| blob | 5aabeeb1cdc416cb17432a8d734bb2a788187264 |
1 /* ELF executable support for BFD.
3 Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001,
4 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011, 2012
5 Free Software Foundation, Inc.
7 This file is part of BFD, the Binary File Descriptor library.
9 This program is free software; you can redistribute it and/or modify
10 it under the terms of the GNU General Public License as published by
11 the Free Software Foundation; either version 3 of the License, or
12 (at your option) any later version.
14 This program is distributed in the hope that it will be useful,
15 but WITHOUT ANY WARRANTY; without even the implied warranty of
16 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
17 GNU General Public License for more details.
19 You should have received a copy of the GNU General Public License
20 along with this program; if not, write to the Free Software
21 Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston,
22 MA 02110-1301, USA. */
25 /*
26 SECTION
27 ELF backends
29 BFD support for ELF formats is being worked on.
30 Currently, the best supported back ends are for sparc and i386
31 (running svr4 or Solaris 2).
33 Documentation of the internals of the support code still needs
34 to be written. The code is changing quickly enough that we
35 haven't bothered yet. */
37 /* For sparc64-cross-sparc32. */
38 #define _SYSCALL32
43 #define ARCH_SIZE 0
48 #ifdef CORE_HEADER
49 #include CORE_HEADER
50 #endif
58 file_ptr offset);
60 /* Swap version information in and out. The version information is
61 currently size independent. If that ever changes, this code will
62 need to move into elfcode.h. */
64 /* Swap in a Verdef structure. */
66 void
70 {
78 }
80 /* Swap out a Verdef structure. */
82 void
86 {
94 }
96 /* Swap in a Verdaux structure. */
98 void
102 {
105 }
107 /* Swap out a Verdaux structure. */
109 void
113 {
116 }
118 /* Swap in a Verneed structure. */
120 void
124 {
130 }
132 /* Swap out a Verneed structure. */
134 void
138 {
144 }
146 /* Swap in a Vernaux structure. */
148 void
152 {
158 }
160 /* Swap out a Vernaux structure. */
162 void
166 {
172 }
174 /* Swap in a Versym structure. */
176 void
180 {
182 }
184 /* Swap out a Versym structure. */
186 void
190 {
192 }
194 /* Standard ELF hash function. Do not change this function; you will
195 cause invalid hash tables to be generated. */
197 unsigned long
199 {
206 {
209 {
211 /* The ELF ABI says `h &= ~g', but this is equivalent in
212 this case and on some machines one insn instead of two. */
214 }
215 }
217 }
219 /* DT_GNU_HASH hash function. Do not change this function; you will
220 cause invalid hash tables to be generated. */
222 unsigned long
224 {
232 }
234 /* Create a tdata field OBJECT_SIZE bytes in length, zeroed out and with
235 the object_id field of an elf_obj_tdata field set to OBJECT_ID. */
236 bfd_boolean
240 {
249 }
252 bfd_boolean
254 {
258 }
260 bfd_boolean
262 {
263 /* I think this can be done just like an object file. */
265 }
269 {
272 file_ptr offset;
273 bfd_size_type shstrtabsize;
283 {
284 /* No cached one, attempt to read, and cache what we read. */
288 /* Allocate and clear an extra byte at the end, to prevent crashes
289 in case the string table is not terminated. */
295 {
299 /* Once we've failed to read it, make sure we don't keep
300 trying. Otherwise, we'll keep allocating space for
301 the string table over and over. */
303 }
304 else
307 }
309 }
315 {
331 {
340 }
343 }
345 /* Read and convert symbols to internal format.
346 SYMCOUNT specifies the number of symbols to read, starting from
347 symbol SYMOFFSET. If any of INTSYM_BUF, EXTSYM_BUF or EXTSHNDX_BUF
348 are non-NULL, they are used to store the internal symbols, external
349 symbols, and symbol section index extensions, respectively.
350 Returns a pointer to the internal symbol buffer (malloced if necessary)
351 or NULL if there were no symbols or some kind of problem. */
353 Elf_Internal_Sym *
361 {
372 bfd_size_type amt;
373 file_ptr pos;
381 /* Normal syms might have section extension entries. */
386 /* Read the symbols. */
395 {
398 }
402 {
405 }
409 else
410 {
414 {
418 }
422 {
425 }
426 }
429 {
435 }
437 /* Convert the symbols to internal form. */
444 {
453 }
455 out:
462 }
464 /* Look up a symbol name. */
470 {
476 /* Check for a bogus st_shndx to avoid crashing. */
478 {
481 }
490 }
492 /* Elf_Internal_Shdr->contents is an array of these for SHT_GROUP
493 sections. The first element is the flags, the rest are section
494 pointers. */
501 /* Return the name of the group signature symbol. Why isn't the
502 signature just a string? */
506 {
509 Elf_External_Sym_Shndx eshndx;
510 Elf_Internal_Sym isym;
512 /* First we need to ensure the symbol table is available. Make sure
513 that it is a symbol table section. */
521 /* Go read the symbol. */
528 }
530 /* Set next_in_group list pointer, and group name for NEWSECT. */
532 static bfd_boolean
534 {
537 /* If num_group is zero, read in all SHT_GROUP sections. The count
538 is set to -1 if there are no SHT_GROUP sections. */
540 {
543 /* First count the number of groups. If we have a SHT_GROUP
544 section with just a flag word (ie. sh_size is 4), ignore it. */
548 #define IS_VALID_GROUP_SECTION_HEADER(shdr) \
549 ( (shdr)->sh_type == SHT_GROUP \
550 && (shdr)->sh_size >= (2 * GRP_ENTRY_SIZE) \
551 && (shdr)->sh_entsize == GRP_ENTRY_SIZE \
552 && ((shdr)->sh_size % GRP_ENTRY_SIZE) == 0)
555 {
560 }
563 {
566 }
567 else
568 {
569 /* We keep a list of elf section headers for group sections,
570 so we can find them quickly. */
571 bfd_size_type amt;
581 {
585 {
589 /* Add to list of sections. */
593 /* Read the raw contents. */
598 /* PR binutils/4110: Handle corrupt group headers. */
600 {
601 _bfd_error_handler
605 }
614 /* Translate raw contents, a flag word followed by an
615 array of elf section indices all in target byte order,
616 to the flag word followed by an array of elf section
617 pointers. */
621 {
628 {
634 }
636 {
640 }
642 }
643 }
644 }
645 }
646 }
649 {
653 {
658 /* Look through this group's sections to see if current
659 section is a member. */
662 {
665 /* We are a member of this group. Go looking through
666 other members to see if any others are linked via
667 next_in_group. */
675 {
676 /* Snarf the group name from other member, and
677 insert current section in circular list. */
681 }
682 else
683 {
691 /* Start a circular list with one element. */
693 }
695 /* If the group section has been created, point to the
696 new member. */
702 }
703 }
704 }
707 {
710 }
712 }
714 bfd_boolean
716 {
722 /* Process SHF_LINK_ORDER. */
724 {
727 {
729 /* FIXME: The old Intel compiler and old strip/objcopy may
730 not set the sh_link or sh_info fields. Hence we could
731 get the situation where elfsec is 0. */
733 {
736 bed->link_order_error_handler
739 }
740 else
741 {
745 {
748 }
750 /* PR 1991, 2008:
751 Some strip/objcopy may leave an incorrect value in
752 sh_link. We don't want to proceed. */
754 {
759 }
762 }
763 }
764 }
766 /* Process section groups. */
771 {
781 /* We won't include relocation sections in section groups in
782 output object files. We adjust the group section size here
783 so that relocatable link will work correctly when
784 relocation sections are in section group in input object
785 files. */
787 else
788 {
789 /* There are some unknown sections in the group. */
792 abfd,
800 }
801 }
803 }
805 bfd_boolean
807 {
809 }
811 /* Make a BFD section from an ELF section. We store a pointer to the
812 BFD section in the bfd_section field of the header. */
814 bfd_boolean
819 {
821 flagword flags;
835 /* Always use the real type/flags. */
853 {
857 }
865 {
870 }
880 {
881 /* The debugging sections appear to be recognized only by name,
882 not any sort of flag. Their SEC_ALLOC bits are cleared. */
883 static const struct
884 {
888 {
912 };
915 {
923 }
924 }
926 /* As a GNU extension, if the name begins with .gnu.linkonce, we
927 only link a single copy of the section. This is used to support
928 g++. g++ will emit each template expansion in its own section.
929 The symbols will be defined as weak, so that multiple definitions
930 are permitted. The GNU linker extension is to actually discard
931 all but one of the sections. */
944 /* We do not parse the PT_NOTE segments as we are interested even in the
945 separate debug info files which may have the segments offsets corrupted.
946 PT_NOTEs from the core files are currently not parsed using BFD. */
948 {
956 }
959 {
963 /* Some ELF linkers produce binaries with all the program header
964 p_paddr fields zero. If we have such a binary with more than
965 one PT_LOAD header, then leave the section lma equal to vma
966 so that we don't create sections with overlapping lma. */
978 {
983 {
987 else
988 /* We used to use the same adjustment for SEC_LOAD
989 sections, but that doesn't work if the segment
990 is packed with code from multiple VMAs.
991 Instead we calculate the section LMA based on
992 the segment LMA. It is assumed that the
993 segment will contain sections with contiguous
994 LMAs, even if the VMAs are not. */
998 /* With contiguous segments, we can't tell from file
999 offsets whether a section with zero size should
1000 be placed at the end of one segment or the
1001 beginning of the next. Decide based on vaddr. */
1006 }
1007 }
1008 }
1010 /* Compress/decompress DWARF debug sections with names: .debug_* and
1011 .zdebug_*, after the section flags is set. */
1015 {
1020 {
1021 /* Compressed section. Check if we should decompress. */
1024 }
1025 else
1026 {
1027 /* Normal section. Check if we should compress. */
1030 }
1034 {
1039 {
1044 }
1046 {
1055 }
1059 {
1064 }
1066 {
1074 }
1076 }
1079 }
1082 }
1088 };
1090 /* ELF relocs are against symbols. If we are producing relocatable
1091 output, and the reloc is against an external symbol, and nothing
1092 has given us any additional addend, the resulting reloc will also
1093 be against the same symbol. In such a case, we don't want to
1094 change anything about the way the reloc is handled, since it will
1095 all be done at final link time. Rather than put special case code
1096 into bfd_perform_relocation, all the reloc types use this howto
1097 function. It just short circuits the reloc if producing
1098 relocatable output against an external symbol. */
1100 bfd_reloc_status_type
1108 {
1113 {
1116 }
1119 }
1120 \f
1121 /* Copy the program header and other data from one object module to
1122 another. */
1124 bfd_boolean
1126 {
1139 /* Copy object attributes. */
1142 }
1146 {
1149 {
1162 }
1164 }
1166 /* Print out the program headers. */
1168 bfd_boolean
1170 {
1178 {
1184 {
1189 {
1192 }
1211 }
1212 }
1216 {
1239 {
1240 Elf_Internal_Dyn dyn;
1243 bfd_boolean stringp;
1253 {
1259 {
1262 }
1323 }
1327 {
1330 }
1331 else
1332 {
1340 }
1342 }
1346 }
1350 {
1353 }
1356 {
1361 {
1366 {
1376 }
1377 }
1378 }
1381 {
1386 {
1395 }
1396 }
1400 error_return:
1404 }
1406 /* Display ELF-specific fields of a symbol. */
1408 void
1412 bfd_print_symbol_type how)
1413 {
1416 {
1426 {
1431 bfd_vma val;
1440 {
1443 }
1446 /* Print the "other" value for a symbol. For common symbols,
1447 we've already printed the size; now print the alignment.
1448 For other symbols, we have no specified alignment, and
1449 we've printed the address; now print the size. */
1452 else
1456 /* If we have version information, print it. */
1460 {
1471 version_string =
1473 else
1474 {
1481 {
1485 {
1487 {
1490 }
1491 }
1492 }
1493 }
1497 else
1498 {
1504 }
1505 }
1507 /* If the st_other field is not zero, print it. */
1511 {
1517 /* Some other non-defined flags are also present, so print
1518 everything hex. */
1520 }
1523 }
1525 }
1526 }
1528 /* Allocate an ELF string table--force the first byte to be zero. */
1532 {
1537 {
1538 bfd_size_type loc;
1543 {
1546 }
1547 }
1549 }
1550 \f
1551 /* ELF .o/exec file reading */
1553 /* Create a new bfd section from an ELF section header. */
1555 bfd_boolean
1557 {
1575 {
1577 /* Inactive section. Throw it away. */
1595 {
1596 /* PR 10478: Accept Solaris binaries with a sh_link
1597 field set to SHN_BEFORE or SHN_AFTER. */
1599 {
1605 /* Otherwise fall through. */
1608 }
1609 }
1613 {
1616 /* The shared libraries distributed with hpux11 have a bogus
1617 sh_link field for the ".dynamic" section. Find the
1618 string table for the ".dynsym" section instead. */
1620 {
1623 }
1624 else
1625 {
1630 {
1633 {
1636 }
1637 }
1638 }
1639 }
1656 /* Sometimes a shared object will map in the symbol table. If
1657 SHF_ALLOC is set, and this is a shared object, then we also
1658 treat this section as a BFD section. We can not base the
1659 decision purely on SHF_ALLOC, because that flag is sometimes
1660 set in a relocatable object file, which would confuse the
1661 linker. */
1665 shindex))
1668 /* Go looking for SHT_SYMTAB_SHNDX too, since if there is one we
1669 can't read symbols without that section loaded as well. It
1670 is most likely specified by the next section header. */
1672 {
1677 {
1682 }
1685 {
1690 }
1693 }
1708 /* Besides being a symbol table, we also treat this as a regular
1709 section, so that objcopy can handle it. */
1726 {
1730 }
1732 {
1733 symtab_strtab:
1737 }
1739 {
1740 dynsymtab_strtab:
1744 /* We also treat this as a regular section, so that objcopy
1745 can handle it. */
1747 shindex);
1748 }
1750 /* If the string table isn't one of the above, then treat it as a
1751 regular section. We need to scan all the headers to be sure,
1752 just in case this strtab section appeared before the above. */
1754 {
1759 {
1762 {
1763 /* Prevent endless recursion on broken objects. */
1772 }
1773 }
1774 }
1779 /* *These* do a lot of work -- but build no sections! */
1780 {
1785 bfd_size_type amt;
1792 /* Check for a bogus link to avoid crashing. */
1794 {
1799 shindex);
1800 }
1802 /* For some incomprehensible reason Oracle distributes
1803 libraries for Solaris in which some of the objects have
1804 bogus sh_link fields. It would be nice if we could just
1805 reject them, but, unfortunately, some people need to use
1806 them. We scan through the section headers; if we find only
1807 one suitable symbol table, we clobber the sh_link to point
1808 to it. I hope this doesn't break anything.
1810 Don't do it on executable nor shared library. */
1814 {
1820 {
1823 {
1825 {
1828 }
1830 }
1831 }
1834 }
1836 /* Get the symbol table. */
1842 /* If this reloc section does not use the main symbol table we
1843 don't treat it as a reloc section. BFD can't adequately
1844 represent such a section, so at least for now, we don't
1845 try. We just present it as a normal section. We also
1846 can't use it as a reloc section if it points to the null
1847 section, an invalid section, another reloc section, or its
1848 sh_link points to the null section. */
1856 shindex);
1867 else
1882 /* In the section to which the relocations apply, mark whether
1883 its relocations are of the REL or RELA variety. */
1885 {
1888 }
1891 }
1919 {
1928 /* We try to keep the same section order as it comes in. */
1931 {
1937 {
1940 }
1941 }
1942 }
1946 /* Possibly an attributes section. */
1949 {
1954 }
1956 /* Check for any processor-specific section types. */
1961 {
1963 /* FIXME: How to properly handle allocated section reserved
1964 for applications? */
1969 else
1970 /* Allow sections reserved for applications. */
1972 shindex);
1973 }
1976 /* FIXME: We should handle this section. */
1982 {
1983 /* Unrecognised OS-specific sections. */
1985 /* SHF_OS_NONCONFORMING indicates that special knowledge is
1986 required to correctly process the section and the file should
1987 be rejected with an error message. */
1992 else
1993 /* Otherwise it should be processed. */
1995 }
1996 else
1997 /* FIXME: We should handle this section. */
2003 }
2006 }
2008 /* Return the local symbol specified by ABFD, R_SYMNDX. */
2010 Elf_Internal_Sym *
2014 {
2018 {
2021 Elf_External_Sym_Shndx eshndx;
2029 {
2032 }
2034 }
2037 }
2039 /* Given an ELF section number, retrieve the corresponding BFD
2040 section. */
2042 asection *
2044 {
2048 }
2051 {
2054 };
2057 {
2060 };
2063 {
2075 };
2078 {
2082 };
2085 {
2096 };
2099 {
2102 };
2105 {
2110 };
2113 {
2116 };
2119 {
2123 };
2126 {
2130 };
2133 {
2139 };
2142 {
2146 /* See struct bfd_elf_special_section declaration for the semantics of
2147 this special case where .prefix_length != strlen (.prefix). */
2150 };
2153 {
2158 };
2161 {
2167 };
2170 {
2195 special_sections_z /* 'z' */
2196 };
2202 {
2209 {
2220 {
2222 {
2229 }
2230 }
2231 else
2232 {
2239 }
2241 }
2244 }
2248 {
2253 /* See if this is one of the special sections. */
2260 {
2266 }
2281 }
2283 bfd_boolean
2285 {
2292 {
2298 }
2300 /* Indicate whether or not this section should use RELA relocations. */
2304 /* When we read a file, we don't need to set ELF section type and
2305 flags. They will be overridden in _bfd_elf_make_section_from_shdr
2306 anyway. We will set ELF section type and flags for all linker
2307 created sections. If user specifies BFD section flags, we will
2308 set ELF section type and flags based on BFD section flags in
2309 elf_fake_sections. Special handling for .init_array/.fini_array
2310 output sections since they may contain .ctors/.dtors input
2311 sections. We don't want _bfd_elf_init_private_section_data to
2312 copy ELF section type from .ctors/.dtors input sections. */
2315 {
2322 {
2325 }
2326 }
2329 }
2331 /* Create a new bfd section from an ELF program header.
2333 Since program segments have no names, we generate a synthetic name
2334 of the form segment<NUM>, where NUM is generally the index in the
2335 program header table. For segments that are split (see below) we
2336 generate the names segment<NUM>a and segment<NUM>b.
2338 Note that some program segments may have a file size that is different than
2339 (less than) the memory size. All this means is that at execution the
2340 system must allocate the amount of memory specified by the memory size,
2341 but only initialize it with the first "file size" bytes read from the
2342 file. This would occur for example, with program segments consisting
2343 of combined data+bss.
2345 To handle the above situation, this routine generates TWO bfd sections
2346 for the single program segment. The first has the length specified by
2347 the file size of the segment, and the second has the length specified
2348 by the difference between the two sizes. In effect, the segment is split
2349 into its initialized and uninitialized parts.
2351 */
2353 bfd_boolean
2358 {
2370 {
2387 {
2391 {
2392 /* FIXME: all we known is that it has execute PERMISSION,
2393 may be data. */
2395 }
2396 }
2398 {
2400 }
2401 }
2404 {
2405 bfd_vma align;
2425 {
2426 /* Hack for gdb. Segments that have not been modified do
2427 not have their contents written to a core file, on the
2428 assumption that a debugger can find the contents in the
2429 executable. We flag this case by setting the fake
2430 section size to zero. Note that "real" bss sections will
2431 always have their contents dumped to the core file. */
2437 }
2440 }
2443 }
2445 bfd_boolean
2447 {
2451 {
2488 /* Check for any processor-specific program segment types. */
2491 }
2492 }
2494 /* Return the REL_HDR for SEC, assuming there is only a single one, either
2495 REL or RELA. */
2497 Elf_Internal_Shdr *
2499 {
2501 {
2504 }
2505 else
2507 }
2509 /* Allocate and initialize a section-header for a new reloc section,
2510 containing relocations against ASECT. It is stored in RELDATA. If
2511 USE_RELA_P is TRUE, we use RELA relocations; otherwise, we use REL
2512 relocations. */
2514 bfd_boolean
2518 bfd_boolean use_rela_p)
2519 {
2523 bfd_size_type amt;
2537 FALSE);
2551 }
2553 /* Return the default section type based on the passed in section flags. */
2555 int
2557 {
2562 }
2564 struct fake_section_arg
2565 {
2567 bfd_boolean failed;
2568 };
2570 /* Set up an ELF internal section header for a section. */
2572 static void
2574 {
2582 {
2583 /* We already failed; just get out of the bfd_map_over_sections
2584 loop. */
2586 }
2593 {
2596 }
2598 /* Don't clear sh_flags. Assembler may set additional bits. */
2603 else
2610 /* The sh_entsize and sh_info fields may have been set already by
2611 copy_private_section_data. */
2616 /* If the section type is unspecified, we set it based on
2617 asect->flags. */
2620 else
2628 {
2629 /* Warn if we are changing a NOBITS section to PROGBITS, but
2630 allow the link to proceed. This can happen when users link
2631 non-bss input sections to bss output sections, or emit data
2632 to a bss output section via a linker script. */
2636 }
2639 {
2680 /* objcopy or strip will copy over sh_info, but may not set
2681 cverdefs. The linker will set cverdefs, but sh_info will be
2682 zero. */
2685 else
2692 /* objcopy or strip will copy over sh_info, but may not set
2693 cverrefs. The linker will set cverrefs, but sh_info will be
2694 zero. */
2697 else
2709 }
2718 {
2723 }
2727 {
2731 {
2736 {
2740 }
2741 }
2742 }
2746 /* If the section has relocs, set up a section header for the
2747 SHT_REL[A] section. If two relocation sections are required for
2748 this section, it is up to the processor-specific back-end to
2749 create the other. */
2751 {
2752 /* When doing a relocatable link, create both REL and RELA sections if
2753 needed. */
2755 /* Do the normal setup if we wouldn't create any sections here. */
2758 {
2761 {
2764 }
2767 {
2770 }
2771 }
2775 asect,
2778 }
2780 /* Check for processor-specific section types. */
2787 {
2788 /* Don't change the header type from NOBITS if we are being
2789 called for objcopy --only-keep-debug. */
2791 }
2792 }
2794 /* Fill in the contents of a SHT_GROUP section. Called from
2795 _bfd_elf_compute_section_file_positions for gas, objcopy, and
2796 when ELF targets use the generic linker, ld. Called for ld -r
2797 from bfd_elf_final_link. */
2799 void
2801 {
2805 bfd_boolean gas;
2807 /* Ignore linker created group section. See elfNN_ia64_object_p in
2808 elfxx-ia64.c. */
2814 {
2817 /* elf_group_id will have been set up by objcopy and the
2818 generic linker. */
2823 {
2824 /* If called from the assembler, swap_out_syms will have set up
2825 elf_section_syms. */
2828 }
2830 }
2832 {
2833 /* The ELF backend linker sets sh_info to -2 when the group
2834 signature symbol is global, and thus the index can't be
2835 set until all local symbols are output. */
2843 {
2848 }
2855 }
2857 /* The contents won't be allocated for "ld -r" or objcopy. */
2860 {
2864 /* Arrange for the section to be written out. */
2867 {
2870 }
2871 }
2875 /* Get the pointer to the first section in the group that gas
2876 squirreled away here. objcopy arranges for this to be set to the
2877 start of the input section group. */
2880 /* First element is a flag word. Rest of section is elf section
2881 indices for all the sections of the group. Write them backwards
2882 just to keep the group in the same order as given in .section
2883 directives, not that it matters. */
2885 {
2893 {
2898 }
2902 }
2908 }
2910 /* Assign all ELF section numbers. The dummy first section is handled here
2911 too. The link/info pointers for the standard section types are filled
2912 in here too, while we're at it. */
2914 static bfd_boolean
2916 {
2922 bfd_boolean need_symtab;
2928 /* SHT_GROUP sections are in relocatable files only. */
2930 {
2931 /* Put SHT_GROUP sections first. */
2933 {
2937 {
2939 {
2940 /* Remove the linker created SHT_GROUP sections. */
2943 }
2944 else
2946 }
2947 }
2948 }
2951 {
2958 {
2961 }
2962 else
2966 {
2969 }
2970 else
2972 }
2983 {
2987 {
2994 }
2997 }
3005 /* Set up the list of section header pointers, in agreement with the
3006 indices. */
3015 {
3018 }
3024 {
3027 {
3030 }
3033 }
3036 {
3048 /* Fill in the sh_link and sh_info fields while we're at it. */
3050 /* sh_link of a reloc section is the section index of the symbol
3051 table. sh_info is the section index of the section to which
3052 the relocation entries apply. */
3054 {
3057 }
3059 {
3062 }
3064 /* We need to set up sh_link for SHF_LINK_ORDER. */
3066 {
3069 {
3070 /* elf_linked_to_section points to the input section. */
3072 {
3073 /* Check discarded linkonce section. */
3075 {
3081 /* Point to the kept section if it has the same
3082 size as the discarded one. */
3085 {
3088 }
3090 }
3094 }
3095 else
3096 {
3097 /* Handle objcopy. */
3099 {
3105 }
3107 }
3109 }
3110 else
3111 {
3112 /* PR 290:
3113 The Intel C compiler generates SHT_IA_64_UNWIND with
3114 SHF_LINK_ORDER. But it doesn't set the sh_link or
3115 sh_info fields. Hence we could get the situation
3116 where s is NULL. */
3120 bed->link_order_error_handler
3123 }
3124 }
3127 {
3130 /* A reloc section which we are treating as a normal BFD
3131 section. sh_link is the section index of the symbol
3132 table. sh_info is the section index of the section to
3133 which the relocation entries apply. We assume that an
3134 allocated reloc section uses the dynamic symbol table.
3135 FIXME: How can we be sure? */
3140 /* We look up the section the relocs apply to by name. */
3144 else
3152 /* We assume that a section named .stab*str is a stabs
3153 string section. We look for a section with the same name
3154 but without the trailing ``str'', and set its sh_link
3155 field to point to this section. */
3158 {
3171 {
3174 /* This is a .stab section. */
3178 }
3179 }
3186 /* sh_link is the section header index of the string table
3187 used for the dynamic entries, or the symbol table, or the
3188 version strings. */
3195 /* sh_link is the section header index of the prelink library
3196 list used for the dynamic entries, or the symbol table, or
3197 the version strings. */
3207 /* sh_link is the section header index of the symbol table
3208 this hash table or version table is for. */
3216 }
3217 }
3222 else
3226 }
3228 /* Map symbol from it's internal number to the external number, moving
3229 all local symbols to be at the head of the list. */
3231 static bfd_boolean
3233 {
3234 /* If the backend has a special mapping, use it. */
3242 }
3244 /* Don't output section symbols for sections that are not going to be
3245 output. */
3247 static bfd_boolean
3249 {
3254 }
3256 static bfd_boolean
3258 {
3271 #ifdef DEBUG
3274 #endif
3277 {
3280 }
3282 max_index++;
3289 /* Init sect_syms entries for any section symbols we have already
3290 decided to output. */
3292 {
3298 {
3305 }
3306 }
3308 /* Classify all of the symbols. */
3310 {
3314 num_locals++;
3315 else
3316 num_globals++;
3317 }
3319 /* We will be adding a section symbol for each normal BFD section. Most
3320 sections will already have a section symbol in outsymbols, but
3321 eg. SHT_GROUP sections will not, and we need the section symbol mapped
3322 at least in that case. */
3324 {
3326 {
3328 num_locals++;
3329 else
3330 num_globals++;
3331 }
3332 }
3334 /* Now sort the symbols so the local symbols are first. */
3342 {
3350 else
3354 }
3356 {
3358 {
3365 else
3369 }
3370 }
3377 }
3379 /* Align to the maximum file alignment that could be required for any
3380 ELF data structure. */
3384 {
3386 }
3388 /* Assign a file position to a section, optionally aligning to the
3389 required section alignment. */
3391 file_ptr
3393 file_ptr offset,
3394 bfd_boolean align)
3395 {
3404 }
3406 /* Compute the file positions we are going to put the sections at, and
3407 otherwise prepare to begin writing out the ELF file. If LINK_INFO
3408 is not NULL, this is being called by the ELF backend linker. */
3410 bfd_boolean
3413 {
3416 bfd_boolean failed;
3419 bfd_boolean need_symtab;
3424 /* Do any elf backend specific processing first. */
3431 /* Post process the headers if necessary. */
3444 /* The backend linker builds symbol table information itself. */
3450 {
3451 /* Non-zero if doing a relocatable link. */
3456 }
3460 {
3464 }
3467 /* sh_name was set in prep_headers. */
3475 /* sh_offset is set in assign_file_positions_except_relocs. */
3482 {
3483 file_ptr off;
3500 /* Now that we know where the .strtab section goes, write it
3501 out. */
3506 }
3511 }
3513 /* Make an initial estimate of the size of the program header. If we
3514 get the number wrong here, we'll redo section placement. */
3516 static bfd_size_type
3518 {
3523 /* Assume we will need exactly two PT_LOAD segments: one for text
3524 and one for data. */
3529 {
3530 /* If we have a loadable interpreter section, we need a
3531 PT_INTERP segment. In this case, assume we also need a
3532 PT_PHDR segment, although that may not be true for all
3533 targets. */
3535 }
3538 {
3539 /* We need a PT_DYNAMIC segment. */
3541 }
3544 {
3545 /* We need a PT_GNU_RELRO segment. */
3547 }
3550 {
3551 /* We need a PT_GNU_EH_FRAME segment. */
3553 }
3556 {
3557 /* We need a PT_GNU_STACK segment. */
3559 }
3562 {
3565 {
3566 /* We need a PT_NOTE segment. */
3568 /* Try to create just one PT_NOTE segment
3569 for all adjacent loadable .note* sections.
3570 gABI requires that within a PT_NOTE segment
3571 (and also inside of each SHT_NOTE section)
3572 each note is padded to a multiple of 4 size,
3573 so we check whether the sections are correctly
3574 aligned. */
3581 }
3582 }
3585 {
3587 {
3588 /* We need a PT_TLS segment. */
3591 }
3592 }
3594 /* Let the backend count up any program headers it might need. */
3597 {
3604 }
3607 }
3609 /* Find the segment that contains the output_section of section. */
3611 Elf_Internal_Phdr *
3613 {
3621 {
3627 }
3630 }
3632 /* Create a mapping from a set of sections to a program segment. */
3639 bfd_boolean phdr)
3640 {
3644 bfd_size_type amt;
3658 {
3659 /* Include the headers in the first PT_LOAD segment. */
3662 }
3665 }
3667 /* Create the PT_DYNAMIC segment, which includes DYNSEC. Returns NULL
3668 on failure. */
3672 {
3685 }
3687 /* Possibly add or remove segments from the segment map. */
3689 static bfd_boolean
3692 bfd_boolean remove_empty_load)
3693 {
3697 /* The placement algorithm assumes that non allocated sections are
3698 not in PT_LOAD segments. We ensure this here by removing such
3699 sections from the segment map. We also remove excluded
3700 sections. Finally, any PT_LOAD segment without sections is
3701 removed. */
3704 {
3708 {
3712 {
3714 new_count++;
3715 }
3716 }
3721 else
3723 }
3727 {
3730 }
3733 }
3735 /* Set up a mapping from BFD sections to program segments. */
3737 bfd_boolean
3739 {
3744 bfd_boolean no_user_phdrs;
3748 {
3754 bfd_vma last_size;
3756 bfd_vma maxpagesize;
3759 bfd_boolean writable;
3763 bfd_size_type amt;
3766 /* Select the allocated sections, and sort them. */
3773 /* Calculate top address, avoiding undefined behaviour of shift
3774 left operator when shift count is equal to size of type
3775 being shifted. */
3781 {
3783 {
3786 /* A wrapping section potentially clashes with header. */
3789 }
3790 }
3796 /* Build the mapping. */
3801 /* If we have a .interp section, then create a PT_PHDR segment for
3802 the program headers and a PT_INTERP segment for the .interp
3803 section. */
3806 {
3813 /* FIXME: UnixWare and Solaris set PF_X, Irix 5 does not. */
3832 }
3834 /* Look through the sections. We put sections in the same program
3835 segment when the start of the second section can be placed within
3836 a few bytes of the end of the first section. */
3847 /* Deal with -Ttext or something similar such that the first section
3848 is not adjacent to the program headers. This is an
3849 approximation, since at this point we don't know exactly how many
3850 program headers we will need. */
3852 {
3863 }
3866 {
3868 bfd_boolean new_segment;
3872 /* See if this section and the last one will fit in the same
3873 segment. */
3876 {
3877 /* If we don't have a segment yet, then we don't need a new
3878 one (we build the last one after this loop). */
3880 }
3882 {
3883 /* If this section has a different relation between the
3884 virtual address and the load address, then we need a new
3885 segment. */
3887 }
3890 {
3891 /* If this section has a load address that makes it overlap
3892 the previous section, then we need a new segment. */
3894 }
3895 /* In the next test we have to be careful when last_hdr->lma is close
3896 to the end of the address space. If the aligned address wraps
3897 around to the start of the address space, then there are no more
3898 pages left in memory and it is OK to assume that the current
3899 section can be included in the current segment. */
3904 {
3905 /* If putting this section in this segment would force us to
3906 skip a page in the segment, then we need a new segment. */
3908 }
3911 {
3912 /* We don't want to put a loadable section after a
3913 nonloadable section in the same segment.
3914 Consider .tbss sections as loadable for this purpose. */
3916 }
3918 {
3919 /* If the file is not demand paged, which means that we
3920 don't require the sections to be correctly aligned in the
3921 file, then there is no other reason for a new segment. */
3923 }
3928 {
3929 /* We don't want to put a writable section in a read only
3930 segment, unless they are on the same page in memory
3931 anyhow. We already know that the last section does not
3932 bring us past the current section on the page, so the
3933 only case in which the new section is not on the same
3934 page as the previous section is when the previous section
3935 ends precisely on a page boundary. */
3937 }
3938 else
3939 {
3940 /* Otherwise, we can use the same segment. */
3942 }
3944 /* Allow interested parties a chance to override our decision. */
3948 new_segment
3950 last_hdr,
3951 new_segment);
3954 {
3958 /* .tbss sections effectively have zero size. */
3962 else
3965 }
3967 /* We need a new program segment. We must create a new program
3968 header holding all the sections from phdr_index until hdr. */
3979 else
3983 /* .tbss sections effectively have zero size. */
3986 else
3990 }
3992 /* Create a final PT_LOAD program segment, but not if it's just
3993 for .tbss. */
3998 {
4005 }
4007 /* If there is a .dynamic section, throw in a PT_DYNAMIC segment. */
4009 {
4015 }
4017 /* For each batch of consecutive loadable .note sections,
4018 add a PT_NOTE segment. We don't use bfd_get_section_by_name,
4019 because if we link together nonloadable .note sections and
4020 loadable .note sections, we will generate two .note sections
4021 in the output file. FIXME: Using names for section types is
4022 bogus anyhow. */
4024 {
4027 {
4034 {
4040 count++;
4041 else
4043 }
4052 {
4056 }
4061 }
4063 {
4066 tls_count++;
4067 }
4068 }
4070 /* If there are any SHF_TLS output sections, add PT_TLS segment. */
4072 {
4081 /* Mandated PF_R. */
4085 {
4089 }
4093 }
4095 /* If there is a .eh_frame_hdr section, throw in a PT_GNU_EH_FRAME
4096 segment. */
4100 {
4112 }
4115 {
4127 }
4130 {
4132 {
4134 {
4143 }
4144 }
4146 /* Make a PT_GNU_RELRO segment only when it isn't empty. */
4148 {
4160 }
4161 }
4165 }
4176 error_return:
4180 }
4182 /* Sort sections by address. */
4184 static int
4186 {
4191 /* Sort by LMA first, since this is the address used to
4192 place the section into a segment. */
4198 /* Then sort by VMA. Normally the LMA and the VMA will be
4199 the same, and this will do nothing. */
4205 /* Put !SEC_LOAD sections after SEC_LOAD ones. */
4207 #define TOEND(x) (((x)->flags & (SEC_LOAD | SEC_THREAD_LOCAL)) == 0)
4210 {
4212 {
4213 /* If the indicies are the same, do not return 0
4214 here, but continue to try the next comparison. */
4217 }
4218 else
4220 }
4224 #undef TOEND
4226 /* Sort by size, to put zero sized sections
4227 before others at the same address. */
4238 }
4240 /* Ian Lance Taylor writes:
4242 We shouldn't be using % with a negative signed number. That's just
4243 not good. We have to make sure either that the number is not
4244 negative, or that the number has an unsigned type. When the types
4245 are all the same size they wind up as unsigned. When file_ptr is a
4246 larger signed type, the arithmetic winds up as signed long long,
4247 which is wrong.
4249 What we're trying to say here is something like ``increase OFF by
4250 the least amount that will cause it to be equal to the VMA modulo
4251 the page size.'' */
4252 /* In other words, something like:
4254 vma_offset = m->sections[0]->vma % bed->maxpagesize;
4255 off_offset = off % bed->maxpagesize;
4256 if (vma_offset < off_offset)
4257 adjustment = vma_offset + bed->maxpagesize - off_offset;
4258 else
4259 adjustment = vma_offset - off_offset;
4261 which can can be collapsed into the expression below. */
4263 static file_ptr
4265 {
4267 }
4269 static void
4271 {
4277 {
4284 else
4288 }
4295 }
4297 static bfd_boolean
4299 {
4301 bfd_boolean ret;
4311 }
4313 /* Assign file positions to the sections based on the mapping from
4314 sections to segments. This function also sets up some fields in
4315 the file header. */
4317 static bfd_boolean
4320 {
4325 file_ptr off;
4326 bfd_size_type maxpagesize;
4337 {
4341 }
4344 {
4347 }
4348 else
4349 {
4350 /* PR binutils/12467. */
4353 }
4359 else
4364 {
4367 }
4369 /* We're writing the size in elf_tdata (abfd)->program_header_size,
4370 see assign_file_positions_except_relocs, so make sure we have
4371 that amount allocated, with trailing space cleared.
4372 The variable alloc contains the computed need, while elf_tdata
4373 (abfd)->program_header_size contains the size used for the
4374 layout.
4375 See ld/emultempl/elf-generic.em:gld${EMULATION_NAME}_map_segments
4376 where the layout is forced to according to a larger size in the
4377 last iterations for the testcase ld-elf/header. */
4396 else
4403 {
4405 bfd_vma off_adjust;
4406 bfd_boolean no_contents;
4408 /* If elf_segment_map is not from map_sections_to_segments, the
4409 sections may not be correctly ordered. NOTE: sorting should
4410 not be done to the PT_NOTE section of a corefile, which may
4411 contain several pseudo-sections artificially created by bfd.
4412 Sorting these pseudo-sections breaks things badly. */
4417 elf_sort_sections);
4419 /* An ELF segment (described by Elf_Internal_Phdr) may contain a
4420 number of sections with contents contributing to both p_filesz
4421 and p_memsz, followed by a number of sections with no contents
4422 that just contribute to p_memsz. In this loop, OFF tracks next
4423 available file offset for PT_LOAD and PT_NOTE segments. */
4429 else
4436 else
4441 {
4442 /* p_align in demand paged PT_LOAD segments effectively stores
4443 the maximum page size. When copying an executable with
4444 objcopy, we set m->p_align from the input file. Use this
4445 value for maxpagesize rather than bed->maxpagesize, which
4446 may be different. Note that we use maxpagesize for PT_TLS
4447 segment alignment later in this function, so we are relying
4448 on at least one PT_LOAD segment appearing before a PT_TLS
4449 segment. */
4454 }
4459 else
4466 {
4467 bfd_size_type align;
4472 else
4473 {
4475 {
4481 }
4485 }
4489 /* If we aren't making room for this section, then
4490 it must be SHT_NOBITS regardless of what we've
4491 set via struct bfd_elf_special_section. */
4494 /* Find out whether this segment contains any loadable
4495 sections. */
4499 {
4502 }
4507 {
4508 /* We shouldn't need to align the segment on disk since
4509 the segment doesn't need file space, but the gABI
4510 arguably requires the alignment and glibc ld.so
4511 checks it. So to comply with the alignment
4512 requirement but not waste file space, we adjust
4513 p_offset for just this segment. (OFF_ADJUST is
4514 subtracted from OFF later.) This may put p_offset
4515 past the end of file, but that shouldn't matter. */
4516 }
4517 else
4519 }
4520 /* Make sure the .dynamic section is the first section in the
4521 PT_DYNAMIC segment. */
4525 {
4526 _bfd_error_handler
4528 abfd);
4531 }
4532 /* Set the note section type to SHT_NOTE. */
4542 {
4548 {
4552 {
4555 abfd);
4558 }
4563 }
4564 }
4567 {
4572 {
4576 {
4581 }
4582 }
4587 {
4590 }
4591 }
4595 {
4598 else
4599 {
4600 file_ptr adjust;
4606 }
4607 }
4609 /* Set up p_filesz, p_memsz, p_align and p_flags from the section
4610 maps. Set filepos for sections in PT_LOAD segments, and in
4611 core files, for sections in PT_NOTE segments.
4612 assign_file_positions_for_non_load_sections will set filepos
4613 for other sections and update p_filesz for other segments. */
4615 {
4617 bfd_size_type align;
4630 {
4639 {
4645 }
4649 {
4651 {
4652 /* We have a PROGBITS section following NOBITS ones.
4653 Allocate file space for the NOBITS section(s) and
4654 zero it. */
4658 }
4661 }
4662 }
4665 {
4666 /* The section at i == 0 is the one that actually contains
4667 everything. */
4669 {
4675 }
4676 else
4677 {
4678 /* The rest are fake sections that shouldn't be written. */
4683 }
4684 }
4685 else
4686 {
4688 {
4692 }
4696 {
4697 /* This is a .tbss section that didn't get a PT_LOAD.
4698 (See _bfd_elf_map_sections_to_segments "Create a
4699 final PT_LOAD".) Set sh_offset to the value it
4700 would have if we had created a zero p_filesz and
4701 p_memsz PT_LOAD header for the section. This
4702 also makes the PT_TLS header have the same
4703 p_offset value. */
4707 }
4710 {
4712 /* A load section without SHF_ALLOC is something like
4713 a note section in a PT_NOTE segment. These take
4714 file space but are not loaded into memory. */
4717 }
4719 {
4723 /* .tbss is special. It doesn't contribute to p_memsz of
4724 normal segments. */
4727 }
4734 }
4737 {
4743 }
4744 }
4747 /* Check that all sections are in a PT_LOAD segment.
4748 Don't check funky gdb generated core files. */
4750 {
4759 {
4760 /* Looks like we have overlays packed into the segment. */
4763 }
4766 {
4774 {
4779 }
4780 }
4781 }
4782 }
4786 }
4788 /* Assign file positions for the other sections. */
4790 static bfd_boolean
4793 {
4802 file_ptr off;
4811 {
4822 {
4825 abfd,
4829 /* We don't need to page align empty sections. */
4833 else
4837 FALSE);
4838 }
4845 else
4847 }
4849 /* Now that we have set the section file positions, we can set up
4850 the file positions for the non PT_LOAD segments. */
4860 {
4866 {
4869 }
4871 {
4875 {
4878 }
4879 }
4880 }
4885 {
4887 {
4893 {
4894 /* During linking the range of the RELRO segment is passed
4895 in link_info. */
4897 {
4903 }
4904 }
4905 else
4906 {
4907 /* Otherwise we are copying an executable or shared
4908 library, but we need to use the same linker logic. */
4910 {
4914 }
4915 }
4918 {
4926 else
4931 }
4932 else
4933 {
4936 }
4937 }
4939 {
4943 {
4949 {
4953 {
4957 }
4958 }
4959 }
4960 }
4962 {
4966 }
4968 {
4972 }
4973 }
4978 }
4980 /* Work out the file positions of all the sections. This is called by
4981 _bfd_elf_compute_section_file_positions. All the section sizes and
4982 VMAs must be known before this is called.
4984 Reloc sections come in two flavours: Those processed specially as
4985 "side-channel" data attached to a section to which they apply, and
4986 those that bfd doesn't process as relocations. The latter sort are
4987 stored in a normal bfd section by bfd_section_from_shdr. We don't
4988 consider the former sort here, unless they form part of the loadable
4989 image. Reloc sections not assigned here will be handled later by
4990 assign_file_positions_for_relocs.
4992 We also don't set the positions of the .symtab and .strtab here. */
4994 static bfd_boolean
4997 {
5000 file_ptr off;
5005 {
5011 /* Start after the ELF header. */
5014 /* We are not creating an executable, which means that we are
5015 not creating a program header, and that the actual order of
5016 the sections in the file is unimportant. */
5018 {
5027 {
5029 }
5030 else
5032 }
5033 }
5034 else
5035 {
5038 /* Assign file positions for the loaded sections based on the
5039 assignment of sections to segments. */
5043 /* And for non-load sections. */
5048 {
5051 }
5053 /* Write out the program headers. */
5060 }
5062 /* Place the section headers. */
5070 }
5072 static bfd_boolean
5074 {
5103 else
5107 {
5112 /* There used to be a long list of cases here, each one setting
5113 e_machine to the same EM_* macro #defined as ELF_MACHINE_CODE
5114 in the corresponding bfd definition. To avoid duplication,
5115 the switch was removed. Machines that need special handling
5116 can generally do it in elf_backend_final_write_processing(),
5117 unless they need the information earlier than the final write.
5118 Such need can generally be supplied by replacing the tests for
5119 e_machine with the conditions used to determine it. */
5122 }
5127 /* No program header, for now. */
5132 /* Each bfd section is section header entry. */
5136 /* If we're building an executable, we'll need a program header table. */
5138 /* It all happens later. */
5139 ;
5140 else
5141 {
5144 }
5158 }
5160 /* Assign file positions for all the reloc sections which are not part
5161 of the loadable file image. */
5163 void
5165 {
5166 file_ptr off;
5174 {
5181 }
5184 }
5186 bfd_boolean
5188 {
5191 bfd_boolean failed;
5207 /* After writing the headers, we need to write the sections too... */
5210 {
5214 {
5220 }
5221 }
5223 /* Write out the section header names. */
5236 /* This is last since write_shdrs_and_ehdr can touch i_shdrp[0]. */
5241 }
5243 bfd_boolean
5245 {
5246 /* Hopefully this can be done just like an object file. */
5248 }
5250 /* Given a section, search the header to find them. */
5252 unsigned int
5254 {
5268 else
5273 {
5278 }
5284 }
5286 /* Given a BFD symbol, return the index in the ELF symbol table, or -1
5287 on error. */
5289 int
5291 {
5296 /* When gas creates relocations against local labels, it creates its
5297 own symbol for the section, but does put the symbol into the
5298 symbol chain, so udata is 0. When the linker is generating
5299 relocatable output, this section symbol may be for one of the
5300 input sections rather than the output section. */
5304 {
5315 }
5320 {
5321 /* This case can occur when using --strip-symbol on a symbol
5322 which is used in a relocation entry. */
5328 }
5330 #if DEBUG & 4
5331 {
5336 }
5337 #endif
5340 }
5342 /* Rewrite program header information. */
5344 static bfd_boolean
5346 {
5356 bfd_boolean p_paddr_valid;
5357 bfd_vma maxpagesize;
5371 /* Returns the end address of the segment + 1. */
5372 #define SEGMENT_END(segment, start) \
5373 (start + (segment->p_memsz > segment->p_filesz \
5374 ? segment->p_memsz : segment->p_filesz))
5376 #define SECTION_SIZE(section, segment) \
5377 (((section->flags & (SEC_HAS_CONTENTS | SEC_THREAD_LOCAL)) \
5378 != SEC_THREAD_LOCAL || segment->p_type == PT_TLS) \
5379 ? section->size : 0)
5381 /* Returns TRUE if the given section is contained within
5382 the given segment. VMA addresses are compared. */
5383 #define IS_CONTAINED_BY_VMA(section, segment) \
5384 (section->vma >= segment->p_vaddr \
5385 && (section->vma + SECTION_SIZE (section, segment) \
5386 <= (SEGMENT_END (segment, segment->p_vaddr))))
5388 /* Returns TRUE if the given section is contained within
5389 the given segment. LMA addresses are compared. */
5390 #define IS_CONTAINED_BY_LMA(section, segment, base) \
5391 (section->lma >= base \
5392 && (section->lma + SECTION_SIZE (section, segment) \
5393 <= SEGMENT_END (segment, base)))
5395 /* Handle PT_NOTE segment. */
5396 #define IS_NOTE(p, s) \
5397 (p->p_type == PT_NOTE \
5398 && elf_section_type (s) == SHT_NOTE \
5399 && (bfd_vma) s->filepos >= p->p_offset \
5400 && ((bfd_vma) s->filepos + s->size \
5401 <= p->p_offset + p->p_filesz))
5403 /* Special case: corefile "NOTE" section containing regs, prpsinfo
5404 etc. */
5405 #define IS_COREFILE_NOTE(p, s) \
5406 (IS_NOTE (p, s) \
5407 && bfd_get_format (ibfd) == bfd_core \
5408 && s->vma == 0 \
5409 && s->lma == 0)
5411 /* The complicated case when p_vaddr is 0 is to handle the Solaris
5412 linker, which generates a PT_INTERP section with p_vaddr and
5413 p_memsz set to 0. */
5414 #define IS_SOLARIS_PT_INTERP(p, s) \
5415 (p->p_vaddr == 0 \
5416 && p->p_paddr == 0 \
5417 && p->p_memsz == 0 \
5418 && p->p_filesz > 0 \
5419 && (s->flags & SEC_HAS_CONTENTS) != 0 \
5420 && s->size > 0 \
5421 && (bfd_vma) s->filepos >= p->p_offset \
5422 && ((bfd_vma) s->filepos + s->size \
5423 <= p->p_offset + p->p_filesz))
5425 /* Decide if the given section should be included in the given segment.
5426 A section will be included if:
5427 1. It is within the address space of the segment -- we use the LMA
5428 if that is set for the segment and the VMA otherwise,
5429 2. It is an allocated section or a NOTE section in a PT_NOTE
5430 segment.
5431 3. There is an output section associated with it,
5432 4. The section has not already been allocated to a previous segment.
5433 5. PT_GNU_STACK segments do not include any sections.
5434 6. PT_TLS segment includes only SHF_TLS sections.
5435 7. SHF_TLS sections are only in PT_TLS or PT_LOAD segments.
5436 8. PT_DYNAMIC should not contain empty sections at the beginning
5437 (with the possible exception of .dynamic). */
5438 #define IS_SECTION_IN_INPUT_SEGMENT(section, segment, bed) \
5439 ((((segment->p_paddr \
5440 ? IS_CONTAINED_BY_LMA (section, segment, segment->p_paddr) \
5441 : IS_CONTAINED_BY_VMA (section, segment)) \
5442 && (section->flags & SEC_ALLOC) != 0) \
5443 || IS_NOTE (segment, section)) \
5444 && segment->p_type != PT_GNU_STACK \
5445 && (segment->p_type != PT_TLS \
5446 || (section->flags & SEC_THREAD_LOCAL)) \
5447 && (segment->p_type == PT_LOAD \
5448 || segment->p_type == PT_TLS \
5449 || (section->flags & SEC_THREAD_LOCAL) == 0) \
5450 && (segment->p_type != PT_DYNAMIC \
5451 || SECTION_SIZE (section, segment) > 0 \
5452 || (segment->p_paddr \
5453 ? segment->p_paddr != section->lma \
5454 : segment->p_vaddr != section->vma) \
5456 == 0)) \
5457 && !section->segment_mark)
5459 /* If the output section of a section in the input segment is NULL,
5460 it is removed from the corresponding output segment. */
5461 #define INCLUDE_SECTION_IN_SEGMENT(section, segment, bed) \
5462 (IS_SECTION_IN_INPUT_SEGMENT (section, segment, bed) \
5463 && section->output_section != NULL)
5465 /* Returns TRUE iff seg1 starts after the end of seg2. */
5466 #define SEGMENT_AFTER_SEGMENT(seg1, seg2, field) \
5467 (seg1->field >= SEGMENT_END (seg2, seg2->field))
5469 /* Returns TRUE iff seg1 and seg2 overlap. Segments overlap iff both
5470 their VMA address ranges and their LMA address ranges overlap.
5471 It is possible to have overlapping VMA ranges without overlapping LMA
5472 ranges. RedBoot images for example can have both .data and .bss mapped
5473 to the same VMA range, but with the .data section mapped to a different
5474 LMA. */
5475 #define SEGMENT_OVERLAPS(seg1, seg2) \
5476 ( !(SEGMENT_AFTER_SEGMENT (seg1, seg2, p_vaddr) \
5477 || SEGMENT_AFTER_SEGMENT (seg2, seg1, p_vaddr)) \
5478 && !(SEGMENT_AFTER_SEGMENT (seg1, seg2, p_paddr) \
5479 || SEGMENT_AFTER_SEGMENT (seg2, seg1, p_paddr)))
5481 /* Initialise the segment mark field. */
5485 /* The Solaris linker creates program headers in which all the
5486 p_paddr fields are zero. When we try to objcopy or strip such a
5487 file, we get confused. Check for this case, and if we find it
5488 don't set the p_paddr_valid fields. */
5494 {
5497 }
5499 /* Scan through the segments specified in the program header
5500 of the input BFD. For this first scan we look for overlaps
5501 in the loadable segments. These can be created by weird
5502 parameters to objcopy. Also, fix some solaris weirdness. */
5506 {
5513 {
5514 /* Mininal change so that the normal section to segment
5515 assignment code will work. */
5518 }
5521 {
5522 /* Remove PT_GNU_RELRO segment. */
5526 }
5528 /* Determine if this segment overlaps any previous segments. */
5530 {
5531 bfd_signed_vma extra_length;
5537 /* Merge the two segments together. */
5539 {
5540 /* Extend SEGMENT2 to include SEGMENT and then delete
5541 SEGMENT. */
5546 {
5549 }
5553 /* Since we have deleted P we must restart the outer loop. */
5557 }
5558 else
5559 {
5560 /* Extend SEGMENT to include SEGMENT2 and then delete
5561 SEGMENT2. */
5566 {
5569 }
5572 }
5573 }
5574 }
5576 /* The second scan attempts to assign sections to segments. */
5580 {
5585 bfd_vma matching_lma;
5586 bfd_vma suggested_lma;
5588 bfd_size_type amt;
5590 bfd_boolean first_matching_lma;
5591 bfd_boolean first_suggested_lma;
5597 /* Compute how many sections might be placed into this segment. */
5601 {
5602 /* Find the first section in the input segment, which may be
5603 removed from the corresponding output segment. */
5605 {
5610 }
5611 }
5613 /* Allocate a segment map big enough to contain
5614 all of the sections we have selected. */
5621 /* Initialise the fields of the segment map. Default to
5622 using the physical address of the segment in the input BFD. */
5628 /* If the first section in the input segment is removed, there is
5629 no need to preserve segment physical address in the corresponding
5630 output segment. */
5632 {
5635 }
5637 /* Determine if this segment contains the ELF file header
5638 and if it contains the program headers themselves. */
5644 {
5653 }
5656 {
5657 /* Special segments, such as the PT_PHDR segment, may contain
5658 no sections, but ordinary, loadable segments should contain
5659 something. They are allowed by the ELF spec however, so only
5660 a warning is produced. */
5664 ibfd);
5671 }
5673 /* Now scan the sections in the input BFD again and attempt
5674 to add their corresponding output sections to the segment map.
5675 The problem here is how to handle an output section which has
5676 been moved (ie had its LMA changed). There are four possibilities:
5678 1. None of the sections have been moved.
5679 In this case we can continue to use the segment LMA from the
5680 input BFD.
5682 2. All of the sections have been moved by the same amount.
5683 In this case we can change the segment's LMA to match the LMA
5684 of the first section.
5686 3. Some of the sections have been moved, others have not.
5687 In this case those sections which have not been moved can be
5688 placed in the current segment which will have to have its size,
5689 and possibly its LMA changed, and a new segment or segments will
5690 have to be created to contain the other sections.
5692 4. The sections have been moved, but not by the same amount.
5693 In this case we can change the segment's LMA to match the LMA
5694 of the first section and we will have to create a new segment
5695 or segments to contain the other sections.
5697 In order to save time, we allocate an array to hold the section
5698 pointers that we are interested in. As these sections get assigned
5699 to a segment, they are removed from this array. */
5705 /* Step One: Scan for segment vs section LMA conflicts.
5706 Also add the sections to the section array allocated above.
5707 Also add the sections to the current segment. In the common
5708 case, where the sections have not been moved, this means that
5709 we have completely filled the segment, and there is nothing
5710 more to do. */
5724 {
5726 {
5731 /* The Solaris native linker always sets p_paddr to 0.
5732 We try to catch that case here, and set it to the
5733 correct value. Note - some backends require that
5734 p_paddr be left as zero. */
5750 /* Match up the physical address of the segment with the
5751 LMA address of the output section. */
5756 {
5758 {
5761 }
5763 /* We assume that if the section fits within the segment
5764 then it does not overlap any other section within that
5765 segment. */
5767 }
5769 {
5772 }
5776 }
5777 }
5781 /* Step Two: Adjust the physical address of the current segment,
5782 if necessary. */
5784 {
5785 /* All of the sections fitted within the segment as currently
5786 specified. This is the default case. Add the segment to
5787 the list of built segments and carry on to process the next
5788 program header in the input BFD. */
5798 /* There is some padding before the first section in the
5799 segment. So, we must account for that in the output
5800 segment's vma. */
5805 }
5806 else
5807 {
5809 {
5810 /* At least one section fits inside the current segment.
5811 Keep it, but modify its physical address to match the
5812 LMA of the first section that fitted. */
5814 }
5815 else
5816 {
5817 /* None of the sections fitted inside the current segment.
5818 Change the current segment's physical address to match
5819 the LMA of the first section. */
5821 }
5823 /* Offset the segment physical address from the lma
5824 to allow for space taken up by elf headers. */
5826 {
5829 else
5830 {
5833 }
5834 }
5837 {
5839 {
5842 /* iehdr->e_phnum is just an estimate of the number
5843 of program headers that we will need. Make a note
5844 here of the number we used and the segment we chose
5845 to hold these headers, so that we can adjust the
5846 offset when we know the correct value. */
5849 }
5850 else
5852 }
5853 }
5855 /* Step Three: Loop over the sections again, this time assigning
5856 those that fit to the current segment and removing them from the
5857 sections array; but making sure not to leave large gaps. Once all
5858 possible sections have been assigned to the current segment it is
5859 added to the list of built segments and if sections still remain
5860 to be assigned, a new segment is constructed before repeating
5861 the loop. */
5863 do
5864 {
5869 /* Fill the current segment with sections that fit. */
5871 {
5883 {
5885 {
5886 /* If the first section in a segment does not start at
5887 the beginning of the segment, then something is
5888 wrong. */
5896 }
5897 else
5898 {
5903 /* If the gap between the end of the previous section
5904 and the start of this section is more than
5905 maxpagesize then we need to start a new segment. */
5907 maxpagesize)
5911 {
5913 {
5916 }
5919 }
5920 }
5926 }
5928 {
5931 }
5932 }
5936 /* Add the current segment to the list of built segments. */
5941 {
5942 /* We still have not allocated all of the sections to
5943 segments. Create a new segment here, initialise it
5944 and carry on looping. */
5949 {
5952 }
5954 /* Initialise the fields of the segment map. Set the physical
5955 physical address to the LMA of the first section that has
5956 not yet been assigned. */
5965 }
5966 }
5970 }
5974 /* If we had to estimate the number of program headers that were
5975 going to be needed, then check our estimate now and adjust
5976 the offset if necessary. */
5978 {
5982 count++;
5985 phdr_adjust_seg->p_paddr
5987 }
5989 #undef SEGMENT_END
5990 #undef SECTION_SIZE
5991 #undef IS_CONTAINED_BY_VMA
5992 #undef IS_CONTAINED_BY_LMA
5993 #undef IS_NOTE
5994 #undef IS_COREFILE_NOTE
5995 #undef IS_SOLARIS_PT_INTERP
5996 #undef IS_SECTION_IN_INPUT_SEGMENT
5997 #undef INCLUDE_SECTION_IN_SEGMENT
5998 #undef SEGMENT_AFTER_SEGMENT
5999 #undef SEGMENT_OVERLAPS
6001 }
6003 /* Copy ELF program header information. */
6005 static bfd_boolean
6007 {
6016 bfd_boolean p_paddr_valid;
6023 /* If all the segment p_paddr fields are zero, don't set
6024 map->p_paddr_valid. */
6031 {
6034 }
6039 {
6042 bfd_size_type amt;
6047 /* Compute how many sections are in this segment. */
6051 {
6054 {
6057 section_count++;
6058 }
6059 }
6061 /* Allocate a segment map big enough to contain
6062 all of the sections we have selected. */
6070 /* Initialize the fields of the output segment map with the
6071 input segment. */
6083 {
6084 /* The PT_GNU_RELRO segment may contain the first a few
6085 bytes in the .got.plt section even if the whole .got.plt
6086 section isn't in the PT_GNU_RELRO segment. We won't
6087 change the size of the PT_GNU_RELRO segment. */
6090 }
6092 /* Determine if this segment contains the ELF file header
6093 and if it contains the program headers themselves. */
6099 {
6108 }
6112 {
6118 {
6121 {
6126 {
6127 bfd_vma seg_off;
6129 /* Section lmas are set up from PT_LOAD header
6130 p_paddr in _bfd_elf_make_section_from_shdr.
6131 If this header has a p_paddr that disagrees
6132 with the section lma, flag the p_paddr as
6133 invalid. */
6136 else
6140 }
6143 }
6144 }
6145 }
6148 /* We need to keep the space used by the headers fixed. */
6154 /* There is some other padding before the first section. */
6161 }
6165 }
6167 /* Copy private BFD data. This copies or rewrites ELF program header
6168 information. */
6170 static bfd_boolean
6172 {
6181 {
6182 /* Check to see if any sections in the input BFD
6183 covered by ELF program header have changed. */
6192 /* Regenerate the segment map if p_paddr is set to 0. */
6196 /* Initialize the segment mark field. */
6205 {
6206 /* PR binutils/3535. The Solaris linker always sets the p_paddr
6207 and p_memsz fields of special segments (DYNAMIC, INTERP) to 0
6208 which severly confuses things, so always regenerate the segment
6209 map in this case. */
6217 {
6218 /* We mark the output section so that we know it comes
6219 from the input BFD. */
6224 /* Check if this section is covered by the segment. */
6227 {
6228 /* FIXME: Check if its output section is changed or
6229 removed. What else do we need to check? */
6238 }
6239 }
6240 }
6242 /* Check to see if any output section do not come from the
6243 input BFD. */
6246 {
6249 else
6251 }
6254 }
6256 rewrite:
6258 }
6260 /* Initialize private output section information from input section. */
6262 bfd_boolean
6269 {
6279 /* For objcopy and relocatable link, don't copy the output ELF
6280 section type from input if the output BFD section flags have been
6281 set to something different. For a final link allow some flags
6282 that the linker clears to differ. */
6285 || (final_link
6290 /* FIXME: Is this correct for all OS/PROC specific flags? */
6294 /* Set things up for objcopy and relocatable link. The output
6295 SHT_GROUP section will have its elf_next_in_group pointing back
6296 to the input group members. Ignore linker created group section.
6297 See elfNN_ia64_object_p in elfxx-ia64.c. */
6299 {
6302 {
6307 }
6308 }
6312 /* We need to handle elf_linked_to_section for SHF_LINK_ORDER. We
6313 don't use the output section of the linked-to section since it
6314 may be NULL at this point. */
6316 {
6320 }
6325 }
6327 /* Copy private section information. This copies over the entsize
6328 field, and sometimes the info field. */
6330 bfd_boolean
6335 {
6354 NULL);
6355 }
6357 /* Look at all the SHT_GROUP sections in IBFD, making any adjustments
6358 necessary if we are removing either the SHT_GROUP section or any of
6359 the group member sections. DISCARDED is the value that a section's
6360 output_section has if the section will be discarded, NULL when this
6361 function is called from objcopy, bfd_abs_section_ptr when called
6362 from the linker. */
6364 bfd_boolean
6366 {
6371 {
6377 {
6378 /* If this member section is being output but the
6379 SHT_GROUP section is not, then clear the group info
6380 set up by _bfd_elf_copy_private_section_data. */
6383 {
6386 }
6387 /* Conversely, if the member section is not being output
6388 but the SHT_GROUP section is, then adjust its size. */
6395 }
6397 {
6399 {
6400 /* If we've been called for ld -r, then we need to
6401 adjust the input section size. This function may
6402 be called multiple times, so save the original
6403 size. */
6407 }
6408 else
6409 {
6410 /* Adjust the output section size when called from
6411 objcopy. */
6413 }
6414 }
6415 }
6418 }
6420 /* Copy private header information. */
6422 bfd_boolean
6424 {
6429 /* Copy over private BFD data if it has not already been copied.
6430 This must be done here, rather than in the copy_private_bfd_data
6431 entry point, because the latter is called after the section
6432 contents have been set, which means that the program headers have
6433 already been worked out. */
6435 {
6438 }
6441 }
6443 /* Copy private symbol information. If this symbol is in a section
6444 which we did not map into a BFD section, try to map the section
6445 index correctly. We use special macro definitions for the mapped
6446 section indices; these definitions are interpreted by the
6447 swap_out_syms function. */
6449 #define MAP_ONESYMTAB (SHN_HIOS + 1)
6450 #define MAP_DYNSYMTAB (SHN_HIOS + 2)
6451 #define MAP_STRTAB (SHN_HIOS + 3)
6452 #define MAP_SHSTRTAB (SHN_HIOS + 4)
6453 #define MAP_SYM_SHNDX (SHN_HIOS + 5)
6455 bfd_boolean
6460 {
6474 {
6489 }
6492 }
6494 /* Swap out the symbols. */
6496 static bfd_boolean
6500 {
6511 bfd_size_type amt;
6512 bfd_boolean name_local_sections;
6517 /* Dump out the symtabs. */
6537 {
6540 }
6546 {
6551 {
6554 }
6561 }
6563 /* Now generate the data (for "contents"). */
6564 {
6565 /* Fill in zeroth symbol and swap it out. */
6566 Elf_Internal_Sym sym;
6578 }
6580 name_local_sections
6586 {
6587 Elf_Internal_Sym sym;
6595 {
6596 /* Local section symbols have no name. */
6598 }
6599 else
6600 {
6605 {
6608 }
6609 }
6615 {
6616 /* ELF common symbols put the alignment into the `value' field,
6617 and the size into the `size' field. This is backwards from
6618 how BFD handles it, so reverse it here. */
6623 else
6627 }
6628 else
6629 {
6634 {
6637 }
6639 /* Don't add in the section vma for relocatable output. */
6648 {
6649 /* This symbol is in a real ELF section which we did
6650 not create as a BFD section. Undo the mapping done
6651 by copy_private_symbol_data. */
6654 {
6672 }
6673 }
6674 else
6675 {
6679 {
6682 /* Writing this would be a hell of a lot easier if
6683 we had some decent documentation on bfd, and
6684 knew what to expect of the library, and what to
6685 demand of applications. For example, it
6686 appears that `objcopy' might not set the
6687 section of a symbol to be a section that is
6688 actually in the output file. */
6691 {
6699 }
6703 }
6704 }
6707 }
6721 else
6727 /* Processor-specific types. */
6734 {
6737 else
6739 }
6741 {
6742 #ifdef USE_STT_COMMON
6745 else
6746 #endif
6748 }
6751 ? STB_WEAK
6753 type);
6756 else
6757 {
6770 }
6773 {
6775 sym.st_target_internal
6777 }
6778 else
6779 {
6782 }
6788 }
6802 }
6804 /* Return the number of bytes required to hold the symtab vector.
6806 Note that we base it on the count plus 1, since we will null terminate
6807 the vector allocated based on this size. However, the ELF symbol table
6808 always has a dummy entry as symbol #0, so it ends up even. */
6810 long
6812 {
6823 }
6825 long
6827 {
6833 {
6836 }
6844 }
6846 long
6848 sec_ptr asect)
6849 {
6851 }
6853 /* Canonicalize the relocs. */
6855 long
6857 sec_ptr section,
6860 {
6875 }
6877 long
6879 {
6886 }
6888 long
6891 {
6898 }
6900 /* Return the size required for the dynamic reloc entries. Any loadable
6901 section that was actually installed in the BFD, and has type SHT_REL
6902 or SHT_RELA, and uses the dynamic symbol table, is considered to be a
6903 dynamic reloc section. */
6905 long
6907 {
6912 {
6915 }
6926 }
6928 /* Canonicalize the dynamic relocation entries. Note that we return the
6929 dynamic relocations as a single block, although they are actually
6930 associated with particular sections; the interface, which was
6931 designed for SunOS style shared libraries, expects that there is only
6932 one set of dynamic relocs. Any loadable section that was actually
6933 installed in the BFD, and has type SHT_REL or SHT_RELA, and uses the
6934 dynamic symbol table, is considered to be a dynamic reloc section. */
6936 long
6940 {
6946 {
6949 }
6954 {
6958 {
6969 }
6970 }
6975 }
6976 \f
6977 /* Read in the version information. */
6979 bfd_boolean
6981 {
6986 {
7004 {
7005 error_return_verref:
7009 }
7023 {
7040 else
7041 {
7047 }
7057 {
7068 else
7080 }
7084 else
7093 }
7097 }
7100 {
7105 Elf_Internal_Verdef iverdefmem;
7129 /* We know the number of entries in the section but not the maximum
7130 index. Therefore we have to run through all entries and find
7131 the maximum. */
7135 {
7147 }
7150 {
7153 else
7155 }
7166 {
7174 {
7175 error_return_verdef:
7179 }
7188 else
7189 {
7195 }
7205 {
7216 else
7225 }
7232 else
7237 }
7241 }
7243 {
7246 else
7247 freeidx++;
7255 }
7257 /* Create a default version based on the soname. */
7259 {
7284 }
7288 error_return:
7292 }
7293 \f
7294 asymbol *
7296 {
7303 else
7304 {
7307 }
7308 }
7310 void
7314 {
7316 }
7318 /* Return whether a symbol name implies a local symbol. Most targets
7319 use this function for the is_local_label_name entry point, but some
7320 override it. */
7322 bfd_boolean
7325 {
7326 /* Normal local symbols start with ``.L''. */
7330 /* At least some SVR4 compilers (e.g., UnixWare 2.1 cc) generate
7331 DWARF debugging symbols starting with ``..''. */
7335 /* gcc will sometimes generate symbols beginning with ``_.L_'' when
7336 emitting DWARF debugging output. I suspect this is actually a
7337 small bug in gcc (it calls ASM_OUTPUT_LABEL when it should call
7338 ASM_GENERATE_INTERNAL_LABEL, and this causes the leading
7339 underscore to be emitted on some ELF targets). For ease of use,
7340 we treat such symbols as local. */
7345 }
7347 alent *
7350 {
7353 }
7355 bfd_boolean
7359 {
7360 /* If this isn't the right architecture for this backend, and this
7361 isn't the generic backend, fail. */
7368 }
7370 /* Find the function to a particular section and offset,
7371 for error reporting. */
7373 static bfd_boolean
7377 bfd_vma offset,
7380 {
7383 bfd_vma low_func;
7385 /* ??? Given multiple file symbols, it is impossible to reliably
7386 choose the right file name for global symbols. File symbols are
7387 local symbols, and thus all file symbols must sort before any
7388 global symbols. The ELF spec may be interpreted to say that a
7389 file symbol must sort before other local symbols, but currently
7390 ld -r doesn't do this. So, for ld -r output, it is possible to
7391 make a better choice of file name for local symbols by ignoring
7392 file symbols appearing after a given local symbol. */
7406 {
7409 bfd_vma code_off;
7412 {
7417 }
7423 {
7431 }
7434 }
7445 }
7447 /* Find the nearest line to a particular section and offset,
7448 for error reporting. */
7450 bfd_boolean
7454 bfd_vma offset,
7458 {
7459 bfd_boolean found;
7463 line_ptr))
7464 {
7468 functionname_ptr);
7471 }
7478 {
7482 functionname_ptr);
7485 }
7504 }
7506 /* Find the line for a symbol. */
7508 bfd_boolean
7511 {
7515 }
7517 /* After a call to bfd_find_nearest_line, successive calls to
7518 bfd_find_inliner_info can be used to get source information about
7519 each level of function inlining that terminated at the address
7520 passed to bfd_find_nearest_line. Currently this is only supported
7521 for DWARF2 with appropriate DWARF3 extensions. */
7523 bfd_boolean
7528 {
7529 bfd_boolean found;
7534 }
7536 int
7538 {
7543 {
7547 {
7556 }
7560 }
7563 }
7565 bfd_boolean
7567 sec_ptr section,
7569 file_ptr offset,
7570 bfd_size_type count)
7571 {
7573 bfd_signed_vma pos;
7586 }
7588 void
7592 {
7594 }
7596 /* Try to convert a non-ELF reloc into an ELF one. */
7598 bfd_boolean
7600 {
7601 /* Check whether we really have an ELF howto. */
7604 {
7605 bfd_reloc_code_real_type code;
7608 /* Alien reloc: Try to determine its type to replace it with an
7609 equivalent ELF reloc. */
7612 {
7614 {
7635 }
7640 {
7643 else
7645 }
7646 }
7647 else
7648 {
7650 {
7671 }
7674 }
7678 else
7680 }
7684 fail:
7690 }
7692 bfd_boolean
7694 {
7697 {
7701 }
7704 }
7706 /* For Rel targets, we encode meaningful data for BFD_RELOC_VTABLE_ENTRY
7707 in the relocation's offset. Thus we cannot allow any sort of sanity
7708 range-checking to interfere. There is nothing else to do in processing
7709 this reloc. */
7711 bfd_reloc_status_type
7712 _bfd_elf_rel_vtable_reloc_fn
7717 {
7719 }
7720 \f
7721 /* Elf core file support. Much of this only works on native
7722 toolchains, since we rely on knowing the
7723 machine-dependent procfs structure in order to pick
7724 out details about the corefile. */
7726 #ifdef HAVE_SYS_PROCFS_H
7727 /* Needed for new procfs interface on sparc-solaris. */
7728 # define _STRUCTURED_PROC 1
7729 # include <sys/procfs.h>
7730 #endif
7732 /* Return a PID that identifies a "thread" for threaded cores, or the
7733 PID of the main process for non-threaded cores. */
7735 static int
7737 {
7745 }
7747 /* If there isn't a section called NAME, make one, using
7748 data from SECT. Note, this function will generate a
7749 reference to NAME, so you shouldn't deallocate or
7750 overwrite it. */
7752 static bfd_boolean
7754 {
7768 }
7770 /* Create a pseudosection containing SIZE bytes at FILEPOS. This
7771 actually creates up to two pseudosections:
7772 - For the single-threaded case, a section named NAME, unless
7773 such a section already exists.
7774 - For the multi-threaded case, a section named "NAME/PID", where
7775 PID is elfcore_make_pid (abfd).
7776 Both pseudosections have identical contents. */
7777 bfd_boolean
7781 ufile_ptr filepos)
7782 {
7788 /* Build the section name. */
7798 SEC_HAS_CONTENTS);
7806 }
7808 /* prstatus_t exists on:
7809 solaris 2.5+
7810 linux 2.[01] + glibc
7811 unixware 4.2
7812 */
7814 #if defined (HAVE_PRSTATUS_T)
7816 static bfd_boolean
7818 {
7823 {
7824 prstatus_t prstat;
7830 /* Do not overwrite the core signal if it
7831 has already been set by another thread. */
7837 /* pr_who exists on:
7838 solaris 2.5+
7839 unixware 4.2
7840 pr_who doesn't exist on:
7841 linux 2.[01]
7842 */
7843 #if defined (HAVE_PRSTATUS_T_PR_WHO)
7845 #else
7847 #endif
7848 }
7849 #if defined (HAVE_PRSTATUS32_T)
7851 {
7852 /* 64-bit host, 32-bit corefile */
7853 prstatus32_t prstat;
7859 /* Do not overwrite the core signal if it
7860 has already been set by another thread. */
7866 /* pr_who exists on:
7867 solaris 2.5+
7868 unixware 4.2
7869 pr_who doesn't exist on:
7870 linux 2.[01]
7871 */
7872 #if defined (HAVE_PRSTATUS32_T_PR_WHO)
7874 #else
7876 #endif
7877 }
7879 else
7880 {
7881 /* Fail - we don't know how to handle any other
7882 note size (ie. data object type). */
7884 }
7886 /* Make a ".reg/999" section and a ".reg" section. */
7889 }
7892 /* Create a pseudosection containing the exact contents of NOTE. */
7893 static bfd_boolean
7897 {
7900 }
7902 /* There isn't a consistent prfpregset_t across platforms,
7903 but it doesn't matter, because we don't have to pick this
7904 data structure apart. */
7906 static bfd_boolean
7908 {
7910 }
7912 /* Linux dumps the Intel SSE regs in a note named "LINUX" with a note
7913 type of NT_PRXFPREG. Just include the whole note's contents
7914 literally. */
7916 static bfd_boolean
7918 {
7920 }
7922 /* Linux dumps the Intel XSAVE extended state in a note named "LINUX"
7923 with a note type of NT_X86_XSTATE. Just include the whole note's
7924 contents literally. */
7926 static bfd_boolean
7928 {
7930 }
7932 static bfd_boolean
7934 {
7936 }
7938 static bfd_boolean
7940 {
7942 }
7944 static bfd_boolean
7946 {
7948 }
7950 static bfd_boolean
7952 {
7954 }
7956 static bfd_boolean
7958 {
7960 }
7962 static bfd_boolean
7964 {
7966 }
7968 static bfd_boolean
7970 {
7972 }
7974 static bfd_boolean
7976 {
7978 }
7980 static bfd_boolean
7982 {
7984 }
7986 static bfd_boolean
7988 {
7990 }
7992 static bfd_boolean
7994 {
7996 }
7998 #if defined (HAVE_PRPSINFO_T)
8002 #endif
8003 #endif
8005 #if defined (HAVE_PSINFO_T)
8009 #endif
8010 #endif
8012 /* return a malloc'ed copy of a string at START which is at
8013 most MAX bytes long, possibly without a terminating '\0'.
8014 the copy will always have a terminating '\0'. */
8018 {
8025 else
8036 }
8038 #if defined (HAVE_PRPSINFO_T) || defined (HAVE_PSINFO_T)
8039 static bfd_boolean
8041 {
8043 {
8044 elfcore_psinfo_t psinfo;
8048 #if defined (HAVE_PSINFO_T_PR_PID) || defined (HAVE_PRPSINFO_T_PR_PID)
8050 #endif
8058 }
8059 #if defined (HAVE_PRPSINFO32_T) || defined (HAVE_PSINFO32_T)
8061 {
8062 /* 64-bit host, 32-bit corefile */
8063 elfcore_psinfo32_t psinfo;
8067 #if defined (HAVE_PSINFO32_T_PR_PID) || defined (HAVE_PRPSINFO32_T_PR_PID)
8069 #endif
8077 }
8078 #endif
8080 else
8081 {
8082 /* Fail - we don't know how to handle any other
8083 note size (ie. data object type). */
8085 }
8087 /* Note that for some reason, a spurious space is tacked
8088 onto the end of the args in some (at least one anyway)
8089 implementations, so strip it off if it exists. */
8091 {
8097 }
8100 }
8103 #if defined (HAVE_PSTATUS_T)
8104 static bfd_boolean
8106 {
8108 #if defined (HAVE_PXSTATUS_T)
8110 #endif
8111 )
8112 {
8113 pstatus_t pstat;
8118 }
8119 #if defined (HAVE_PSTATUS32_T)
8121 {
8122 /* 64-bit host, 32-bit corefile */
8123 pstatus32_t pstat;
8128 }
8129 #endif
8130 /* Could grab some more details from the "representative"
8131 lwpstatus_t in pstat.pr_lwp, but we'll catch it all in an
8132 NT_LWPSTATUS note, presumably. */
8135 }
8138 #if defined (HAVE_LWPSTATUS_T)
8139 static bfd_boolean
8141 {
8142 lwpstatus_t lwpstat;
8149 #if defined (HAVE_LWPXSTATUS_T)
8151 #endif
8152 )
8158 /* Do not overwrite the core signal if it has already been set by
8159 another thread. */
8163 /* Make a ".reg/999" section. */
8176 #if defined (HAVE_LWPSTATUS_T_PR_CONTEXT)
8180 #endif
8182 #if defined (HAVE_LWPSTATUS_T_PR_REG)
8185 #endif
8192 /* Make a ".reg2/999" section */
8205 #if defined (HAVE_LWPSTATUS_T_PR_CONTEXT)
8209 #endif
8211 #if defined (HAVE_LWPSTATUS_T_PR_FPREG)
8214 #endif
8219 }
8222 static bfd_boolean
8224 {
8231 bfd_vma base_addr;
8242 {
8244 /* FIXME: need to add ->core_command. */
8245 /* process_info.pid */
8247 /* process_info.signal */
8252 /* Make a ".reg/999" section. */
8253 /* thread_info.tid */
8267 /* sizeof (thread_info.thread_context) */
8269 /* offsetof (thread_info.thread_context) */
8273 /* thread_info.is_active_thread */
8282 /* Make a ".module/xxxxxxxx" section. */
8283 /* module_info.base_address */
8306 }
8309 }
8311 static bfd_boolean
8313 {
8317 {
8325 #if defined (HAVE_PRSTATUS_T)
8327 #else
8329 #endif
8331 #if defined (HAVE_PSTATUS_T)
8334 #endif
8336 #if defined (HAVE_LWPSTATUS_T)
8339 #endif
8351 else
8358 else
8365 else
8372 else
8379 else
8386 else
8393 else
8400 else
8407 else
8414 else
8421 else
8428 else
8435 else
8443 #if defined (HAVE_PRPSINFO_T) || defined (HAVE_PSINFO_T)
8445 #else
8447 #endif
8450 {
8452 SEC_HAS_CONTENTS);
8461 }
8462 }
8463 }
8465 static bfd_boolean
8467 {
8476 }
8478 static bfd_boolean
8480 {
8482 {
8488 }
8489 }
8491 static bfd_boolean
8493 {
8505 }
8507 static bfd_boolean
8509 {
8511 {
8517 }
8518 }
8520 static bfd_boolean
8522 {
8527 {
8530 }
8532 }
8534 static bfd_boolean
8536 {
8537 /* Signal number at offset 0x08. */
8541 /* Process ID at offset 0x50. */
8545 /* Command name at 0x7c (max 32 bytes, including nul). */
8550 note);
8551 }
8553 static bfd_boolean
8555 {
8562 {
8563 /* NetBSD-specific core "procinfo". Note that we expect to
8564 find this note before any of the others, which is fine,
8565 since the kernel writes this note out first when it
8566 creates a core file. */
8569 }
8571 /* As of Jan 2002 there are no other machine-independent notes
8572 defined for NetBSD core files. If the note type is less
8573 than the start of the machine-dependent note types, we don't
8574 understand it. */
8581 {
8582 /* On the Alpha, SPARC (32-bit and 64-bit), PT_GETREGS == mach+0 and
8583 PT_GETFPREGS == mach+2. */
8588 {
8597 }
8599 /* On all other arch's, PT_GETREGS == mach+1 and
8600 PT_GETFPREGS == mach+3. */
8604 {
8613 }
8614 }
8615 /* NOTREACHED */
8616 }
8618 static bfd_boolean
8620 {
8621 /* Signal number at offset 0x08. */
8625 /* Process ID at offset 0x20. */
8629 /* Command name at 0x48 (max 32 bytes, including nul). */
8634 }
8636 static bfd_boolean
8638 {
8652 {
8654 SEC_HAS_CONTENTS);
8663 }
8666 {
8668 SEC_HAS_CONTENTS);
8677 }
8680 }
8682 static bfd_boolean
8684 {
8692 /* nto_procfs_status 'pid' field is at offset 0. */
8695 /* nto_procfs_status 'tid' field is at offset 4. Pass it back. */
8698 /* nto_procfs_status 'flags' field is at offset 8. */
8701 /* nto_procfs_status 'what' field is at offset 14. */
8703 {
8706 }
8708 /* _DEBUG_FLAG_CURTID (current thread) is 0x80. Some cores
8709 do not come from signals so we make sure we set the current
8710 thread just in case. */
8714 /* Make a ".qnx_core_status/%d" section. */
8731 }
8733 static bfd_boolean
8738 {
8743 /* Make a "(base)/%d" section. */
8759 /* This is the current thread. */
8764 }
8766 #define BFD_QNT_CORE_INFO 7
8767 #define BFD_QNT_CORE_STATUS 8
8768 #define BFD_QNT_CORE_GREG 9
8769 #define BFD_QNT_CORE_FPREG 10
8771 static bfd_boolean
8773 {
8774 /* Every GREG section has a STATUS section before it. Store the
8775 tid from the previous call to pass down to the next gregs
8776 function. */
8780 {
8791 }
8792 }
8794 static bfd_boolean
8796 {
8801 /* Use note name as section name. */
8818 }
8820 /* Function: elfcore_write_note
8822 Inputs:
8823 buffer to hold note, and current size of buffer
8824 name of note
8825 type of note
8826 data for note
8827 size of data for note
8829 Writes note to end of buffer. ELF64 notes are written exactly as
8830 for ELF32, despite the current (as of 2006) ELF gabi specifying
8831 that they ought to have 8-byte namesz and descsz field, and have
8832 8-byte alignment. Other writers, eg. Linux kernel, do the same.
8834 Return:
8835 Pointer to realloc'd buffer, *BUFSIZ updated. */
8845 {
8868 {
8872 {
8875 }
8876 }
8880 {
8883 }
8885 }
8893 {
8897 {
8903 }
8905 #if defined (HAVE_PRPSINFO_T) || defined (HAVE_PSINFO_T)
8906 #if defined (HAVE_PRPSINFO32_T) || defined (HAVE_PSINFO32_T)
8908 {
8909 #if defined (HAVE_PSINFO32_T)
8910 psinfo32_t data;
8912 #else
8913 prpsinfo32_t data;
8915 #endif
8922 }
8923 else
8924 #endif
8925 {
8926 #if defined (HAVE_PSINFO_T)
8927 psinfo_t data;
8929 #else
8930 prpsinfo_t data;
8932 #endif
8939 }
8944 }
8953 {
8957 {
8960 NT_PRSTATUS,
8964 }
8966 #if defined (HAVE_PRSTATUS_T)
8967 #if defined (HAVE_PRSTATUS32_T)
8969 {
8970 prstatus32_t prstat;
8978 }
8979 else
8980 #endif
8981 {
8982 prstatus_t prstat;
8990 }
8995 }
8997 #if defined (HAVE_LWPSTATUS_T)
9005 {
9006 lwpstatus_t lwpstat;
9012 #if defined (HAVE_LWPSTATUS_T_PR_REG)
9014 #elif defined (HAVE_LWPSTATUS_T_PR_CONTEXT)
9015 #if !defined(gregs)
9018 #else
9021 #endif
9022 #endif
9025 }
9028 #if defined (HAVE_PSTATUS_T)
9036 {
9038 #if defined (HAVE_PSTATUS32_T)
9042 {
9043 pstatus32_t pstat;
9050 }
9051 else
9052 #endif
9053 {
9054 pstatus_t pstat;
9061 }
9062 }
9071 {
9075 }
9083 {
9087 }
9092 {
9096 }
9104 {
9108 }
9116 {
9120 }
9128 {
9133 }
9141 {
9145 }
9153 {
9157 }
9165 {
9169 }
9177 {
9181 }
9189 {
9193 }
9201 {
9206 }
9214 {
9219 }
9227 {
9231 }
9240 {
9270 }
9272 static bfd_boolean
9274 {
9279 {
9280 /* FIXME: bad alignment assumption. */
9282 Elf_Internal_Note in;
9303 {
9309 {
9312 }
9314 {
9317 }
9319 {
9322 }
9324 {
9327 }
9328 else
9329 {
9332 }
9337 {
9340 }
9343 {
9346 }
9348 }
9351 }
9354 }
9356 static bfd_boolean
9358 {
9373 {
9376 }
9380 }
9381 \f
9382 /* Providing external access to the ELF program header table. */
9384 /* Return an upper bound on the number of bytes required to store a
9385 copy of ABFD's program header table entries. Return -1 if an error
9386 occurs; bfd_get_error will return an appropriate code. */
9388 long
9390 {
9392 {
9395 }
9398 }
9400 /* Copy ABFD's program header table entries to *PHDRS. The entries
9401 will be stored as an array of Elf_Internal_Phdr structures, as
9402 defined in include/elf/internal.h. To find out how large the
9403 buffer needs to be, call bfd_get_elf_phdr_upper_bound.
9405 Return the number of program header table entries read, or -1 if an
9406 error occurs; bfd_get_error will return an appropriate code. */
9408 int
9410 {
9414 {
9417 }
9424 }
9426 enum elf_reloc_type_class
9428 {
9430 }
9432 /* For RELA architectures, return the relocation value for a
9433 relocation against a local symbol. */
9435 bfd_vma
9440 {
9442 bfd_vma relocation;
9450 {
9456 {
9457 /* If we have changed the section, and our original section is
9458 marked with SEC_EXCLUDE, it means that the original
9459 SEC_MERGE section has been completely subsumed in some
9460 other SEC_MERGE section. In this case, we need to leave
9461 some info around for --emit-relocs. */
9465 }
9468 }
9470 }
9472 bfd_vma
9476 bfd_vma addend)
9477 {
9486 }
9488 bfd_vma
9492 bfd_vma offset)
9493 {
9495 {
9498 offset);
9503 {
9507 }
9509 }
9510 }
9511 \f
9512 /* Create a new BFD as if by bfd_openr. Rather than opening a file,
9513 reconstruct an ELF file by reading the segments out of remote memory
9514 based on the ELF file header at EHDR_VMA and the ELF program headers it
9515 points to. If not null, *LOADBASEP is filled in with the difference
9516 between the VMAs from which the segments were read, and the VMAs the
9517 file headers (and hence BFD's idea of each section's VMA) put them at.
9519 The function TARGET_READ_MEMORY is called to copy LEN bytes from the
9520 remote memory at target address VMA into the local buffer at MYADDR; it
9521 should return zero on success or an `errno' code on failure. TEMPL must
9522 be a BFD for an ELF target with the word size and byte order found in
9523 the remote memory. */
9525 bfd *
9526 bfd_elf_bfd_from_remote_memory
9528 bfd_vma ehdr_vma,
9531 {
9534 }
9535 \f
9536 long
9543 {
9591 {
9594 {
9595 #ifdef BFD64
9597 #else
9599 #endif
9600 }
9601 }
9611 {
9613 bfd_vma addr;
9620 /* Undefined syms won't have BSF_LOCAL or BSF_GLOBAL set. Since
9621 we are defining a symbol, ensure one of them is set. */
9633 {
9640 ;
9644 }
9648 }
9651 }
9653 /* It is only used by x86-64 so far. */
9654 asection _bfd_elf_large_com_section
9658 void
9661 {
9668 /* To make things simpler for the loader on Linux systems we set the
9669 osabi field to ELFOSABI_GNU if the binary contains symbols of
9670 the STT_GNU_IFUNC type or STB_GNU_UNIQUE binding. */
9674 }
9677 /* Return TRUE for ELF symbol types that represent functions.
9678 This is the default version of this function, which is sufficient for
9679 most targets. It returns true if TYPE is STT_FUNC or STT_GNU_IFUNC. */
9681 bfd_boolean
9683 {
9686 }
9688 /* Return TRUE iff the ELF symbol SYM might be a function. Set *CODE_SEC
9689 and *CODE_OFF to the function's entry point. */
9691 bfd_boolean
9694 {
9702 }