) }\n\
|
|
.rel.dtors : { *(.rel.dtors) }\n\
|
|
.rela.dtors : { *(.rela.dtors) }\n\
|
|
.rel.init : { *(.rel.init) }\n\
|
|
.rela.init : { *(.rela.init) }\n\
|
|
.rel.fini : { *(.rel.fini) }\n\
|
|
.rela.fini : { *(.rela.fini) }\n\
|
|
.rel.bss : { *(.rel.bss) }\n\
|
|
.rela.bss : { *(.rela.bss) }\n\
|
|
.rel.plt : { *(.rel.plt) }\n\
|
|
.rela.plt : { *(.rela.plt) }\n\
|
|
.rodata : { *(.rodata) }\n\
|
|
.rodata1 : { *(.rodata1) }\n\
|
|
.init : { *(.init) } =0\n\
|
|
.text :\n\
|
|
{\n\
|
|
_ftext = . ;\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
_etext = .;\n\
|
|
PROVIDE (etext = .);\n\
|
|
.fini : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
. = .;\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
. += . - 0x0400000;\n\
|
|
.data :\n\
|
|
{\n\
|
|
_fdata = . ;\n\
|
|
*(.data)\n\
|
|
CONSTRUCTORS\n\
|
|
}\n\
|
|
.data1 : { *(.data1) }\n\
|
|
.ctors : { *(.ctors) }\n\
|
|
.dtors : { *(.dtors) }\n\
|
|
_gp = ALIGN(16) + 0x7ff0;\n\
|
|
.got :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata : { *(.sdata) }\n\
|
|
.lit8 : { *(.lit8) }\n\
|
|
.lit4 : { *(.lit4) }\n\
|
|
_edata = .;\n\
|
|
PROVIDE (edata = .);\n\
|
|
__bss_start = .;\n\
|
|
_fbss = .;\n\
|
|
.sbss : { *(.sbss) *(.scommon) }\n\
|
|
.bss :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
_end = . ;\n\
|
|
PROVIDE (end = .);\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
else if (!config.magic_demand_paged)
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
SEARCH_DIR(/usr/local/mips-elf/lib);\n\
|
|
/* Do we need any of these for elf?\n\
|
|
__DYNAMIC = 0; */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
. = 0x0400000;\n\
|
|
.interp : { *(.interp) }\n\
|
|
.reginfo : { *(.reginfo) }\n\
|
|
.dynamic : { *(.dynamic) }\n\
|
|
.dynstr : { *(.dynstr) }\n\
|
|
.dynsym : { *(.dynsym) }\n\
|
|
.hash : { *(.hash) }\n\
|
|
.rel.text : { *(.rel.text) }\n\
|
|
.rela.text : { *(.rela.text) }\n\
|
|
.rel.data : { *(.rel.data) }\n\
|
|
.rela.data : { *(.rela.data) }\n\
|
|
.rel.rodata : { *(.rel.rodata) }\n\
|
|
.rela.rodata : { *(.rela.rodata) }\n\
|
|
.rel.got : { *(.rel.got) }\n\
|
|
.rela.got : { *(.rela.got) }\n\
|
|
.rel.ctors : { *(.rel.ctors) }\n\
|
|
.rela.ctors : { *(.rela.ctors) }\n\
|
|
.rel.dtors : { *(.rel.dtors) }\n\
|
|
.rela.dtors : { *(.rela.dtors) }\n\
|
|
.rel.init : { *(.rel.init) }\n\
|
|
.rela.init : { *(.rela.init) }\n\
|
|
.rel.fini : { *(.rel.fini) }\n\
|
|
.rela.fini : { *(.rela.fini) }\n\
|
|
.rel.bss : { *(.rel.bss) }\n\
|
|
.rela.bss : { *(.rela.bss) }\n\
|
|
.rel.plt : { *(.rel.plt) }\n\
|
|
.rela.plt : { *(.rela.plt) }\n\
|
|
.rodata : { *(.rodata) }\n\
|
|
.rodata1 : { *(.rodata1) }\n\
|
|
.init : { *(.init) } =0\n\
|
|
.text :\n\
|
|
{\n\
|
|
_ftext = . ;\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
_etext = .;\n\
|
|
PROVIDE (etext = .);\n\
|
|
.fini : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
. = 0x10000000;\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
. += 0x10000000 - 0x0400000;\n\
|
|
.data :\n\
|
|
{\n\
|
|
_fdata = . ;\n\
|
|
*(.data)\n\
|
|
CONSTRUCTORS\n\
|
|
}\n\
|
|
.data1 : { *(.data1) }\n\
|
|
.ctors : { *(.ctors) }\n\
|
|
.dtors : { *(.dtors) }\n\
|
|
_gp = ALIGN(16) + 0x7ff0;\n\
|
|
.got :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata : { *(.sdata) }\n\
|
|
.lit8 : { *(.lit8) }\n\
|
|
.lit4 : { *(.lit4) }\n\
|
|
_edata = .;\n\
|
|
PROVIDE (edata = .);\n\
|
|
__bss_start = .;\n\
|
|
_fbss = .;\n\
|
|
.sbss : { *(.sbss) *(.scommon) }\n\
|
|
.bss :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
_end = . ;\n\
|
|
PROVIDE (end = .);\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
else if (link_info.shared)
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
SEARCH_DIR(/usr/local/mips-elf/lib);\n\
|
|
/* Do we need any of these for elf?\n\
|
|
__DYNAMIC = 0; */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
. = 0x5ffe0000 + SIZEOF_HEADERS;\n\
|
|
.reginfo : { *(.reginfo) }\n\
|
|
.dynamic : { *(.dynamic) }\n\
|
|
.dynstr : { *(.dynstr) }\n\
|
|
.dynsym : { *(.dynsym) }\n\
|
|
.hash : { *(.hash) }\n\
|
|
.rel.text : { *(.rel.text) }\n\
|
|
.rela.text : { *(.rela.text) }\n\
|
|
.rel.data : { *(.rel.data) }\n\
|
|
.rela.data : { *(.rela.data) }\n\
|
|
.rel.rodata : { *(.rel.rodata) }\n\
|
|
.rela.rodata : { *(.rela.rodata) }\n\
|
|
.rel.got : { *(.rel.got) }\n\
|
|
.rela.got : { *(.rela.got) }\n\
|
|
.rel.ctors : { *(.rel.ctors) }\n\
|
|
.rela.ctors : { *(.rela.ctors) }\n\
|
|
.rel.dtors : { *(.rel.dtors) }\n\
|
|
.rela.dtors : { *(.rela.dtors) }\n\
|
|
.rel.init : { *(.rel.init) }\n\
|
|
.rela.init : { *(.rela.init) }\n\
|
|
.rel.fini : { *(.rel.fini) }\n\
|
|
.rela.fini : { *(.rela.fini) }\n\
|
|
.rel.bss : { *(.rel.bss) }\n\
|
|
.rela.bss : { *(.rela.bss) }\n\
|
|
.rel.plt : { *(.rel.plt) }\n\
|
|
.rela.plt : { *(.rela.plt) }\n\
|
|
.rodata : { *(.rodata) }\n\
|
|
.rodata1 : { *(.rodata1) }\n\
|
|
.init : { *(.init) } =0\n\
|
|
.text :\n\
|
|
{\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
.fini : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
. = 0x10000000;\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
. += 0x10000;\n\
|
|
.data :\n\
|
|
{\n\
|
|
*(.data)\n\
|
|
CONSTRUCTORS\n\
|
|
}\n\
|
|
.data1 : { *(.data1) }\n\
|
|
.ctors : { *(.ctors) }\n\
|
|
.dtors : { *(.dtors) }\n\
|
|
_gp = ALIGN(16) + 0x7ff0;\n\
|
|
.got :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata : { *(.sdata) }\n\
|
|
.lit8 : { *(.lit8) }\n\
|
|
.lit4 : { *(.lit4) }\n\
|
|
.sbss : { *(.sbss) *(.scommon) }\n\
|
|
.bss :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
else
|
|
return "OUTPUT_FORMAT(\"elf32-bigmips\", \"elf32-bigmips\",\n\
|
|
\"elf32-littlemips\")\n\
|
|
OUTPUT_ARCH(mips)\n\
|
|
ENTRY(_start)\n\
|
|
SEARCH_DIR(/usr/local/mips-elf/lib);\n\
|
|
/* Do we need any of these for elf?\n\
|
|
__DYNAMIC = 0; */\n\
|
|
SECTIONS\n\
|
|
{\n\
|
|
/* Read-only sections, merged into text segment: */\n\
|
|
. = 0x0400000;\n\
|
|
.interp : { *(.interp) }\n\
|
|
.reginfo : { *(.reginfo) }\n\
|
|
.dynamic : { *(.dynamic) }\n\
|
|
.dynstr : { *(.dynstr) }\n\
|
|
.dynsym : { *(.dynsym) }\n\
|
|
.hash : { *(.hash) }\n\
|
|
.rel.text : { *(.rel.text) }\n\
|
|
.rela.text : { *(.rela.text) }\n\
|
|
.rel.data : { *(.rel.data) }\n\
|
|
.rela.data : { *(.rela.data) }\n\
|
|
.rel.rodata : { *(.rel.rodata) }\n\
|
|
.rela.rodata : { *(.rela.rodata) }\n\
|
|
.rel.got : { *(.rel.got) }\n\
|
|
.rela.got : { *(.rela.got) }\n\
|
|
.rel.ctors : { *(.rel.ctors) }\n\
|
|
.rela.ctors : { *(.rela.ctors) }\n\
|
|
.rel.dtors : { *(.rel.dtors) }\n\
|
|
.rela.dtors : { *(.rela.dtors) }\n\
|
|
.rel.init : { *(.rel.init) }\n\
|
|
.rela.init : { *(.rela.init) }\n\
|
|
.rel.fini : { *(.rel.fini) }\n\
|
|
.rela.fini : { *(.rela.fini) }\n\
|
|
.rel.bss : { *(.rel.bss) }\n\
|
|
.rela.bss : { *(.rela.bss) }\n\
|
|
.rel.plt : { *(.rel.plt) }\n\
|
|
.rela.plt : { *(.rela.plt) }\n\
|
|
.rodata : { *(.rodata) }\n\
|
|
.rodata1 : { *(.rodata1) }\n\
|
|
.init : { *(.init) } =0\n\
|
|
.text :\n\
|
|
{\n\
|
|
_ftext = . ;\n\
|
|
*(.text)\n\
|
|
*(.stub)\n\
|
|
/* .gnu.warning sections are handled specially by elf32.em. */\n\
|
|
*(.gnu.warning)\n\
|
|
} =0\n\
|
|
_etext = .;\n\
|
|
PROVIDE (etext = .);\n\
|
|
.fini : { *(.fini) } =0\n\
|
|
/* Adjust the address for the data segment. We want to adjust up to\n\
|
|
the same address within the page on the next page up. It would\n\
|
|
be more correct to do this:\n\
|
|
. = 0x10000000;\n\
|
|
The current expression does not correctly handle the case of a\n\
|
|
text segment ending precisely at the end of a page; it causes the\n\
|
|
data segment to skip a page. The above expression does not have\n\
|
|
this problem, but it will currently (2/95) cause BFD to allocate\n\
|
|
a single segment, combining both text and data, for this case.\n\
|
|
This will prevent the text segment from being shared among\n\
|
|
multiple executions of the program; I think that is more\n\
|
|
important than losing a page of the virtual address space (note\n\
|
|
that no actual memory is lost; the page which is skipped can not\n\
|
|
be referenced). */\n\
|
|
. += 0x10000000 - 0x0400000;\n\
|
|
.data :\n\
|
|
{\n\
|
|
_fdata = . ;\n\
|
|
*(.data)\n\
|
|
CONSTRUCTORS\n\
|
|
}\n\
|
|
.data1 : { *(.data1) }\n\
|
|
.ctors : { *(.ctors) }\n\
|
|
.dtors : { *(.dtors) }\n\
|
|
_gp = ALIGN(16) + 0x7ff0;\n\
|
|
.got :\n\
|
|
{\n\
|
|
*(.got.plt) *(.got)\n\
|
|
}\n\
|
|
/* We want the small data sections together, so single-instruction offsets\n\
|
|
can access them all, and initialized data all before uninitialized, so\n\
|
|
we can shorten the on-disk segment size. */\n\
|
|
.sdata : { *(.sdata) }\n\
|
|
.lit8 : { *(.lit8) }\n\
|
|
.lit4 : { *(.lit4) }\n\
|
|
_edata = .;\n\
|
|
PROVIDE (edata = .);\n\
|
|
__bss_start = .;\n\
|
|
_fbss = .;\n\
|
|
.sbss : { *(.sbss) *(.scommon) }\n\
|
|
.bss :\n\
|
|
{\n\
|
|
*(.dynbss)\n\
|
|
*(.bss)\n\
|
|
*(COMMON)\n\
|
|
}\n\
|
|
_end = . ;\n\
|
|
PROVIDE (end = .);\n\
|
|
/* These are needed for ELF backends which have not yet been\n\
|
|
converted to the new style linker. */\n\
|
|
.stab 0 : { *(.stab) }\n\
|
|
.stabstr 0 : { *(.stabstr) }\n\
|
|
/* DWARF debug sections.\n\
|
|
Symbols in the .debug DWARF section are relative to the beginning of the\n\
|
|
section so we begin .debug at 0. It's not clear yet what needs to happen\n\
|
|
for the others. */\n\
|
|
.debug 0 : { *(.debug) }\n\
|
|
.debug_srcinfo 0 : { *(.debug_srcinfo) }\n\
|
|
.debug_aranges 0 : { *(.debug_aranges) }\n\
|
|
.debug_pubnames 0 : { *(.debug_pubnames) }\n\
|
|
.debug_sfnames 0 : { *(.debug_sfnames) }\n\
|
|
.line 0 : { *(.line) }\n\
|
|
/* These must appear regardless of . */\n\
|
|
.gptab.sdata : { *(.gptab.data) *(.gptab.sdata) }\n\
|
|
.gptab.sbss : { *(.gptab.bss) *(.gptab.sbss) }\n\
|
|
}\n\n";
|
|
}
|
|
|
|
struct ld_emulation_xfer_struct ld_elf32ebmip_emulation =
|
|
{
|
|
gldelf32ebmip_before_parse,
|
|
syslib_default,
|
|
hll_default,
|
|
after_parse_default,
|
|
gldelf32ebmip_after_open,
|
|
after_allocation_default,
|
|
set_output_arch_default,
|
|
ldemul_default_target,
|
|
gldelf32ebmip_before_allocation,
|
|
gldelf32ebmip_get_script,
|
|
"elf32ebmip",
|
|
"elf32-bigmips",
|
|
NULL,
|
|
NULL,
|
|
gldelf32ebmip_open_dynamic_archive,
|
|
gldelf32ebmip_place_orphan
|
|
};
|