1 /* MIPS-specific support for ELF
2 Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002,
3 2003, 2004, 2005, 2006 Free Software Foundation, Inc.
5 Most of the information added by Ian Lance Taylor, Cygnus Support,
7 N32/64 ABI support added by Mark Mitchell, CodeSourcery, LLC.
8 <mark@codesourcery.com>
9 Traditional MIPS targets support added by Koundinya.K, Dansk Data
10 Elektronik & Operations Research Group. <kk@ddeorg.soft.net>
12 This file is part of BFD, the Binary File Descriptor library.
14 This program is free software; you can redistribute it and/or modify
15 it under the terms of the GNU General Public License as published by
16 the Free Software Foundation; either version 2 of the License, or
17 (at your option) any later version.
19 This program is distributed in the hope that it will be useful,
20 but WITHOUT ANY WARRANTY; without even the implied warranty of
21 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
22 GNU General Public License for more details.
24 You should have received a copy of the GNU General Public License
25 along with this program; if not, write to the Free Software
26 Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston, MA 02110-1301, USA. */
28 /* This file handles functionality common to the different MIPS ABI's. */
33 #include "libiberty.h"
35 #include "elfxx-mips.h"
37 #include "elf-vxworks.h"
39 /* Get the ECOFF swapping routines. */
41 #include "coff/symconst.h"
42 #include "coff/ecoff.h"
43 #include "coff/mips.h"
47 /* This structure is used to hold information about one GOT entry.
48 There are three types of entry:
50 (1) absolute addresses
52 (2) SYMBOL + OFFSET addresses, where SYMBOL is local to an input bfd
53 (abfd != NULL, symndx >= 0)
54 (3) global and forced-local symbols
55 (abfd != NULL, symndx == -1)
57 Type (3) entries are treated differently for different types of GOT.
58 In the "master" GOT -- i.e. the one that describes every GOT
59 reference needed in the link -- the mips_got_entry is keyed on both
60 the symbol and the input bfd that references it. If it turns out
61 that we need multiple GOTs, we can then use this information to
62 create separate GOTs for each input bfd.
64 However, we want each of these separate GOTs to have at most one
65 entry for a given symbol, so their type (3) entries are keyed only
66 on the symbol. The input bfd given by the "abfd" field is somewhat
67 arbitrary in this case.
69 This means that when there are multiple GOTs, each GOT has a unique
70 mips_got_entry for every symbol within it. We can therefore use the
71 mips_got_entry fields (tls_type and gotidx) to track the symbol's
74 However, if it turns out that we need only a single GOT, we continue
75 to use the master GOT to describe it. There may therefore be several
76 mips_got_entries for the same symbol, each with a different input bfd.
77 We want to make sure that each symbol gets a unique GOT entry, so when
78 there's a single GOT, we use the symbol's hash entry, not the
79 mips_got_entry fields, to track a symbol's GOT index. */
82 /* The input bfd in which the symbol is defined. */
84 /* The index of the symbol, as stored in the relocation r_info, if
85 we have a local symbol; -1 otherwise. */
89 /* If abfd == NULL, an address that must be stored in the got. */
91 /* If abfd != NULL && symndx != -1, the addend of the relocation
92 that should be added to the symbol value. */
94 /* If abfd != NULL && symndx == -1, the hash table entry
95 corresponding to a global symbol in the got (or, local, if
97 struct mips_elf_link_hash_entry
*h
;
100 /* The TLS types included in this GOT entry (specifically, GD and
101 IE). The GD and IE flags can be added as we encounter new
102 relocations. LDM can also be set; it will always be alone, not
103 combined with any GD or IE flags. An LDM GOT entry will be
104 a local symbol entry with r_symndx == 0. */
105 unsigned char tls_type
;
107 /* The offset from the beginning of the .got section to the entry
108 corresponding to this symbol+addend. If it's a global symbol
109 whose offset is yet to be decided, it's going to be -1. */
113 /* This structure is used to hold .got information when linking. */
117 /* The global symbol in the GOT with the lowest index in the dynamic
119 struct elf_link_hash_entry
*global_gotsym
;
120 /* The number of global .got entries. */
121 unsigned int global_gotno
;
122 /* The number of .got slots used for TLS. */
123 unsigned int tls_gotno
;
124 /* The first unused TLS .got entry. Used only during
125 mips_elf_initialize_tls_index. */
126 unsigned int tls_assigned_gotno
;
127 /* The number of local .got entries. */
128 unsigned int local_gotno
;
129 /* The number of local .got entries we have used. */
130 unsigned int assigned_gotno
;
131 /* A hash table holding members of the got. */
132 struct htab
*got_entries
;
133 /* A hash table mapping input bfds to other mips_got_info. NULL
134 unless multi-got was necessary. */
135 struct htab
*bfd2got
;
136 /* In multi-got links, a pointer to the next got (err, rather, most
137 of the time, it points to the previous got). */
138 struct mips_got_info
*next
;
139 /* This is the GOT index of the TLS LDM entry for the GOT, MINUS_ONE
140 for none, or MINUS_TWO for not yet assigned. This is needed
141 because a single-GOT link may have multiple hash table entries
142 for the LDM. It does not get initialized in multi-GOT mode. */
143 bfd_vma tls_ldm_offset
;
146 /* Map an input bfd to a got in a multi-got link. */
148 struct mips_elf_bfd2got_hash
{
150 struct mips_got_info
*g
;
153 /* Structure passed when traversing the bfd2got hash table, used to
154 create and merge bfd's gots. */
156 struct mips_elf_got_per_bfd_arg
158 /* A hashtable that maps bfds to gots. */
160 /* The output bfd. */
162 /* The link information. */
163 struct bfd_link_info
*info
;
164 /* A pointer to the primary got, i.e., the one that's going to get
165 the implicit relocations from DT_MIPS_LOCAL_GOTNO and
167 struct mips_got_info
*primary
;
168 /* A non-primary got we're trying to merge with other input bfd's
170 struct mips_got_info
*current
;
171 /* The maximum number of got entries that can be addressed with a
173 unsigned int max_count
;
174 /* The number of local and global entries in the primary got. */
175 unsigned int primary_count
;
176 /* The number of local and global entries in the current got. */
177 unsigned int current_count
;
178 /* The total number of global entries which will live in the
179 primary got and be automatically relocated. This includes
180 those not referenced by the primary GOT but included in
182 unsigned int global_count
;
185 /* Another structure used to pass arguments for got entries traversal. */
187 struct mips_elf_set_global_got_offset_arg
189 struct mips_got_info
*g
;
191 unsigned int needed_relocs
;
192 struct bfd_link_info
*info
;
195 /* A structure used to count TLS relocations or GOT entries, for GOT
196 entry or ELF symbol table traversal. */
198 struct mips_elf_count_tls_arg
200 struct bfd_link_info
*info
;
204 struct _mips_elf_section_data
206 struct bfd_elf_section_data elf
;
209 struct mips_got_info
*got_info
;
214 #define mips_elf_section_data(sec) \
215 ((struct _mips_elf_section_data *) elf_section_data (sec))
217 /* This structure is passed to mips_elf_sort_hash_table_f when sorting
218 the dynamic symbols. */
220 struct mips_elf_hash_sort_data
222 /* The symbol in the global GOT with the lowest dynamic symbol table
224 struct elf_link_hash_entry
*low
;
225 /* The least dynamic symbol table index corresponding to a non-TLS
226 symbol with a GOT entry. */
227 long min_got_dynindx
;
228 /* The greatest dynamic symbol table index corresponding to a symbol
229 with a GOT entry that is not referenced (e.g., a dynamic symbol
230 with dynamic relocations pointing to it from non-primary GOTs). */
231 long max_unref_got_dynindx
;
232 /* The greatest dynamic symbol table index not corresponding to a
233 symbol without a GOT entry. */
234 long max_non_got_dynindx
;
237 /* The MIPS ELF linker needs additional information for each symbol in
238 the global hash table. */
240 struct mips_elf_link_hash_entry
242 struct elf_link_hash_entry root
;
244 /* External symbol information. */
247 /* Number of R_MIPS_32, R_MIPS_REL32, or R_MIPS_64 relocs against
249 unsigned int possibly_dynamic_relocs
;
251 /* If the R_MIPS_32, R_MIPS_REL32, or R_MIPS_64 reloc is against
252 a readonly section. */
253 bfd_boolean readonly_reloc
;
255 /* We must not create a stub for a symbol that has relocations
256 related to taking the function's address, i.e. any but
257 R_MIPS_CALL*16 ones -- see "MIPS ABI Supplement, 3rd Edition",
259 bfd_boolean no_fn_stub
;
261 /* If there is a stub that 32 bit functions should use to call this
262 16 bit function, this points to the section containing the stub. */
265 /* Whether we need the fn_stub; this is set if this symbol appears
266 in any relocs other than a 16 bit call. */
267 bfd_boolean need_fn_stub
;
269 /* If there is a stub that 16 bit functions should use to call this
270 32 bit function, this points to the section containing the stub. */
273 /* This is like the call_stub field, but it is used if the function
274 being called returns a floating point value. */
275 asection
*call_fp_stub
;
277 /* Are we forced local? This will only be set if we have converted
278 the initial global GOT entry to a local GOT entry. */
279 bfd_boolean forced_local
;
281 /* Are we referenced by some kind of relocation? */
282 bfd_boolean is_relocation_target
;
284 /* Are we referenced by branch relocations? */
285 bfd_boolean is_branch_target
;
289 #define GOT_TLS_LDM 2
291 #define GOT_TLS_OFFSET_DONE 0x40
292 #define GOT_TLS_DONE 0x80
293 unsigned char tls_type
;
294 /* This is only used in single-GOT mode; in multi-GOT mode there
295 is one mips_got_entry per GOT entry, so the offset is stored
296 there. In single-GOT mode there may be many mips_got_entry
297 structures all referring to the same GOT slot. It might be
298 possible to use root.got.offset instead, but that field is
299 overloaded already. */
300 bfd_vma tls_got_offset
;
303 /* MIPS ELF linker hash table. */
305 struct mips_elf_link_hash_table
307 struct elf_link_hash_table root
;
309 /* We no longer use this. */
310 /* String section indices for the dynamic section symbols. */
311 bfd_size_type dynsym_sec_strindex
[SIZEOF_MIPS_DYNSYM_SECNAMES
];
313 /* The number of .rtproc entries. */
314 bfd_size_type procedure_count
;
315 /* The size of the .compact_rel section (if SGI_COMPAT). */
316 bfd_size_type compact_rel_size
;
317 /* This flag indicates that the value of DT_MIPS_RLD_MAP dynamic
318 entry is set to the address of __rld_obj_head as in IRIX5. */
319 bfd_boolean use_rld_obj_head
;
320 /* This is the value of the __rld_map or __rld_obj_head symbol. */
322 /* This is set if we see any mips16 stub sections. */
323 bfd_boolean mips16_stubs_seen
;
324 /* True if we're generating code for VxWorks. */
325 bfd_boolean is_vxworks
;
326 /* Shortcuts to some dynamic sections, or NULL if they are not
334 /* The size of the PLT header in bytes (VxWorks only). */
335 bfd_vma plt_header_size
;
336 /* The size of a PLT entry in bytes (VxWorks only). */
337 bfd_vma plt_entry_size
;
338 /* The size of a function stub entry in bytes. */
339 bfd_vma function_stub_size
;
342 #define TLS_RELOC_P(r_type) \
343 (r_type == R_MIPS_TLS_DTPMOD32 \
344 || r_type == R_MIPS_TLS_DTPMOD64 \
345 || r_type == R_MIPS_TLS_DTPREL32 \
346 || r_type == R_MIPS_TLS_DTPREL64 \
347 || r_type == R_MIPS_TLS_GD \
348 || r_type == R_MIPS_TLS_LDM \
349 || r_type == R_MIPS_TLS_DTPREL_HI16 \
350 || r_type == R_MIPS_TLS_DTPREL_LO16 \
351 || r_type == R_MIPS_TLS_GOTTPREL \
352 || r_type == R_MIPS_TLS_TPREL32 \
353 || r_type == R_MIPS_TLS_TPREL64 \
354 || r_type == R_MIPS_TLS_TPREL_HI16 \
355 || r_type == R_MIPS_TLS_TPREL_LO16)
357 /* Structure used to pass information to mips_elf_output_extsym. */
362 struct bfd_link_info
*info
;
363 struct ecoff_debug_info
*debug
;
364 const struct ecoff_debug_swap
*swap
;
368 /* The names of the runtime procedure table symbols used on IRIX5. */
370 static const char * const mips_elf_dynsym_rtproc_names
[] =
373 "_procedure_string_table",
374 "_procedure_table_size",
378 /* These structures are used to generate the .compact_rel section on
383 unsigned long id1
; /* Always one? */
384 unsigned long num
; /* Number of compact relocation entries. */
385 unsigned long id2
; /* Always two? */
386 unsigned long offset
; /* The file offset of the first relocation. */
387 unsigned long reserved0
; /* Zero? */
388 unsigned long reserved1
; /* Zero? */
397 bfd_byte reserved0
[4];
398 bfd_byte reserved1
[4];
399 } Elf32_External_compact_rel
;
403 unsigned int ctype
: 1; /* 1: long 0: short format. See below. */
404 unsigned int rtype
: 4; /* Relocation types. See below. */
405 unsigned int dist2to
: 8;
406 unsigned int relvaddr
: 19; /* (VADDR - vaddr of the previous entry)/ 4 */
407 unsigned long konst
; /* KONST field. See below. */
408 unsigned long vaddr
; /* VADDR to be relocated. */
413 unsigned int ctype
: 1; /* 1: long 0: short format. See below. */
414 unsigned int rtype
: 4; /* Relocation types. See below. */
415 unsigned int dist2to
: 8;
416 unsigned int relvaddr
: 19; /* (VADDR - vaddr of the previous entry)/ 4 */
417 unsigned long konst
; /* KONST field. See below. */
425 } Elf32_External_crinfo
;
431 } Elf32_External_crinfo2
;
433 /* These are the constants used to swap the bitfields in a crinfo. */
435 #define CRINFO_CTYPE (0x1)
436 #define CRINFO_CTYPE_SH (31)
437 #define CRINFO_RTYPE (0xf)
438 #define CRINFO_RTYPE_SH (27)
439 #define CRINFO_DIST2TO (0xff)
440 #define CRINFO_DIST2TO_SH (19)
441 #define CRINFO_RELVADDR (0x7ffff)
442 #define CRINFO_RELVADDR_SH (0)
444 /* A compact relocation info has long (3 words) or short (2 words)
445 formats. A short format doesn't have VADDR field and relvaddr
446 fields contains ((VADDR - vaddr of the previous entry) >> 2). */
447 #define CRF_MIPS_LONG 1
448 #define CRF_MIPS_SHORT 0
450 /* There are 4 types of compact relocation at least. The value KONST
451 has different meaning for each type:
454 CT_MIPS_REL32 Address in data
455 CT_MIPS_WORD Address in word (XXX)
456 CT_MIPS_GPHI_LO GP - vaddr
457 CT_MIPS_JMPAD Address to jump
460 #define CRT_MIPS_REL32 0xa
461 #define CRT_MIPS_WORD 0xb
462 #define CRT_MIPS_GPHI_LO 0xc
463 #define CRT_MIPS_JMPAD 0xd
465 #define mips_elf_set_cr_format(x,format) ((x).ctype = (format))
466 #define mips_elf_set_cr_type(x,type) ((x).rtype = (type))
467 #define mips_elf_set_cr_dist2to(x,v) ((x).dist2to = (v))
468 #define mips_elf_set_cr_relvaddr(x,d) ((x).relvaddr = (d)<<2)
470 /* The structure of the runtime procedure descriptor created by the
471 loader for use by the static exception system. */
473 typedef struct runtime_pdr
{
474 bfd_vma adr
; /* Memory address of start of procedure. */
475 long regmask
; /* Save register mask. */
476 long regoffset
; /* Save register offset. */
477 long fregmask
; /* Save floating point register mask. */
478 long fregoffset
; /* Save floating point register offset. */
479 long frameoffset
; /* Frame size. */
480 short framereg
; /* Frame pointer register. */
481 short pcreg
; /* Offset or reg of return pc. */
482 long irpss
; /* Index into the runtime string table. */
484 struct exception_info
*exception_info
;/* Pointer to exception array. */
486 #define cbRPDR sizeof (RPDR)
487 #define rpdNil ((pRPDR) 0)
489 static struct mips_got_entry
*mips_elf_create_local_got_entry
490 (bfd
*, struct bfd_link_info
*, bfd
*, struct mips_got_info
*, asection
*,
491 asection
*, bfd_vma
, unsigned long, struct mips_elf_link_hash_entry
*, int);
492 static bfd_boolean mips_elf_sort_hash_table_f
493 (struct mips_elf_link_hash_entry
*, void *);
494 static bfd_vma mips_elf_high
496 static bfd_boolean mips16_stub_section_p
498 static bfd_boolean mips_elf_create_dynamic_relocation
499 (bfd
*, struct bfd_link_info
*, const Elf_Internal_Rela
*,
500 struct mips_elf_link_hash_entry
*, asection
*, bfd_vma
,
501 bfd_vma
*, asection
*);
502 static hashval_t mips_elf_got_entry_hash
504 static bfd_vma mips_elf_adjust_gp
505 (bfd
*, struct mips_got_info
*, bfd
*);
506 static struct mips_got_info
*mips_elf_got_for_ibfd
507 (struct mips_got_info
*, bfd
*);
509 /* This will be used when we sort the dynamic relocation records. */
510 static bfd
*reldyn_sorting_bfd
;
512 /* Nonzero if ABFD is using the N32 ABI. */
513 #define ABI_N32_P(abfd) \
514 ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI2) != 0)
516 /* Nonzero if ABFD is using the N64 ABI. */
517 #define ABI_64_P(abfd) \
518 (get_elf_backend_data (abfd)->s->elfclass == ELFCLASS64)
520 /* Nonzero if ABFD is using NewABI conventions. */
521 #define NEWABI_P(abfd) (ABI_N32_P (abfd) || ABI_64_P (abfd))
523 /* The IRIX compatibility level we are striving for. */
524 #define IRIX_COMPAT(abfd) \
525 (get_elf_backend_data (abfd)->elf_backend_mips_irix_compat (abfd))
527 /* Whether we are trying to be compatible with IRIX at all. */
528 #define SGI_COMPAT(abfd) \
529 (IRIX_COMPAT (abfd) != ict_none)
531 /* The name of the options section. */
532 #define MIPS_ELF_OPTIONS_SECTION_NAME(abfd) \
533 (NEWABI_P (abfd) ? ".MIPS.options" : ".options")
535 /* True if NAME is the recognized name of any SHT_MIPS_OPTIONS section.
536 Some IRIX system files do not use MIPS_ELF_OPTIONS_SECTION_NAME. */
537 #define MIPS_ELF_OPTIONS_SECTION_NAME_P(NAME) \
538 (strcmp (NAME, ".MIPS.options") == 0 || strcmp (NAME, ".options") == 0)
540 /* Whether the section is readonly. */
541 #define MIPS_ELF_READONLY_SECTION(sec) \
542 ((sec->flags & (SEC_ALLOC | SEC_LOAD | SEC_READONLY)) \
543 == (SEC_ALLOC | SEC_LOAD | SEC_READONLY))
545 /* The name of the stub section. */
546 #define MIPS_ELF_STUB_SECTION_NAME(abfd) ".MIPS.stubs"
548 /* The size of an external REL relocation. */
549 #define MIPS_ELF_REL_SIZE(abfd) \
550 (get_elf_backend_data (abfd)->s->sizeof_rel)
552 /* The size of an external RELA relocation. */
553 #define MIPS_ELF_RELA_SIZE(abfd) \
554 (get_elf_backend_data (abfd)->s->sizeof_rela)
556 /* The size of an external dynamic table entry. */
557 #define MIPS_ELF_DYN_SIZE(abfd) \
558 (get_elf_backend_data (abfd)->s->sizeof_dyn)
560 /* The size of a GOT entry. */
561 #define MIPS_ELF_GOT_SIZE(abfd) \
562 (get_elf_backend_data (abfd)->s->arch_size / 8)
564 /* The size of a symbol-table entry. */
565 #define MIPS_ELF_SYM_SIZE(abfd) \
566 (get_elf_backend_data (abfd)->s->sizeof_sym)
568 /* The default alignment for sections, as a power of two. */
569 #define MIPS_ELF_LOG_FILE_ALIGN(abfd) \
570 (get_elf_backend_data (abfd)->s->log_file_align)
572 /* Get word-sized data. */
573 #define MIPS_ELF_GET_WORD(abfd, ptr) \
574 (ABI_64_P (abfd) ? bfd_get_64 (abfd, ptr) : bfd_get_32 (abfd, ptr))
576 /* Put out word-sized data. */
577 #define MIPS_ELF_PUT_WORD(abfd, val, ptr) \
579 ? bfd_put_64 (abfd, val, ptr) \
580 : bfd_put_32 (abfd, val, ptr))
582 /* Add a dynamic symbol table-entry. */
583 #define MIPS_ELF_ADD_DYNAMIC_ENTRY(info, tag, val) \
584 _bfd_elf_add_dynamic_entry (info, tag, val)
586 #define MIPS_ELF_RTYPE_TO_HOWTO(abfd, rtype, rela) \
587 (get_elf_backend_data (abfd)->elf_backend_mips_rtype_to_howto (rtype, rela))
589 /* Determine whether the internal relocation of index REL_IDX is REL
590 (zero) or RELA (non-zero). The assumption is that, if there are
591 two relocation sections for this section, one of them is REL and
592 the other is RELA. If the index of the relocation we're testing is
593 in range for the first relocation section, check that the external
594 relocation size is that for RELA. It is also assumed that, if
595 rel_idx is not in range for the first section, and this first
596 section contains REL relocs, then the relocation is in the second
597 section, that is RELA. */
598 #define MIPS_RELOC_RELA_P(abfd, sec, rel_idx) \
599 ((NUM_SHDR_ENTRIES (&elf_section_data (sec)->rel_hdr) \
600 * get_elf_backend_data (abfd)->s->int_rels_per_ext_rel \
601 > (bfd_vma)(rel_idx)) \
602 == (elf_section_data (sec)->rel_hdr.sh_entsize \
603 == (ABI_64_P (abfd) ? sizeof (Elf64_External_Rela) \
604 : sizeof (Elf32_External_Rela))))
606 /* The name of the dynamic relocation section. */
607 #define MIPS_ELF_REL_DYN_NAME(INFO) \
608 (mips_elf_hash_table (INFO)->is_vxworks ? ".rela.dyn" : ".rel.dyn")
610 /* In case we're on a 32-bit machine, construct a 64-bit "-1" value
611 from smaller values. Start with zero, widen, *then* decrement. */
612 #define MINUS_ONE (((bfd_vma)0) - 1)
613 #define MINUS_TWO (((bfd_vma)0) - 2)
615 /* The number of local .got entries we reserve. */
616 #define MIPS_RESERVED_GOTNO(INFO) \
617 (mips_elf_hash_table (INFO)->is_vxworks ? 3 : 2)
619 /* The offset of $gp from the beginning of the .got section. */
620 #define ELF_MIPS_GP_OFFSET(INFO) \
621 (mips_elf_hash_table (INFO)->is_vxworks ? 0x0 : 0x7ff0)
623 /* The maximum size of the GOT for it to be addressable using 16-bit
625 #define MIPS_ELF_GOT_MAX_SIZE(INFO) (ELF_MIPS_GP_OFFSET (INFO) + 0x7fff)
627 /* Instructions which appear in a stub. */
628 #define STUB_LW(abfd) \
630 ? 0xdf998010 /* ld t9,0x8010(gp) */ \
631 : 0x8f998010)) /* lw t9,0x8010(gp) */
632 #define STUB_MOVE(abfd) \
634 ? 0x03e0782d /* daddu t7,ra */ \
635 : 0x03e07821)) /* addu t7,ra */
636 #define STUB_LUI(VAL) (0x3c180000 + (VAL)) /* lui t8,VAL */
637 #define STUB_JALR 0x0320f809 /* jalr t9,ra */
638 #define STUB_ORI(VAL) (0x37180000 + (VAL)) /* ori t8,t8,VAL */
639 #define STUB_LI16U(VAL) (0x34180000 + (VAL)) /* ori t8,zero,VAL unsigned */
640 #define STUB_LI16S(abfd, VAL) \
642 ? (0x64180000 + (VAL)) /* daddiu t8,zero,VAL sign extended */ \
643 : (0x24180000 + (VAL)))) /* addiu t8,zero,VAL sign extended */
645 #define MIPS_FUNCTION_STUB_NORMAL_SIZE 16
646 #define MIPS_FUNCTION_STUB_BIG_SIZE 20
648 /* The name of the dynamic interpreter. This is put in the .interp
651 #define ELF_DYNAMIC_INTERPRETER(abfd) \
652 (ABI_N32_P (abfd) ? "/usr/lib32/libc.so.1" \
653 : ABI_64_P (abfd) ? "/usr/lib64/libc.so.1" \
654 : "/usr/lib/libc.so.1")
657 #define MNAME(bfd,pre,pos) \
658 (ABI_64_P (bfd) ? CONCAT4 (pre,64,_,pos) : CONCAT4 (pre,32,_,pos))
659 #define ELF_R_SYM(bfd, i) \
660 (ABI_64_P (bfd) ? ELF64_R_SYM (i) : ELF32_R_SYM (i))
661 #define ELF_R_TYPE(bfd, i) \
662 (ABI_64_P (bfd) ? ELF64_MIPS_R_TYPE (i) : ELF32_R_TYPE (i))
663 #define ELF_R_INFO(bfd, s, t) \
664 (ABI_64_P (bfd) ? ELF64_R_INFO (s, t) : ELF32_R_INFO (s, t))
666 #define MNAME(bfd,pre,pos) CONCAT4 (pre,32,_,pos)
667 #define ELF_R_SYM(bfd, i) \
669 #define ELF_R_TYPE(bfd, i) \
671 #define ELF_R_INFO(bfd, s, t) \
672 (ELF32_R_INFO (s, t))
675 /* The mips16 compiler uses a couple of special sections to handle
676 floating point arguments.
678 Section names that look like .mips16.fn.FNNAME contain stubs that
679 copy floating point arguments from the fp regs to the gp regs and
680 then jump to FNNAME. If any 32 bit function calls FNNAME, the
681 call should be redirected to the stub instead. If no 32 bit
682 function calls FNNAME, the stub should be discarded. We need to
683 consider any reference to the function, not just a call, because
684 if the address of the function is taken we will need the stub,
685 since the address might be passed to a 32 bit function.
687 Section names that look like .mips16.call.FNNAME contain stubs
688 that copy floating point arguments from the gp regs to the fp
689 regs and then jump to FNNAME. If FNNAME is a 32 bit function,
690 then any 16 bit function that calls FNNAME should be redirected
691 to the stub instead. If FNNAME is not a 32 bit function, the
692 stub should be discarded.
694 .mips16.call.fp.FNNAME sections are similar, but contain stubs
695 which call FNNAME and then copy the return value from the fp regs
696 to the gp regs. These stubs store the return value in $18 while
697 calling FNNAME; any function which might call one of these stubs
698 must arrange to save $18 around the call. (This case is not
699 needed for 32 bit functions that call 16 bit functions, because
700 16 bit functions always return floating point values in both
703 Note that in all cases FNNAME might be defined statically.
704 Therefore, FNNAME is not used literally. Instead, the relocation
705 information will indicate which symbol the section is for.
707 We record any stubs that we find in the symbol table. */
709 #define FN_STUB ".mips16.fn."
710 #define CALL_STUB ".mips16.call."
711 #define CALL_FP_STUB ".mips16.call.fp."
713 #define FN_STUB_P(name) CONST_STRNEQ (name, FN_STUB)
714 #define CALL_STUB_P(name) CONST_STRNEQ (name, CALL_STUB)
715 #define CALL_FP_STUB_P(name) CONST_STRNEQ (name, CALL_FP_STUB)
717 /* The format of the first PLT entry in a VxWorks executable. */
718 static const bfd_vma mips_vxworks_exec_plt0_entry
[] = {
719 0x3c190000, /* lui t9, %hi(_GLOBAL_OFFSET_TABLE_) */
720 0x27390000, /* addiu t9, t9, %lo(_GLOBAL_OFFSET_TABLE_) */
721 0x8f390008, /* lw t9, 8(t9) */
722 0x00000000, /* nop */
723 0x03200008, /* jr t9 */
727 /* The format of subsequent PLT entries. */
728 static const bfd_vma mips_vxworks_exec_plt_entry
[] = {
729 0x10000000, /* b .PLT_resolver */
730 0x24180000, /* li t8, <pltindex> */
731 0x3c190000, /* lui t9, %hi(<.got.plt slot>) */
732 0x27390000, /* addiu t9, t9, %lo(<.got.plt slot>) */
733 0x8f390000, /* lw t9, 0(t9) */
734 0x00000000, /* nop */
735 0x03200008, /* jr t9 */
739 /* The format of the first PLT entry in a VxWorks shared object. */
740 static const bfd_vma mips_vxworks_shared_plt0_entry
[] = {
741 0x8f990008, /* lw t9, 8(gp) */
742 0x00000000, /* nop */
743 0x03200008, /* jr t9 */
744 0x00000000, /* nop */
745 0x00000000, /* nop */
749 /* The format of subsequent PLT entries. */
750 static const bfd_vma mips_vxworks_shared_plt_entry
[] = {
751 0x10000000, /* b .PLT_resolver */
752 0x24180000 /* li t8, <pltindex> */
755 /* Look up an entry in a MIPS ELF linker hash table. */
757 #define mips_elf_link_hash_lookup(table, string, create, copy, follow) \
758 ((struct mips_elf_link_hash_entry *) \
759 elf_link_hash_lookup (&(table)->root, (string), (create), \
762 /* Traverse a MIPS ELF linker hash table. */
764 #define mips_elf_link_hash_traverse(table, func, info) \
765 (elf_link_hash_traverse \
767 (bfd_boolean (*) (struct elf_link_hash_entry *, void *)) (func), \
770 /* Get the MIPS ELF linker hash table from a link_info structure. */
772 #define mips_elf_hash_table(p) \
773 ((struct mips_elf_link_hash_table *) ((p)->hash))
775 /* Find the base offsets for thread-local storage in this object,
776 for GD/LD and IE/LE respectively. */
778 #define TP_OFFSET 0x7000
779 #define DTP_OFFSET 0x8000
782 dtprel_base (struct bfd_link_info
*info
)
784 /* If tls_sec is NULL, we should have signalled an error already. */
785 if (elf_hash_table (info
)->tls_sec
== NULL
)
787 return elf_hash_table (info
)->tls_sec
->vma
+ DTP_OFFSET
;
791 tprel_base (struct bfd_link_info
*info
)
793 /* If tls_sec is NULL, we should have signalled an error already. */
794 if (elf_hash_table (info
)->tls_sec
== NULL
)
796 return elf_hash_table (info
)->tls_sec
->vma
+ TP_OFFSET
;
799 /* Create an entry in a MIPS ELF linker hash table. */
801 static struct bfd_hash_entry
*
802 mips_elf_link_hash_newfunc (struct bfd_hash_entry
*entry
,
803 struct bfd_hash_table
*table
, const char *string
)
805 struct mips_elf_link_hash_entry
*ret
=
806 (struct mips_elf_link_hash_entry
*) entry
;
808 /* Allocate the structure if it has not already been allocated by a
811 ret
= bfd_hash_allocate (table
, sizeof (struct mips_elf_link_hash_entry
));
813 return (struct bfd_hash_entry
*) ret
;
815 /* Call the allocation method of the superclass. */
816 ret
= ((struct mips_elf_link_hash_entry
*)
817 _bfd_elf_link_hash_newfunc ((struct bfd_hash_entry
*) ret
,
821 /* Set local fields. */
822 memset (&ret
->esym
, 0, sizeof (EXTR
));
823 /* We use -2 as a marker to indicate that the information has
824 not been set. -1 means there is no associated ifd. */
826 ret
->possibly_dynamic_relocs
= 0;
827 ret
->readonly_reloc
= FALSE
;
828 ret
->no_fn_stub
= FALSE
;
830 ret
->need_fn_stub
= FALSE
;
831 ret
->call_stub
= NULL
;
832 ret
->call_fp_stub
= NULL
;
833 ret
->forced_local
= FALSE
;
834 ret
->is_branch_target
= FALSE
;
835 ret
->is_relocation_target
= FALSE
;
836 ret
->tls_type
= GOT_NORMAL
;
839 return (struct bfd_hash_entry
*) ret
;
843 _bfd_mips_elf_new_section_hook (bfd
*abfd
, asection
*sec
)
845 if (!sec
->used_by_bfd
)
847 struct _mips_elf_section_data
*sdata
;
848 bfd_size_type amt
= sizeof (*sdata
);
850 sdata
= bfd_zalloc (abfd
, amt
);
853 sec
->used_by_bfd
= sdata
;
856 return _bfd_elf_new_section_hook (abfd
, sec
);
859 /* Read ECOFF debugging information from a .mdebug section into a
860 ecoff_debug_info structure. */
863 _bfd_mips_elf_read_ecoff_info (bfd
*abfd
, asection
*section
,
864 struct ecoff_debug_info
*debug
)
867 const struct ecoff_debug_swap
*swap
;
870 swap
= get_elf_backend_data (abfd
)->elf_backend_ecoff_debug_swap
;
871 memset (debug
, 0, sizeof (*debug
));
873 ext_hdr
= bfd_malloc (swap
->external_hdr_size
);
874 if (ext_hdr
== NULL
&& swap
->external_hdr_size
!= 0)
877 if (! bfd_get_section_contents (abfd
, section
, ext_hdr
, 0,
878 swap
->external_hdr_size
))
881 symhdr
= &debug
->symbolic_header
;
882 (*swap
->swap_hdr_in
) (abfd
, ext_hdr
, symhdr
);
884 /* The symbolic header contains absolute file offsets and sizes to
886 #define READ(ptr, offset, count, size, type) \
887 if (symhdr->count == 0) \
891 bfd_size_type amt = (bfd_size_type) size * symhdr->count; \
892 debug->ptr = bfd_malloc (amt); \
893 if (debug->ptr == NULL) \
895 if (bfd_seek (abfd, symhdr->offset, SEEK_SET) != 0 \
896 || bfd_bread (debug->ptr, amt, abfd) != amt) \
900 READ (line
, cbLineOffset
, cbLine
, sizeof (unsigned char), unsigned char *);
901 READ (external_dnr
, cbDnOffset
, idnMax
, swap
->external_dnr_size
, void *);
902 READ (external_pdr
, cbPdOffset
, ipdMax
, swap
->external_pdr_size
, void *);
903 READ (external_sym
, cbSymOffset
, isymMax
, swap
->external_sym_size
, void *);
904 READ (external_opt
, cbOptOffset
, ioptMax
, swap
->external_opt_size
, void *);
905 READ (external_aux
, cbAuxOffset
, iauxMax
, sizeof (union aux_ext
),
907 READ (ss
, cbSsOffset
, issMax
, sizeof (char), char *);
908 READ (ssext
, cbSsExtOffset
, issExtMax
, sizeof (char), char *);
909 READ (external_fdr
, cbFdOffset
, ifdMax
, swap
->external_fdr_size
, void *);
910 READ (external_rfd
, cbRfdOffset
, crfd
, swap
->external_rfd_size
, void *);
911 READ (external_ext
, cbExtOffset
, iextMax
, swap
->external_ext_size
, void *);
921 if (debug
->line
!= NULL
)
923 if (debug
->external_dnr
!= NULL
)
924 free (debug
->external_dnr
);
925 if (debug
->external_pdr
!= NULL
)
926 free (debug
->external_pdr
);
927 if (debug
->external_sym
!= NULL
)
928 free (debug
->external_sym
);
929 if (debug
->external_opt
!= NULL
)
930 free (debug
->external_opt
);
931 if (debug
->external_aux
!= NULL
)
932 free (debug
->external_aux
);
933 if (debug
->ss
!= NULL
)
935 if (debug
->ssext
!= NULL
)
937 if (debug
->external_fdr
!= NULL
)
938 free (debug
->external_fdr
);
939 if (debug
->external_rfd
!= NULL
)
940 free (debug
->external_rfd
);
941 if (debug
->external_ext
!= NULL
)
942 free (debug
->external_ext
);
946 /* Swap RPDR (runtime procedure table entry) for output. */
949 ecoff_swap_rpdr_out (bfd
*abfd
, const RPDR
*in
, struct rpdr_ext
*ex
)
951 H_PUT_S32 (abfd
, in
->adr
, ex
->p_adr
);
952 H_PUT_32 (abfd
, in
->regmask
, ex
->p_regmask
);
953 H_PUT_32 (abfd
, in
->regoffset
, ex
->p_regoffset
);
954 H_PUT_32 (abfd
, in
->fregmask
, ex
->p_fregmask
);
955 H_PUT_32 (abfd
, in
->fregoffset
, ex
->p_fregoffset
);
956 H_PUT_32 (abfd
, in
->frameoffset
, ex
->p_frameoffset
);
958 H_PUT_16 (abfd
, in
->framereg
, ex
->p_framereg
);
959 H_PUT_16 (abfd
, in
->pcreg
, ex
->p_pcreg
);
961 H_PUT_32 (abfd
, in
->irpss
, ex
->p_irpss
);
964 /* Create a runtime procedure table from the .mdebug section. */
967 mips_elf_create_procedure_table (void *handle
, bfd
*abfd
,
968 struct bfd_link_info
*info
, asection
*s
,
969 struct ecoff_debug_info
*debug
)
971 const struct ecoff_debug_swap
*swap
;
972 HDRR
*hdr
= &debug
->symbolic_header
;
974 struct rpdr_ext
*erp
;
976 struct pdr_ext
*epdr
;
977 struct sym_ext
*esym
;
982 unsigned long sindex
;
986 const char *no_name_func
= _("static procedure (no name)");
994 swap
= get_elf_backend_data (abfd
)->elf_backend_ecoff_debug_swap
;
996 sindex
= strlen (no_name_func
) + 1;
1000 size
= swap
->external_pdr_size
;
1002 epdr
= bfd_malloc (size
* count
);
1006 if (! _bfd_ecoff_get_accumulated_pdr (handle
, (bfd_byte
*) epdr
))
1009 size
= sizeof (RPDR
);
1010 rp
= rpdr
= bfd_malloc (size
* count
);
1014 size
= sizeof (char *);
1015 sv
= bfd_malloc (size
* count
);
1019 count
= hdr
->isymMax
;
1020 size
= swap
->external_sym_size
;
1021 esym
= bfd_malloc (size
* count
);
1025 if (! _bfd_ecoff_get_accumulated_sym (handle
, (bfd_byte
*) esym
))
1028 count
= hdr
->issMax
;
1029 ss
= bfd_malloc (count
);
1032 if (! _bfd_ecoff_get_accumulated_ss (handle
, (bfd_byte
*) ss
))
1035 count
= hdr
->ipdMax
;
1036 for (i
= 0; i
< (unsigned long) count
; i
++, rp
++)
1038 (*swap
->swap_pdr_in
) (abfd
, epdr
+ i
, &pdr
);
1039 (*swap
->swap_sym_in
) (abfd
, &esym
[pdr
.isym
], &sym
);
1040 rp
->adr
= sym
.value
;
1041 rp
->regmask
= pdr
.regmask
;
1042 rp
->regoffset
= pdr
.regoffset
;
1043 rp
->fregmask
= pdr
.fregmask
;
1044 rp
->fregoffset
= pdr
.fregoffset
;
1045 rp
->frameoffset
= pdr
.frameoffset
;
1046 rp
->framereg
= pdr
.framereg
;
1047 rp
->pcreg
= pdr
.pcreg
;
1049 sv
[i
] = ss
+ sym
.iss
;
1050 sindex
+= strlen (sv
[i
]) + 1;
1054 size
= sizeof (struct rpdr_ext
) * (count
+ 2) + sindex
;
1055 size
= BFD_ALIGN (size
, 16);
1056 rtproc
= bfd_alloc (abfd
, size
);
1059 mips_elf_hash_table (info
)->procedure_count
= 0;
1063 mips_elf_hash_table (info
)->procedure_count
= count
+ 2;
1066 memset (erp
, 0, sizeof (struct rpdr_ext
));
1068 str
= (char *) rtproc
+ sizeof (struct rpdr_ext
) * (count
+ 2);
1069 strcpy (str
, no_name_func
);
1070 str
+= strlen (no_name_func
) + 1;
1071 for (i
= 0; i
< count
; i
++)
1073 ecoff_swap_rpdr_out (abfd
, rpdr
+ i
, erp
+ i
);
1074 strcpy (str
, sv
[i
]);
1075 str
+= strlen (sv
[i
]) + 1;
1077 H_PUT_S32 (abfd
, -1, (erp
+ count
)->p_adr
);
1079 /* Set the size and contents of .rtproc section. */
1081 s
->contents
= rtproc
;
1083 /* Skip this section later on (I don't think this currently
1084 matters, but someday it might). */
1085 s
->map_head
.link_order
= NULL
;
1114 /* Check the mips16 stubs for a particular symbol, and see if we can
1118 mips_elf_check_mips16_stubs (struct mips_elf_link_hash_entry
*h
,
1119 void *data ATTRIBUTE_UNUSED
)
1121 if (h
->root
.root
.type
== bfd_link_hash_warning
)
1122 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
1124 if (h
->fn_stub
!= NULL
1125 && ! h
->need_fn_stub
)
1127 /* We don't need the fn_stub; the only references to this symbol
1128 are 16 bit calls. Clobber the size to 0 to prevent it from
1129 being included in the link. */
1130 h
->fn_stub
->size
= 0;
1131 h
->fn_stub
->flags
&= ~SEC_RELOC
;
1132 h
->fn_stub
->reloc_count
= 0;
1133 h
->fn_stub
->flags
|= SEC_EXCLUDE
;
1136 if (h
->call_stub
!= NULL
1137 && h
->root
.other
== STO_MIPS16
)
1139 /* We don't need the call_stub; this is a 16 bit function, so
1140 calls from other 16 bit functions are OK. Clobber the size
1141 to 0 to prevent it from being included in the link. */
1142 h
->call_stub
->size
= 0;
1143 h
->call_stub
->flags
&= ~SEC_RELOC
;
1144 h
->call_stub
->reloc_count
= 0;
1145 h
->call_stub
->flags
|= SEC_EXCLUDE
;
1148 if (h
->call_fp_stub
!= NULL
1149 && h
->root
.other
== STO_MIPS16
)
1151 /* We don't need the call_stub; this is a 16 bit function, so
1152 calls from other 16 bit functions are OK. Clobber the size
1153 to 0 to prevent it from being included in the link. */
1154 h
->call_fp_stub
->size
= 0;
1155 h
->call_fp_stub
->flags
&= ~SEC_RELOC
;
1156 h
->call_fp_stub
->reloc_count
= 0;
1157 h
->call_fp_stub
->flags
|= SEC_EXCLUDE
;
1163 /* R_MIPS16_26 is used for the mips16 jal and jalx instructions.
1164 Most mips16 instructions are 16 bits, but these instructions
1167 The format of these instructions is:
1169 +--------------+--------------------------------+
1170 | JALX | X| Imm 20:16 | Imm 25:21 |
1171 +--------------+--------------------------------+
1173 +-----------------------------------------------+
1175 JALX is the 5-bit value 00011. X is 0 for jal, 1 for jalx.
1176 Note that the immediate value in the first word is swapped.
1178 When producing a relocatable object file, R_MIPS16_26 is
1179 handled mostly like R_MIPS_26. In particular, the addend is
1180 stored as a straight 26-bit value in a 32-bit instruction.
1181 (gas makes life simpler for itself by never adjusting a
1182 R_MIPS16_26 reloc to be against a section, so the addend is
1183 always zero). However, the 32 bit instruction is stored as 2
1184 16-bit values, rather than a single 32-bit value. In a
1185 big-endian file, the result is the same; in a little-endian
1186 file, the two 16-bit halves of the 32 bit value are swapped.
1187 This is so that a disassembler can recognize the jal
1190 When doing a final link, R_MIPS16_26 is treated as a 32 bit
1191 instruction stored as two 16-bit values. The addend A is the
1192 contents of the targ26 field. The calculation is the same as
1193 R_MIPS_26. When storing the calculated value, reorder the
1194 immediate value as shown above, and don't forget to store the
1195 value as two 16-bit values.
1197 To put it in MIPS ABI terms, the relocation field is T-targ26-16,
1201 +--------+----------------------+
1205 +--------+----------------------+
1208 +----------+------+-------------+
1212 +----------+--------------------+
1213 where targ26-16 is sub1 followed by sub2 (i.e., the addend field A is
1214 ((sub1 << 16) | sub2)).
1216 When producing a relocatable object file, the calculation is
1217 (((A < 2) | ((P + 4) & 0xf0000000) + S) >> 2)
1218 When producing a fully linked file, the calculation is
1219 let R = (((A < 2) | ((P + 4) & 0xf0000000) + S) >> 2)
1220 ((R & 0x1f0000) << 5) | ((R & 0x3e00000) >> 5) | (R & 0xffff)
1222 R_MIPS16_GPREL is used for GP-relative addressing in mips16
1223 mode. A typical instruction will have a format like this:
1225 +--------------+--------------------------------+
1226 | EXTEND | Imm 10:5 | Imm 15:11 |
1227 +--------------+--------------------------------+
1228 | Major | rx | ry | Imm 4:0 |
1229 +--------------+--------------------------------+
1231 EXTEND is the five bit value 11110. Major is the instruction
1234 This is handled exactly like R_MIPS_GPREL16, except that the
1235 addend is retrieved and stored as shown in this diagram; that
1236 is, the Imm fields above replace the V-rel16 field.
1238 All we need to do here is shuffle the bits appropriately. As
1239 above, the two 16-bit halves must be swapped on a
1240 little-endian system.
1242 R_MIPS16_HI16 and R_MIPS16_LO16 are used in mips16 mode to
1243 access data when neither GP-relative nor PC-relative addressing
1244 can be used. They are handled like R_MIPS_HI16 and R_MIPS_LO16,
1245 except that the addend is retrieved and stored as shown above
1249 _bfd_mips16_elf_reloc_unshuffle (bfd
*abfd
, int r_type
,
1250 bfd_boolean jal_shuffle
, bfd_byte
*data
)
1252 bfd_vma extend
, insn
, val
;
1254 if (r_type
!= R_MIPS16_26
&& r_type
!= R_MIPS16_GPREL
1255 && r_type
!= R_MIPS16_HI16
&& r_type
!= R_MIPS16_LO16
)
1258 /* Pick up the mips16 extend instruction and the real instruction. */
1259 extend
= bfd_get_16 (abfd
, data
);
1260 insn
= bfd_get_16 (abfd
, data
+ 2);
1261 if (r_type
== R_MIPS16_26
)
1264 val
= ((extend
& 0xfc00) << 16) | ((extend
& 0x3e0) << 11)
1265 | ((extend
& 0x1f) << 21) | insn
;
1267 val
= extend
<< 16 | insn
;
1270 val
= ((extend
& 0xf800) << 16) | ((insn
& 0xffe0) << 11)
1271 | ((extend
& 0x1f) << 11) | (extend
& 0x7e0) | (insn
& 0x1f);
1272 bfd_put_32 (abfd
, val
, data
);
1276 _bfd_mips16_elf_reloc_shuffle (bfd
*abfd
, int r_type
,
1277 bfd_boolean jal_shuffle
, bfd_byte
*data
)
1279 bfd_vma extend
, insn
, val
;
1281 if (r_type
!= R_MIPS16_26
&& r_type
!= R_MIPS16_GPREL
1282 && r_type
!= R_MIPS16_HI16
&& r_type
!= R_MIPS16_LO16
)
1285 val
= bfd_get_32 (abfd
, data
);
1286 if (r_type
== R_MIPS16_26
)
1290 insn
= val
& 0xffff;
1291 extend
= ((val
>> 16) & 0xfc00) | ((val
>> 11) & 0x3e0)
1292 | ((val
>> 21) & 0x1f);
1296 insn
= val
& 0xffff;
1302 insn
= ((val
>> 11) & 0xffe0) | (val
& 0x1f);
1303 extend
= ((val
>> 16) & 0xf800) | ((val
>> 11) & 0x1f) | (val
& 0x7e0);
1305 bfd_put_16 (abfd
, insn
, data
+ 2);
1306 bfd_put_16 (abfd
, extend
, data
);
1309 bfd_reloc_status_type
1310 _bfd_mips_elf_gprel16_with_gp (bfd
*abfd
, asymbol
*symbol
,
1311 arelent
*reloc_entry
, asection
*input_section
,
1312 bfd_boolean relocatable
, void *data
, bfd_vma gp
)
1316 bfd_reloc_status_type status
;
1318 if (bfd_is_com_section (symbol
->section
))
1321 relocation
= symbol
->value
;
1323 relocation
+= symbol
->section
->output_section
->vma
;
1324 relocation
+= symbol
->section
->output_offset
;
1326 if (reloc_entry
->address
> bfd_get_section_limit (abfd
, input_section
))
1327 return bfd_reloc_outofrange
;
1329 /* Set val to the offset into the section or symbol. */
1330 val
= reloc_entry
->addend
;
1332 _bfd_mips_elf_sign_extend (val
, 16);
1334 /* Adjust val for the final section location and GP value. If we
1335 are producing relocatable output, we don't want to do this for
1336 an external symbol. */
1338 || (symbol
->flags
& BSF_SECTION_SYM
) != 0)
1339 val
+= relocation
- gp
;
1341 if (reloc_entry
->howto
->partial_inplace
)
1343 status
= _bfd_relocate_contents (reloc_entry
->howto
, abfd
, val
,
1345 + reloc_entry
->address
);
1346 if (status
!= bfd_reloc_ok
)
1350 reloc_entry
->addend
= val
;
1353 reloc_entry
->address
+= input_section
->output_offset
;
1355 return bfd_reloc_ok
;
1358 /* Used to store a REL high-part relocation such as R_MIPS_HI16 or
1359 R_MIPS_GOT16. REL is the relocation, INPUT_SECTION is the section
1360 that contains the relocation field and DATA points to the start of
1365 struct mips_hi16
*next
;
1367 asection
*input_section
;
1371 /* FIXME: This should not be a static variable. */
1373 static struct mips_hi16
*mips_hi16_list
;
1375 /* A howto special_function for REL *HI16 relocations. We can only
1376 calculate the correct value once we've seen the partnering
1377 *LO16 relocation, so just save the information for later.
1379 The ABI requires that the *LO16 immediately follow the *HI16.
1380 However, as a GNU extension, we permit an arbitrary number of
1381 *HI16s to be associated with a single *LO16. This significantly
1382 simplies the relocation handling in gcc. */
1384 bfd_reloc_status_type
1385 _bfd_mips_elf_hi16_reloc (bfd
*abfd ATTRIBUTE_UNUSED
, arelent
*reloc_entry
,
1386 asymbol
*symbol ATTRIBUTE_UNUSED
, void *data
,
1387 asection
*input_section
, bfd
*output_bfd
,
1388 char **error_message ATTRIBUTE_UNUSED
)
1390 struct mips_hi16
*n
;
1392 if (reloc_entry
->address
> bfd_get_section_limit (abfd
, input_section
))
1393 return bfd_reloc_outofrange
;
1395 n
= bfd_malloc (sizeof *n
);
1397 return bfd_reloc_outofrange
;
1399 n
->next
= mips_hi16_list
;
1401 n
->input_section
= input_section
;
1402 n
->rel
= *reloc_entry
;
1405 if (output_bfd
!= NULL
)
1406 reloc_entry
->address
+= input_section
->output_offset
;
1408 return bfd_reloc_ok
;
1411 /* A howto special_function for REL R_MIPS_GOT16 relocations. This is just
1412 like any other 16-bit relocation when applied to global symbols, but is
1413 treated in the same as R_MIPS_HI16 when applied to local symbols. */
1415 bfd_reloc_status_type
1416 _bfd_mips_elf_got16_reloc (bfd
*abfd
, arelent
*reloc_entry
, asymbol
*symbol
,
1417 void *data
, asection
*input_section
,
1418 bfd
*output_bfd
, char **error_message
)
1420 if ((symbol
->flags
& (BSF_GLOBAL
| BSF_WEAK
)) != 0
1421 || bfd_is_und_section (bfd_get_section (symbol
))
1422 || bfd_is_com_section (bfd_get_section (symbol
)))
1423 /* The relocation is against a global symbol. */
1424 return _bfd_mips_elf_generic_reloc (abfd
, reloc_entry
, symbol
, data
,
1425 input_section
, output_bfd
,
1428 return _bfd_mips_elf_hi16_reloc (abfd
, reloc_entry
, symbol
, data
,
1429 input_section
, output_bfd
, error_message
);
1432 /* A howto special_function for REL *LO16 relocations. The *LO16 itself
1433 is a straightforward 16 bit inplace relocation, but we must deal with
1434 any partnering high-part relocations as well. */
1436 bfd_reloc_status_type
1437 _bfd_mips_elf_lo16_reloc (bfd
*abfd
, arelent
*reloc_entry
, asymbol
*symbol
,
1438 void *data
, asection
*input_section
,
1439 bfd
*output_bfd
, char **error_message
)
1442 bfd_byte
*location
= (bfd_byte
*) data
+ reloc_entry
->address
;
1444 if (reloc_entry
->address
> bfd_get_section_limit (abfd
, input_section
))
1445 return bfd_reloc_outofrange
;
1447 _bfd_mips16_elf_reloc_unshuffle (abfd
, reloc_entry
->howto
->type
, FALSE
,
1449 vallo
= bfd_get_32 (abfd
, location
);
1450 _bfd_mips16_elf_reloc_shuffle (abfd
, reloc_entry
->howto
->type
, FALSE
,
1453 while (mips_hi16_list
!= NULL
)
1455 bfd_reloc_status_type ret
;
1456 struct mips_hi16
*hi
;
1458 hi
= mips_hi16_list
;
1460 /* R_MIPS_GOT16 relocations are something of a special case. We
1461 want to install the addend in the same way as for a R_MIPS_HI16
1462 relocation (with a rightshift of 16). However, since GOT16
1463 relocations can also be used with global symbols, their howto
1464 has a rightshift of 0. */
1465 if (hi
->rel
.howto
->type
== R_MIPS_GOT16
)
1466 hi
->rel
.howto
= MIPS_ELF_RTYPE_TO_HOWTO (abfd
, R_MIPS_HI16
, FALSE
);
1468 /* VALLO is a signed 16-bit number. Bias it by 0x8000 so that any
1469 carry or borrow will induce a change of +1 or -1 in the high part. */
1470 hi
->rel
.addend
+= (vallo
+ 0x8000) & 0xffff;
1472 ret
= _bfd_mips_elf_generic_reloc (abfd
, &hi
->rel
, symbol
, hi
->data
,
1473 hi
->input_section
, output_bfd
,
1475 if (ret
!= bfd_reloc_ok
)
1478 mips_hi16_list
= hi
->next
;
1482 return _bfd_mips_elf_generic_reloc (abfd
, reloc_entry
, symbol
, data
,
1483 input_section
, output_bfd
,
1487 /* A generic howto special_function. This calculates and installs the
1488 relocation itself, thus avoiding the oft-discussed problems in
1489 bfd_perform_relocation and bfd_install_relocation. */
1491 bfd_reloc_status_type
1492 _bfd_mips_elf_generic_reloc (bfd
*abfd ATTRIBUTE_UNUSED
, arelent
*reloc_entry
,
1493 asymbol
*symbol
, void *data ATTRIBUTE_UNUSED
,
1494 asection
*input_section
, bfd
*output_bfd
,
1495 char **error_message ATTRIBUTE_UNUSED
)
1498 bfd_reloc_status_type status
;
1499 bfd_boolean relocatable
;
1501 relocatable
= (output_bfd
!= NULL
);
1503 if (reloc_entry
->address
> bfd_get_section_limit (abfd
, input_section
))
1504 return bfd_reloc_outofrange
;
1506 /* Build up the field adjustment in VAL. */
1508 if (!relocatable
|| (symbol
->flags
& BSF_SECTION_SYM
) != 0)
1510 /* Either we're calculating the final field value or we have a
1511 relocation against a section symbol. Add in the section's
1512 offset or address. */
1513 val
+= symbol
->section
->output_section
->vma
;
1514 val
+= symbol
->section
->output_offset
;
1519 /* We're calculating the final field value. Add in the symbol's value
1520 and, if pc-relative, subtract the address of the field itself. */
1521 val
+= symbol
->value
;
1522 if (reloc_entry
->howto
->pc_relative
)
1524 val
-= input_section
->output_section
->vma
;
1525 val
-= input_section
->output_offset
;
1526 val
-= reloc_entry
->address
;
1530 /* VAL is now the final adjustment. If we're keeping this relocation
1531 in the output file, and if the relocation uses a separate addend,
1532 we just need to add VAL to that addend. Otherwise we need to add
1533 VAL to the relocation field itself. */
1534 if (relocatable
&& !reloc_entry
->howto
->partial_inplace
)
1535 reloc_entry
->addend
+= val
;
1538 bfd_byte
*location
= (bfd_byte
*) data
+ reloc_entry
->address
;
1540 /* Add in the separate addend, if any. */
1541 val
+= reloc_entry
->addend
;
1543 /* Add VAL to the relocation field. */
1544 _bfd_mips16_elf_reloc_unshuffle (abfd
, reloc_entry
->howto
->type
, FALSE
,
1546 status
= _bfd_relocate_contents (reloc_entry
->howto
, abfd
, val
,
1548 _bfd_mips16_elf_reloc_shuffle (abfd
, reloc_entry
->howto
->type
, FALSE
,
1551 if (status
!= bfd_reloc_ok
)
1556 reloc_entry
->address
+= input_section
->output_offset
;
1558 return bfd_reloc_ok
;
1561 /* Swap an entry in a .gptab section. Note that these routines rely
1562 on the equivalence of the two elements of the union. */
1565 bfd_mips_elf32_swap_gptab_in (bfd
*abfd
, const Elf32_External_gptab
*ex
,
1568 in
->gt_entry
.gt_g_value
= H_GET_32 (abfd
, ex
->gt_entry
.gt_g_value
);
1569 in
->gt_entry
.gt_bytes
= H_GET_32 (abfd
, ex
->gt_entry
.gt_bytes
);
1573 bfd_mips_elf32_swap_gptab_out (bfd
*abfd
, const Elf32_gptab
*in
,
1574 Elf32_External_gptab
*ex
)
1576 H_PUT_32 (abfd
, in
->gt_entry
.gt_g_value
, ex
->gt_entry
.gt_g_value
);
1577 H_PUT_32 (abfd
, in
->gt_entry
.gt_bytes
, ex
->gt_entry
.gt_bytes
);
1581 bfd_elf32_swap_compact_rel_out (bfd
*abfd
, const Elf32_compact_rel
*in
,
1582 Elf32_External_compact_rel
*ex
)
1584 H_PUT_32 (abfd
, in
->id1
, ex
->id1
);
1585 H_PUT_32 (abfd
, in
->num
, ex
->num
);
1586 H_PUT_32 (abfd
, in
->id2
, ex
->id2
);
1587 H_PUT_32 (abfd
, in
->offset
, ex
->offset
);
1588 H_PUT_32 (abfd
, in
->reserved0
, ex
->reserved0
);
1589 H_PUT_32 (abfd
, in
->reserved1
, ex
->reserved1
);
1593 bfd_elf32_swap_crinfo_out (bfd
*abfd
, const Elf32_crinfo
*in
,
1594 Elf32_External_crinfo
*ex
)
1598 l
= (((in
->ctype
& CRINFO_CTYPE
) << CRINFO_CTYPE_SH
)
1599 | ((in
->rtype
& CRINFO_RTYPE
) << CRINFO_RTYPE_SH
)
1600 | ((in
->dist2to
& CRINFO_DIST2TO
) << CRINFO_DIST2TO_SH
)
1601 | ((in
->relvaddr
& CRINFO_RELVADDR
) << CRINFO_RELVADDR_SH
));
1602 H_PUT_32 (abfd
, l
, ex
->info
);
1603 H_PUT_32 (abfd
, in
->konst
, ex
->konst
);
1604 H_PUT_32 (abfd
, in
->vaddr
, ex
->vaddr
);
1607 /* A .reginfo section holds a single Elf32_RegInfo structure. These
1608 routines swap this structure in and out. They are used outside of
1609 BFD, so they are globally visible. */
1612 bfd_mips_elf32_swap_reginfo_in (bfd
*abfd
, const Elf32_External_RegInfo
*ex
,
1615 in
->ri_gprmask
= H_GET_32 (abfd
, ex
->ri_gprmask
);
1616 in
->ri_cprmask
[0] = H_GET_32 (abfd
, ex
->ri_cprmask
[0]);
1617 in
->ri_cprmask
[1] = H_GET_32 (abfd
, ex
->ri_cprmask
[1]);
1618 in
->ri_cprmask
[2] = H_GET_32 (abfd
, ex
->ri_cprmask
[2]);
1619 in
->ri_cprmask
[3] = H_GET_32 (abfd
, ex
->ri_cprmask
[3]);
1620 in
->ri_gp_value
= H_GET_32 (abfd
, ex
->ri_gp_value
);
1624 bfd_mips_elf32_swap_reginfo_out (bfd
*abfd
, const Elf32_RegInfo
*in
,
1625 Elf32_External_RegInfo
*ex
)
1627 H_PUT_32 (abfd
, in
->ri_gprmask
, ex
->ri_gprmask
);
1628 H_PUT_32 (abfd
, in
->ri_cprmask
[0], ex
->ri_cprmask
[0]);
1629 H_PUT_32 (abfd
, in
->ri_cprmask
[1], ex
->ri_cprmask
[1]);
1630 H_PUT_32 (abfd
, in
->ri_cprmask
[2], ex
->ri_cprmask
[2]);
1631 H_PUT_32 (abfd
, in
->ri_cprmask
[3], ex
->ri_cprmask
[3]);
1632 H_PUT_32 (abfd
, in
->ri_gp_value
, ex
->ri_gp_value
);
1635 /* In the 64 bit ABI, the .MIPS.options section holds register
1636 information in an Elf64_Reginfo structure. These routines swap
1637 them in and out. They are globally visible because they are used
1638 outside of BFD. These routines are here so that gas can call them
1639 without worrying about whether the 64 bit ABI has been included. */
1642 bfd_mips_elf64_swap_reginfo_in (bfd
*abfd
, const Elf64_External_RegInfo
*ex
,
1643 Elf64_Internal_RegInfo
*in
)
1645 in
->ri_gprmask
= H_GET_32 (abfd
, ex
->ri_gprmask
);
1646 in
->ri_pad
= H_GET_32 (abfd
, ex
->ri_pad
);
1647 in
->ri_cprmask
[0] = H_GET_32 (abfd
, ex
->ri_cprmask
[0]);
1648 in
->ri_cprmask
[1] = H_GET_32 (abfd
, ex
->ri_cprmask
[1]);
1649 in
->ri_cprmask
[2] = H_GET_32 (abfd
, ex
->ri_cprmask
[2]);
1650 in
->ri_cprmask
[3] = H_GET_32 (abfd
, ex
->ri_cprmask
[3]);
1651 in
->ri_gp_value
= H_GET_64 (abfd
, ex
->ri_gp_value
);
1655 bfd_mips_elf64_swap_reginfo_out (bfd
*abfd
, const Elf64_Internal_RegInfo
*in
,
1656 Elf64_External_RegInfo
*ex
)
1658 H_PUT_32 (abfd
, in
->ri_gprmask
, ex
->ri_gprmask
);
1659 H_PUT_32 (abfd
, in
->ri_pad
, ex
->ri_pad
);
1660 H_PUT_32 (abfd
, in
->ri_cprmask
[0], ex
->ri_cprmask
[0]);
1661 H_PUT_32 (abfd
, in
->ri_cprmask
[1], ex
->ri_cprmask
[1]);
1662 H_PUT_32 (abfd
, in
->ri_cprmask
[2], ex
->ri_cprmask
[2]);
1663 H_PUT_32 (abfd
, in
->ri_cprmask
[3], ex
->ri_cprmask
[3]);
1664 H_PUT_64 (abfd
, in
->ri_gp_value
, ex
->ri_gp_value
);
1667 /* Swap in an options header. */
1670 bfd_mips_elf_swap_options_in (bfd
*abfd
, const Elf_External_Options
*ex
,
1671 Elf_Internal_Options
*in
)
1673 in
->kind
= H_GET_8 (abfd
, ex
->kind
);
1674 in
->size
= H_GET_8 (abfd
, ex
->size
);
1675 in
->section
= H_GET_16 (abfd
, ex
->section
);
1676 in
->info
= H_GET_32 (abfd
, ex
->info
);
1679 /* Swap out an options header. */
1682 bfd_mips_elf_swap_options_out (bfd
*abfd
, const Elf_Internal_Options
*in
,
1683 Elf_External_Options
*ex
)
1685 H_PUT_8 (abfd
, in
->kind
, ex
->kind
);
1686 H_PUT_8 (abfd
, in
->size
, ex
->size
);
1687 H_PUT_16 (abfd
, in
->section
, ex
->section
);
1688 H_PUT_32 (abfd
, in
->info
, ex
->info
);
1691 /* This function is called via qsort() to sort the dynamic relocation
1692 entries by increasing r_symndx value. */
1695 sort_dynamic_relocs (const void *arg1
, const void *arg2
)
1697 Elf_Internal_Rela int_reloc1
;
1698 Elf_Internal_Rela int_reloc2
;
1701 bfd_elf32_swap_reloc_in (reldyn_sorting_bfd
, arg1
, &int_reloc1
);
1702 bfd_elf32_swap_reloc_in (reldyn_sorting_bfd
, arg2
, &int_reloc2
);
1704 diff
= ELF32_R_SYM (int_reloc1
.r_info
) - ELF32_R_SYM (int_reloc2
.r_info
);
1708 if (int_reloc1
.r_offset
< int_reloc2
.r_offset
)
1710 if (int_reloc1
.r_offset
> int_reloc2
.r_offset
)
1715 /* Like sort_dynamic_relocs, but used for elf64 relocations. */
1718 sort_dynamic_relocs_64 (const void *arg1 ATTRIBUTE_UNUSED
,
1719 const void *arg2 ATTRIBUTE_UNUSED
)
1722 Elf_Internal_Rela int_reloc1
[3];
1723 Elf_Internal_Rela int_reloc2
[3];
1725 (*get_elf_backend_data (reldyn_sorting_bfd
)->s
->swap_reloc_in
)
1726 (reldyn_sorting_bfd
, arg1
, int_reloc1
);
1727 (*get_elf_backend_data (reldyn_sorting_bfd
)->s
->swap_reloc_in
)
1728 (reldyn_sorting_bfd
, arg2
, int_reloc2
);
1730 if (ELF64_R_SYM (int_reloc1
[0].r_info
) < ELF64_R_SYM (int_reloc2
[0].r_info
))
1732 if (ELF64_R_SYM (int_reloc1
[0].r_info
) > ELF64_R_SYM (int_reloc2
[0].r_info
))
1735 if (int_reloc1
[0].r_offset
< int_reloc2
[0].r_offset
)
1737 if (int_reloc1
[0].r_offset
> int_reloc2
[0].r_offset
)
1746 /* This routine is used to write out ECOFF debugging external symbol
1747 information. It is called via mips_elf_link_hash_traverse. The
1748 ECOFF external symbol information must match the ELF external
1749 symbol information. Unfortunately, at this point we don't know
1750 whether a symbol is required by reloc information, so the two
1751 tables may wind up being different. We must sort out the external
1752 symbol information before we can set the final size of the .mdebug
1753 section, and we must set the size of the .mdebug section before we
1754 can relocate any sections, and we can't know which symbols are
1755 required by relocation until we relocate the sections.
1756 Fortunately, it is relatively unlikely that any symbol will be
1757 stripped but required by a reloc. In particular, it can not happen
1758 when generating a final executable. */
1761 mips_elf_output_extsym (struct mips_elf_link_hash_entry
*h
, void *data
)
1763 struct extsym_info
*einfo
= data
;
1765 asection
*sec
, *output_section
;
1767 if (h
->root
.root
.type
== bfd_link_hash_warning
)
1768 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
1770 if (h
->root
.indx
== -2)
1772 else if ((h
->root
.def_dynamic
1773 || h
->root
.ref_dynamic
1774 || h
->root
.type
== bfd_link_hash_new
)
1775 && !h
->root
.def_regular
1776 && !h
->root
.ref_regular
)
1778 else if (einfo
->info
->strip
== strip_all
1779 || (einfo
->info
->strip
== strip_some
1780 && bfd_hash_lookup (einfo
->info
->keep_hash
,
1781 h
->root
.root
.root
.string
,
1782 FALSE
, FALSE
) == NULL
))
1790 if (h
->esym
.ifd
== -2)
1793 h
->esym
.cobol_main
= 0;
1794 h
->esym
.weakext
= 0;
1795 h
->esym
.reserved
= 0;
1796 h
->esym
.ifd
= ifdNil
;
1797 h
->esym
.asym
.value
= 0;
1798 h
->esym
.asym
.st
= stGlobal
;
1800 if (h
->root
.root
.type
== bfd_link_hash_undefined
1801 || h
->root
.root
.type
== bfd_link_hash_undefweak
)
1805 /* Use undefined class. Also, set class and type for some
1807 name
= h
->root
.root
.root
.string
;
1808 if (strcmp (name
, mips_elf_dynsym_rtproc_names
[0]) == 0
1809 || strcmp (name
, mips_elf_dynsym_rtproc_names
[1]) == 0)
1811 h
->esym
.asym
.sc
= scData
;
1812 h
->esym
.asym
.st
= stLabel
;
1813 h
->esym
.asym
.value
= 0;
1815 else if (strcmp (name
, mips_elf_dynsym_rtproc_names
[2]) == 0)
1817 h
->esym
.asym
.sc
= scAbs
;
1818 h
->esym
.asym
.st
= stLabel
;
1819 h
->esym
.asym
.value
=
1820 mips_elf_hash_table (einfo
->info
)->procedure_count
;
1822 else if (strcmp (name
, "_gp_disp") == 0 && ! NEWABI_P (einfo
->abfd
))
1824 h
->esym
.asym
.sc
= scAbs
;
1825 h
->esym
.asym
.st
= stLabel
;
1826 h
->esym
.asym
.value
= elf_gp (einfo
->abfd
);
1829 h
->esym
.asym
.sc
= scUndefined
;
1831 else if (h
->root
.root
.type
!= bfd_link_hash_defined
1832 && h
->root
.root
.type
!= bfd_link_hash_defweak
)
1833 h
->esym
.asym
.sc
= scAbs
;
1838 sec
= h
->root
.root
.u
.def
.section
;
1839 output_section
= sec
->output_section
;
1841 /* When making a shared library and symbol h is the one from
1842 the another shared library, OUTPUT_SECTION may be null. */
1843 if (output_section
== NULL
)
1844 h
->esym
.asym
.sc
= scUndefined
;
1847 name
= bfd_section_name (output_section
->owner
, output_section
);
1849 if (strcmp (name
, ".text") == 0)
1850 h
->esym
.asym
.sc
= scText
;
1851 else if (strcmp (name
, ".data") == 0)
1852 h
->esym
.asym
.sc
= scData
;
1853 else if (strcmp (name
, ".sdata") == 0)
1854 h
->esym
.asym
.sc
= scSData
;
1855 else if (strcmp (name
, ".rodata") == 0
1856 || strcmp (name
, ".rdata") == 0)
1857 h
->esym
.asym
.sc
= scRData
;
1858 else if (strcmp (name
, ".bss") == 0)
1859 h
->esym
.asym
.sc
= scBss
;
1860 else if (strcmp (name
, ".sbss") == 0)
1861 h
->esym
.asym
.sc
= scSBss
;
1862 else if (strcmp (name
, ".init") == 0)
1863 h
->esym
.asym
.sc
= scInit
;
1864 else if (strcmp (name
, ".fini") == 0)
1865 h
->esym
.asym
.sc
= scFini
;
1867 h
->esym
.asym
.sc
= scAbs
;
1871 h
->esym
.asym
.reserved
= 0;
1872 h
->esym
.asym
.index
= indexNil
;
1875 if (h
->root
.root
.type
== bfd_link_hash_common
)
1876 h
->esym
.asym
.value
= h
->root
.root
.u
.c
.size
;
1877 else if (h
->root
.root
.type
== bfd_link_hash_defined
1878 || h
->root
.root
.type
== bfd_link_hash_defweak
)
1880 if (h
->esym
.asym
.sc
== scCommon
)
1881 h
->esym
.asym
.sc
= scBss
;
1882 else if (h
->esym
.asym
.sc
== scSCommon
)
1883 h
->esym
.asym
.sc
= scSBss
;
1885 sec
= h
->root
.root
.u
.def
.section
;
1886 output_section
= sec
->output_section
;
1887 if (output_section
!= NULL
)
1888 h
->esym
.asym
.value
= (h
->root
.root
.u
.def
.value
1889 + sec
->output_offset
1890 + output_section
->vma
);
1892 h
->esym
.asym
.value
= 0;
1894 else if (h
->root
.needs_plt
)
1896 struct mips_elf_link_hash_entry
*hd
= h
;
1897 bfd_boolean no_fn_stub
= h
->no_fn_stub
;
1899 while (hd
->root
.root
.type
== bfd_link_hash_indirect
)
1901 hd
= (struct mips_elf_link_hash_entry
*)h
->root
.root
.u
.i
.link
;
1902 no_fn_stub
= no_fn_stub
|| hd
->no_fn_stub
;
1907 /* Set type and value for a symbol with a function stub. */
1908 h
->esym
.asym
.st
= stProc
;
1909 sec
= hd
->root
.root
.u
.def
.section
;
1911 h
->esym
.asym
.value
= 0;
1914 output_section
= sec
->output_section
;
1915 if (output_section
!= NULL
)
1916 h
->esym
.asym
.value
= (hd
->root
.plt
.offset
1917 + sec
->output_offset
1918 + output_section
->vma
);
1920 h
->esym
.asym
.value
= 0;
1925 if (! bfd_ecoff_debug_one_external (einfo
->abfd
, einfo
->debug
, einfo
->swap
,
1926 h
->root
.root
.root
.string
,
1929 einfo
->failed
= TRUE
;
1936 /* A comparison routine used to sort .gptab entries. */
1939 gptab_compare (const void *p1
, const void *p2
)
1941 const Elf32_gptab
*a1
= p1
;
1942 const Elf32_gptab
*a2
= p2
;
1944 return a1
->gt_entry
.gt_g_value
- a2
->gt_entry
.gt_g_value
;
1947 /* Functions to manage the got entry hash table. */
1949 /* Use all 64 bits of a bfd_vma for the computation of a 32-bit
1952 static INLINE hashval_t
1953 mips_elf_hash_bfd_vma (bfd_vma addr
)
1956 return addr
+ (addr
>> 32);
1962 /* got_entries only match if they're identical, except for gotidx, so
1963 use all fields to compute the hash, and compare the appropriate
1967 mips_elf_got_entry_hash (const void *entry_
)
1969 const struct mips_got_entry
*entry
= (struct mips_got_entry
*)entry_
;
1971 return entry
->symndx
1972 + ((entry
->tls_type
& GOT_TLS_LDM
) << 17)
1973 + (! entry
->abfd
? mips_elf_hash_bfd_vma (entry
->d
.address
)
1975 + (entry
->symndx
>= 0 ? mips_elf_hash_bfd_vma (entry
->d
.addend
)
1976 : entry
->d
.h
->root
.root
.root
.hash
));
1980 mips_elf_got_entry_eq (const void *entry1
, const void *entry2
)
1982 const struct mips_got_entry
*e1
= (struct mips_got_entry
*)entry1
;
1983 const struct mips_got_entry
*e2
= (struct mips_got_entry
*)entry2
;
1985 /* An LDM entry can only match another LDM entry. */
1986 if ((e1
->tls_type
^ e2
->tls_type
) & GOT_TLS_LDM
)
1989 return e1
->abfd
== e2
->abfd
&& e1
->symndx
== e2
->symndx
1990 && (! e1
->abfd
? e1
->d
.address
== e2
->d
.address
1991 : e1
->symndx
>= 0 ? e1
->d
.addend
== e2
->d
.addend
1992 : e1
->d
.h
== e2
->d
.h
);
1995 /* multi_got_entries are still a match in the case of global objects,
1996 even if the input bfd in which they're referenced differs, so the
1997 hash computation and compare functions are adjusted
2001 mips_elf_multi_got_entry_hash (const void *entry_
)
2003 const struct mips_got_entry
*entry
= (struct mips_got_entry
*)entry_
;
2005 return entry
->symndx
2007 ? mips_elf_hash_bfd_vma (entry
->d
.address
)
2008 : entry
->symndx
>= 0
2009 ? ((entry
->tls_type
& GOT_TLS_LDM
)
2010 ? (GOT_TLS_LDM
<< 17)
2012 + mips_elf_hash_bfd_vma (entry
->d
.addend
)))
2013 : entry
->d
.h
->root
.root
.root
.hash
);
2017 mips_elf_multi_got_entry_eq (const void *entry1
, const void *entry2
)
2019 const struct mips_got_entry
*e1
= (struct mips_got_entry
*)entry1
;
2020 const struct mips_got_entry
*e2
= (struct mips_got_entry
*)entry2
;
2022 /* Any two LDM entries match. */
2023 if (e1
->tls_type
& e2
->tls_type
& GOT_TLS_LDM
)
2026 /* Nothing else matches an LDM entry. */
2027 if ((e1
->tls_type
^ e2
->tls_type
) & GOT_TLS_LDM
)
2030 return e1
->symndx
== e2
->symndx
2031 && (e1
->symndx
>= 0 ? e1
->abfd
== e2
->abfd
&& e1
->d
.addend
== e2
->d
.addend
2032 : e1
->abfd
== NULL
|| e2
->abfd
== NULL
2033 ? e1
->abfd
== e2
->abfd
&& e1
->d
.address
== e2
->d
.address
2034 : e1
->d
.h
== e2
->d
.h
);
2037 /* Return the dynamic relocation section. If it doesn't exist, try to
2038 create a new it if CREATE_P, otherwise return NULL. Also return NULL
2039 if creation fails. */
2042 mips_elf_rel_dyn_section (struct bfd_link_info
*info
, bfd_boolean create_p
)
2048 dname
= MIPS_ELF_REL_DYN_NAME (info
);
2049 dynobj
= elf_hash_table (info
)->dynobj
;
2050 sreloc
= bfd_get_section_by_name (dynobj
, dname
);
2051 if (sreloc
== NULL
&& create_p
)
2053 sreloc
= bfd_make_section_with_flags (dynobj
, dname
,
2058 | SEC_LINKER_CREATED
2061 || ! bfd_set_section_alignment (dynobj
, sreloc
,
2062 MIPS_ELF_LOG_FILE_ALIGN (dynobj
)))
2068 /* Returns the GOT section for ABFD. */
2071 mips_elf_got_section (bfd
*abfd
, bfd_boolean maybe_excluded
)
2073 asection
*sgot
= bfd_get_section_by_name (abfd
, ".got");
2075 || (! maybe_excluded
&& (sgot
->flags
& SEC_EXCLUDE
) != 0))
2080 /* Returns the GOT information associated with the link indicated by
2081 INFO. If SGOTP is non-NULL, it is filled in with the GOT
2084 static struct mips_got_info
*
2085 mips_elf_got_info (bfd
*abfd
, asection
**sgotp
)
2088 struct mips_got_info
*g
;
2090 sgot
= mips_elf_got_section (abfd
, TRUE
);
2091 BFD_ASSERT (sgot
!= NULL
);
2092 BFD_ASSERT (mips_elf_section_data (sgot
) != NULL
);
2093 g
= mips_elf_section_data (sgot
)->u
.got_info
;
2094 BFD_ASSERT (g
!= NULL
);
2097 *sgotp
= (sgot
->flags
& SEC_EXCLUDE
) == 0 ? sgot
: NULL
;
2102 /* Count the number of relocations needed for a TLS GOT entry, with
2103 access types from TLS_TYPE, and symbol H (or a local symbol if H
2107 mips_tls_got_relocs (struct bfd_link_info
*info
, unsigned char tls_type
,
2108 struct elf_link_hash_entry
*h
)
2112 bfd_boolean need_relocs
= FALSE
;
2113 bfd_boolean dyn
= elf_hash_table (info
)->dynamic_sections_created
;
2115 if (h
&& WILL_CALL_FINISH_DYNAMIC_SYMBOL (dyn
, info
->shared
, h
)
2116 && (!info
->shared
|| !SYMBOL_REFERENCES_LOCAL (info
, h
)))
2119 if ((info
->shared
|| indx
!= 0)
2121 || ELF_ST_VISIBILITY (h
->other
) == STV_DEFAULT
2122 || h
->root
.type
!= bfd_link_hash_undefweak
))
2128 if (tls_type
& GOT_TLS_GD
)
2135 if (tls_type
& GOT_TLS_IE
)
2138 if ((tls_type
& GOT_TLS_LDM
) && info
->shared
)
2144 /* Count the number of TLS relocations required for the GOT entry in
2145 ARG1, if it describes a local symbol. */
2148 mips_elf_count_local_tls_relocs (void **arg1
, void *arg2
)
2150 struct mips_got_entry
*entry
= * (struct mips_got_entry
**) arg1
;
2151 struct mips_elf_count_tls_arg
*arg
= arg2
;
2153 if (entry
->abfd
!= NULL
&& entry
->symndx
!= -1)
2154 arg
->needed
+= mips_tls_got_relocs (arg
->info
, entry
->tls_type
, NULL
);
2159 /* Count the number of TLS GOT entries required for the global (or
2160 forced-local) symbol in ARG1. */
2163 mips_elf_count_global_tls_entries (void *arg1
, void *arg2
)
2165 struct mips_elf_link_hash_entry
*hm
2166 = (struct mips_elf_link_hash_entry
*) arg1
;
2167 struct mips_elf_count_tls_arg
*arg
= arg2
;
2169 if (hm
->tls_type
& GOT_TLS_GD
)
2171 if (hm
->tls_type
& GOT_TLS_IE
)
2177 /* Count the number of TLS relocations required for the global (or
2178 forced-local) symbol in ARG1. */
2181 mips_elf_count_global_tls_relocs (void *arg1
, void *arg2
)
2183 struct mips_elf_link_hash_entry
*hm
2184 = (struct mips_elf_link_hash_entry
*) arg1
;
2185 struct mips_elf_count_tls_arg
*arg
= arg2
;
2187 arg
->needed
+= mips_tls_got_relocs (arg
->info
, hm
->tls_type
, &hm
->root
);
2192 /* Output a simple dynamic relocation into SRELOC. */
2195 mips_elf_output_dynamic_relocation (bfd
*output_bfd
,
2201 Elf_Internal_Rela rel
[3];
2203 memset (rel
, 0, sizeof (rel
));
2205 rel
[0].r_info
= ELF_R_INFO (output_bfd
, indx
, r_type
);
2206 rel
[0].r_offset
= rel
[1].r_offset
= rel
[2].r_offset
= offset
;
2208 if (ABI_64_P (output_bfd
))
2210 (*get_elf_backend_data (output_bfd
)->s
->swap_reloc_out
)
2211 (output_bfd
, &rel
[0],
2213 + sreloc
->reloc_count
* sizeof (Elf64_Mips_External_Rel
)));
2216 bfd_elf32_swap_reloc_out
2217 (output_bfd
, &rel
[0],
2219 + sreloc
->reloc_count
* sizeof (Elf32_External_Rel
)));
2220 ++sreloc
->reloc_count
;
2223 /* Initialize a set of TLS GOT entries for one symbol. */
2226 mips_elf_initialize_tls_slots (bfd
*abfd
, bfd_vma got_offset
,
2227 unsigned char *tls_type_p
,
2228 struct bfd_link_info
*info
,
2229 struct mips_elf_link_hash_entry
*h
,
2233 asection
*sreloc
, *sgot
;
2234 bfd_vma offset
, offset2
;
2236 bfd_boolean need_relocs
= FALSE
;
2238 dynobj
= elf_hash_table (info
)->dynobj
;
2239 sgot
= mips_elf_got_section (dynobj
, FALSE
);
2244 bfd_boolean dyn
= elf_hash_table (info
)->dynamic_sections_created
;
2246 if (WILL_CALL_FINISH_DYNAMIC_SYMBOL (dyn
, info
->shared
, &h
->root
)
2247 && (!info
->shared
|| !SYMBOL_REFERENCES_LOCAL (info
, &h
->root
)))
2248 indx
= h
->root
.dynindx
;
2251 if (*tls_type_p
& GOT_TLS_DONE
)
2254 if ((info
->shared
|| indx
!= 0)
2256 || ELF_ST_VISIBILITY (h
->root
.other
) == STV_DEFAULT
2257 || h
->root
.type
!= bfd_link_hash_undefweak
))
2260 /* MINUS_ONE means the symbol is not defined in this object. It may not
2261 be defined at all; assume that the value doesn't matter in that
2262 case. Otherwise complain if we would use the value. */
2263 BFD_ASSERT (value
!= MINUS_ONE
|| (indx
!= 0 && need_relocs
)
2264 || h
->root
.root
.type
== bfd_link_hash_undefweak
);
2266 /* Emit necessary relocations. */
2267 sreloc
= mips_elf_rel_dyn_section (info
, FALSE
);
2269 /* General Dynamic. */
2270 if (*tls_type_p
& GOT_TLS_GD
)
2272 offset
= got_offset
;
2273 offset2
= offset
+ MIPS_ELF_GOT_SIZE (abfd
);
2277 mips_elf_output_dynamic_relocation
2278 (abfd
, sreloc
, indx
,
2279 ABI_64_P (abfd
) ? R_MIPS_TLS_DTPMOD64
: R_MIPS_TLS_DTPMOD32
,
2280 sgot
->output_offset
+ sgot
->output_section
->vma
+ offset
);
2283 mips_elf_output_dynamic_relocation
2284 (abfd
, sreloc
, indx
,
2285 ABI_64_P (abfd
) ? R_MIPS_TLS_DTPREL64
: R_MIPS_TLS_DTPREL32
,
2286 sgot
->output_offset
+ sgot
->output_section
->vma
+ offset2
);
2288 MIPS_ELF_PUT_WORD (abfd
, value
- dtprel_base (info
),
2289 sgot
->contents
+ offset2
);
2293 MIPS_ELF_PUT_WORD (abfd
, 1,
2294 sgot
->contents
+ offset
);
2295 MIPS_ELF_PUT_WORD (abfd
, value
- dtprel_base (info
),
2296 sgot
->contents
+ offset2
);
2299 got_offset
+= 2 * MIPS_ELF_GOT_SIZE (abfd
);
2302 /* Initial Exec model. */
2303 if (*tls_type_p
& GOT_TLS_IE
)
2305 offset
= got_offset
;
2310 MIPS_ELF_PUT_WORD (abfd
, value
- elf_hash_table (info
)->tls_sec
->vma
,
2311 sgot
->contents
+ offset
);
2313 MIPS_ELF_PUT_WORD (abfd
, 0,
2314 sgot
->contents
+ offset
);
2316 mips_elf_output_dynamic_relocation
2317 (abfd
, sreloc
, indx
,
2318 ABI_64_P (abfd
) ? R_MIPS_TLS_TPREL64
: R_MIPS_TLS_TPREL32
,
2319 sgot
->output_offset
+ sgot
->output_section
->vma
+ offset
);
2322 MIPS_ELF_PUT_WORD (abfd
, value
- tprel_base (info
),
2323 sgot
->contents
+ offset
);
2326 if (*tls_type_p
& GOT_TLS_LDM
)
2328 /* The initial offset is zero, and the LD offsets will include the
2329 bias by DTP_OFFSET. */
2330 MIPS_ELF_PUT_WORD (abfd
, 0,
2331 sgot
->contents
+ got_offset
2332 + MIPS_ELF_GOT_SIZE (abfd
));
2335 MIPS_ELF_PUT_WORD (abfd
, 1,
2336 sgot
->contents
+ got_offset
);
2338 mips_elf_output_dynamic_relocation
2339 (abfd
, sreloc
, indx
,
2340 ABI_64_P (abfd
) ? R_MIPS_TLS_DTPMOD64
: R_MIPS_TLS_DTPMOD32
,
2341 sgot
->output_offset
+ sgot
->output_section
->vma
+ got_offset
);
2344 *tls_type_p
|= GOT_TLS_DONE
;
2347 /* Return the GOT index to use for a relocation of type R_TYPE against
2348 a symbol accessed using TLS_TYPE models. The GOT entries for this
2349 symbol in this GOT start at GOT_INDEX. This function initializes the
2350 GOT entries and corresponding relocations. */
2353 mips_tls_got_index (bfd
*abfd
, bfd_vma got_index
, unsigned char *tls_type
,
2354 int r_type
, struct bfd_link_info
*info
,
2355 struct mips_elf_link_hash_entry
*h
, bfd_vma symbol
)
2357 BFD_ASSERT (r_type
== R_MIPS_TLS_GOTTPREL
|| r_type
== R_MIPS_TLS_GD
2358 || r_type
== R_MIPS_TLS_LDM
);
2360 mips_elf_initialize_tls_slots (abfd
, got_index
, tls_type
, info
, h
, symbol
);
2362 if (r_type
== R_MIPS_TLS_GOTTPREL
)
2364 BFD_ASSERT (*tls_type
& GOT_TLS_IE
);
2365 if (*tls_type
& GOT_TLS_GD
)
2366 return got_index
+ 2 * MIPS_ELF_GOT_SIZE (abfd
);
2371 if (r_type
== R_MIPS_TLS_GD
)
2373 BFD_ASSERT (*tls_type
& GOT_TLS_GD
);
2377 if (r_type
== R_MIPS_TLS_LDM
)
2379 BFD_ASSERT (*tls_type
& GOT_TLS_LDM
);
2386 /* Return the offset from _GLOBAL_OFFSET_TABLE_ of the .got.plt entry
2387 for global symbol H. .got.plt comes before the GOT, so the offset
2388 will be negative. */
2391 mips_elf_gotplt_index (struct bfd_link_info
*info
,
2392 struct elf_link_hash_entry
*h
)
2394 bfd_vma plt_index
, got_address
, got_value
;
2395 struct mips_elf_link_hash_table
*htab
;
2397 htab
= mips_elf_hash_table (info
);
2398 BFD_ASSERT (h
->plt
.offset
!= (bfd_vma
) -1);
2400 /* Calculate the index of the symbol's PLT entry. */
2401 plt_index
= (h
->plt
.offset
- htab
->plt_header_size
) / htab
->plt_entry_size
;
2403 /* Calculate the address of the associated .got.plt entry. */
2404 got_address
= (htab
->sgotplt
->output_section
->vma
2405 + htab
->sgotplt
->output_offset
2408 /* Calculate the value of _GLOBAL_OFFSET_TABLE_. */
2409 got_value
= (htab
->root
.hgot
->root
.u
.def
.section
->output_section
->vma
2410 + htab
->root
.hgot
->root
.u
.def
.section
->output_offset
2411 + htab
->root
.hgot
->root
.u
.def
.value
);
2413 return got_address
- got_value
;
2416 /* Return the GOT offset for address VALUE, which was derived from
2417 a symbol belonging to INPUT_SECTION. If there is not yet a GOT
2418 entry for this value, create one. If R_SYMNDX refers to a TLS symbol,
2419 create a TLS GOT entry instead. Return -1 if no satisfactory GOT
2420 offset can be found. */
2423 mips_elf_local_got_index (bfd
*abfd
, bfd
*ibfd
, struct bfd_link_info
*info
,
2424 asection
*input_section
, bfd_vma value
,
2425 unsigned long r_symndx
,
2426 struct mips_elf_link_hash_entry
*h
, int r_type
)
2429 struct mips_got_info
*g
;
2430 struct mips_got_entry
*entry
;
2432 g
= mips_elf_got_info (elf_hash_table (info
)->dynobj
, &sgot
);
2434 entry
= mips_elf_create_local_got_entry (abfd
, info
, ibfd
, g
, sgot
,
2435 input_section
, value
,
2436 r_symndx
, h
, r_type
);
2440 if (TLS_RELOC_P (r_type
))
2442 if (entry
->symndx
== -1 && g
->next
== NULL
)
2443 /* A type (3) entry in the single-GOT case. We use the symbol's
2444 hash table entry to track the index. */
2445 return mips_tls_got_index (abfd
, h
->tls_got_offset
, &h
->tls_type
,
2446 r_type
, info
, h
, value
);
2448 return mips_tls_got_index (abfd
, entry
->gotidx
, &entry
->tls_type
,
2449 r_type
, info
, h
, value
);
2452 return entry
->gotidx
;
2455 /* Returns the GOT index for the global symbol indicated by H. */
2458 mips_elf_global_got_index (bfd
*abfd
, bfd
*ibfd
, struct elf_link_hash_entry
*h
,
2459 int r_type
, struct bfd_link_info
*info
)
2463 struct mips_got_info
*g
, *gg
;
2464 long global_got_dynindx
= 0;
2466 gg
= g
= mips_elf_got_info (abfd
, &sgot
);
2467 if (g
->bfd2got
&& ibfd
)
2469 struct mips_got_entry e
, *p
;
2471 BFD_ASSERT (h
->dynindx
>= 0);
2473 g
= mips_elf_got_for_ibfd (g
, ibfd
);
2474 if (g
->next
!= gg
|| TLS_RELOC_P (r_type
))
2478 e
.d
.h
= (struct mips_elf_link_hash_entry
*)h
;
2481 p
= htab_find (g
->got_entries
, &e
);
2483 BFD_ASSERT (p
->gotidx
> 0);
2485 if (TLS_RELOC_P (r_type
))
2487 bfd_vma value
= MINUS_ONE
;
2488 if ((h
->root
.type
== bfd_link_hash_defined
2489 || h
->root
.type
== bfd_link_hash_defweak
)
2490 && h
->root
.u
.def
.section
->output_section
)
2491 value
= (h
->root
.u
.def
.value
2492 + h
->root
.u
.def
.section
->output_offset
2493 + h
->root
.u
.def
.section
->output_section
->vma
);
2495 return mips_tls_got_index (abfd
, p
->gotidx
, &p
->tls_type
, r_type
,
2496 info
, e
.d
.h
, value
);
2503 if (gg
->global_gotsym
!= NULL
)
2504 global_got_dynindx
= gg
->global_gotsym
->dynindx
;
2506 if (TLS_RELOC_P (r_type
))
2508 struct mips_elf_link_hash_entry
*hm
2509 = (struct mips_elf_link_hash_entry
*) h
;
2510 bfd_vma value
= MINUS_ONE
;
2512 if ((h
->root
.type
== bfd_link_hash_defined
2513 || h
->root
.type
== bfd_link_hash_defweak
)
2514 && h
->root
.u
.def
.section
->output_section
)
2515 value
= (h
->root
.u
.def
.value
2516 + h
->root
.u
.def
.section
->output_offset
2517 + h
->root
.u
.def
.section
->output_section
->vma
);
2519 index
= mips_tls_got_index (abfd
, hm
->tls_got_offset
, &hm
->tls_type
,
2520 r_type
, info
, hm
, value
);
2524 /* Once we determine the global GOT entry with the lowest dynamic
2525 symbol table index, we must put all dynamic symbols with greater
2526 indices into the GOT. That makes it easy to calculate the GOT
2528 BFD_ASSERT (h
->dynindx
>= global_got_dynindx
);
2529 index
= ((h
->dynindx
- global_got_dynindx
+ g
->local_gotno
)
2530 * MIPS_ELF_GOT_SIZE (abfd
));
2532 BFD_ASSERT (index
< sgot
->size
);
2537 /* Find a GOT page entry that points to within 32KB of VALUE, which was
2538 calculated from a symbol belonging to INPUT_SECTION. These entries
2539 are supposed to be placed at small offsets in the GOT, i.e., within
2540 32KB of GP. Return the index of the GOT entry, or -1 if no entry
2541 could be created. If OFFSETP is nonnull, use it to return the
2542 offset of the GOT entry from VALUE. */
2545 mips_elf_got_page (bfd
*abfd
, bfd
*ibfd
, struct bfd_link_info
*info
,
2546 asection
*input_section
, bfd_vma value
, bfd_vma
*offsetp
)
2549 struct mips_got_info
*g
;
2550 bfd_vma page
, index
;
2551 struct mips_got_entry
*entry
;
2553 g
= mips_elf_got_info (elf_hash_table (info
)->dynobj
, &sgot
);
2555 page
= (value
+ 0x8000) & ~(bfd_vma
) 0xffff;
2556 entry
= mips_elf_create_local_got_entry (abfd
, info
, ibfd
, g
, sgot
,
2557 input_section
, page
, 0,
2558 NULL
, R_MIPS_GOT_PAGE
);
2563 index
= entry
->gotidx
;
2566 *offsetp
= value
- entry
->d
.address
;
2571 /* Find a local GOT entry for an R_MIPS_GOT16 relocation against VALUE,
2572 which was calculated from a symbol belonging to INPUT_SECTION.
2573 EXTERNAL is true if the relocation was against a global symbol
2574 that has been forced local. */
2577 mips_elf_got16_entry (bfd
*abfd
, bfd
*ibfd
, struct bfd_link_info
*info
,
2578 asection
*input_section
, bfd_vma value
,
2579 bfd_boolean external
)
2582 struct mips_got_info
*g
;
2583 struct mips_got_entry
*entry
;
2585 /* GOT16 relocations against local symbols are followed by a LO16
2586 relocation; those against global symbols are not. Thus if the
2587 symbol was originally local, the GOT16 relocation should load the
2588 equivalent of %hi(VALUE), otherwise it should load VALUE itself. */
2590 value
= mips_elf_high (value
) << 16;
2592 g
= mips_elf_got_info (elf_hash_table (info
)->dynobj
, &sgot
);
2594 entry
= mips_elf_create_local_got_entry (abfd
, info
, ibfd
, g
, sgot
,
2595 input_section
, value
, 0,
2596 NULL
, R_MIPS_GOT16
);
2598 return entry
->gotidx
;
2603 /* Returns the offset for the entry at the INDEXth position
2607 mips_elf_got_offset_from_index (bfd
*dynobj
, bfd
*output_bfd
,
2608 bfd
*input_bfd
, bfd_vma index
)
2612 struct mips_got_info
*g
;
2614 g
= mips_elf_got_info (dynobj
, &sgot
);
2615 gp
= _bfd_get_gp_value (output_bfd
)
2616 + mips_elf_adjust_gp (output_bfd
, g
, input_bfd
);
2618 return sgot
->output_section
->vma
+ sgot
->output_offset
+ index
- gp
;
2621 /* Create and return a local GOT entry for VALUE, which was calculated
2622 from a symbol belonging to INPUT_SECTON. Return NULL if it could not
2623 be created. If R_SYMNDX refers to a TLS symbol, create a TLS entry
2626 static struct mips_got_entry
*
2627 mips_elf_create_local_got_entry (bfd
*abfd
, struct bfd_link_info
*info
,
2628 bfd
*ibfd
, struct mips_got_info
*gg
,
2629 asection
*sgot
, asection
*input_section
,
2630 bfd_vma value
, unsigned long r_symndx
,
2631 struct mips_elf_link_hash_entry
*h
,
2634 struct mips_got_entry entry
, **loc
;
2635 struct mips_got_info
*g
;
2636 struct mips_elf_link_hash_table
*htab
;
2638 htab
= mips_elf_hash_table (info
);
2642 entry
.d
.address
= value
;
2645 g
= mips_elf_got_for_ibfd (gg
, ibfd
);
2648 g
= mips_elf_got_for_ibfd (gg
, abfd
);
2649 BFD_ASSERT (g
!= NULL
);
2652 /* We might have a symbol, H, if it has been forced local. Use the
2653 global entry then. It doesn't matter whether an entry is local
2654 or global for TLS, since the dynamic linker does not
2655 automatically relocate TLS GOT entries. */
2656 BFD_ASSERT (h
== NULL
|| h
->root
.forced_local
);
2657 if (TLS_RELOC_P (r_type
))
2659 struct mips_got_entry
*p
;
2662 if (r_type
== R_MIPS_TLS_LDM
)
2664 entry
.tls_type
= GOT_TLS_LDM
;
2670 entry
.symndx
= r_symndx
;
2676 p
= (struct mips_got_entry
*)
2677 htab_find (g
->got_entries
, &entry
);
2683 loc
= (struct mips_got_entry
**) htab_find_slot (g
->got_entries
, &entry
,
2688 entry
.gotidx
= MIPS_ELF_GOT_SIZE (abfd
) * g
->assigned_gotno
++;
2691 *loc
= (struct mips_got_entry
*)bfd_alloc (abfd
, sizeof entry
);
2696 memcpy (*loc
, &entry
, sizeof entry
);
2698 if (g
->assigned_gotno
>= g
->local_gotno
)
2700 (*loc
)->gotidx
= -1;
2701 /* We didn't allocate enough space in the GOT. */
2702 (*_bfd_error_handler
)
2703 (_("not enough GOT space for local GOT entries"));
2704 bfd_set_error (bfd_error_bad_value
);
2708 MIPS_ELF_PUT_WORD (abfd
, value
,
2709 (sgot
->contents
+ entry
.gotidx
));
2711 /* These GOT entries need a dynamic relocation on VxWorks. Because
2712 the offset between segments is not fixed, the relocation must be
2713 against a symbol in the same segment as the original symbol.
2714 The easiest way to do this is to take INPUT_SECTION's output
2715 section and emit a relocation against its section symbol. */
2716 if (htab
->is_vxworks
)
2718 Elf_Internal_Rela outrel
;
2719 asection
*s
, *output_section
;
2721 bfd_vma got_address
;
2724 s
= mips_elf_rel_dyn_section (info
, FALSE
);
2725 output_section
= input_section
->output_section
;
2726 dynindx
= elf_section_data (output_section
)->dynindx
;
2727 got_address
= (sgot
->output_section
->vma
2728 + sgot
->output_offset
2731 loc
= s
->contents
+ (s
->reloc_count
++ * sizeof (Elf32_External_Rela
));
2732 outrel
.r_offset
= got_address
;
2733 outrel
.r_info
= ELF32_R_INFO (dynindx
, R_MIPS_32
);
2734 outrel
.r_addend
= value
- output_section
->vma
;
2735 bfd_elf32_swap_reloca_out (abfd
, &outrel
, loc
);
2741 /* Sort the dynamic symbol table so that symbols that need GOT entries
2742 appear towards the end. This reduces the amount of GOT space
2743 required. MAX_LOCAL is used to set the number of local symbols
2744 known to be in the dynamic symbol table. During
2745 _bfd_mips_elf_size_dynamic_sections, this value is 1. Afterward, the
2746 section symbols are added and the count is higher. */
2749 mips_elf_sort_hash_table (struct bfd_link_info
*info
, unsigned long max_local
)
2751 struct mips_elf_hash_sort_data hsd
;
2752 struct mips_got_info
*g
;
2755 dynobj
= elf_hash_table (info
)->dynobj
;
2757 g
= mips_elf_got_info (dynobj
, NULL
);
2760 hsd
.max_unref_got_dynindx
=
2761 hsd
.min_got_dynindx
= elf_hash_table (info
)->dynsymcount
2762 /* In the multi-got case, assigned_gotno of the master got_info
2763 indicate the number of entries that aren't referenced in the
2764 primary GOT, but that must have entries because there are
2765 dynamic relocations that reference it. Since they aren't
2766 referenced, we move them to the end of the GOT, so that they
2767 don't prevent other entries that are referenced from getting
2768 too large offsets. */
2769 - (g
->next
? g
->assigned_gotno
: 0);
2770 hsd
.max_non_got_dynindx
= max_local
;
2771 mips_elf_link_hash_traverse (((struct mips_elf_link_hash_table
*)
2772 elf_hash_table (info
)),
2773 mips_elf_sort_hash_table_f
,
2776 /* There should have been enough room in the symbol table to
2777 accommodate both the GOT and non-GOT symbols. */
2778 BFD_ASSERT (hsd
.max_non_got_dynindx
<= hsd
.min_got_dynindx
);
2779 BFD_ASSERT ((unsigned long)hsd
.max_unref_got_dynindx
2780 <= elf_hash_table (info
)->dynsymcount
);
2782 /* Now we know which dynamic symbol has the lowest dynamic symbol
2783 table index in the GOT. */
2784 g
->global_gotsym
= hsd
.low
;
2789 /* If H needs a GOT entry, assign it the highest available dynamic
2790 index. Otherwise, assign it the lowest available dynamic
2794 mips_elf_sort_hash_table_f (struct mips_elf_link_hash_entry
*h
, void *data
)
2796 struct mips_elf_hash_sort_data
*hsd
= data
;
2798 if (h
->root
.root
.type
== bfd_link_hash_warning
)
2799 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
2801 /* Symbols without dynamic symbol table entries aren't interesting
2803 if (h
->root
.dynindx
== -1)
2806 /* Global symbols that need GOT entries that are not explicitly
2807 referenced are marked with got offset 2. Those that are
2808 referenced get a 1, and those that don't need GOT entries get
2810 if (h
->root
.got
.offset
== 2)
2812 BFD_ASSERT (h
->tls_type
== GOT_NORMAL
);
2814 if (hsd
->max_unref_got_dynindx
== hsd
->min_got_dynindx
)
2815 hsd
->low
= (struct elf_link_hash_entry
*) h
;
2816 h
->root
.dynindx
= hsd
->max_unref_got_dynindx
++;
2818 else if (h
->root
.got
.offset
!= 1)
2819 h
->root
.dynindx
= hsd
->max_non_got_dynindx
++;
2822 BFD_ASSERT (h
->tls_type
== GOT_NORMAL
);
2824 h
->root
.dynindx
= --hsd
->min_got_dynindx
;
2825 hsd
->low
= (struct elf_link_hash_entry
*) h
;
2831 /* If H is a symbol that needs a global GOT entry, but has a dynamic
2832 symbol table index lower than any we've seen to date, record it for
2836 mips_elf_record_global_got_symbol (struct elf_link_hash_entry
*h
,
2837 bfd
*abfd
, struct bfd_link_info
*info
,
2838 struct mips_got_info
*g
,
2839 unsigned char tls_flag
)
2841 struct mips_got_entry entry
, **loc
;
2843 /* A global symbol in the GOT must also be in the dynamic symbol
2845 if (h
->dynindx
== -1)
2847 switch (ELF_ST_VISIBILITY (h
->other
))
2851 _bfd_mips_elf_hide_symbol (info
, h
, TRUE
);
2854 if (!bfd_elf_link_record_dynamic_symbol (info
, h
))
2858 /* Make sure we have a GOT to put this entry into. */
2859 BFD_ASSERT (g
!= NULL
);
2863 entry
.d
.h
= (struct mips_elf_link_hash_entry
*) h
;
2866 loc
= (struct mips_got_entry
**) htab_find_slot (g
->got_entries
, &entry
,
2869 /* If we've already marked this entry as needing GOT space, we don't
2870 need to do it again. */
2873 (*loc
)->tls_type
|= tls_flag
;
2877 *loc
= (struct mips_got_entry
*)bfd_alloc (abfd
, sizeof entry
);
2883 entry
.tls_type
= tls_flag
;
2885 memcpy (*loc
, &entry
, sizeof entry
);
2887 if (h
->got
.offset
!= MINUS_ONE
)
2890 /* By setting this to a value other than -1, we are indicating that
2891 there needs to be a GOT entry for H. Avoid using zero, as the
2892 generic ELF copy_indirect_symbol tests for <= 0. */
2899 /* Reserve space in G for a GOT entry containing the value of symbol
2900 SYMNDX in input bfd ABDF, plus ADDEND. */
2903 mips_elf_record_local_got_symbol (bfd
*abfd
, long symndx
, bfd_vma addend
,
2904 struct mips_got_info
*g
,
2905 unsigned char tls_flag
)
2907 struct mips_got_entry entry
, **loc
;
2910 entry
.symndx
= symndx
;
2911 entry
.d
.addend
= addend
;
2912 entry
.tls_type
= tls_flag
;
2913 loc
= (struct mips_got_entry
**)
2914 htab_find_slot (g
->got_entries
, &entry
, INSERT
);
2918 if (tls_flag
== GOT_TLS_GD
&& !((*loc
)->tls_type
& GOT_TLS_GD
))
2921 (*loc
)->tls_type
|= tls_flag
;
2923 else if (tls_flag
== GOT_TLS_IE
&& !((*loc
)->tls_type
& GOT_TLS_IE
))
2926 (*loc
)->tls_type
|= tls_flag
;
2934 entry
.tls_type
= tls_flag
;
2935 if (tls_flag
== GOT_TLS_IE
)
2937 else if (tls_flag
== GOT_TLS_GD
)
2939 else if (g
->tls_ldm_offset
== MINUS_ONE
)
2941 g
->tls_ldm_offset
= MINUS_TWO
;
2947 entry
.gotidx
= g
->local_gotno
++;
2951 *loc
= (struct mips_got_entry
*)bfd_alloc (abfd
, sizeof entry
);
2956 memcpy (*loc
, &entry
, sizeof entry
);
2961 /* Compute the hash value of the bfd in a bfd2got hash entry. */
2964 mips_elf_bfd2got_entry_hash (const void *entry_
)
2966 const struct mips_elf_bfd2got_hash
*entry
2967 = (struct mips_elf_bfd2got_hash
*)entry_
;
2969 return entry
->bfd
->id
;
2972 /* Check whether two hash entries have the same bfd. */
2975 mips_elf_bfd2got_entry_eq (const void *entry1
, const void *entry2
)
2977 const struct mips_elf_bfd2got_hash
*e1
2978 = (const struct mips_elf_bfd2got_hash
*)entry1
;
2979 const struct mips_elf_bfd2got_hash
*e2
2980 = (const struct mips_elf_bfd2got_hash
*)entry2
;
2982 return e1
->bfd
== e2
->bfd
;
2985 /* In a multi-got link, determine the GOT to be used for IBFD. G must
2986 be the master GOT data. */
2988 static struct mips_got_info
*
2989 mips_elf_got_for_ibfd (struct mips_got_info
*g
, bfd
*ibfd
)
2991 struct mips_elf_bfd2got_hash e
, *p
;
2997 p
= htab_find (g
->bfd2got
, &e
);
2998 return p
? p
->g
: NULL
;
3001 /* Create one separate got for each bfd that has entries in the global
3002 got, such that we can tell how many local and global entries each
3006 mips_elf_make_got_per_bfd (void **entryp
, void *p
)
3008 struct mips_got_entry
*entry
= (struct mips_got_entry
*)*entryp
;
3009 struct mips_elf_got_per_bfd_arg
*arg
= (struct mips_elf_got_per_bfd_arg
*)p
;
3010 htab_t bfd2got
= arg
->bfd2got
;
3011 struct mips_got_info
*g
;
3012 struct mips_elf_bfd2got_hash bfdgot_entry
, *bfdgot
;
3015 /* Find the got_info for this GOT entry's input bfd. Create one if
3017 bfdgot_entry
.bfd
= entry
->abfd
;
3018 bfdgotp
= htab_find_slot (bfd2got
, &bfdgot_entry
, INSERT
);
3019 bfdgot
= (struct mips_elf_bfd2got_hash
*)*bfdgotp
;
3025 bfdgot
= (struct mips_elf_bfd2got_hash
*)bfd_alloc
3026 (arg
->obfd
, sizeof (struct mips_elf_bfd2got_hash
));
3036 bfdgot
->bfd
= entry
->abfd
;
3037 bfdgot
->g
= g
= (struct mips_got_info
*)
3038 bfd_alloc (arg
->obfd
, sizeof (struct mips_got_info
));
3045 g
->global_gotsym
= NULL
;
3046 g
->global_gotno
= 0;
3048 g
->assigned_gotno
= -1;
3050 g
->tls_assigned_gotno
= 0;
3051 g
->tls_ldm_offset
= MINUS_ONE
;
3052 g
->got_entries
= htab_try_create (1, mips_elf_multi_got_entry_hash
,
3053 mips_elf_multi_got_entry_eq
, NULL
);
3054 if (g
->got_entries
== NULL
)
3064 /* Insert the GOT entry in the bfd's got entry hash table. */
3065 entryp
= htab_find_slot (g
->got_entries
, entry
, INSERT
);
3066 if (*entryp
!= NULL
)
3071 if (entry
->tls_type
)
3073 if (entry
->tls_type
& (GOT_TLS_GD
| GOT_TLS_LDM
))
3075 if (entry
->tls_type
& GOT_TLS_IE
)
3078 else if (entry
->symndx
>= 0 || entry
->d
.h
->forced_local
)
3086 /* Attempt to merge gots of different input bfds. Try to use as much
3087 as possible of the primary got, since it doesn't require explicit
3088 dynamic relocations, but don't use bfds that would reference global
3089 symbols out of the addressable range. Failing the primary got,
3090 attempt to merge with the current got, or finish the current got
3091 and then make make the new got current. */
3094 mips_elf_merge_gots (void **bfd2got_
, void *p
)
3096 struct mips_elf_bfd2got_hash
*bfd2got
3097 = (struct mips_elf_bfd2got_hash
*)*bfd2got_
;
3098 struct mips_elf_got_per_bfd_arg
*arg
= (struct mips_elf_got_per_bfd_arg
*)p
;
3099 unsigned int lcount
= bfd2got
->g
->local_gotno
;
3100 unsigned int gcount
= bfd2got
->g
->global_gotno
;
3101 unsigned int tcount
= bfd2got
->g
->tls_gotno
;
3102 unsigned int maxcnt
= arg
->max_count
;
3103 bfd_boolean too_many_for_tls
= FALSE
;
3105 /* We place TLS GOT entries after both locals and globals. The globals
3106 for the primary GOT may overflow the normal GOT size limit, so be
3107 sure not to merge a GOT which requires TLS with the primary GOT in that
3108 case. This doesn't affect non-primary GOTs. */
3111 unsigned int primary_total
= lcount
+ tcount
+ arg
->global_count
;
3112 if (primary_total
> maxcnt
)
3113 too_many_for_tls
= TRUE
;
3116 /* If we don't have a primary GOT and this is not too big, use it as
3117 a starting point for the primary GOT. */
3118 if (! arg
->primary
&& lcount
+ gcount
+ tcount
<= maxcnt
3119 && ! too_many_for_tls
)
3121 arg
->primary
= bfd2got
->g
;
3122 arg
->primary_count
= lcount
+ gcount
;
3124 /* If it looks like we can merge this bfd's entries with those of
3125 the primary, merge them. The heuristics is conservative, but we
3126 don't have to squeeze it too hard. */
3127 else if (arg
->primary
&& ! too_many_for_tls
3128 && (arg
->primary_count
+ lcount
+ gcount
+ tcount
) <= maxcnt
)
3130 struct mips_got_info
*g
= bfd2got
->g
;
3131 int old_lcount
= arg
->primary
->local_gotno
;
3132 int old_gcount
= arg
->primary
->global_gotno
;
3133 int old_tcount
= arg
->primary
->tls_gotno
;
3135 bfd2got
->g
= arg
->primary
;
3137 htab_traverse (g
->got_entries
,
3138 mips_elf_make_got_per_bfd
,
3140 if (arg
->obfd
== NULL
)
3143 htab_delete (g
->got_entries
);
3144 /* We don't have to worry about releasing memory of the actual
3145 got entries, since they're all in the master got_entries hash
3148 BFD_ASSERT (old_lcount
+ lcount
>= arg
->primary
->local_gotno
);
3149 BFD_ASSERT (old_gcount
+ gcount
>= arg
->primary
->global_gotno
);
3150 BFD_ASSERT (old_tcount
+ tcount
>= arg
->primary
->tls_gotno
);
3152 arg
->primary_count
= arg
->primary
->local_gotno
3153 + arg
->primary
->global_gotno
+ arg
->primary
->tls_gotno
;
3155 /* If we can merge with the last-created got, do it. */
3156 else if (arg
->current
3157 && arg
->current_count
+ lcount
+ gcount
+ tcount
<= maxcnt
)
3159 struct mips_got_info
*g
= bfd2got
->g
;
3160 int old_lcount
= arg
->current
->local_gotno
;
3161 int old_gcount
= arg
->current
->global_gotno
;
3162 int old_tcount
= arg
->current
->tls_gotno
;
3164 bfd2got
->g
= arg
->current
;
3166 htab_traverse (g
->got_entries
,
3167 mips_elf_make_got_per_bfd
,
3169 if (arg
->obfd
== NULL
)
3172 htab_delete (g
->got_entries
);
3174 BFD_ASSERT (old_lcount
+ lcount
>= arg
->current
->local_gotno
);
3175 BFD_ASSERT (old_gcount
+ gcount
>= arg
->current
->global_gotno
);
3176 BFD_ASSERT (old_tcount
+ tcount
>= arg
->current
->tls_gotno
);
3178 arg
->current_count
= arg
->current
->local_gotno
3179 + arg
->current
->global_gotno
+ arg
->current
->tls_gotno
;
3181 /* Well, we couldn't merge, so create a new GOT. Don't check if it
3182 fits; if it turns out that it doesn't, we'll get relocation
3183 overflows anyway. */
3186 bfd2got
->g
->next
= arg
->current
;
3187 arg
->current
= bfd2got
->g
;
3189 arg
->current_count
= lcount
+ gcount
+ 2 * tcount
;
3195 /* Set the TLS GOT index for the GOT entry in ENTRYP. ENTRYP's NEXT field
3196 is null iff there is just a single GOT. */
3199 mips_elf_initialize_tls_index (void **entryp
, void *p
)
3201 struct mips_got_entry
*entry
= (struct mips_got_entry
*)*entryp
;
3202 struct mips_got_info
*g
= p
;
3205 /* We're only interested in TLS symbols. */
3206 if (entry
->tls_type
== 0)
3209 next_index
= MIPS_ELF_GOT_SIZE (entry
->abfd
) * (long) g
->tls_assigned_gotno
;
3211 if (entry
->symndx
== -1 && g
->next
== NULL
)
3213 /* A type (3) got entry in the single-GOT case. We use the symbol's
3214 hash table entry to track its index. */
3215 if (entry
->d
.h
->tls_type
& GOT_TLS_OFFSET_DONE
)
3217 entry
->d
.h
->tls_type
|= GOT_TLS_OFFSET_DONE
;
3218 entry
->d
.h
->tls_got_offset
= next_index
;
3222 if (entry
->tls_type
& GOT_TLS_LDM
)
3224 /* There are separate mips_got_entry objects for each input bfd
3225 that requires an LDM entry. Make sure that all LDM entries in
3226 a GOT resolve to the same index. */
3227 if (g
->tls_ldm_offset
!= MINUS_TWO
&& g
->tls_ldm_offset
!= MINUS_ONE
)
3229 entry
->gotidx
= g
->tls_ldm_offset
;
3232 g
->tls_ldm_offset
= next_index
;
3234 entry
->gotidx
= next_index
;
3237 /* Account for the entries we've just allocated. */
3238 if (entry
->tls_type
& (GOT_TLS_GD
| GOT_TLS_LDM
))
3239 g
->tls_assigned_gotno
+= 2;
3240 if (entry
->tls_type
& GOT_TLS_IE
)
3241 g
->tls_assigned_gotno
+= 1;
3246 /* If passed a NULL mips_got_info in the argument, set the marker used
3247 to tell whether a global symbol needs a got entry (in the primary
3248 got) to the given VALUE.
3250 If passed a pointer G to a mips_got_info in the argument (it must
3251 not be the primary GOT), compute the offset from the beginning of
3252 the (primary) GOT section to the entry in G corresponding to the
3253 global symbol. G's assigned_gotno must contain the index of the
3254 first available global GOT entry in G. VALUE must contain the size
3255 of a GOT entry in bytes. For each global GOT entry that requires a
3256 dynamic relocation, NEEDED_RELOCS is incremented, and the symbol is
3257 marked as not eligible for lazy resolution through a function
3260 mips_elf_set_global_got_offset (void **entryp
, void *p
)
3262 struct mips_got_entry
*entry
= (struct mips_got_entry
*)*entryp
;
3263 struct mips_elf_set_global_got_offset_arg
*arg
3264 = (struct mips_elf_set_global_got_offset_arg
*)p
;
3265 struct mips_got_info
*g
= arg
->g
;
3267 if (g
&& entry
->tls_type
!= GOT_NORMAL
)
3268 arg
->needed_relocs
+=
3269 mips_tls_got_relocs (arg
->info
, entry
->tls_type
,
3270 entry
->symndx
== -1 ? &entry
->d
.h
->root
: NULL
);
3272 if (entry
->abfd
!= NULL
&& entry
->symndx
== -1
3273 && entry
->d
.h
->root
.dynindx
!= -1
3274 && entry
->d
.h
->tls_type
== GOT_NORMAL
)
3278 BFD_ASSERT (g
->global_gotsym
== NULL
);
3280 entry
->gotidx
= arg
->value
* (long) g
->assigned_gotno
++;
3281 if (arg
->info
->shared
3282 || (elf_hash_table (arg
->info
)->dynamic_sections_created
3283 && entry
->d
.h
->root
.def_dynamic
3284 && !entry
->d
.h
->root
.def_regular
))
3285 ++arg
->needed_relocs
;
3288 entry
->d
.h
->root
.got
.offset
= arg
->value
;
3294 /* Mark any global symbols referenced in the GOT we are iterating over
3295 as inelligible for lazy resolution stubs. */
3297 mips_elf_set_no_stub (void **entryp
, void *p ATTRIBUTE_UNUSED
)
3299 struct mips_got_entry
*entry
= (struct mips_got_entry
*)*entryp
;
3301 if (entry
->abfd
!= NULL
3302 && entry
->symndx
== -1
3303 && entry
->d
.h
->root
.dynindx
!= -1)
3304 entry
->d
.h
->no_fn_stub
= TRUE
;
3309 /* Follow indirect and warning hash entries so that each got entry
3310 points to the final symbol definition. P must point to a pointer
3311 to the hash table we're traversing. Since this traversal may
3312 modify the hash table, we set this pointer to NULL to indicate
3313 we've made a potentially-destructive change to the hash table, so
3314 the traversal must be restarted. */
3316 mips_elf_resolve_final_got_entry (void **entryp
, void *p
)
3318 struct mips_got_entry
*entry
= (struct mips_got_entry
*)*entryp
;
3319 htab_t got_entries
= *(htab_t
*)p
;
3321 if (entry
->abfd
!= NULL
&& entry
->symndx
== -1)
3323 struct mips_elf_link_hash_entry
*h
= entry
->d
.h
;
3325 while (h
->root
.root
.type
== bfd_link_hash_indirect
3326 || h
->root
.root
.type
== bfd_link_hash_warning
)
3327 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
3329 if (entry
->d
.h
== h
)
3334 /* If we can't find this entry with the new bfd hash, re-insert
3335 it, and get the traversal restarted. */
3336 if (! htab_find (got_entries
, entry
))
3338 htab_clear_slot (got_entries
, entryp
);
3339 entryp
= htab_find_slot (got_entries
, entry
, INSERT
);
3342 /* Abort the traversal, since the whole table may have
3343 moved, and leave it up to the parent to restart the
3345 *(htab_t
*)p
= NULL
;
3348 /* We might want to decrement the global_gotno count, but it's
3349 either too early or too late for that at this point. */
3355 /* Turn indirect got entries in a got_entries table into their final
3358 mips_elf_resolve_final_got_entries (struct mips_got_info
*g
)
3364 got_entries
= g
->got_entries
;
3366 htab_traverse (got_entries
,
3367 mips_elf_resolve_final_got_entry
,
3370 while (got_entries
== NULL
);
3373 /* Return the offset of an input bfd IBFD's GOT from the beginning of
3376 mips_elf_adjust_gp (bfd
*abfd
, struct mips_got_info
*g
, bfd
*ibfd
)
3378 if (g
->bfd2got
== NULL
)
3381 g
= mips_elf_got_for_ibfd (g
, ibfd
);
3385 BFD_ASSERT (g
->next
);
3389 return (g
->local_gotno
+ g
->global_gotno
+ g
->tls_gotno
)
3390 * MIPS_ELF_GOT_SIZE (abfd
);
3393 /* Turn a single GOT that is too big for 16-bit addressing into
3394 a sequence of GOTs, each one 16-bit addressable. */
3397 mips_elf_multi_got (bfd
*abfd
, struct bfd_link_info
*info
,
3398 struct mips_got_info
*g
, asection
*got
,
3399 bfd_size_type pages
)
3401 struct mips_elf_got_per_bfd_arg got_per_bfd_arg
;
3402 struct mips_elf_set_global_got_offset_arg set_got_offset_arg
;
3403 struct mips_got_info
*gg
;
3404 unsigned int assign
;
3406 g
->bfd2got
= htab_try_create (1, mips_elf_bfd2got_entry_hash
,
3407 mips_elf_bfd2got_entry_eq
, NULL
);
3408 if (g
->bfd2got
== NULL
)
3411 got_per_bfd_arg
.bfd2got
= g
->bfd2got
;
3412 got_per_bfd_arg
.obfd
= abfd
;
3413 got_per_bfd_arg
.info
= info
;
3415 /* Count how many GOT entries each input bfd requires, creating a
3416 map from bfd to got info while at that. */
3417 htab_traverse (g
->got_entries
, mips_elf_make_got_per_bfd
, &got_per_bfd_arg
);
3418 if (got_per_bfd_arg
.obfd
== NULL
)
3421 got_per_bfd_arg
.current
= NULL
;
3422 got_per_bfd_arg
.primary
= NULL
;
3423 /* Taking out PAGES entries is a worst-case estimate. We could
3424 compute the maximum number of pages that each separate input bfd
3425 uses, but it's probably not worth it. */
3426 got_per_bfd_arg
.max_count
= ((MIPS_ELF_GOT_MAX_SIZE (info
)
3427 / MIPS_ELF_GOT_SIZE (abfd
))
3428 - MIPS_RESERVED_GOTNO (info
) - pages
);
3429 /* The number of globals that will be included in the primary GOT.
3430 See the calls to mips_elf_set_global_got_offset below for more
3432 got_per_bfd_arg
.global_count
= g
->global_gotno
;
3434 /* Try to merge the GOTs of input bfds together, as long as they
3435 don't seem to exceed the maximum GOT size, choosing one of them
3436 to be the primary GOT. */
3437 htab_traverse (g
->bfd2got
, mips_elf_merge_gots
, &got_per_bfd_arg
);
3438 if (got_per_bfd_arg
.obfd
== NULL
)
3441 /* If we do not find any suitable primary GOT, create an empty one. */
3442 if (got_per_bfd_arg
.primary
== NULL
)
3444 g
->next
= (struct mips_got_info
*)
3445 bfd_alloc (abfd
, sizeof (struct mips_got_info
));
3446 if (g
->next
== NULL
)
3449 g
->next
->global_gotsym
= NULL
;
3450 g
->next
->global_gotno
= 0;
3451 g
->next
->local_gotno
= 0;
3452 g
->next
->tls_gotno
= 0;
3453 g
->next
->assigned_gotno
= 0;
3454 g
->next
->tls_assigned_gotno
= 0;
3455 g
->next
->tls_ldm_offset
= MINUS_ONE
;
3456 g
->next
->got_entries
= htab_try_create (1, mips_elf_multi_got_entry_hash
,
3457 mips_elf_multi_got_entry_eq
,
3459 if (g
->next
->got_entries
== NULL
)
3461 g
->next
->bfd2got
= NULL
;
3464 g
->next
= got_per_bfd_arg
.primary
;
3465 g
->next
->next
= got_per_bfd_arg
.current
;
3467 /* GG is now the master GOT, and G is the primary GOT. */
3471 /* Map the output bfd to the primary got. That's what we're going
3472 to use for bfds that use GOT16 or GOT_PAGE relocations that we
3473 didn't mark in check_relocs, and we want a quick way to find it.
3474 We can't just use gg->next because we're going to reverse the
3477 struct mips_elf_bfd2got_hash
*bfdgot
;
3480 bfdgot
= (struct mips_elf_bfd2got_hash
*)bfd_alloc
3481 (abfd
, sizeof (struct mips_elf_bfd2got_hash
));
3488 bfdgotp
= htab_find_slot (gg
->bfd2got
, bfdgot
, INSERT
);
3490 BFD_ASSERT (*bfdgotp
== NULL
);
3494 /* The IRIX dynamic linker requires every symbol that is referenced
3495 in a dynamic relocation to be present in the primary GOT, so
3496 arrange for them to appear after those that are actually
3499 GNU/Linux could very well do without it, but it would slow down
3500 the dynamic linker, since it would have to resolve every dynamic
3501 symbol referenced in other GOTs more than once, without help from
3502 the cache. Also, knowing that every external symbol has a GOT
3503 helps speed up the resolution of local symbols too, so GNU/Linux
3504 follows IRIX's practice.
3506 The number 2 is used by mips_elf_sort_hash_table_f to count
3507 global GOT symbols that are unreferenced in the primary GOT, with
3508 an initial dynamic index computed from gg->assigned_gotno, where
3509 the number of unreferenced global entries in the primary GOT is
3513 gg
->assigned_gotno
= gg
->global_gotno
- g
->global_gotno
;
3514 g
->global_gotno
= gg
->global_gotno
;
3515 set_got_offset_arg
.value
= 2;
3519 /* This could be used for dynamic linkers that don't optimize
3520 symbol resolution while applying relocations so as to use
3521 primary GOT entries or assuming the symbol is locally-defined.
3522 With this code, we assign lower dynamic indices to global
3523 symbols that are not referenced in the primary GOT, so that
3524 their entries can be omitted. */
3525 gg
->assigned_gotno
= 0;
3526 set_got_offset_arg
.value
= -1;
3529 /* Reorder dynamic symbols as described above (which behavior
3530 depends on the setting of VALUE). */
3531 set_got_offset_arg
.g
= NULL
;
3532 htab_traverse (gg
->got_entries
, mips_elf_set_global_got_offset
,
3533 &set_got_offset_arg
);
3534 set_got_offset_arg
.value
= 1;
3535 htab_traverse (g
->got_entries
, mips_elf_set_global_got_offset
,
3536 &set_got_offset_arg
);
3537 if (! mips_elf_sort_hash_table (info
, 1))
3540 /* Now go through the GOTs assigning them offset ranges.
3541 [assigned_gotno, local_gotno[ will be set to the range of local
3542 entries in each GOT. We can then compute the end of a GOT by
3543 adding local_gotno to global_gotno. We reverse the list and make
3544 it circular since then we'll be able to quickly compute the
3545 beginning of a GOT, by computing the end of its predecessor. To
3546 avoid special cases for the primary GOT, while still preserving
3547 assertions that are valid for both single- and multi-got links,
3548 we arrange for the main got struct to have the right number of
3549 global entries, but set its local_gotno such that the initial
3550 offset of the primary GOT is zero. Remember that the primary GOT
3551 will become the last item in the circular linked list, so it
3552 points back to the master GOT. */
3553 gg
->local_gotno
= -g
->global_gotno
;
3554 gg
->global_gotno
= g
->global_gotno
;
3561 struct mips_got_info
*gn
;
3563 assign
+= MIPS_RESERVED_GOTNO (info
);
3564 g
->assigned_gotno
= assign
;
3565 g
->local_gotno
+= assign
+ pages
;
3566 assign
= g
->local_gotno
+ g
->global_gotno
+ g
->tls_gotno
;
3568 /* Take g out of the direct list, and push it onto the reversed
3569 list that gg points to. g->next is guaranteed to be nonnull after
3570 this operation, as required by mips_elf_initialize_tls_index. */
3575 /* Set up any TLS entries. We always place the TLS entries after
3576 all non-TLS entries. */
3577 g
->tls_assigned_gotno
= g
->local_gotno
+ g
->global_gotno
;
3578 htab_traverse (g
->got_entries
, mips_elf_initialize_tls_index
, g
);
3580 /* Move onto the next GOT. It will be a secondary GOT if nonull. */
3583 /* Mark global symbols in every non-primary GOT as ineligible for
3586 htab_traverse (g
->got_entries
, mips_elf_set_no_stub
, NULL
);
3590 got
->size
= (gg
->next
->local_gotno
3591 + gg
->next
->global_gotno
3592 + gg
->next
->tls_gotno
) * MIPS_ELF_GOT_SIZE (abfd
);
3598 /* Returns the first relocation of type r_type found, beginning with
3599 RELOCATION. RELEND is one-past-the-end of the relocation table. */
3601 static const Elf_Internal_Rela
*
3602 mips_elf_next_relocation (bfd
*abfd ATTRIBUTE_UNUSED
, unsigned int r_type
,
3603 const Elf_Internal_Rela
*relocation
,
3604 const Elf_Internal_Rela
*relend
)
3606 unsigned long r_symndx
= ELF_R_SYM (abfd
, relocation
->r_info
);
3608 while (relocation
< relend
)
3610 if (ELF_R_TYPE (abfd
, relocation
->r_info
) == r_type
3611 && ELF_R_SYM (abfd
, relocation
->r_info
) == r_symndx
)
3617 /* We didn't find it. */
3621 /* Return whether a relocation is against a local symbol. */
3624 mips_elf_local_relocation_p (bfd
*input_bfd
,
3625 const Elf_Internal_Rela
*relocation
,
3626 asection
**local_sections
,
3627 bfd_boolean check_forced
)
3629 unsigned long r_symndx
;
3630 Elf_Internal_Shdr
*symtab_hdr
;
3631 struct mips_elf_link_hash_entry
*h
;
3634 r_symndx
= ELF_R_SYM (input_bfd
, relocation
->r_info
);
3635 symtab_hdr
= &elf_tdata (input_bfd
)->symtab_hdr
;
3636 extsymoff
= (elf_bad_symtab (input_bfd
)) ? 0 : symtab_hdr
->sh_info
;
3638 if (r_symndx
< extsymoff
)
3640 if (elf_bad_symtab (input_bfd
) && local_sections
[r_symndx
] != NULL
)
3645 /* Look up the hash table to check whether the symbol
3646 was forced local. */
3647 h
= (struct mips_elf_link_hash_entry
*)
3648 elf_sym_hashes (input_bfd
) [r_symndx
- extsymoff
];
3649 /* Find the real hash-table entry for this symbol. */
3650 while (h
->root
.root
.type
== bfd_link_hash_indirect
3651 || h
->root
.root
.type
== bfd_link_hash_warning
)
3652 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
3653 if (h
->root
.forced_local
)
3660 /* Sign-extend VALUE, which has the indicated number of BITS. */
3663 _bfd_mips_elf_sign_extend (bfd_vma value
, int bits
)
3665 if (value
& ((bfd_vma
) 1 << (bits
- 1)))
3666 /* VALUE is negative. */
3667 value
|= ((bfd_vma
) - 1) << bits
;
3672 /* Return non-zero if the indicated VALUE has overflowed the maximum
3673 range expressible by a signed number with the indicated number of
3677 mips_elf_overflow_p (bfd_vma value
, int bits
)
3679 bfd_signed_vma svalue
= (bfd_signed_vma
) value
;
3681 if (svalue
> (1 << (bits
- 1)) - 1)
3682 /* The value is too big. */
3684 else if (svalue
< -(1 << (bits
- 1)))
3685 /* The value is too small. */
3692 /* Calculate the %high function. */
3695 mips_elf_high (bfd_vma value
)
3697 return ((value
+ (bfd_vma
) 0x8000) >> 16) & 0xffff;
3700 /* Calculate the %higher function. */
3703 mips_elf_higher (bfd_vma value ATTRIBUTE_UNUSED
)
3706 return ((value
+ (bfd_vma
) 0x80008000) >> 32) & 0xffff;
3713 /* Calculate the %highest function. */
3716 mips_elf_highest (bfd_vma value ATTRIBUTE_UNUSED
)
3719 return ((value
+ (((bfd_vma
) 0x8000 << 32) | 0x80008000)) >> 48) & 0xffff;
3726 /* Create the .compact_rel section. */
3729 mips_elf_create_compact_rel_section
3730 (bfd
*abfd
, struct bfd_link_info
*info ATTRIBUTE_UNUSED
)
3733 register asection
*s
;
3735 if (bfd_get_section_by_name (abfd
, ".compact_rel") == NULL
)
3737 flags
= (SEC_HAS_CONTENTS
| SEC_IN_MEMORY
| SEC_LINKER_CREATED
3740 s
= bfd_make_section_with_flags (abfd
, ".compact_rel", flags
);
3742 || ! bfd_set_section_alignment (abfd
, s
,
3743 MIPS_ELF_LOG_FILE_ALIGN (abfd
)))
3746 s
->size
= sizeof (Elf32_External_compact_rel
);
3752 /* Create the .got section to hold the global offset table. */
3755 mips_elf_create_got_section (bfd
*abfd
, struct bfd_link_info
*info
,
3756 bfd_boolean maybe_exclude
)
3759 register asection
*s
;
3760 struct elf_link_hash_entry
*h
;
3761 struct bfd_link_hash_entry
*bh
;
3762 struct mips_got_info
*g
;
3764 struct mips_elf_link_hash_table
*htab
;
3766 htab
= mips_elf_hash_table (info
);
3768 /* This function may be called more than once. */
3769 s
= mips_elf_got_section (abfd
, TRUE
);
3772 if (! maybe_exclude
)
3773 s
->flags
&= ~SEC_EXCLUDE
;
3777 flags
= (SEC_ALLOC
| SEC_LOAD
| SEC_HAS_CONTENTS
| SEC_IN_MEMORY
3778 | SEC_LINKER_CREATED
);
3781 flags
|= SEC_EXCLUDE
;
3783 /* We have to use an alignment of 2**4 here because this is hardcoded
3784 in the function stub generation and in the linker script. */
3785 s
= bfd_make_section_with_flags (abfd
, ".got", flags
);
3787 || ! bfd_set_section_alignment (abfd
, s
, 4))
3790 /* Define the symbol _GLOBAL_OFFSET_TABLE_. We don't do this in the
3791 linker script because we don't want to define the symbol if we
3792 are not creating a global offset table. */
3794 if (! (_bfd_generic_link_add_one_symbol
3795 (info
, abfd
, "_GLOBAL_OFFSET_TABLE_", BSF_GLOBAL
, s
,
3796 0, NULL
, FALSE
, get_elf_backend_data (abfd
)->collect
, &bh
)))
3799 h
= (struct elf_link_hash_entry
*) bh
;
3802 h
->type
= STT_OBJECT
;
3803 elf_hash_table (info
)->hgot
= h
;
3806 && ! bfd_elf_link_record_dynamic_symbol (info
, h
))
3809 amt
= sizeof (struct mips_got_info
);
3810 g
= bfd_alloc (abfd
, amt
);
3813 g
->global_gotsym
= NULL
;
3814 g
->global_gotno
= 0;
3816 g
->local_gotno
= MIPS_RESERVED_GOTNO (info
);
3817 g
->assigned_gotno
= MIPS_RESERVED_GOTNO (info
);
3820 g
->tls_ldm_offset
= MINUS_ONE
;
3821 g
->got_entries
= htab_try_create (1, mips_elf_got_entry_hash
,
3822 mips_elf_got_entry_eq
, NULL
);
3823 if (g
->got_entries
== NULL
)
3825 mips_elf_section_data (s
)->u
.got_info
= g
;
3826 mips_elf_section_data (s
)->elf
.this_hdr
.sh_flags
3827 |= SHF_ALLOC
| SHF_WRITE
| SHF_MIPS_GPREL
;
3829 /* VxWorks also needs a .got.plt section. */
3830 if (htab
->is_vxworks
)
3832 s
= bfd_make_section_with_flags (abfd
, ".got.plt",
3833 SEC_ALLOC
| SEC_LOAD
| SEC_HAS_CONTENTS
3834 | SEC_IN_MEMORY
| SEC_LINKER_CREATED
);
3835 if (s
== NULL
|| !bfd_set_section_alignment (abfd
, s
, 4))
3843 /* Return true if H refers to the special VxWorks __GOTT_BASE__ or
3844 __GOTT_INDEX__ symbols. These symbols are only special for
3845 shared objects; they are not used in executables. */
3848 is_gott_symbol (struct bfd_link_info
*info
, struct elf_link_hash_entry
*h
)
3850 return (mips_elf_hash_table (info
)->is_vxworks
3852 && (strcmp (h
->root
.root
.string
, "__GOTT_BASE__") == 0
3853 || strcmp (h
->root
.root
.string
, "__GOTT_INDEX__") == 0));
3856 /* Calculate the value produced by the RELOCATION (which comes from
3857 the INPUT_BFD). The ADDEND is the addend to use for this
3858 RELOCATION; RELOCATION->R_ADDEND is ignored.
3860 The result of the relocation calculation is stored in VALUEP.
3861 REQUIRE_JALXP indicates whether or not the opcode used with this
3862 relocation must be JALX.
3864 This function returns bfd_reloc_continue if the caller need take no
3865 further action regarding this relocation, bfd_reloc_notsupported if
3866 something goes dramatically wrong, bfd_reloc_overflow if an
3867 overflow occurs, and bfd_reloc_ok to indicate success. */
3869 static bfd_reloc_status_type
3870 mips_elf_calculate_relocation (bfd
*abfd
, bfd
*input_bfd
,
3871 asection
*input_section
,
3872 struct bfd_link_info
*info
,
3873 const Elf_Internal_Rela
*relocation
,
3874 bfd_vma addend
, reloc_howto_type
*howto
,
3875 Elf_Internal_Sym
*local_syms
,
3876 asection
**local_sections
, bfd_vma
*valuep
,
3877 const char **namep
, bfd_boolean
*require_jalxp
,
3878 bfd_boolean save_addend
)
3880 /* The eventual value we will return. */
3882 /* The address of the symbol against which the relocation is
3885 /* The final GP value to be used for the relocatable, executable, or
3886 shared object file being produced. */
3887 bfd_vma gp
= MINUS_ONE
;
3888 /* The place (section offset or address) of the storage unit being
3891 /* The value of GP used to create the relocatable object. */
3892 bfd_vma gp0
= MINUS_ONE
;
3893 /* The offset into the global offset table at which the address of
3894 the relocation entry symbol, adjusted by the addend, resides
3895 during execution. */
3896 bfd_vma g
= MINUS_ONE
;
3897 /* The section in which the symbol referenced by the relocation is
3899 asection
*sec
= NULL
;
3900 struct mips_elf_link_hash_entry
*h
= NULL
;
3901 /* TRUE if the symbol referred to by this relocation is a local
3903 bfd_boolean local_p
, was_local_p
;
3904 /* TRUE if the symbol referred to by this relocation is "_gp_disp". */
3905 bfd_boolean gp_disp_p
= FALSE
;
3906 /* TRUE if the symbol referred to by this relocation is
3907 "__gnu_local_gp". */
3908 bfd_boolean gnu_local_gp_p
= FALSE
;
3909 Elf_Internal_Shdr
*symtab_hdr
;
3911 unsigned long r_symndx
;
3913 /* TRUE if overflow occurred during the calculation of the
3914 relocation value. */
3915 bfd_boolean overflowed_p
;
3916 /* TRUE if this relocation refers to a MIPS16 function. */
3917 bfd_boolean target_is_16_bit_code_p
= FALSE
;
3918 struct mips_elf_link_hash_table
*htab
;
3921 dynobj
= elf_hash_table (info
)->dynobj
;
3922 htab
= mips_elf_hash_table (info
);
3924 /* Parse the relocation. */
3925 r_symndx
= ELF_R_SYM (input_bfd
, relocation
->r_info
);
3926 r_type
= ELF_R_TYPE (input_bfd
, relocation
->r_info
);
3927 p
= (input_section
->output_section
->vma
3928 + input_section
->output_offset
3929 + relocation
->r_offset
);
3931 /* Assume that there will be no overflow. */
3932 overflowed_p
= FALSE
;
3934 /* Figure out whether or not the symbol is local, and get the offset
3935 used in the array of hash table entries. */
3936 symtab_hdr
= &elf_tdata (input_bfd
)->symtab_hdr
;
3937 local_p
= mips_elf_local_relocation_p (input_bfd
, relocation
,
3938 local_sections
, FALSE
);
3939 was_local_p
= local_p
;
3940 if (! elf_bad_symtab (input_bfd
))
3941 extsymoff
= symtab_hdr
->sh_info
;
3944 /* The symbol table does not follow the rule that local symbols
3945 must come before globals. */
3949 /* Figure out the value of the symbol. */
3952 Elf_Internal_Sym
*sym
;
3954 sym
= local_syms
+ r_symndx
;
3955 sec
= local_sections
[r_symndx
];
3957 symbol
= sec
->output_section
->vma
+ sec
->output_offset
;
3958 if (ELF_ST_TYPE (sym
->st_info
) != STT_SECTION
3959 || (sec
->flags
& SEC_MERGE
))
3960 symbol
+= sym
->st_value
;
3961 if ((sec
->flags
& SEC_MERGE
)
3962 && ELF_ST_TYPE (sym
->st_info
) == STT_SECTION
)
3964 addend
= _bfd_elf_rel_local_sym (abfd
, sym
, &sec
, addend
);
3966 addend
+= sec
->output_section
->vma
+ sec
->output_offset
;
3969 /* MIPS16 text labels should be treated as odd. */
3970 if (sym
->st_other
== STO_MIPS16
)
3973 /* Record the name of this symbol, for our caller. */
3974 *namep
= bfd_elf_string_from_elf_section (input_bfd
,
3975 symtab_hdr
->sh_link
,
3978 *namep
= bfd_section_name (input_bfd
, sec
);
3980 target_is_16_bit_code_p
= (sym
->st_other
== STO_MIPS16
);
3984 /* ??? Could we use RELOC_FOR_GLOBAL_SYMBOL here ? */
3986 /* For global symbols we look up the symbol in the hash-table. */
3987 h
= ((struct mips_elf_link_hash_entry
*)
3988 elf_sym_hashes (input_bfd
) [r_symndx
- extsymoff
]);
3989 /* Find the real hash-table entry for this symbol. */
3990 while (h
->root
.root
.type
== bfd_link_hash_indirect
3991 || h
->root
.root
.type
== bfd_link_hash_warning
)
3992 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
3994 /* Record the name of this symbol, for our caller. */
3995 *namep
= h
->root
.root
.root
.string
;
3997 /* See if this is the special _gp_disp symbol. Note that such a
3998 symbol must always be a global symbol. */
3999 if (strcmp (*namep
, "_gp_disp") == 0
4000 && ! NEWABI_P (input_bfd
))
4002 /* Relocations against _gp_disp are permitted only with
4003 R_MIPS_HI16 and R_MIPS_LO16 relocations. */
4004 if (r_type
!= R_MIPS_HI16
&& r_type
!= R_MIPS_LO16
4005 && r_type
!= R_MIPS16_HI16
&& r_type
!= R_MIPS16_LO16
)
4006 return bfd_reloc_notsupported
;
4010 /* See if this is the special _gp symbol. Note that such a
4011 symbol must always be a global symbol. */
4012 else if (strcmp (*namep
, "__gnu_local_gp") == 0)
4013 gnu_local_gp_p
= TRUE
;
4016 /* If this symbol is defined, calculate its address. Note that
4017 _gp_disp is a magic symbol, always implicitly defined by the
4018 linker, so it's inappropriate to check to see whether or not
4020 else if ((h
->root
.root
.type
== bfd_link_hash_defined
4021 || h
->root
.root
.type
== bfd_link_hash_defweak
)
4022 && h
->root
.root
.u
.def
.section
)
4024 sec
= h
->root
.root
.u
.def
.section
;
4025 if (sec
->output_section
)
4026 symbol
= (h
->root
.root
.u
.def
.value
4027 + sec
->output_section
->vma
4028 + sec
->output_offset
);
4030 symbol
= h
->root
.root
.u
.def
.value
;
4032 else if (h
->root
.root
.type
== bfd_link_hash_undefweak
)
4033 /* We allow relocations against undefined weak symbols, giving
4034 it the value zero, so that you can undefined weak functions
4035 and check to see if they exist by looking at their
4038 else if (info
->unresolved_syms_in_objects
== RM_IGNORE
4039 && ELF_ST_VISIBILITY (h
->root
.other
) == STV_DEFAULT
)
4041 else if (strcmp (*namep
, SGI_COMPAT (input_bfd
)
4042 ? "_DYNAMIC_LINK" : "_DYNAMIC_LINKING") == 0)
4044 /* If this is a dynamic link, we should have created a
4045 _DYNAMIC_LINK symbol or _DYNAMIC_LINKING(for normal mips) symbol
4046 in in _bfd_mips_elf_create_dynamic_sections.
4047 Otherwise, we should define the symbol with a value of 0.
4048 FIXME: It should probably get into the symbol table
4050 BFD_ASSERT (! info
->shared
);
4051 BFD_ASSERT (bfd_get_section_by_name (abfd
, ".dynamic") == NULL
);
4054 else if (ELF_MIPS_IS_OPTIONAL (h
->root
.other
))
4056 /* This is an optional symbol - an Irix specific extension to the
4057 ELF spec. Ignore it for now.
4058 XXX - FIXME - there is more to the spec for OPTIONAL symbols
4059 than simply ignoring them, but we do not handle this for now.
4060 For information see the "64-bit ELF Object File Specification"
4061 which is available from here:
4062 http://techpubs.sgi.com/library/manuals/4000/007-4658-001/pdf/007-4658-001.pdf */
4067 if (! ((*info
->callbacks
->undefined_symbol
)
4068 (info
, h
->root
.root
.root
.string
, input_bfd
,
4069 input_section
, relocation
->r_offset
,
4070 (info
->unresolved_syms_in_objects
== RM_GENERATE_ERROR
)
4071 || ELF_ST_VISIBILITY (h
->root
.other
))))
4072 return bfd_reloc_undefined
;
4076 target_is_16_bit_code_p
= (h
->root
.other
== STO_MIPS16
);
4079 /* If this is a 32- or 64-bit call to a 16-bit function with a stub, we
4080 need to redirect the call to the stub, unless we're already *in*
4082 if (r_type
!= R_MIPS16_26
&& !info
->relocatable
4083 && ((h
!= NULL
&& h
->fn_stub
!= NULL
)
4085 && elf_tdata (input_bfd
)->local_stubs
!= NULL
4086 && elf_tdata (input_bfd
)->local_stubs
[r_symndx
] != NULL
))
4087 && !mips16_stub_section_p (input_bfd
, input_section
))
4089 /* This is a 32- or 64-bit call to a 16-bit function. We should
4090 have already noticed that we were going to need the
4093 sec
= elf_tdata (input_bfd
)->local_stubs
[r_symndx
];
4096 BFD_ASSERT (h
->need_fn_stub
);
4100 symbol
= sec
->output_section
->vma
+ sec
->output_offset
;
4101 /* The target is 16-bit, but the stub isn't. */
4102 target_is_16_bit_code_p
= FALSE
;
4104 /* If this is a 16-bit call to a 32- or 64-bit function with a stub, we
4105 need to redirect the call to the stub. */
4106 else if (r_type
== R_MIPS16_26
&& !info
->relocatable
4108 && ((h
->call_stub
!= NULL
|| h
->call_fp_stub
!= NULL
)
4110 && elf_tdata (input_bfd
)->local_call_stubs
!= NULL
4111 && elf_tdata (input_bfd
)->local_call_stubs
[r_symndx
] != NULL
))
4112 && !target_is_16_bit_code_p
)
4115 sec
= elf_tdata (input_bfd
)->local_call_stubs
[r_symndx
];
4118 /* If both call_stub and call_fp_stub are defined, we can figure
4119 out which one to use by checking which one appears in the input
4121 if (h
->call_stub
!= NULL
&& h
->call_fp_stub
!= NULL
)
4126 for (o
= input_bfd
->sections
; o
!= NULL
; o
= o
->next
)
4128 if (CALL_FP_STUB_P (bfd_get_section_name (input_bfd
, o
)))
4130 sec
= h
->call_fp_stub
;
4137 else if (h
->call_stub
!= NULL
)
4140 sec
= h
->call_fp_stub
;
4143 BFD_ASSERT (sec
->size
> 0);
4144 symbol
= sec
->output_section
->vma
+ sec
->output_offset
;
4147 /* Calls from 16-bit code to 32-bit code and vice versa require the
4148 special jalx instruction. */
4149 *require_jalxp
= (!info
->relocatable
4150 && (((r_type
== R_MIPS16_26
) && !target_is_16_bit_code_p
)
4151 || ((r_type
== R_MIPS_26
) && target_is_16_bit_code_p
)));
4153 local_p
= mips_elf_local_relocation_p (input_bfd
, relocation
,
4154 local_sections
, TRUE
);
4156 /* If we haven't already determined the GOT offset, or the GP value,
4157 and we're going to need it, get it now. */
4160 case R_MIPS_GOT_PAGE
:
4161 case R_MIPS_GOT_OFST
:
4162 /* We need to decay to GOT_DISP/addend if the symbol doesn't
4164 local_p
= local_p
|| _bfd_elf_symbol_refs_local_p (&h
->root
, info
, 1);
4165 if (local_p
|| r_type
== R_MIPS_GOT_OFST
)
4171 case R_MIPS_GOT_DISP
:
4172 case R_MIPS_GOT_HI16
:
4173 case R_MIPS_CALL_HI16
:
4174 case R_MIPS_GOT_LO16
:
4175 case R_MIPS_CALL_LO16
:
4177 case R_MIPS_TLS_GOTTPREL
:
4178 case R_MIPS_TLS_LDM
:
4179 /* Find the index into the GOT where this value is located. */
4180 if (r_type
== R_MIPS_TLS_LDM
)
4182 g
= mips_elf_local_got_index (abfd
, input_bfd
, info
,
4183 sec
, 0, 0, NULL
, r_type
);
4185 return bfd_reloc_outofrange
;
4189 /* On VxWorks, CALL relocations should refer to the .got.plt
4190 entry, which is initialized to point at the PLT stub. */
4191 if (htab
->is_vxworks
4192 && (r_type
== R_MIPS_CALL_HI16
4193 || r_type
== R_MIPS_CALL_LO16
4194 || r_type
== R_MIPS_CALL16
))
4196 BFD_ASSERT (addend
== 0);
4197 BFD_ASSERT (h
->root
.needs_plt
);
4198 g
= mips_elf_gotplt_index (info
, &h
->root
);
4202 /* GOT_PAGE may take a non-zero addend, that is ignored in a
4203 GOT_PAGE relocation that decays to GOT_DISP because the
4204 symbol turns out to be global. The addend is then added
4206 BFD_ASSERT (addend
== 0 || r_type
== R_MIPS_GOT_PAGE
);
4207 g
= mips_elf_global_got_index (dynobj
, input_bfd
,
4208 &h
->root
, r_type
, info
);
4209 if (h
->tls_type
== GOT_NORMAL
4210 && (! elf_hash_table(info
)->dynamic_sections_created
4212 && (info
->symbolic
|| h
->root
.forced_local
)
4213 && h
->root
.def_regular
)))
4215 /* This is a static link or a -Bsymbolic link. The
4216 symbol is defined locally, or was forced to be local.
4217 We must initialize this entry in the GOT. */
4218 asection
*sgot
= mips_elf_got_section (dynobj
, FALSE
);
4219 MIPS_ELF_PUT_WORD (dynobj
, symbol
, sgot
->contents
+ g
);
4223 else if (!htab
->is_vxworks
4224 && (r_type
== R_MIPS_CALL16
|| (r_type
== R_MIPS_GOT16
)))
4225 /* The calculation below does not involve "g". */
4229 g
= mips_elf_local_got_index (abfd
, input_bfd
, info
, sec
,
4230 symbol
+ addend
, r_symndx
, h
, r_type
);
4232 return bfd_reloc_outofrange
;
4235 /* Convert GOT indices to actual offsets. */
4236 g
= mips_elf_got_offset_from_index (dynobj
, abfd
, input_bfd
, g
);
4241 case R_MIPS_GPREL16
:
4242 case R_MIPS_GPREL32
:
4243 case R_MIPS_LITERAL
:
4246 case R_MIPS16_GPREL
:
4247 gp0
= _bfd_get_gp_value (input_bfd
);
4248 gp
= _bfd_get_gp_value (abfd
);
4250 gp
+= mips_elf_adjust_gp (abfd
, mips_elf_got_info (dynobj
, NULL
),
4261 /* Relocations against the VxWorks __GOTT_BASE__ and __GOTT_INDEX__
4262 symbols are resolved by the loader. Add them to .rela.dyn. */
4263 if (h
!= NULL
&& is_gott_symbol (info
, &h
->root
))
4265 Elf_Internal_Rela outrel
;
4269 s
= mips_elf_rel_dyn_section (info
, FALSE
);
4270 loc
= s
->contents
+ s
->reloc_count
++ * sizeof (Elf32_External_Rela
);
4272 outrel
.r_offset
= (input_section
->output_section
->vma
4273 + input_section
->output_offset
4274 + relocation
->r_offset
);
4275 outrel
.r_info
= ELF32_R_INFO (h
->root
.dynindx
, r_type
);
4276 outrel
.r_addend
= addend
;
4277 bfd_elf32_swap_reloca_out (abfd
, &outrel
, loc
);
4279 /* If we've written this relocation for a readonly section,
4280 we need to set DF_TEXTREL again, so that we do not delete the
4282 if (MIPS_ELF_READONLY_SECTION (input_section
))
4283 info
->flags
|= DF_TEXTREL
;
4286 return bfd_reloc_ok
;
4289 /* Figure out what kind of relocation is being performed. */
4293 return bfd_reloc_continue
;
4296 value
= symbol
+ _bfd_mips_elf_sign_extend (addend
, 16);
4297 overflowed_p
= mips_elf_overflow_p (value
, 16);
4304 || (!htab
->is_vxworks
4305 && htab
->root
.dynamic_sections_created
4307 && h
->root
.def_dynamic
4308 && !h
->root
.def_regular
))
4310 && (input_section
->flags
& SEC_ALLOC
) != 0)
4312 /* If we're creating a shared library, or this relocation is
4313 against a symbol in a shared library, then we can't know
4314 where the symbol will end up. So, we create a relocation
4315 record in the output, and leave the job up to the dynamic
4318 In VxWorks executables, references to external symbols
4319 are handled using copy relocs or PLT stubs, so there's
4320 no need to add a dynamic relocation here. */
4322 if (!mips_elf_create_dynamic_relocation (abfd
,
4330 return bfd_reloc_undefined
;
4334 if (r_type
!= R_MIPS_REL32
)
4335 value
= symbol
+ addend
;
4339 value
&= howto
->dst_mask
;
4343 value
= symbol
+ addend
- p
;
4344 value
&= howto
->dst_mask
;
4348 /* The calculation for R_MIPS16_26 is just the same as for an
4349 R_MIPS_26. It's only the storage of the relocated field into
4350 the output file that's different. That's handled in
4351 mips_elf_perform_relocation. So, we just fall through to the
4352 R_MIPS_26 case here. */
4355 value
= ((addend
| ((p
+ 4) & 0xf0000000)) + symbol
) >> 2;
4358 value
= (_bfd_mips_elf_sign_extend (addend
, 28) + symbol
) >> 2;
4359 if (h
->root
.root
.type
!= bfd_link_hash_undefweak
)
4360 overflowed_p
= (value
>> 26) != ((p
+ 4) >> 28);
4362 value
&= howto
->dst_mask
;
4365 case R_MIPS_TLS_DTPREL_HI16
:
4366 value
= (mips_elf_high (addend
+ symbol
- dtprel_base (info
))
4370 case R_MIPS_TLS_DTPREL_LO16
:
4371 value
= (symbol
+ addend
- dtprel_base (info
)) & howto
->dst_mask
;
4374 case R_MIPS_TLS_TPREL_HI16
:
4375 value
= (mips_elf_high (addend
+ symbol
- tprel_base (info
))
4379 case R_MIPS_TLS_TPREL_LO16
:
4380 value
= (symbol
+ addend
- tprel_base (info
)) & howto
->dst_mask
;
4387 value
= mips_elf_high (addend
+ symbol
);
4388 value
&= howto
->dst_mask
;
4392 /* For MIPS16 ABI code we generate this sequence
4393 0: li $v0,%hi(_gp_disp)
4394 4: addiupc $v1,%lo(_gp_disp)
4398 So the offsets of hi and lo relocs are the same, but the
4399 $pc is four higher than $t9 would be, so reduce
4400 both reloc addends by 4. */
4401 if (r_type
== R_MIPS16_HI16
)
4402 value
= mips_elf_high (addend
+ gp
- p
- 4);
4404 value
= mips_elf_high (addend
+ gp
- p
);
4405 overflowed_p
= mips_elf_overflow_p (value
, 16);
4412 value
= (symbol
+ addend
) & howto
->dst_mask
;
4415 /* See the comment for R_MIPS16_HI16 above for the reason
4416 for this conditional. */
4417 if (r_type
== R_MIPS16_LO16
)
4418 value
= addend
+ gp
- p
;
4420 value
= addend
+ gp
- p
+ 4;
4421 /* The MIPS ABI requires checking the R_MIPS_LO16 relocation
4422 for overflow. But, on, say, IRIX5, relocations against
4423 _gp_disp are normally generated from the .cpload
4424 pseudo-op. It generates code that normally looks like
4427 lui $gp,%hi(_gp_disp)
4428 addiu $gp,$gp,%lo(_gp_disp)
4431 Here $t9 holds the address of the function being called,
4432 as required by the MIPS ELF ABI. The R_MIPS_LO16
4433 relocation can easily overflow in this situation, but the
4434 R_MIPS_HI16 relocation will handle the overflow.
4435 Therefore, we consider this a bug in the MIPS ABI, and do
4436 not check for overflow here. */
4440 case R_MIPS_LITERAL
:
4441 /* Because we don't merge literal sections, we can handle this
4442 just like R_MIPS_GPREL16. In the long run, we should merge
4443 shared literals, and then we will need to additional work
4448 case R_MIPS16_GPREL
:
4449 /* The R_MIPS16_GPREL performs the same calculation as
4450 R_MIPS_GPREL16, but stores the relocated bits in a different
4451 order. We don't need to do anything special here; the
4452 differences are handled in mips_elf_perform_relocation. */
4453 case R_MIPS_GPREL16
:
4454 /* Only sign-extend the addend if it was extracted from the
4455 instruction. If the addend was separate, leave it alone,
4456 otherwise we may lose significant bits. */
4457 if (howto
->partial_inplace
)
4458 addend
= _bfd_mips_elf_sign_extend (addend
, 16);
4459 value
= symbol
+ addend
- gp
;
4460 /* If the symbol was local, any earlier relocatable links will
4461 have adjusted its addend with the gp offset, so compensate
4462 for that now. Don't do it for symbols forced local in this
4463 link, though, since they won't have had the gp offset applied
4467 overflowed_p
= mips_elf_overflow_p (value
, 16);
4472 /* VxWorks does not have separate local and global semantics for
4473 R_MIPS_GOT16; every relocation evaluates to "G". */
4474 if (!htab
->is_vxworks
&& local_p
)
4478 forced
= ! mips_elf_local_relocation_p (input_bfd
, relocation
,
4479 local_sections
, FALSE
);
4480 value
= mips_elf_got16_entry (abfd
, input_bfd
, info
, sec
,
4481 symbol
+ addend
, forced
);
4482 if (value
== MINUS_ONE
)
4483 return bfd_reloc_outofrange
;
4485 = mips_elf_got_offset_from_index (dynobj
, abfd
, input_bfd
, value
);
4486 overflowed_p
= mips_elf_overflow_p (value
, 16);
4493 case R_MIPS_TLS_GOTTPREL
:
4494 case R_MIPS_TLS_LDM
:
4495 case R_MIPS_GOT_DISP
:
4498 overflowed_p
= mips_elf_overflow_p (value
, 16);
4501 case R_MIPS_GPREL32
:
4502 value
= (addend
+ symbol
+ gp0
- gp
);
4504 value
&= howto
->dst_mask
;
4508 case R_MIPS_GNU_REL16_S2
:
4509 value
= symbol
+ _bfd_mips_elf_sign_extend (addend
, 18) - p
;
4510 overflowed_p
= mips_elf_overflow_p (value
, 18);
4511 value
>>= howto
->rightshift
;
4512 value
&= howto
->dst_mask
;
4515 case R_MIPS_GOT_HI16
:
4516 case R_MIPS_CALL_HI16
:
4517 /* We're allowed to handle these two relocations identically.
4518 The dynamic linker is allowed to handle the CALL relocations
4519 differently by creating a lazy evaluation stub. */
4521 value
= mips_elf_high (value
);
4522 value
&= howto
->dst_mask
;
4525 case R_MIPS_GOT_LO16
:
4526 case R_MIPS_CALL_LO16
:
4527 value
= g
& howto
->dst_mask
;
4530 case R_MIPS_GOT_PAGE
:
4531 /* GOT_PAGE relocations that reference non-local symbols decay
4532 to GOT_DISP. The corresponding GOT_OFST relocation decays to
4536 value
= mips_elf_got_page (abfd
, input_bfd
, info
, sec
,
4537 symbol
+ addend
, NULL
);
4538 if (value
== MINUS_ONE
)
4539 return bfd_reloc_outofrange
;
4540 value
= mips_elf_got_offset_from_index (dynobj
, abfd
, input_bfd
, value
);
4541 overflowed_p
= mips_elf_overflow_p (value
, 16);
4544 case R_MIPS_GOT_OFST
:
4546 mips_elf_got_page (abfd
, input_bfd
, info
, sec
,
4547 symbol
+ addend
, &value
);
4550 overflowed_p
= mips_elf_overflow_p (value
, 16);
4554 value
= symbol
- addend
;
4555 value
&= howto
->dst_mask
;
4559 value
= mips_elf_higher (addend
+ symbol
);
4560 value
&= howto
->dst_mask
;
4563 case R_MIPS_HIGHEST
:
4564 value
= mips_elf_highest (addend
+ symbol
);
4565 value
&= howto
->dst_mask
;
4568 case R_MIPS_SCN_DISP
:
4569 value
= symbol
+ addend
- sec
->output_offset
;
4570 value
&= howto
->dst_mask
;
4574 /* This relocation is only a hint. In some cases, we optimize
4575 it into a bal instruction. But we don't try to optimize
4576 branches to the PLT; that will wind up wasting time. */
4577 if (h
!= NULL
&& h
->root
.plt
.offset
!= (bfd_vma
) -1)
4578 return bfd_reloc_continue
;
4579 value
= symbol
+ addend
;
4583 case R_MIPS_GNU_VTINHERIT
:
4584 case R_MIPS_GNU_VTENTRY
:
4585 /* We don't do anything with these at present. */
4586 return bfd_reloc_continue
;
4589 /* An unrecognized relocation type. */
4590 return bfd_reloc_notsupported
;
4593 /* Store the VALUE for our caller. */
4595 return overflowed_p
? bfd_reloc_overflow
: bfd_reloc_ok
;
4598 /* Obtain the field relocated by RELOCATION. */
4601 mips_elf_obtain_contents (reloc_howto_type
*howto
,
4602 const Elf_Internal_Rela
*relocation
,
4603 bfd
*input_bfd
, bfd_byte
*contents
)
4606 bfd_byte
*location
= contents
+ relocation
->r_offset
;
4608 /* Obtain the bytes. */
4609 x
= bfd_get ((8 * bfd_get_reloc_size (howto
)), input_bfd
, location
);
4614 /* It has been determined that the result of the RELOCATION is the
4615 VALUE. Use HOWTO to place VALUE into the output file at the
4616 appropriate position. The SECTION is the section to which the
4617 relocation applies. If REQUIRE_JALX is TRUE, then the opcode used
4618 for the relocation must be either JAL or JALX, and it is
4619 unconditionally converted to JALX.
4621 Returns FALSE if anything goes wrong. */
4624 mips_elf_perform_relocation (struct bfd_link_info
*info
,
4625 reloc_howto_type
*howto
,
4626 const Elf_Internal_Rela
*relocation
,
4627 bfd_vma value
, bfd
*input_bfd
,
4628 asection
*input_section
, bfd_byte
*contents
,
4629 bfd_boolean require_jalx
)
4633 int r_type
= ELF_R_TYPE (input_bfd
, relocation
->r_info
);
4635 /* Figure out where the relocation is occurring. */
4636 location
= contents
+ relocation
->r_offset
;
4638 _bfd_mips16_elf_reloc_unshuffle (input_bfd
, r_type
, FALSE
, location
);
4640 /* Obtain the current value. */
4641 x
= mips_elf_obtain_contents (howto
, relocation
, input_bfd
, contents
);
4643 /* Clear the field we are setting. */
4644 x
&= ~howto
->dst_mask
;
4646 /* Set the field. */
4647 x
|= (value
& howto
->dst_mask
);
4649 /* If required, turn JAL into JALX. */
4653 bfd_vma opcode
= x
>> 26;
4654 bfd_vma jalx_opcode
;
4656 /* Check to see if the opcode is already JAL or JALX. */
4657 if (r_type
== R_MIPS16_26
)
4659 ok
= ((opcode
== 0x6) || (opcode
== 0x7));
4664 ok
= ((opcode
== 0x3) || (opcode
== 0x1d));
4668 /* If the opcode is not JAL or JALX, there's a problem. */
4671 (*_bfd_error_handler
)
4672 (_("%B: %A+0x%lx: jump to stub routine which is not jal"),
4675 (unsigned long) relocation
->r_offset
);
4676 bfd_set_error (bfd_error_bad_value
);
4680 /* Make this the JALX opcode. */
4681 x
= (x
& ~(0x3f << 26)) | (jalx_opcode
<< 26);
4684 /* On the RM9000, bal is faster than jal, because bal uses branch
4685 prediction hardware. If we are linking for the RM9000, and we
4686 see jal, and bal fits, use it instead. Note that this
4687 transformation should be safe for all architectures. */
4688 if (bfd_get_mach (input_bfd
) == bfd_mach_mips9000
4689 && !info
->relocatable
4691 && ((r_type
== R_MIPS_26
&& (x
>> 26) == 0x3) /* jal addr */
4692 || (r_type
== R_MIPS_JALR
&& x
== 0x0320f809))) /* jalr t9 */
4698 addr
= (input_section
->output_section
->vma
4699 + input_section
->output_offset
4700 + relocation
->r_offset
4702 if (r_type
== R_MIPS_26
)
4703 dest
= (value
<< 2) | ((addr
>> 28) << 28);
4707 if (off
<= 0x1ffff && off
>= -0x20000)
4708 x
= 0x04110000 | (((bfd_vma
) off
>> 2) & 0xffff); /* bal addr */
4711 /* Put the value into the output. */
4712 bfd_put (8 * bfd_get_reloc_size (howto
), input_bfd
, x
, location
);
4714 _bfd_mips16_elf_reloc_shuffle(input_bfd
, r_type
, !info
->relocatable
,
4720 /* Returns TRUE if SECTION is a MIPS16 stub section. */
4723 mips16_stub_section_p (bfd
*abfd ATTRIBUTE_UNUSED
, asection
*section
)
4725 const char *name
= bfd_get_section_name (abfd
, section
);
4727 return FN_STUB_P (name
) || CALL_STUB_P (name
) || CALL_FP_STUB_P (name
);
4730 /* Add room for N relocations to the .rel(a).dyn section in ABFD. */
4733 mips_elf_allocate_dynamic_relocations (bfd
*abfd
, struct bfd_link_info
*info
,
4737 struct mips_elf_link_hash_table
*htab
;
4739 htab
= mips_elf_hash_table (info
);
4740 s
= mips_elf_rel_dyn_section (info
, FALSE
);
4741 BFD_ASSERT (s
!= NULL
);
4743 if (htab
->is_vxworks
)
4744 s
->size
+= n
* MIPS_ELF_RELA_SIZE (abfd
);
4749 /* Make room for a null element. */
4750 s
->size
+= MIPS_ELF_REL_SIZE (abfd
);
4753 s
->size
+= n
* MIPS_ELF_REL_SIZE (abfd
);
4757 /* Create a rel.dyn relocation for the dynamic linker to resolve. REL
4758 is the original relocation, which is now being transformed into a
4759 dynamic relocation. The ADDENDP is adjusted if necessary; the
4760 caller should store the result in place of the original addend. */
4763 mips_elf_create_dynamic_relocation (bfd
*output_bfd
,
4764 struct bfd_link_info
*info
,
4765 const Elf_Internal_Rela
*rel
,
4766 struct mips_elf_link_hash_entry
*h
,
4767 asection
*sec
, bfd_vma symbol
,
4768 bfd_vma
*addendp
, asection
*input_section
)
4770 Elf_Internal_Rela outrel
[3];
4775 bfd_boolean defined_p
;
4776 struct mips_elf_link_hash_table
*htab
;
4778 htab
= mips_elf_hash_table (info
);
4779 r_type
= ELF_R_TYPE (output_bfd
, rel
->r_info
);
4780 dynobj
= elf_hash_table (info
)->dynobj
;
4781 sreloc
= mips_elf_rel_dyn_section (info
, FALSE
);
4782 BFD_ASSERT (sreloc
!= NULL
);
4783 BFD_ASSERT (sreloc
->contents
!= NULL
);
4784 BFD_ASSERT (sreloc
->reloc_count
* MIPS_ELF_REL_SIZE (output_bfd
)
4787 outrel
[0].r_offset
=
4788 _bfd_elf_section_offset (output_bfd
, info
, input_section
, rel
[0].r_offset
);
4789 outrel
[1].r_offset
=
4790 _bfd_elf_section_offset (output_bfd
, info
, input_section
, rel
[1].r_offset
);
4791 outrel
[2].r_offset
=
4792 _bfd_elf_section_offset (output_bfd
, info
, input_section
, rel
[2].r_offset
);
4794 if (outrel
[0].r_offset
== MINUS_ONE
)
4795 /* The relocation field has been deleted. */
4798 if (outrel
[0].r_offset
== MINUS_TWO
)
4800 /* The relocation field has been converted into a relative value of
4801 some sort. Functions like _bfd_elf_write_section_eh_frame expect
4802 the field to be fully relocated, so add in the symbol's value. */
4807 /* We must now calculate the dynamic symbol table index to use
4808 in the relocation. */
4810 && (!h
->root
.def_regular
4811 || (info
->shared
&& !info
->symbolic
&& !h
->root
.forced_local
)))
4813 indx
= h
->root
.dynindx
;
4814 if (SGI_COMPAT (output_bfd
))
4815 defined_p
= h
->root
.def_regular
;
4817 /* ??? glibc's ld.so just adds the final GOT entry to the
4818 relocation field. It therefore treats relocs against
4819 defined symbols in the same way as relocs against
4820 undefined symbols. */
4825 if (sec
!= NULL
&& bfd_is_abs_section (sec
))
4827 else if (sec
== NULL
|| sec
->owner
== NULL
)
4829 bfd_set_error (bfd_error_bad_value
);
4834 indx
= elf_section_data (sec
->output_section
)->dynindx
;
4837 asection
*osec
= htab
->root
.text_index_section
;
4838 indx
= elf_section_data (osec
)->dynindx
;
4844 /* Instead of generating a relocation using the section
4845 symbol, we may as well make it a fully relative
4846 relocation. We want to avoid generating relocations to
4847 local symbols because we used to generate them
4848 incorrectly, without adding the original symbol value,
4849 which is mandated by the ABI for section symbols. In
4850 order to give dynamic loaders and applications time to
4851 phase out the incorrect use, we refrain from emitting
4852 section-relative relocations. It's not like they're
4853 useful, after all. This should be a bit more efficient
4855 /* ??? Although this behavior is compatible with glibc's ld.so,
4856 the ABI says that relocations against STN_UNDEF should have
4857 a symbol value of 0. Irix rld honors this, so relocations
4858 against STN_UNDEF have no effect. */
4859 if (!SGI_COMPAT (output_bfd
))
4864 /* If the relocation was previously an absolute relocation and
4865 this symbol will not be referred to by the relocation, we must
4866 adjust it by the value we give it in the dynamic symbol table.
4867 Otherwise leave the job up to the dynamic linker. */
4868 if (defined_p
&& r_type
!= R_MIPS_REL32
)
4871 if (htab
->is_vxworks
)
4872 /* VxWorks uses non-relative relocations for this. */
4873 outrel
[0].r_info
= ELF32_R_INFO (indx
, R_MIPS_32
);
4875 /* The relocation is always an REL32 relocation because we don't
4876 know where the shared library will wind up at load-time. */
4877 outrel
[0].r_info
= ELF_R_INFO (output_bfd
, (unsigned long) indx
,
4880 /* For strict adherence to the ABI specification, we should
4881 generate a R_MIPS_64 relocation record by itself before the
4882 _REL32/_64 record as well, such that the addend is read in as
4883 a 64-bit value (REL32 is a 32-bit relocation, after all).
4884 However, since none of the existing ELF64 MIPS dynamic
4885 loaders seems to care, we don't waste space with these
4886 artificial relocations. If this turns out to not be true,
4887 mips_elf_allocate_dynamic_relocation() should be tweaked so
4888 as to make room for a pair of dynamic relocations per
4889 invocation if ABI_64_P, and here we should generate an
4890 additional relocation record with R_MIPS_64 by itself for a
4891 NULL symbol before this relocation record. */
4892 outrel
[1].r_info
= ELF_R_INFO (output_bfd
, 0,
4893 ABI_64_P (output_bfd
)
4896 outrel
[2].r_info
= ELF_R_INFO (output_bfd
, 0, R_MIPS_NONE
);
4898 /* Adjust the output offset of the relocation to reference the
4899 correct location in the output file. */
4900 outrel
[0].r_offset
+= (input_section
->output_section
->vma
4901 + input_section
->output_offset
);
4902 outrel
[1].r_offset
+= (input_section
->output_section
->vma
4903 + input_section
->output_offset
);
4904 outrel
[2].r_offset
+= (input_section
->output_section
->vma
4905 + input_section
->output_offset
);
4907 /* Put the relocation back out. We have to use the special
4908 relocation outputter in the 64-bit case since the 64-bit
4909 relocation format is non-standard. */
4910 if (ABI_64_P (output_bfd
))
4912 (*get_elf_backend_data (output_bfd
)->s
->swap_reloc_out
)
4913 (output_bfd
, &outrel
[0],
4915 + sreloc
->reloc_count
* sizeof (Elf64_Mips_External_Rel
)));
4917 else if (htab
->is_vxworks
)
4919 /* VxWorks uses RELA rather than REL dynamic relocations. */
4920 outrel
[0].r_addend
= *addendp
;
4921 bfd_elf32_swap_reloca_out
4922 (output_bfd
, &outrel
[0],
4924 + sreloc
->reloc_count
* sizeof (Elf32_External_Rela
)));
4927 bfd_elf32_swap_reloc_out
4928 (output_bfd
, &outrel
[0],
4929 (sreloc
->contents
+ sreloc
->reloc_count
* sizeof (Elf32_External_Rel
)));
4931 /* We've now added another relocation. */
4932 ++sreloc
->reloc_count
;
4934 /* Make sure the output section is writable. The dynamic linker
4935 will be writing to it. */
4936 elf_section_data (input_section
->output_section
)->this_hdr
.sh_flags
4939 /* On IRIX5, make an entry of compact relocation info. */
4940 if (IRIX_COMPAT (output_bfd
) == ict_irix5
)
4942 asection
*scpt
= bfd_get_section_by_name (dynobj
, ".compact_rel");
4947 Elf32_crinfo cptrel
;
4949 mips_elf_set_cr_format (cptrel
, CRF_MIPS_LONG
);
4950 cptrel
.vaddr
= (rel
->r_offset
4951 + input_section
->output_section
->vma
4952 + input_section
->output_offset
);
4953 if (r_type
== R_MIPS_REL32
)
4954 mips_elf_set_cr_type (cptrel
, CRT_MIPS_REL32
);
4956 mips_elf_set_cr_type (cptrel
, CRT_MIPS_WORD
);
4957 mips_elf_set_cr_dist2to (cptrel
, 0);
4958 cptrel
.konst
= *addendp
;
4960 cr
= (scpt
->contents
4961 + sizeof (Elf32_External_compact_rel
));
4962 mips_elf_set_cr_relvaddr (cptrel
, 0);
4963 bfd_elf32_swap_crinfo_out (output_bfd
, &cptrel
,
4964 ((Elf32_External_crinfo
*) cr
4965 + scpt
->reloc_count
));
4966 ++scpt
->reloc_count
;
4970 /* If we've written this relocation for a readonly section,
4971 we need to set DF_TEXTREL again, so that we do not delete the
4973 if (MIPS_ELF_READONLY_SECTION (input_section
))
4974 info
->flags
|= DF_TEXTREL
;
4979 /* Return the MACH for a MIPS e_flags value. */
4982 _bfd_elf_mips_mach (flagword flags
)
4984 switch (flags
& EF_MIPS_MACH
)
4986 case E_MIPS_MACH_3900
:
4987 return bfd_mach_mips3900
;
4989 case E_MIPS_MACH_4010
:
4990 return bfd_mach_mips4010
;
4992 case E_MIPS_MACH_4100
:
4993 return bfd_mach_mips4100
;
4995 case E_MIPS_MACH_4111
:
4996 return bfd_mach_mips4111
;
4998 case E_MIPS_MACH_4120
:
4999 return bfd_mach_mips4120
;
5001 case E_MIPS_MACH_4650
:
5002 return bfd_mach_mips4650
;
5004 case E_MIPS_MACH_5400
:
5005 return bfd_mach_mips5400
;
5007 case E_MIPS_MACH_5500
:
5008 return bfd_mach_mips5500
;
5010 case E_MIPS_MACH_9000
:
5011 return bfd_mach_mips9000
;
5013 case E_MIPS_MACH_SB1
:
5014 return bfd_mach_mips_sb1
;
5017 switch (flags
& EF_MIPS_ARCH
)
5021 return bfd_mach_mips3000
;
5024 return bfd_mach_mips6000
;
5027 return bfd_mach_mips4000
;
5030 return bfd_mach_mips8000
;
5033 return bfd_mach_mips5
;
5035 case E_MIPS_ARCH_32
:
5036 return bfd_mach_mipsisa32
;
5038 case E_MIPS_ARCH_64
:
5039 return bfd_mach_mipsisa64
;
5041 case E_MIPS_ARCH_32R2
:
5042 return bfd_mach_mipsisa32r2
;
5044 case E_MIPS_ARCH_64R2
:
5045 return bfd_mach_mipsisa64r2
;
5052 /* Return printable name for ABI. */
5054 static INLINE
char *
5055 elf_mips_abi_name (bfd
*abfd
)
5059 flags
= elf_elfheader (abfd
)->e_flags
;
5060 switch (flags
& EF_MIPS_ABI
)
5063 if (ABI_N32_P (abfd
))
5065 else if (ABI_64_P (abfd
))
5069 case E_MIPS_ABI_O32
:
5071 case E_MIPS_ABI_O64
:
5073 case E_MIPS_ABI_EABI32
:
5075 case E_MIPS_ABI_EABI64
:
5078 return "unknown abi";
5082 /* MIPS ELF uses two common sections. One is the usual one, and the
5083 other is for small objects. All the small objects are kept
5084 together, and then referenced via the gp pointer, which yields
5085 faster assembler code. This is what we use for the small common
5086 section. This approach is copied from ecoff.c. */
5087 static asection mips_elf_scom_section
;
5088 static asymbol mips_elf_scom_symbol
;
5089 static asymbol
*mips_elf_scom_symbol_ptr
;
5091 /* MIPS ELF also uses an acommon section, which represents an
5092 allocated common symbol which may be overridden by a
5093 definition in a shared library. */
5094 static asection mips_elf_acom_section
;
5095 static asymbol mips_elf_acom_symbol
;
5096 static asymbol
*mips_elf_acom_symbol_ptr
;
5098 /* Handle the special MIPS section numbers that a symbol may use.
5099 This is used for both the 32-bit and the 64-bit ABI. */
5102 _bfd_mips_elf_symbol_processing (bfd
*abfd
, asymbol
*asym
)
5104 elf_symbol_type
*elfsym
;
5106 elfsym
= (elf_symbol_type
*) asym
;
5107 switch (elfsym
->internal_elf_sym
.st_shndx
)
5109 case SHN_MIPS_ACOMMON
:
5110 /* This section is used in a dynamically linked executable file.
5111 It is an allocated common section. The dynamic linker can
5112 either resolve these symbols to something in a shared
5113 library, or it can just leave them here. For our purposes,
5114 we can consider these symbols to be in a new section. */
5115 if (mips_elf_acom_section
.name
== NULL
)
5117 /* Initialize the acommon section. */
5118 mips_elf_acom_section
.name
= ".acommon";
5119 mips_elf_acom_section
.flags
= SEC_ALLOC
;
5120 mips_elf_acom_section
.output_section
= &mips_elf_acom_section
;
5121 mips_elf_acom_section
.symbol
= &mips_elf_acom_symbol
;
5122 mips_elf_acom_section
.symbol_ptr_ptr
= &mips_elf_acom_symbol_ptr
;
5123 mips_elf_acom_symbol
.name
= ".acommon";
5124 mips_elf_acom_symbol
.flags
= BSF_SECTION_SYM
;
5125 mips_elf_acom_symbol
.section
= &mips_elf_acom_section
;
5126 mips_elf_acom_symbol_ptr
= &mips_elf_acom_symbol
;
5128 asym
->section
= &mips_elf_acom_section
;
5132 /* Common symbols less than the GP size are automatically
5133 treated as SHN_MIPS_SCOMMON symbols on IRIX5. */
5134 if (asym
->value
> elf_gp_size (abfd
)
5135 || ELF_ST_TYPE (elfsym
->internal_elf_sym
.st_info
) == STT_TLS
5136 || IRIX_COMPAT (abfd
) == ict_irix6
)
5139 case SHN_MIPS_SCOMMON
:
5140 if (mips_elf_scom_section
.name
== NULL
)
5142 /* Initialize the small common section. */
5143 mips_elf_scom_section
.name
= ".scommon";
5144 mips_elf_scom_section
.flags
= SEC_IS_COMMON
;
5145 mips_elf_scom_section
.output_section
= &mips_elf_scom_section
;
5146 mips_elf_scom_section
.symbol
= &mips_elf_scom_symbol
;
5147 mips_elf_scom_section
.symbol_ptr_ptr
= &mips_elf_scom_symbol_ptr
;
5148 mips_elf_scom_symbol
.name
= ".scommon";
5149 mips_elf_scom_symbol
.flags
= BSF_SECTION_SYM
;
5150 mips_elf_scom_symbol
.section
= &mips_elf_scom_section
;
5151 mips_elf_scom_symbol_ptr
= &mips_elf_scom_symbol
;
5153 asym
->section
= &mips_elf_scom_section
;
5154 asym
->value
= elfsym
->internal_elf_sym
.st_size
;
5157 case SHN_MIPS_SUNDEFINED
:
5158 asym
->section
= bfd_und_section_ptr
;
5163 asection
*section
= bfd_get_section_by_name (abfd
, ".text");
5165 BFD_ASSERT (SGI_COMPAT (abfd
));
5166 if (section
!= NULL
)
5168 asym
->section
= section
;
5169 /* MIPS_TEXT is a bit special, the address is not an offset
5170 to the base of the .text section. So substract the section
5171 base address to make it an offset. */
5172 asym
->value
-= section
->vma
;
5179 asection
*section
= bfd_get_section_by_name (abfd
, ".data");
5181 BFD_ASSERT (SGI_COMPAT (abfd
));
5182 if (section
!= NULL
)
5184 asym
->section
= section
;
5185 /* MIPS_DATA is a bit special, the address is not an offset
5186 to the base of the .data section. So substract the section
5187 base address to make it an offset. */
5188 asym
->value
-= section
->vma
;
5195 /* Implement elf_backend_eh_frame_address_size. This differs from
5196 the default in the way it handles EABI64.
5198 EABI64 was originally specified as an LP64 ABI, and that is what
5199 -mabi=eabi normally gives on a 64-bit target. However, gcc has
5200 historically accepted the combination of -mabi=eabi and -mlong32,
5201 and this ILP32 variation has become semi-official over time.
5202 Both forms use elf32 and have pointer-sized FDE addresses.
5204 If an EABI object was generated by GCC 4.0 or above, it will have
5205 an empty .gcc_compiled_longXX section, where XX is the size of longs
5206 in bits. Unfortunately, ILP32 objects generated by earlier compilers
5207 have no special marking to distinguish them from LP64 objects.
5209 We don't want users of the official LP64 ABI to be punished for the
5210 existence of the ILP32 variant, but at the same time, we don't want
5211 to mistakenly interpret pre-4.0 ILP32 objects as being LP64 objects.
5212 We therefore take the following approach:
5214 - If ABFD contains a .gcc_compiled_longXX section, use it to
5215 determine the pointer size.
5217 - Otherwise check the type of the first relocation. Assume that
5218 the LP64 ABI is being used if the relocation is of type R_MIPS_64.
5222 The second check is enough to detect LP64 objects generated by pre-4.0
5223 compilers because, in the kind of output generated by those compilers,
5224 the first relocation will be associated with either a CIE personality
5225 routine or an FDE start address. Furthermore, the compilers never
5226 used a special (non-pointer) encoding for this ABI.
5228 Checking the relocation type should also be safe because there is no
5229 reason to use R_MIPS_64 in an ILP32 object. Pre-4.0 compilers never
5233 _bfd_mips_elf_eh_frame_address_size (bfd
*abfd
, asection
*sec
)
5235 if (elf_elfheader (abfd
)->e_ident
[EI_CLASS
] == ELFCLASS64
)
5237 if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
) == E_MIPS_ABI_EABI64
)
5239 bfd_boolean long32_p
, long64_p
;
5241 long32_p
= bfd_get_section_by_name (abfd
, ".gcc_compiled_long32") != 0;
5242 long64_p
= bfd_get_section_by_name (abfd
, ".gcc_compiled_long64") != 0;
5243 if (long32_p
&& long64_p
)
5250 if (sec
->reloc_count
> 0
5251 && elf_section_data (sec
)->relocs
!= NULL
5252 && (ELF32_R_TYPE (elf_section_data (sec
)->relocs
[0].r_info
)
5261 /* There appears to be a bug in the MIPSpro linker that causes GOT_DISP
5262 relocations against two unnamed section symbols to resolve to the
5263 same address. For example, if we have code like:
5265 lw $4,%got_disp(.data)($gp)
5266 lw $25,%got_disp(.text)($gp)
5269 then the linker will resolve both relocations to .data and the program
5270 will jump there rather than to .text.
5272 We can work around this problem by giving names to local section symbols.
5273 This is also what the MIPSpro tools do. */
5276 _bfd_mips_elf_name_local_section_symbols (bfd
*abfd
)
5278 return SGI_COMPAT (abfd
);
5281 /* Work over a section just before writing it out. This routine is
5282 used by both the 32-bit and the 64-bit ABI. FIXME: We recognize
5283 sections that need the SHF_MIPS_GPREL flag by name; there has to be
5287 _bfd_mips_elf_section_processing (bfd
*abfd
, Elf_Internal_Shdr
*hdr
)
5289 if (hdr
->sh_type
== SHT_MIPS_REGINFO
5290 && hdr
->sh_size
> 0)
5294 BFD_ASSERT (hdr
->sh_size
== sizeof (Elf32_External_RegInfo
));
5295 BFD_ASSERT (hdr
->contents
== NULL
);
5298 hdr
->sh_offset
+ sizeof (Elf32_External_RegInfo
) - 4,
5301 H_PUT_32 (abfd
, elf_gp (abfd
), buf
);
5302 if (bfd_bwrite (buf
, 4, abfd
) != 4)
5306 if (hdr
->sh_type
== SHT_MIPS_OPTIONS
5307 && hdr
->bfd_section
!= NULL
5308 && mips_elf_section_data (hdr
->bfd_section
) != NULL
5309 && mips_elf_section_data (hdr
->bfd_section
)->u
.tdata
!= NULL
)
5311 bfd_byte
*contents
, *l
, *lend
;
5313 /* We stored the section contents in the tdata field in the
5314 set_section_contents routine. We save the section contents
5315 so that we don't have to read them again.
5316 At this point we know that elf_gp is set, so we can look
5317 through the section contents to see if there is an
5318 ODK_REGINFO structure. */
5320 contents
= mips_elf_section_data (hdr
->bfd_section
)->u
.tdata
;
5322 lend
= contents
+ hdr
->sh_size
;
5323 while (l
+ sizeof (Elf_External_Options
) <= lend
)
5325 Elf_Internal_Options intopt
;
5327 bfd_mips_elf_swap_options_in (abfd
, (Elf_External_Options
*) l
,
5329 if (intopt
.size
< sizeof (Elf_External_Options
))
5331 (*_bfd_error_handler
)
5332 (_("%B: Warning: bad `%s' option size %u smaller than its header"),
5333 abfd
, MIPS_ELF_OPTIONS_SECTION_NAME (abfd
), intopt
.size
);
5336 if (ABI_64_P (abfd
) && intopt
.kind
== ODK_REGINFO
)
5343 + sizeof (Elf_External_Options
)
5344 + (sizeof (Elf64_External_RegInfo
) - 8)),
5347 H_PUT_64 (abfd
, elf_gp (abfd
), buf
);
5348 if (bfd_bwrite (buf
, 8, abfd
) != 8)
5351 else if (intopt
.kind
== ODK_REGINFO
)
5358 + sizeof (Elf_External_Options
)
5359 + (sizeof (Elf32_External_RegInfo
) - 4)),
5362 H_PUT_32 (abfd
, elf_gp (abfd
), buf
);
5363 if (bfd_bwrite (buf
, 4, abfd
) != 4)
5370 if (hdr
->bfd_section
!= NULL
)
5372 const char *name
= bfd_get_section_name (abfd
, hdr
->bfd_section
);
5374 if (strcmp (name
, ".sdata") == 0
5375 || strcmp (name
, ".lit8") == 0
5376 || strcmp (name
, ".lit4") == 0)
5378 hdr
->sh_flags
|= SHF_ALLOC
| SHF_WRITE
| SHF_MIPS_GPREL
;
5379 hdr
->sh_type
= SHT_PROGBITS
;
5381 else if (strcmp (name
, ".sbss") == 0)
5383 hdr
->sh_flags
|= SHF_ALLOC
| SHF_WRITE
| SHF_MIPS_GPREL
;
5384 hdr
->sh_type
= SHT_NOBITS
;
5386 else if (strcmp (name
, ".srdata") == 0)
5388 hdr
->sh_flags
|= SHF_ALLOC
| SHF_MIPS_GPREL
;
5389 hdr
->sh_type
= SHT_PROGBITS
;
5391 else if (strcmp (name
, ".compact_rel") == 0)
5394 hdr
->sh_type
= SHT_PROGBITS
;
5396 else if (strcmp (name
, ".rtproc") == 0)
5398 if (hdr
->sh_addralign
!= 0 && hdr
->sh_entsize
== 0)
5400 unsigned int adjust
;
5402 adjust
= hdr
->sh_size
% hdr
->sh_addralign
;
5404 hdr
->sh_size
+= hdr
->sh_addralign
- adjust
;
5412 /* Handle a MIPS specific section when reading an object file. This
5413 is called when elfcode.h finds a section with an unknown type.
5414 This routine supports both the 32-bit and 64-bit ELF ABI.
5416 FIXME: We need to handle the SHF_MIPS_GPREL flag, but I'm not sure
5420 _bfd_mips_elf_section_from_shdr (bfd
*abfd
,
5421 Elf_Internal_Shdr
*hdr
,
5427 /* There ought to be a place to keep ELF backend specific flags, but
5428 at the moment there isn't one. We just keep track of the
5429 sections by their name, instead. Fortunately, the ABI gives
5430 suggested names for all the MIPS specific sections, so we will
5431 probably get away with this. */
5432 switch (hdr
->sh_type
)
5434 case SHT_MIPS_LIBLIST
:
5435 if (strcmp (name
, ".liblist") != 0)
5439 if (strcmp (name
, ".msym") != 0)
5442 case SHT_MIPS_CONFLICT
:
5443 if (strcmp (name
, ".conflict") != 0)
5446 case SHT_MIPS_GPTAB
:
5447 if (! CONST_STRNEQ (name
, ".gptab."))
5450 case SHT_MIPS_UCODE
:
5451 if (strcmp (name
, ".ucode") != 0)
5454 case SHT_MIPS_DEBUG
:
5455 if (strcmp (name
, ".mdebug") != 0)
5457 flags
= SEC_DEBUGGING
;
5459 case SHT_MIPS_REGINFO
:
5460 if (strcmp (name
, ".reginfo") != 0
5461 || hdr
->sh_size
!= sizeof (Elf32_External_RegInfo
))
5463 flags
= (SEC_LINK_ONCE
| SEC_LINK_DUPLICATES_SAME_SIZE
);
5465 case SHT_MIPS_IFACE
:
5466 if (strcmp (name
, ".MIPS.interfaces") != 0)
5469 case SHT_MIPS_CONTENT
:
5470 if (! CONST_STRNEQ (name
, ".MIPS.content"))
5473 case SHT_MIPS_OPTIONS
:
5474 if (!MIPS_ELF_OPTIONS_SECTION_NAME_P (name
))
5477 case SHT_MIPS_DWARF
:
5478 if (! CONST_STRNEQ (name
, ".debug_"))
5481 case SHT_MIPS_SYMBOL_LIB
:
5482 if (strcmp (name
, ".MIPS.symlib") != 0)
5485 case SHT_MIPS_EVENTS
:
5486 if (! CONST_STRNEQ (name
, ".MIPS.events")
5487 && ! CONST_STRNEQ (name
, ".MIPS.post_rel"))
5494 if (! _bfd_elf_make_section_from_shdr (abfd
, hdr
, name
, shindex
))
5499 if (! bfd_set_section_flags (abfd
, hdr
->bfd_section
,
5500 (bfd_get_section_flags (abfd
,
5506 /* FIXME: We should record sh_info for a .gptab section. */
5508 /* For a .reginfo section, set the gp value in the tdata information
5509 from the contents of this section. We need the gp value while
5510 processing relocs, so we just get it now. The .reginfo section
5511 is not used in the 64-bit MIPS ELF ABI. */
5512 if (hdr
->sh_type
== SHT_MIPS_REGINFO
)
5514 Elf32_External_RegInfo ext
;
5517 if (! bfd_get_section_contents (abfd
, hdr
->bfd_section
,
5518 &ext
, 0, sizeof ext
))
5520 bfd_mips_elf32_swap_reginfo_in (abfd
, &ext
, &s
);
5521 elf_gp (abfd
) = s
.ri_gp_value
;
5524 /* For a SHT_MIPS_OPTIONS section, look for a ODK_REGINFO entry, and
5525 set the gp value based on what we find. We may see both
5526 SHT_MIPS_REGINFO and SHT_MIPS_OPTIONS/ODK_REGINFO; in that case,
5527 they should agree. */
5528 if (hdr
->sh_type
== SHT_MIPS_OPTIONS
)
5530 bfd_byte
*contents
, *l
, *lend
;
5532 contents
= bfd_malloc (hdr
->sh_size
);
5533 if (contents
== NULL
)
5535 if (! bfd_get_section_contents (abfd
, hdr
->bfd_section
, contents
,
5542 lend
= contents
+ hdr
->sh_size
;
5543 while (l
+ sizeof (Elf_External_Options
) <= lend
)
5545 Elf_Internal_Options intopt
;
5547 bfd_mips_elf_swap_options_in (abfd
, (Elf_External_Options
*) l
,
5549 if (intopt
.size
< sizeof (Elf_External_Options
))
5551 (*_bfd_error_handler
)
5552 (_("%B: Warning: bad `%s' option size %u smaller than its header"),
5553 abfd
, MIPS_ELF_OPTIONS_SECTION_NAME (abfd
), intopt
.size
);
5556 if (ABI_64_P (abfd
) && intopt
.kind
== ODK_REGINFO
)
5558 Elf64_Internal_RegInfo intreg
;
5560 bfd_mips_elf64_swap_reginfo_in
5562 ((Elf64_External_RegInfo
*)
5563 (l
+ sizeof (Elf_External_Options
))),
5565 elf_gp (abfd
) = intreg
.ri_gp_value
;
5567 else if (intopt
.kind
== ODK_REGINFO
)
5569 Elf32_RegInfo intreg
;
5571 bfd_mips_elf32_swap_reginfo_in
5573 ((Elf32_External_RegInfo
*)
5574 (l
+ sizeof (Elf_External_Options
))),
5576 elf_gp (abfd
) = intreg
.ri_gp_value
;
5586 /* Set the correct type for a MIPS ELF section. We do this by the
5587 section name, which is a hack, but ought to work. This routine is
5588 used by both the 32-bit and the 64-bit ABI. */
5591 _bfd_mips_elf_fake_sections (bfd
*abfd
, Elf_Internal_Shdr
*hdr
, asection
*sec
)
5593 register const char *name
;
5594 unsigned int sh_type
;
5596 name
= bfd_get_section_name (abfd
, sec
);
5597 sh_type
= hdr
->sh_type
;
5599 if (strcmp (name
, ".liblist") == 0)
5601 hdr
->sh_type
= SHT_MIPS_LIBLIST
;
5602 hdr
->sh_info
= sec
->size
/ sizeof (Elf32_Lib
);
5603 /* The sh_link field is set in final_write_processing. */
5605 else if (strcmp (name
, ".conflict") == 0)
5606 hdr
->sh_type
= SHT_MIPS_CONFLICT
;
5607 else if (CONST_STRNEQ (name
, ".gptab."))
5609 hdr
->sh_type
= SHT_MIPS_GPTAB
;
5610 hdr
->sh_entsize
= sizeof (Elf32_External_gptab
);
5611 /* The sh_info field is set in final_write_processing. */
5613 else if (strcmp (name
, ".ucode") == 0)
5614 hdr
->sh_type
= SHT_MIPS_UCODE
;
5615 else if (strcmp (name
, ".mdebug") == 0)
5617 hdr
->sh_type
= SHT_MIPS_DEBUG
;
5618 /* In a shared object on IRIX 5.3, the .mdebug section has an
5619 entsize of 0. FIXME: Does this matter? */
5620 if (SGI_COMPAT (abfd
) && (abfd
->flags
& DYNAMIC
) != 0)
5621 hdr
->sh_entsize
= 0;
5623 hdr
->sh_entsize
= 1;
5625 else if (strcmp (name
, ".reginfo") == 0)
5627 hdr
->sh_type
= SHT_MIPS_REGINFO
;
5628 /* In a shared object on IRIX 5.3, the .reginfo section has an
5629 entsize of 0x18. FIXME: Does this matter? */
5630 if (SGI_COMPAT (abfd
))
5632 if ((abfd
->flags
& DYNAMIC
) != 0)
5633 hdr
->sh_entsize
= sizeof (Elf32_External_RegInfo
);
5635 hdr
->sh_entsize
= 1;
5638 hdr
->sh_entsize
= sizeof (Elf32_External_RegInfo
);
5640 else if (SGI_COMPAT (abfd
)
5641 && (strcmp (name
, ".hash") == 0
5642 || strcmp (name
, ".dynamic") == 0
5643 || strcmp (name
, ".dynstr") == 0))
5645 if (SGI_COMPAT (abfd
))
5646 hdr
->sh_entsize
= 0;
5648 /* This isn't how the IRIX6 linker behaves. */
5649 hdr
->sh_info
= SIZEOF_MIPS_DYNSYM_SECNAMES
;
5652 else if (strcmp (name
, ".got") == 0
5653 || strcmp (name
, ".srdata") == 0
5654 || strcmp (name
, ".sdata") == 0
5655 || strcmp (name
, ".sbss") == 0
5656 || strcmp (name
, ".lit4") == 0
5657 || strcmp (name
, ".lit8") == 0)
5658 hdr
->sh_flags
|= SHF_MIPS_GPREL
;
5659 else if (strcmp (name
, ".MIPS.interfaces") == 0)
5661 hdr
->sh_type
= SHT_MIPS_IFACE
;
5662 hdr
->sh_flags
|= SHF_MIPS_NOSTRIP
;
5664 else if (CONST_STRNEQ (name
, ".MIPS.content"))
5666 hdr
->sh_type
= SHT_MIPS_CONTENT
;
5667 hdr
->sh_flags
|= SHF_MIPS_NOSTRIP
;
5668 /* The sh_info field is set in final_write_processing. */
5670 else if (MIPS_ELF_OPTIONS_SECTION_NAME_P (name
))
5672 hdr
->sh_type
= SHT_MIPS_OPTIONS
;
5673 hdr
->sh_entsize
= 1;
5674 hdr
->sh_flags
|= SHF_MIPS_NOSTRIP
;
5676 else if (CONST_STRNEQ (name
, ".debug_"))
5677 hdr
->sh_type
= SHT_MIPS_DWARF
;
5678 else if (strcmp (name
, ".MIPS.symlib") == 0)
5680 hdr
->sh_type
= SHT_MIPS_SYMBOL_LIB
;
5681 /* The sh_link and sh_info fields are set in
5682 final_write_processing. */
5684 else if (CONST_STRNEQ (name
, ".MIPS.events")
5685 || CONST_STRNEQ (name
, ".MIPS.post_rel"))
5687 hdr
->sh_type
= SHT_MIPS_EVENTS
;
5688 hdr
->sh_flags
|= SHF_MIPS_NOSTRIP
;
5689 /* The sh_link field is set in final_write_processing. */
5691 else if (strcmp (name
, ".msym") == 0)
5693 hdr
->sh_type
= SHT_MIPS_MSYM
;
5694 hdr
->sh_flags
|= SHF_ALLOC
;
5695 hdr
->sh_entsize
= 8;
5698 /* In the unlikely event a special section is empty it has to lose its
5699 special meaning. This may happen e.g. when using `strip' with the
5700 "--only-keep-debug" option. */
5701 if (sec
->size
> 0 && !(sec
->flags
& SEC_HAS_CONTENTS
))
5702 hdr
->sh_type
= sh_type
;
5704 /* The generic elf_fake_sections will set up REL_HDR using the default
5705 kind of relocations. We used to set up a second header for the
5706 non-default kind of relocations here, but only NewABI would use
5707 these, and the IRIX ld doesn't like resulting empty RELA sections.
5708 Thus we create those header only on demand now. */
5713 /* Given a BFD section, try to locate the corresponding ELF section
5714 index. This is used by both the 32-bit and the 64-bit ABI.
5715 Actually, it's not clear to me that the 64-bit ABI supports these,
5716 but for non-PIC objects we will certainly want support for at least
5717 the .scommon section. */
5720 _bfd_mips_elf_section_from_bfd_section (bfd
*abfd ATTRIBUTE_UNUSED
,
5721 asection
*sec
, int *retval
)
5723 if (strcmp (bfd_get_section_name (abfd
, sec
), ".scommon") == 0)
5725 *retval
= SHN_MIPS_SCOMMON
;
5728 if (strcmp (bfd_get_section_name (abfd
, sec
), ".acommon") == 0)
5730 *retval
= SHN_MIPS_ACOMMON
;
5736 /* Hook called by the linker routine which adds symbols from an object
5737 file. We must handle the special MIPS section numbers here. */
5740 _bfd_mips_elf_add_symbol_hook (bfd
*abfd
, struct bfd_link_info
*info
,
5741 Elf_Internal_Sym
*sym
, const char **namep
,
5742 flagword
*flagsp ATTRIBUTE_UNUSED
,
5743 asection
**secp
, bfd_vma
*valp
)
5745 if (SGI_COMPAT (abfd
)
5746 && (abfd
->flags
& DYNAMIC
) != 0
5747 && strcmp (*namep
, "_rld_new_interface") == 0)
5749 /* Skip IRIX5 rld entry name. */
5754 /* Shared objects may have a dynamic symbol '_gp_disp' defined as
5755 a SECTION *ABS*. This causes ld to think it can resolve _gp_disp
5756 by setting a DT_NEEDED for the shared object. Since _gp_disp is
5757 a magic symbol resolved by the linker, we ignore this bogus definition
5758 of _gp_disp. New ABI objects do not suffer from this problem so this
5759 is not done for them. */
5761 && (sym
->st_shndx
== SHN_ABS
)
5762 && (strcmp (*namep
, "_gp_disp") == 0))
5768 switch (sym
->st_shndx
)
5771 /* Common symbols less than the GP size are automatically
5772 treated as SHN_MIPS_SCOMMON symbols. */
5773 if (sym
->st_size
> elf_gp_size (abfd
)
5774 || ELF_ST_TYPE (sym
->st_info
) == STT_TLS
5775 || IRIX_COMPAT (abfd
) == ict_irix6
)
5778 case SHN_MIPS_SCOMMON
:
5779 *secp
= bfd_make_section_old_way (abfd
, ".scommon");
5780 (*secp
)->flags
|= SEC_IS_COMMON
;
5781 *valp
= sym
->st_size
;
5785 /* This section is used in a shared object. */
5786 if (elf_tdata (abfd
)->elf_text_section
== NULL
)
5788 asymbol
*elf_text_symbol
;
5789 asection
*elf_text_section
;
5790 bfd_size_type amt
= sizeof (asection
);
5792 elf_text_section
= bfd_zalloc (abfd
, amt
);
5793 if (elf_text_section
== NULL
)
5796 amt
= sizeof (asymbol
);
5797 elf_text_symbol
= bfd_zalloc (abfd
, amt
);
5798 if (elf_text_symbol
== NULL
)
5801 /* Initialize the section. */
5803 elf_tdata (abfd
)->elf_text_section
= elf_text_section
;
5804 elf_tdata (abfd
)->elf_text_symbol
= elf_text_symbol
;
5806 elf_text_section
->symbol
= elf_text_symbol
;
5807 elf_text_section
->symbol_ptr_ptr
= &elf_tdata (abfd
)->elf_text_symbol
;
5809 elf_text_section
->name
= ".text";
5810 elf_text_section
->flags
= SEC_NO_FLAGS
;
5811 elf_text_section
->output_section
= NULL
;
5812 elf_text_section
->owner
= abfd
;
5813 elf_text_symbol
->name
= ".text";
5814 elf_text_symbol
->flags
= BSF_SECTION_SYM
| BSF_DYNAMIC
;
5815 elf_text_symbol
->section
= elf_text_section
;
5817 /* This code used to do *secp = bfd_und_section_ptr if
5818 info->shared. I don't know why, and that doesn't make sense,
5819 so I took it out. */
5820 *secp
= elf_tdata (abfd
)->elf_text_section
;
5823 case SHN_MIPS_ACOMMON
:
5824 /* Fall through. XXX Can we treat this as allocated data? */
5826 /* This section is used in a shared object. */
5827 if (elf_tdata (abfd
)->elf_data_section
== NULL
)
5829 asymbol
*elf_data_symbol
;
5830 asection
*elf_data_section
;
5831 bfd_size_type amt
= sizeof (asection
);
5833 elf_data_section
= bfd_zalloc (abfd
, amt
);
5834 if (elf_data_section
== NULL
)
5837 amt
= sizeof (asymbol
);
5838 elf_data_symbol
= bfd_zalloc (abfd
, amt
);
5839 if (elf_data_symbol
== NULL
)
5842 /* Initialize the section. */
5844 elf_tdata (abfd
)->elf_data_section
= elf_data_section
;
5845 elf_tdata (abfd
)->elf_data_symbol
= elf_data_symbol
;
5847 elf_data_section
->symbol
= elf_data_symbol
;
5848 elf_data_section
->symbol_ptr_ptr
= &elf_tdata (abfd
)->elf_data_symbol
;
5850 elf_data_section
->name
= ".data";
5851 elf_data_section
->flags
= SEC_NO_FLAGS
;
5852 elf_data_section
->output_section
= NULL
;
5853 elf_data_section
->owner
= abfd
;
5854 elf_data_symbol
->name
= ".data";
5855 elf_data_symbol
->flags
= BSF_SECTION_SYM
| BSF_DYNAMIC
;
5856 elf_data_symbol
->section
= elf_data_section
;
5858 /* This code used to do *secp = bfd_und_section_ptr if
5859 info->shared. I don't know why, and that doesn't make sense,
5860 so I took it out. */
5861 *secp
= elf_tdata (abfd
)->elf_data_section
;
5864 case SHN_MIPS_SUNDEFINED
:
5865 *secp
= bfd_und_section_ptr
;
5869 if (SGI_COMPAT (abfd
)
5871 && info
->hash
->creator
== abfd
->xvec
5872 && strcmp (*namep
, "__rld_obj_head") == 0)
5874 struct elf_link_hash_entry
*h
;
5875 struct bfd_link_hash_entry
*bh
;
5877 /* Mark __rld_obj_head as dynamic. */
5879 if (! (_bfd_generic_link_add_one_symbol
5880 (info
, abfd
, *namep
, BSF_GLOBAL
, *secp
, *valp
, NULL
, FALSE
,
5881 get_elf_backend_data (abfd
)->collect
, &bh
)))
5884 h
= (struct elf_link_hash_entry
*) bh
;
5887 h
->type
= STT_OBJECT
;
5889 if (! bfd_elf_link_record_dynamic_symbol (info
, h
))
5892 mips_elf_hash_table (info
)->use_rld_obj_head
= TRUE
;
5895 /* If this is a mips16 text symbol, add 1 to the value to make it
5896 odd. This will cause something like .word SYM to come up with
5897 the right value when it is loaded into the PC. */
5898 if (sym
->st_other
== STO_MIPS16
)
5904 /* This hook function is called before the linker writes out a global
5905 symbol. We mark symbols as small common if appropriate. This is
5906 also where we undo the increment of the value for a mips16 symbol. */
5909 _bfd_mips_elf_link_output_symbol_hook
5910 (struct bfd_link_info
*info ATTRIBUTE_UNUSED
,
5911 const char *name ATTRIBUTE_UNUSED
, Elf_Internal_Sym
*sym
,
5912 asection
*input_sec
, struct elf_link_hash_entry
*h ATTRIBUTE_UNUSED
)
5914 /* If we see a common symbol, which implies a relocatable link, then
5915 if a symbol was small common in an input file, mark it as small
5916 common in the output file. */
5917 if (sym
->st_shndx
== SHN_COMMON
5918 && strcmp (input_sec
->name
, ".scommon") == 0)
5919 sym
->st_shndx
= SHN_MIPS_SCOMMON
;
5921 if (sym
->st_other
== STO_MIPS16
)
5922 sym
->st_value
&= ~1;
5927 /* Functions for the dynamic linker. */
5929 /* Create dynamic sections when linking against a dynamic object. */
5932 _bfd_mips_elf_create_dynamic_sections (bfd
*abfd
, struct bfd_link_info
*info
)
5934 struct elf_link_hash_entry
*h
;
5935 struct bfd_link_hash_entry
*bh
;
5937 register asection
*s
;
5938 const char * const *namep
;
5939 struct mips_elf_link_hash_table
*htab
;
5941 htab
= mips_elf_hash_table (info
);
5942 flags
= (SEC_ALLOC
| SEC_LOAD
| SEC_HAS_CONTENTS
| SEC_IN_MEMORY
5943 | SEC_LINKER_CREATED
| SEC_READONLY
);
5945 /* The psABI requires a read-only .dynamic section, but the VxWorks
5947 if (!htab
->is_vxworks
)
5949 s
= bfd_get_section_by_name (abfd
, ".dynamic");
5952 if (! bfd_set_section_flags (abfd
, s
, flags
))
5957 /* We need to create .got section. */
5958 if (! mips_elf_create_got_section (abfd
, info
, FALSE
))
5961 if (! mips_elf_rel_dyn_section (info
, TRUE
))
5964 /* Create .stub section. */
5965 if (bfd_get_section_by_name (abfd
,
5966 MIPS_ELF_STUB_SECTION_NAME (abfd
)) == NULL
)
5968 s
= bfd_make_section_with_flags (abfd
,
5969 MIPS_ELF_STUB_SECTION_NAME (abfd
),
5972 || ! bfd_set_section_alignment (abfd
, s
,
5973 MIPS_ELF_LOG_FILE_ALIGN (abfd
)))
5977 if ((IRIX_COMPAT (abfd
) == ict_irix5
|| IRIX_COMPAT (abfd
) == ict_none
)
5979 && bfd_get_section_by_name (abfd
, ".rld_map") == NULL
)
5981 s
= bfd_make_section_with_flags (abfd
, ".rld_map",
5982 flags
&~ (flagword
) SEC_READONLY
);
5984 || ! bfd_set_section_alignment (abfd
, s
,
5985 MIPS_ELF_LOG_FILE_ALIGN (abfd
)))
5989 /* On IRIX5, we adjust add some additional symbols and change the
5990 alignments of several sections. There is no ABI documentation
5991 indicating that this is necessary on IRIX6, nor any evidence that
5992 the linker takes such action. */
5993 if (IRIX_COMPAT (abfd
) == ict_irix5
)
5995 for (namep
= mips_elf_dynsym_rtproc_names
; *namep
!= NULL
; namep
++)
5998 if (! (_bfd_generic_link_add_one_symbol
5999 (info
, abfd
, *namep
, BSF_GLOBAL
, bfd_und_section_ptr
, 0,
6000 NULL
, FALSE
, get_elf_backend_data (abfd
)->collect
, &bh
)))
6003 h
= (struct elf_link_hash_entry
*) bh
;
6006 h
->type
= STT_SECTION
;
6008 if (! bfd_elf_link_record_dynamic_symbol (info
, h
))
6012 /* We need to create a .compact_rel section. */
6013 if (SGI_COMPAT (abfd
))
6015 if (!mips_elf_create_compact_rel_section (abfd
, info
))
6019 /* Change alignments of some sections. */
6020 s
= bfd_get_section_by_name (abfd
, ".hash");
6022 bfd_set_section_alignment (abfd
, s
, MIPS_ELF_LOG_FILE_ALIGN (abfd
));
6023 s
= bfd_get_section_by_name (abfd
, ".dynsym");
6025 bfd_set_section_alignment (abfd
, s
, MIPS_ELF_LOG_FILE_ALIGN (abfd
));
6026 s
= bfd_get_section_by_name (abfd
, ".dynstr");
6028 bfd_set_section_alignment (abfd
, s
, MIPS_ELF_LOG_FILE_ALIGN (abfd
));
6029 s
= bfd_get_section_by_name (abfd
, ".reginfo");
6031 bfd_set_section_alignment (abfd
, s
, MIPS_ELF_LOG_FILE_ALIGN (abfd
));
6032 s
= bfd_get_section_by_name (abfd
, ".dynamic");
6034 bfd_set_section_alignment (abfd
, s
, MIPS_ELF_LOG_FILE_ALIGN (abfd
));
6041 name
= SGI_COMPAT (abfd
) ? "_DYNAMIC_LINK" : "_DYNAMIC_LINKING";
6043 if (!(_bfd_generic_link_add_one_symbol
6044 (info
, abfd
, name
, BSF_GLOBAL
, bfd_abs_section_ptr
, 0,
6045 NULL
, FALSE
, get_elf_backend_data (abfd
)->collect
, &bh
)))
6048 h
= (struct elf_link_hash_entry
*) bh
;
6051 h
->type
= STT_SECTION
;
6053 if (! bfd_elf_link_record_dynamic_symbol (info
, h
))
6056 if (! mips_elf_hash_table (info
)->use_rld_obj_head
)
6058 /* __rld_map is a four byte word located in the .data section
6059 and is filled in by the rtld to contain a pointer to
6060 the _r_debug structure. Its symbol value will be set in
6061 _bfd_mips_elf_finish_dynamic_symbol. */
6062 s
= bfd_get_section_by_name (abfd
, ".rld_map");
6063 BFD_ASSERT (s
!= NULL
);
6065 name
= SGI_COMPAT (abfd
) ? "__rld_map" : "__RLD_MAP";
6067 if (!(_bfd_generic_link_add_one_symbol
6068 (info
, abfd
, name
, BSF_GLOBAL
, s
, 0, NULL
, FALSE
,
6069 get_elf_backend_data (abfd
)->collect
, &bh
)))
6072 h
= (struct elf_link_hash_entry
*) bh
;
6075 h
->type
= STT_OBJECT
;
6077 if (! bfd_elf_link_record_dynamic_symbol (info
, h
))
6082 if (htab
->is_vxworks
)
6084 /* Create the .plt, .rela.plt, .dynbss and .rela.bss sections.
6085 Also create the _PROCEDURE_LINKAGE_TABLE symbol. */
6086 if (!_bfd_elf_create_dynamic_sections (abfd
, info
))
6089 /* Cache the sections created above. */
6090 htab
->sdynbss
= bfd_get_section_by_name (abfd
, ".dynbss");
6091 htab
->srelbss
= bfd_get_section_by_name (abfd
, ".rela.bss");
6092 htab
->srelplt
= bfd_get_section_by_name (abfd
, ".rela.plt");
6093 htab
->splt
= bfd_get_section_by_name (abfd
, ".plt");
6095 || (!htab
->srelbss
&& !info
->shared
)
6100 /* Do the usual VxWorks handling. */
6101 if (!elf_vxworks_create_dynamic_sections (abfd
, info
, &htab
->srelplt2
))
6104 /* Work out the PLT sizes. */
6107 htab
->plt_header_size
6108 = 4 * ARRAY_SIZE (mips_vxworks_shared_plt0_entry
);
6109 htab
->plt_entry_size
6110 = 4 * ARRAY_SIZE (mips_vxworks_shared_plt_entry
);
6114 htab
->plt_header_size
6115 = 4 * ARRAY_SIZE (mips_vxworks_exec_plt0_entry
);
6116 htab
->plt_entry_size
6117 = 4 * ARRAY_SIZE (mips_vxworks_exec_plt_entry
);
6124 /* Look through the relocs for a section during the first phase, and
6125 allocate space in the global offset table. */
6128 _bfd_mips_elf_check_relocs (bfd
*abfd
, struct bfd_link_info
*info
,
6129 asection
*sec
, const Elf_Internal_Rela
*relocs
)
6133 Elf_Internal_Shdr
*symtab_hdr
;
6134 struct elf_link_hash_entry
**sym_hashes
;
6135 struct mips_got_info
*g
;
6137 const Elf_Internal_Rela
*rel
;
6138 const Elf_Internal_Rela
*rel_end
;
6141 const struct elf_backend_data
*bed
;
6142 struct mips_elf_link_hash_table
*htab
;
6144 if (info
->relocatable
)
6147 htab
= mips_elf_hash_table (info
);
6148 dynobj
= elf_hash_table (info
)->dynobj
;
6149 symtab_hdr
= &elf_tdata (abfd
)->symtab_hdr
;
6150 sym_hashes
= elf_sym_hashes (abfd
);
6151 extsymoff
= (elf_bad_symtab (abfd
)) ? 0 : symtab_hdr
->sh_info
;
6153 /* Check for the mips16 stub sections. */
6155 name
= bfd_get_section_name (abfd
, sec
);
6156 if (FN_STUB_P (name
))
6158 unsigned long r_symndx
;
6160 /* Look at the relocation information to figure out which symbol
6163 r_symndx
= ELF_R_SYM (abfd
, relocs
->r_info
);
6165 if (r_symndx
< extsymoff
6166 || sym_hashes
[r_symndx
- extsymoff
] == NULL
)
6170 /* This stub is for a local symbol. This stub will only be
6171 needed if there is some relocation in this BFD, other
6172 than a 16 bit function call, which refers to this symbol. */
6173 for (o
= abfd
->sections
; o
!= NULL
; o
= o
->next
)
6175 Elf_Internal_Rela
*sec_relocs
;
6176 const Elf_Internal_Rela
*r
, *rend
;
6178 /* We can ignore stub sections when looking for relocs. */
6179 if ((o
->flags
& SEC_RELOC
) == 0
6180 || o
->reloc_count
== 0
6181 || mips16_stub_section_p (abfd
, o
))
6185 = _bfd_elf_link_read_relocs (abfd
, o
, NULL
, NULL
,
6187 if (sec_relocs
== NULL
)
6190 rend
= sec_relocs
+ o
->reloc_count
;
6191 for (r
= sec_relocs
; r
< rend
; r
++)
6192 if (ELF_R_SYM (abfd
, r
->r_info
) == r_symndx
6193 && ELF_R_TYPE (abfd
, r
->r_info
) != R_MIPS16_26
)
6196 if (elf_section_data (o
)->relocs
!= sec_relocs
)
6205 /* There is no non-call reloc for this stub, so we do
6206 not need it. Since this function is called before
6207 the linker maps input sections to output sections, we
6208 can easily discard it by setting the SEC_EXCLUDE
6210 sec
->flags
|= SEC_EXCLUDE
;
6214 /* Record this stub in an array of local symbol stubs for
6216 if (elf_tdata (abfd
)->local_stubs
== NULL
)
6218 unsigned long symcount
;
6222 if (elf_bad_symtab (abfd
))
6223 symcount
= NUM_SHDR_ENTRIES (symtab_hdr
);
6225 symcount
= symtab_hdr
->sh_info
;
6226 amt
= symcount
* sizeof (asection
*);
6227 n
= bfd_zalloc (abfd
, amt
);
6230 elf_tdata (abfd
)->local_stubs
= n
;
6233 sec
->flags
|= SEC_KEEP
;
6234 elf_tdata (abfd
)->local_stubs
[r_symndx
] = sec
;
6236 /* We don't need to set mips16_stubs_seen in this case.
6237 That flag is used to see whether we need to look through
6238 the global symbol table for stubs. We don't need to set
6239 it here, because we just have a local stub. */
6243 struct mips_elf_link_hash_entry
*h
;
6245 h
= ((struct mips_elf_link_hash_entry
*)
6246 sym_hashes
[r_symndx
- extsymoff
]);
6248 while (h
->root
.root
.type
== bfd_link_hash_indirect
6249 || h
->root
.root
.type
== bfd_link_hash_warning
)
6250 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
6252 /* H is the symbol this stub is for. */
6254 /* If we already have an appropriate stub for this function, we
6255 don't need another one, so we can discard this one. Since
6256 this function is called before the linker maps input sections
6257 to output sections, we can easily discard it by setting the
6258 SEC_EXCLUDE flag. */
6259 if (h
->fn_stub
!= NULL
)
6261 sec
->flags
|= SEC_EXCLUDE
;
6265 sec
->flags
|= SEC_KEEP
;
6267 mips_elf_hash_table (info
)->mips16_stubs_seen
= TRUE
;
6270 else if (CALL_STUB_P (name
) || CALL_FP_STUB_P (name
))
6272 unsigned long r_symndx
;
6273 struct mips_elf_link_hash_entry
*h
;
6276 /* Look at the relocation information to figure out which symbol
6279 r_symndx
= ELF_R_SYM (abfd
, relocs
->r_info
);
6281 if (r_symndx
< extsymoff
6282 || sym_hashes
[r_symndx
- extsymoff
] == NULL
)
6286 /* This stub is for a local symbol. This stub will only be
6287 needed if there is some relocation (R_MIPS16_26) in this BFD
6288 that refers to this symbol. */
6289 for (o
= abfd
->sections
; o
!= NULL
; o
= o
->next
)
6291 Elf_Internal_Rela
*sec_relocs
;
6292 const Elf_Internal_Rela
*r
, *rend
;
6294 /* We can ignore stub sections when looking for relocs. */
6295 if ((o
->flags
& SEC_RELOC
) == 0
6296 || o
->reloc_count
== 0
6297 || mips16_stub_section_p (abfd
, o
))
6301 = _bfd_elf_link_read_relocs (abfd
, o
, NULL
, NULL
,
6303 if (sec_relocs
== NULL
)
6306 rend
= sec_relocs
+ o
->reloc_count
;
6307 for (r
= sec_relocs
; r
< rend
; r
++)
6308 if (ELF_R_SYM (abfd
, r
->r_info
) == r_symndx
6309 && ELF_R_TYPE (abfd
, r
->r_info
) == R_MIPS16_26
)
6312 if (elf_section_data (o
)->relocs
!= sec_relocs
)
6321 /* There is no non-call reloc for this stub, so we do
6322 not need it. Since this function is called before
6323 the linker maps input sections to output sections, we
6324 can easily discard it by setting the SEC_EXCLUDE
6326 sec
->flags
|= SEC_EXCLUDE
;
6330 /* Record this stub in an array of local symbol call_stubs for
6332 if (elf_tdata (abfd
)->local_call_stubs
== NULL
)
6334 unsigned long symcount
;
6338 if (elf_bad_symtab (abfd
))
6339 symcount
= NUM_SHDR_ENTRIES (symtab_hdr
);
6341 symcount
= symtab_hdr
->sh_info
;
6342 amt
= symcount
* sizeof (asection
*);
6343 n
= bfd_zalloc (abfd
, amt
);
6346 elf_tdata (abfd
)->local_call_stubs
= n
;
6349 sec
->flags
|= SEC_KEEP
;
6350 elf_tdata (abfd
)->local_call_stubs
[r_symndx
] = sec
;
6352 /* We don't need to set mips16_stubs_seen in this case.
6353 That flag is used to see whether we need to look through
6354 the global symbol table for stubs. We don't need to set
6355 it here, because we just have a local stub. */
6359 h
= ((struct mips_elf_link_hash_entry
*)
6360 sym_hashes
[r_symndx
- extsymoff
]);
6362 /* H is the symbol this stub is for. */
6364 if (CALL_FP_STUB_P (name
))
6365 loc
= &h
->call_fp_stub
;
6367 loc
= &h
->call_stub
;
6369 /* If we already have an appropriate stub for this function, we
6370 don't need another one, so we can discard this one. Since
6371 this function is called before the linker maps input sections
6372 to output sections, we can easily discard it by setting the
6373 SEC_EXCLUDE flag. */
6376 sec
->flags
|= SEC_EXCLUDE
;
6380 sec
->flags
|= SEC_KEEP
;
6382 mips_elf_hash_table (info
)->mips16_stubs_seen
= TRUE
;
6393 sgot
= mips_elf_got_section (dynobj
, FALSE
);
6398 BFD_ASSERT (mips_elf_section_data (sgot
) != NULL
);
6399 g
= mips_elf_section_data (sgot
)->u
.got_info
;
6400 BFD_ASSERT (g
!= NULL
);
6405 bed
= get_elf_backend_data (abfd
);
6406 rel_end
= relocs
+ sec
->reloc_count
* bed
->s
->int_rels_per_ext_rel
;
6407 for (rel
= relocs
; rel
< rel_end
; ++rel
)
6409 unsigned long r_symndx
;
6410 unsigned int r_type
;
6411 struct elf_link_hash_entry
*h
;
6413 r_symndx
= ELF_R_SYM (abfd
, rel
->r_info
);
6414 r_type
= ELF_R_TYPE (abfd
, rel
->r_info
);
6416 if (r_symndx
< extsymoff
)
6418 else if (r_symndx
>= extsymoff
+ NUM_SHDR_ENTRIES (symtab_hdr
))
6420 (*_bfd_error_handler
)
6421 (_("%B: Malformed reloc detected for section %s"),
6423 bfd_set_error (bfd_error_bad_value
);
6428 h
= sym_hashes
[r_symndx
- extsymoff
];
6430 /* This may be an indirect symbol created because of a version. */
6433 while (h
->root
.type
== bfd_link_hash_indirect
)
6434 h
= (struct elf_link_hash_entry
*) h
->root
.u
.i
.link
;
6438 /* Some relocs require a global offset table. */
6439 if (dynobj
== NULL
|| sgot
== NULL
)
6445 case R_MIPS_CALL_HI16
:
6446 case R_MIPS_CALL_LO16
:
6447 case R_MIPS_GOT_HI16
:
6448 case R_MIPS_GOT_LO16
:
6449 case R_MIPS_GOT_PAGE
:
6450 case R_MIPS_GOT_OFST
:
6451 case R_MIPS_GOT_DISP
:
6452 case R_MIPS_TLS_GOTTPREL
:
6454 case R_MIPS_TLS_LDM
:
6456 elf_hash_table (info
)->dynobj
= dynobj
= abfd
;
6457 if (! mips_elf_create_got_section (dynobj
, info
, FALSE
))
6459 g
= mips_elf_got_info (dynobj
, &sgot
);
6460 if (htab
->is_vxworks
&& !info
->shared
)
6462 (*_bfd_error_handler
)
6463 (_("%B: GOT reloc at 0x%lx not expected in executables"),
6464 abfd
, (unsigned long) rel
->r_offset
);
6465 bfd_set_error (bfd_error_bad_value
);
6473 /* In VxWorks executables, references to external symbols
6474 are handled using copy relocs or PLT stubs, so there's
6475 no need to add a dynamic relocation here. */
6477 && (info
->shared
|| (h
!= NULL
&& !htab
->is_vxworks
))
6478 && (sec
->flags
& SEC_ALLOC
) != 0)
6479 elf_hash_table (info
)->dynobj
= dynobj
= abfd
;
6489 ((struct mips_elf_link_hash_entry
*) h
)->is_relocation_target
= TRUE
;
6491 /* Relocations against the special VxWorks __GOTT_BASE__ and
6492 __GOTT_INDEX__ symbols must be left to the loader. Allocate
6493 room for them in .rela.dyn. */
6494 if (is_gott_symbol (info
, h
))
6498 sreloc
= mips_elf_rel_dyn_section (info
, TRUE
);
6502 mips_elf_allocate_dynamic_relocations (dynobj
, info
, 1);
6503 if (MIPS_ELF_READONLY_SECTION (sec
))
6504 /* We tell the dynamic linker that there are
6505 relocations against the text segment. */
6506 info
->flags
|= DF_TEXTREL
;
6509 else if (r_type
== R_MIPS_CALL_LO16
6510 || r_type
== R_MIPS_GOT_LO16
6511 || r_type
== R_MIPS_GOT_DISP
6512 || (r_type
== R_MIPS_GOT16
&& htab
->is_vxworks
))
6514 /* We may need a local GOT entry for this relocation. We
6515 don't count R_MIPS_GOT_PAGE because we can estimate the
6516 maximum number of pages needed by looking at the size of
6517 the segment. Similar comments apply to R_MIPS_GOT16 and
6518 R_MIPS_CALL16, except on VxWorks, where GOT relocations
6519 always evaluate to "G". We don't count R_MIPS_GOT_HI16, or
6520 R_MIPS_CALL_HI16 because these are always followed by an
6521 R_MIPS_GOT_LO16 or R_MIPS_CALL_LO16. */
6522 if (! mips_elf_record_local_got_symbol (abfd
, r_symndx
,
6523 rel
->r_addend
, g
, 0))
6532 (*_bfd_error_handler
)
6533 (_("%B: CALL16 reloc at 0x%lx not against global symbol"),
6534 abfd
, (unsigned long) rel
->r_offset
);
6535 bfd_set_error (bfd_error_bad_value
);
6540 case R_MIPS_CALL_HI16
:
6541 case R_MIPS_CALL_LO16
:
6544 /* VxWorks call relocations point the function's .got.plt
6545 entry, which will be allocated by adjust_dynamic_symbol.
6546 Otherwise, this symbol requires a global GOT entry. */
6547 if (!htab
->is_vxworks
6548 && !mips_elf_record_global_got_symbol (h
, abfd
, info
, g
, 0))
6551 /* We need a stub, not a plt entry for the undefined
6552 function. But we record it as if it needs plt. See
6553 _bfd_elf_adjust_dynamic_symbol. */
6559 case R_MIPS_GOT_PAGE
:
6560 /* If this is a global, overridable symbol, GOT_PAGE will
6561 decay to GOT_DISP, so we'll need a GOT entry for it. */
6566 struct mips_elf_link_hash_entry
*hmips
=
6567 (struct mips_elf_link_hash_entry
*) h
;
6569 while (hmips
->root
.root
.type
== bfd_link_hash_indirect
6570 || hmips
->root
.root
.type
== bfd_link_hash_warning
)
6571 hmips
= (struct mips_elf_link_hash_entry
*)
6572 hmips
->root
.root
.u
.i
.link
;
6574 if (hmips
->root
.def_regular
6575 && ! (info
->shared
&& ! info
->symbolic
6576 && ! hmips
->root
.forced_local
))
6582 case R_MIPS_GOT_HI16
:
6583 case R_MIPS_GOT_LO16
:
6584 case R_MIPS_GOT_DISP
:
6585 if (h
&& ! mips_elf_record_global_got_symbol (h
, abfd
, info
, g
, 0))
6589 case R_MIPS_TLS_GOTTPREL
:
6591 info
->flags
|= DF_STATIC_TLS
;
6594 case R_MIPS_TLS_LDM
:
6595 if (r_type
== R_MIPS_TLS_LDM
)
6603 /* This symbol requires a global offset table entry, or two
6604 for TLS GD relocations. */
6606 unsigned char flag
= (r_type
== R_MIPS_TLS_GD
6608 : r_type
== R_MIPS_TLS_LDM
6613 struct mips_elf_link_hash_entry
*hmips
=
6614 (struct mips_elf_link_hash_entry
*) h
;
6615 hmips
->tls_type
|= flag
;
6617 if (h
&& ! mips_elf_record_global_got_symbol (h
, abfd
, info
, g
, flag
))
6622 BFD_ASSERT (flag
== GOT_TLS_LDM
|| r_symndx
!= 0);
6624 if (! mips_elf_record_local_got_symbol (abfd
, r_symndx
,
6625 rel
->r_addend
, g
, flag
))
6634 /* In VxWorks executables, references to external symbols
6635 are handled using copy relocs or PLT stubs, so there's
6636 no need to add a .rela.dyn entry for this relocation. */
6637 if ((info
->shared
|| (h
!= NULL
&& !htab
->is_vxworks
))
6638 && (sec
->flags
& SEC_ALLOC
) != 0)
6642 sreloc
= mips_elf_rel_dyn_section (info
, TRUE
);
6648 /* When creating a shared object, we must copy these
6649 reloc types into the output file as R_MIPS_REL32
6650 relocs. Make room for this reloc in .rel(a).dyn. */
6651 mips_elf_allocate_dynamic_relocations (dynobj
, info
, 1);
6652 if (MIPS_ELF_READONLY_SECTION (sec
))
6653 /* We tell the dynamic linker that there are
6654 relocations against the text segment. */
6655 info
->flags
|= DF_TEXTREL
;
6659 struct mips_elf_link_hash_entry
*hmips
;
6661 /* We only need to copy this reloc if the symbol is
6662 defined in a dynamic object. */
6663 hmips
= (struct mips_elf_link_hash_entry
*) h
;
6664 ++hmips
->possibly_dynamic_relocs
;
6665 if (MIPS_ELF_READONLY_SECTION (sec
))
6666 /* We need it to tell the dynamic linker if there
6667 are relocations against the text segment. */
6668 hmips
->readonly_reloc
= TRUE
;
6671 /* Even though we don't directly need a GOT entry for
6672 this symbol, a symbol must have a dynamic symbol
6673 table index greater that DT_MIPS_GOTSYM if there are
6674 dynamic relocations against it. This does not apply
6675 to VxWorks, which does not have the usual coupling
6676 between global GOT entries and .dynsym entries. */
6677 if (h
!= NULL
&& !htab
->is_vxworks
)
6680 elf_hash_table (info
)->dynobj
= dynobj
= abfd
;
6681 if (! mips_elf_create_got_section (dynobj
, info
, TRUE
))
6683 g
= mips_elf_got_info (dynobj
, &sgot
);
6684 if (! mips_elf_record_global_got_symbol (h
, abfd
, info
, g
, 0))
6689 if (SGI_COMPAT (abfd
))
6690 mips_elf_hash_table (info
)->compact_rel_size
+=
6691 sizeof (Elf32_External_crinfo
);
6696 ((struct mips_elf_link_hash_entry
*) h
)->is_branch_target
= TRUE
;
6701 ((struct mips_elf_link_hash_entry
*) h
)->is_branch_target
= TRUE
;
6704 case R_MIPS_GPREL16
:
6705 case R_MIPS_LITERAL
:
6706 case R_MIPS_GPREL32
:
6707 if (SGI_COMPAT (abfd
))
6708 mips_elf_hash_table (info
)->compact_rel_size
+=
6709 sizeof (Elf32_External_crinfo
);
6712 /* This relocation describes the C++ object vtable hierarchy.
6713 Reconstruct it for later use during GC. */
6714 case R_MIPS_GNU_VTINHERIT
:
6715 if (!bfd_elf_gc_record_vtinherit (abfd
, sec
, h
, rel
->r_offset
))
6719 /* This relocation describes which C++ vtable entries are actually
6720 used. Record for later use during GC. */
6721 case R_MIPS_GNU_VTENTRY
:
6722 if (!bfd_elf_gc_record_vtentry (abfd
, sec
, h
, rel
->r_offset
))
6730 /* We must not create a stub for a symbol that has relocations
6731 related to taking the function's address. This doesn't apply to
6732 VxWorks, where CALL relocs refer to a .got.plt entry instead of
6733 a normal .got entry. */
6734 if (!htab
->is_vxworks
&& h
!= NULL
)
6738 ((struct mips_elf_link_hash_entry
*) h
)->no_fn_stub
= TRUE
;
6741 case R_MIPS_CALL_HI16
:
6742 case R_MIPS_CALL_LO16
:
6747 /* If this reloc is not a 16 bit call, and it has a global
6748 symbol, then we will need the fn_stub if there is one.
6749 References from a stub section do not count. */
6751 && r_type
!= R_MIPS16_26
6752 && !mips16_stub_section_p (abfd
, sec
))
6754 struct mips_elf_link_hash_entry
*mh
;
6756 mh
= (struct mips_elf_link_hash_entry
*) h
;
6757 mh
->need_fn_stub
= TRUE
;
6765 _bfd_mips_relax_section (bfd
*abfd
, asection
*sec
,
6766 struct bfd_link_info
*link_info
,
6769 Elf_Internal_Rela
*internal_relocs
;
6770 Elf_Internal_Rela
*irel
, *irelend
;
6771 Elf_Internal_Shdr
*symtab_hdr
;
6772 bfd_byte
*contents
= NULL
;
6774 bfd_boolean changed_contents
= FALSE
;
6775 bfd_vma sec_start
= sec
->output_section
->vma
+ sec
->output_offset
;
6776 Elf_Internal_Sym
*isymbuf
= NULL
;
6778 /* We are not currently changing any sizes, so only one pass. */
6781 if (link_info
->relocatable
)
6784 internal_relocs
= _bfd_elf_link_read_relocs (abfd
, sec
, NULL
, NULL
,
6785 link_info
->keep_memory
);
6786 if (internal_relocs
== NULL
)
6789 irelend
= internal_relocs
+ sec
->reloc_count
6790 * get_elf_backend_data (abfd
)->s
->int_rels_per_ext_rel
;
6791 symtab_hdr
= &elf_tdata (abfd
)->symtab_hdr
;
6792 extsymoff
= (elf_bad_symtab (abfd
)) ? 0 : symtab_hdr
->sh_info
;
6794 for (irel
= internal_relocs
; irel
< irelend
; irel
++)
6797 bfd_signed_vma sym_offset
;
6798 unsigned int r_type
;
6799 unsigned long r_symndx
;
6801 unsigned long instruction
;
6803 /* Turn jalr into bgezal, and jr into beq, if they're marked
6804 with a JALR relocation, that indicate where they jump to.
6805 This saves some pipeline bubbles. */
6806 r_type
= ELF_R_TYPE (abfd
, irel
->r_info
);
6807 if (r_type
!= R_MIPS_JALR
)
6810 r_symndx
= ELF_R_SYM (abfd
, irel
->r_info
);
6811 /* Compute the address of the jump target. */
6812 if (r_symndx
>= extsymoff
)
6814 struct mips_elf_link_hash_entry
*h
6815 = ((struct mips_elf_link_hash_entry
*)
6816 elf_sym_hashes (abfd
) [r_symndx
- extsymoff
]);
6818 while (h
->root
.root
.type
== bfd_link_hash_indirect
6819 || h
->root
.root
.type
== bfd_link_hash_warning
)
6820 h
= (struct mips_elf_link_hash_entry
*) h
->root
.root
.u
.i
.link
;
6822 /* If a symbol is undefined, or if it may be overridden,
6824 if (! ((h
->root
.root
.type
== bfd_link_hash_defined
6825 || h
->root
.root
.type
== bfd_link_hash_defweak
)
6826 && h
->root
.root
.u
.def
.section
)
6827 || (link_info
->shared
&& ! link_info
->symbolic
6828 && !h
->root
.forced_local
))
6831 sym_sec
= h
->root
.root
.u
.def
.section
;
6832 if (sym_sec
->output_section
)
6833 symval
= (h
->root
.root
.u
.def
.value
6834 + sym_sec
->output_section
->vma
6835 + sym_sec
->output_offset
);
6837 symval
= h
->root
.root
.u
.def
.value
;
6841 Elf_Internal_Sym
*isym
;
6843 /* Read this BFD's symbols if we haven't done so already. */
6844 if (isymbuf
== NULL
&& symtab_hdr
->sh_info
!= 0)
6846 isymbuf
= (Elf_Internal_Sym
*) symtab_hdr
->contents
;
6847 if (isymbuf
== NULL
)
6848 isymbuf
= bfd_elf_get_elf_syms (abfd
, symtab_hdr
,
6849 symtab_hdr
->sh_info
, 0,
6851 if (isymbuf
== NULL
)
6855 isym
= isymbuf
+ r_symndx
;
6856 if (isym
->st_shndx
== SHN_UNDEF
)
6858 else if (isym
->st_shndx
== SHN_ABS
)
6859 sym_sec
= bfd_abs_section_ptr
;
6860 else if (isym
->st_shndx
== SHN_COMMON
)
6861 sym_sec
= bfd_com_section_ptr
;
6864 = bfd_section_from_elf_index (abfd
, isym
->st_shndx
);
6865 symval
= isym
->st_value
6866 + sym_sec
->output_section
->vma
6867 + sym_sec
->output_offset
;
6870 /* Compute branch offset, from delay slot of the jump to the
6872 sym_offset
= (symval
+ irel
->r_addend
)
6873 - (sec_start
+ irel
->r_offset
+ 4);
6875 /* Branch offset must be properly aligned. */
6876 if ((sym_offset
& 3) != 0)
6881 /* Check that it's in range. */
6882 if (sym_offset
< -0x8000 || sym_offset
>= 0x8000)
6885 /* Get the section contents if we haven't done so already. */
6886 if (contents
== NULL
)
6888 /* Get cached copy if it exists. */
6889 if (elf_section_data (sec
)->this_hdr
.contents
!= NULL
)
6890 contents
= elf_section_data (sec
)->this_hdr
.contents
;
6893 if (!bfd_malloc_and_get_section (abfd
, sec
, &contents
))
6898 instruction
= bfd_get_32 (abfd
, contents
+ irel
->r_offset
);
6900 /* If it was jalr <reg>, turn it into bgezal $zero, <target>. */
6901 if ((instruction
& 0xfc1fffff) == 0x0000f809)
6902 instruction
= 0x04110000;
6903 /* If it was jr <reg>, turn it into b <target>. */
6904 else if ((instruction
& 0xfc1fffff) == 0x00000008)
6905 instruction
= 0x10000000;
6909 instruction
|= (sym_offset
& 0xffff);
6910 bfd_put_32 (abfd
, instruction
, contents
+ irel
->r_offset
);
6911 changed_contents
= TRUE
;
6914 if (contents
!= NULL
6915 && elf_section_data (sec
)->this_hdr
.contents
!= contents
)
6917 if (!changed_contents
&& !link_info
->keep_memory
)
6921 /* Cache the section contents for elf_link_input_bfd. */
6922 elf_section_data (sec
)->this_hdr
.contents
= contents
;
6928 if (contents
!= NULL
6929 && elf_section_data (sec
)->this_hdr
.contents
!= contents
)
6934 /* Adjust a symbol defined by a dynamic object and referenced by a
6935 regular object. The current definition is in some section of the
6936 dynamic object, but we're not including those sections. We have to
6937 change the definition to something the rest of the link can
6941 _bfd_mips_elf_adjust_dynamic_symbol (struct bfd_link_info
*info
,
6942 struct elf_link_hash_entry
*h
)
6945 struct mips_elf_link_hash_entry
*hmips
;
6947 struct mips_elf_link_hash_table
*htab
;
6949 htab
= mips_elf_hash_table (info
);
6950 dynobj
= elf_hash_table (info
)->dynobj
;
6952 /* Make sure we know what is going on here. */
6953 BFD_ASSERT (dynobj
!= NULL
6955 || h
->u
.weakdef
!= NULL
6958 && !h
->def_regular
)));
6960 /* If this symbol is defined in a dynamic object, we need to copy
6961 any R_MIPS_32 or R_MIPS_REL32 relocs against it into the output
6963 hmips
= (struct mips_elf_link_hash_entry
*) h
;
6964 if (! info
->relocatable
6965 && hmips
->possibly_dynamic_relocs
!= 0
6966 && (h
->root
.type
== bfd_link_hash_defweak
6967 || !h
->def_regular
))
6969 mips_elf_allocate_dynamic_relocations
6970 (dynobj
, info
, hmips
->possibly_dynamic_relocs
);
6971 if (hmips
->readonly_reloc
)
6972 /* We tell the dynamic linker that there are relocations
6973 against the text segment. */
6974 info
->flags
|= DF_TEXTREL
;
6977 /* For a function, create a stub, if allowed. */
6978 if (! hmips
->no_fn_stub
6981 if (! elf_hash_table (info
)->dynamic_sections_created
)
6984 /* If this symbol is not defined in a regular file, then set
6985 the symbol to the stub location. This is required to make
6986 function pointers compare as equal between the normal
6987 executable and the shared library. */
6988 if (!h
->def_regular
)
6990 /* We need .stub section. */
6991 s
= bfd_get_section_by_name (dynobj
,
6992 MIPS_ELF_STUB_SECTION_NAME (dynobj
));
6993 BFD_ASSERT (s
!= NULL
);
6995 h
->root
.u
.def
.section
= s
;
6996 h
->root
.u
.def
.value
= s
->size
;
6998 /* XXX Write this stub address somewhere. */
6999 h
->plt
.offset
= s
->size
;
7001 /* Make room for this stub code. */
7002 s
->size
+= htab
->function_stub_size
;
7004 /* The last half word of the stub will be filled with the index
7005 of this symbol in .dynsym section. */
7009 else if ((h
->type
== STT_FUNC
)
7012 /* This will set the entry for this symbol in the GOT to 0, and
7013 the dynamic linker will take care of this. */
7014 h
->root
.u
.def
.value
= 0;
7018 /* If this is a weak symbol, and there is a real definition, the
7019 processor independent code will have arranged for us to see the
7020 real definition first, and we can just use the same value. */
7021 if (h
->u
.weakdef
!= NULL
)
7023 BFD_ASSERT (h
->u
.weakdef
->root
.type
== bfd_link_hash_defined
7024 || h
->u
.weakdef
->root
.type
== bfd_link_hash_defweak
);
7025 h
->root
.u
.def
.section
= h
->u
.weakdef
->root
.u
.def
.section
;
7026 h
->root
.u
.def
.value
= h
->u
.weakdef
->root
.u
.def
.value
;
7030 /* This is a reference to a symbol defined by a dynamic object which
7031 is not a function. */
7036 /* Likewise, for VxWorks. */
7039 _bfd_mips_vxworks_adjust_dynamic_symbol (struct bfd_link_info
*info
,
7040 struct elf_link_hash_entry
*h
)
7043 struct mips_elf_link_hash_entry
*hmips
;
7044 struct mips_elf_link_hash_table
*htab
;
7045 unsigned int power_of_two
;
7047 htab
= mips_elf_hash_table (info
);
7048 dynobj
= elf_hash_table (info
)->dynobj
;
7049 hmips
= (struct mips_elf_link_hash_entry
*) h
;
7051 /* Make sure we know what is going on here. */
7052 BFD_ASSERT (dynobj
!= NULL
7055 || h
->u
.weakdef
!= NULL
7058 && !h
->def_regular
)));
7060 /* If the symbol is defined by a dynamic object, we need a PLT stub if
7061 either (a) we want to branch to the symbol or (b) we're linking an
7062 executable that needs a canonical function address. In the latter
7063 case, the canonical address will be the address of the executable's
7065 if ((hmips
->is_branch_target
7067 && h
->type
== STT_FUNC
7068 && hmips
->is_relocation_target
))
7072 && !h
->forced_local
)
7075 /* Locally-binding symbols do not need a PLT stub; we can refer to
7076 the functions directly. */
7077 else if (h
->needs_plt
7078 && (SYMBOL_CALLS_LOCAL (info
, h
)
7079 || (ELF_ST_VISIBILITY (h
->other
) != STV_DEFAULT
7080 && h
->root
.type
== bfd_link_hash_undefweak
)))
7088 /* If this is the first symbol to need a PLT entry, allocate room
7089 for the header, and for the header's .rela.plt.unloaded entries. */
7090 if (htab
->splt
->size
== 0)
7092 htab
->splt
->size
+= htab
->plt_header_size
;
7094 htab
->srelplt2
->size
+= 2 * sizeof (Elf32_External_Rela
);
7097 /* Assign the next .plt entry to this symbol. */
7098 h
->plt
.offset
= htab
->splt
->size
;
7099 htab
->splt
->size
+= htab
->plt_entry_size
;
7101 /* If the output file has no definition of the symbol, set the
7102 symbol's value to the address of the stub. For executables,
7103 point at the PLT load stub rather than the lazy resolution stub;
7104 this stub will become the canonical function address. */
7105 if (!h
->def_regular
)
7107 h
->root
.u
.def
.section
= htab
->splt
;
7108 h
->root
.u
.def
.value
= h
->plt
.offset
;
7110 h
->root
.u
.def
.value
+= 8;
7113 /* Make room for the .got.plt entry and the R_JUMP_SLOT relocation. */
7114 htab
->sgotplt
->size
+= 4;
7115 htab
->srelplt
->size
+= sizeof (Elf32_External_Rela
);
7117 /* Make room for the .rela.plt.unloaded relocations. */
7119 htab
->srelplt2
->size
+= 3 * sizeof (Elf32_External_Rela
);
7124 /* If a function symbol is defined by a dynamic object, and we do not
7125 need a PLT stub for it, the symbol's value should be zero. */
7126 if (h
->type
== STT_FUNC
7131 h
->root
.u
.def
.value
= 0;
7135 /* If this is a weak symbol, and there is a real definition, the
7136 processor independent code will have arranged for us to see the
7137 real definition first, and we can just use the same value. */
7138 if (h
->u
.weakdef
!= NULL
)
7140 BFD_ASSERT (h
->u
.weakdef
->root
.type
== bfd_link_hash_defined
7141 || h
->u
.weakdef
->root
.type
== bfd_link_hash_defweak
);
7142 h
->root
.u
.def
.section
= h
->u
.weakdef
->root
.u
.def
.section
;
7143 h
->root
.u
.def
.value
= h
->u
.weakdef
->root
.u
.def
.value
;
7147 /* This is a reference to a symbol defined by a dynamic object which
7148 is not a function. */
7152 /* We must allocate the symbol in our .dynbss section, which will
7153 become part of the .bss section of the executable. There will be
7154 an entry for this symbol in the .dynsym section. The dynamic
7155 object will contain position independent code, so all references
7156 from the dynamic object to this symbol will go through the global
7157 offset table. The dynamic linker will use the .dynsym entry to
7158 determine the address it must put in the global offset table, so
7159 both the dynamic object and the regular object will refer to the
7160 same memory location for the variable. */
7162 if ((h
->root
.u
.def
.section
->flags
& SEC_ALLOC
) != 0)
7164 htab
->srelbss
->size
+= sizeof (Elf32_External_Rela
);
7168 /* We need to figure out the alignment required for this symbol. */
7169 power_of_two
= bfd_log2 (h
->size
);
7170 if (power_of_two
> 4)
7173 /* Apply the required alignment. */
7174 htab
->sdynbss
->size
= BFD_ALIGN (htab
->sdynbss
->size
,
7175 (bfd_size_type
) 1 << power_of_two
);
7176 if (power_of_two
> bfd_get_section_alignment (dynobj
, htab
->sdynbss
)
7177 && !bfd_set_section_alignment (dynobj
, htab
->sdynbss
, power_of_two
))
7180 /* Define the symbol as being at this point in the section. */
7181 h
->root
.u
.def
.section
= htab
->sdynbss
;
7182 h
->root
.u
.def
.value
= htab
->sdynbss
->size
;
7184 /* Increment the section size to make room for the symbol. */
7185 htab
->sdynbss
->size
+= h
->size
;
7190 /* Return the number of dynamic section symbols required by OUTPUT_BFD.
7191 The number might be exact or a worst-case estimate, depending on how
7192 much information is available to elf_backend_omit_section_dynsym at
7193 the current linking stage. */
7195 static bfd_size_type
7196 count_section_dynsyms (bfd
*output_bfd
, struct bfd_link_info
*info
)
7198 bfd_size_type count
;
7201 if (info
->shared
|| elf_hash_table (info
)->is_relocatable_executable
)
7204 const struct elf_backend_data
*bed
;
7206 bed
= get_elf_backend_data (output_bfd
);
7207 for (p
= output_bfd
->sections
; p
; p
= p
->next
)
7208 if ((p
->flags
& SEC_EXCLUDE
) == 0
7209 && (p
->flags
& SEC_ALLOC
) != 0
7210 && !(*bed
->elf_backend_omit_section_dynsym
) (output_bfd
, info
, p
))
7216 /* This function is called after all the input files have been read,
7217 and the input sections have been assigned to output sections. We
7218 check for any mips16 stub sections that we can discard. */
7221 _bfd_mips_elf_always_size_sections (bfd
*output_bfd
,
7222 struct bfd_link_info
*info
)
7228 struct mips_got_info
*g
;
7230 bfd_size_type loadable_size
= 0;
7231 bfd_size_type local_gotno
;
7232 bfd_size_type dynsymcount
;
7234 struct mips_elf_count_tls_arg count_tls_arg
;
7235 struct mips_elf_link_hash_table
*htab
;
7237 htab
= mips_elf_hash_table (info
);
7239 /* The .reginfo section has a fixed size. */
7240 ri
= bfd_get_section_by_name (output_bfd
, ".reginfo");
7242 bfd_set_section_size (output_bfd
, ri
, sizeof (Elf32_External_RegInfo
));
7244 if (! (info
->relocatable
7245 || ! mips_elf_hash_table (info
)->mips16_stubs_seen
))
7246 mips_elf_link_hash_traverse (mips_elf_hash_table (info
),
7247 mips_elf_check_mips16_stubs
, NULL
);
7249 dynobj
= elf_hash_table (info
)->dynobj
;
7251 /* Relocatable links don't have it. */
7254 g
= mips_elf_got_info (dynobj
, &s
);
7258 /* Calculate the total loadable size of the output. That
7259 will give us the maximum number of GOT_PAGE entries
7261 for (sub
= info
->input_bfds
; sub
; sub
= sub
->link_next
)
7263 asection
*subsection
;
7265 for (subsection
= sub
->sections
;
7267 subsection
= subsection
->next
)
7269 if ((subsection
->flags
& SEC_ALLOC
) == 0)
7271 loadable_size
+= ((subsection
->size
+ 0xf)
7272 &~ (bfd_size_type
) 0xf);
7276 /* There has to be a global GOT entry for every symbol with
7277 a dynamic symbol table index of DT_MIPS_GOTSYM or
7278 higher. Therefore, it make sense to put those symbols
7279 that need GOT entries at the end of the symbol table. We
7281 if (! mips_elf_sort_hash_table (info
, 1))
7284 if (g
->global_gotsym
!= NULL
)
7285 i
= elf_hash_table (info
)->dynsymcount
- g
->global_gotsym
->dynindx
;
7287 /* If there are no global symbols, or none requiring
7288 relocations, then GLOBAL_GOTSYM will be NULL. */
7291 /* Get a worst-case estimate of the number of dynamic symbols needed.
7292 At this point, dynsymcount does not account for section symbols
7293 and count_section_dynsyms may overestimate the number that will
7295 dynsymcount
= (elf_hash_table (info
)->dynsymcount
7296 + count_section_dynsyms (output_bfd
, info
));
7298 /* Determine the size of one stub entry. */
7299 htab
->function_stub_size
= (dynsymcount
> 0x10000
7300 ? MIPS_FUNCTION_STUB_BIG_SIZE
7301 : MIPS_FUNCTION_STUB_NORMAL_SIZE
);
7303 /* In the worst case, we'll get one stub per dynamic symbol, plus
7304 one to account for the dummy entry at the end required by IRIX
7306 loadable_size
+= htab
->function_stub_size
* (i
+ 1);
7308 if (htab
->is_vxworks
)
7309 /* There's no need to allocate page entries for VxWorks; R_MIPS_GOT16
7310 relocations against local symbols evaluate to "G", and the EABI does
7311 not include R_MIPS_GOT_PAGE. */
7314 /* Assume there are two loadable segments consisting of contiguous
7315 sections. Is 5 enough? */
7316 local_gotno
= (loadable_size
>> 16) + 5;
7318 g
->local_gotno
+= local_gotno
;
7319 s
->size
+= g
->local_gotno
* MIPS_ELF_GOT_SIZE (output_bfd
);
7321 g
->global_gotno
= i
;
7322 s
->size
+= i
* MIPS_ELF_GOT_SIZE (output_bfd
);
7324 /* We need to calculate tls_gotno for global symbols at this point
7325 instead of building it up earlier, to avoid doublecounting
7326 entries for one global symbol from multiple input files. */
7327 count_tls_arg
.info
= info
;
7328 count_tls_arg
.needed
= 0;
7329 elf_link_hash_traverse (elf_hash_table (info
),
7330 mips_elf_count_global_tls_entries
,
7332 g
->tls_gotno
+= count_tls_arg
.needed
;
7333 s
->size
+= g
->tls_gotno
* MIPS_ELF_GOT_SIZE (output_bfd
);
7335 mips_elf_resolve_final_got_entries (g
);
7337 /* VxWorks does not support multiple GOTs. It initializes $gp to
7338 __GOTT_BASE__[__GOTT_INDEX__], the value of which is set by the
7340 if (!htab
->is_vxworks
&& s
->size
> MIPS_ELF_GOT_MAX_SIZE (info
))
7342 if (! mips_elf_multi_got (output_bfd
, info
, g
, s
, local_gotno
))
7347 /* Set up TLS entries for the first GOT. */
7348 g
->tls_assigned_gotno
= g
->global_gotno
+ g
->local_gotno
;
7349 htab_traverse (g
->got_entries
, mips_elf_initialize_tls_index
, g
);
7355 /* Set the sizes of the dynamic sections. */
7358 _bfd_mips_elf_size_dynamic_sections (bfd
*output_bfd
,
7359 struct bfd_link_info
*info
)
7362 asection
*s
, *sreldyn
;
7363 bfd_boolean reltext
;
7364 struct mips_elf_link_hash_table
*htab
;
7366 htab
= mips_elf_hash_table (info
);
7367 dynobj
= elf_hash_table (info
)->dynobj
;
7368 BFD_ASSERT (dynobj
!= NULL
);
7370 if (elf_hash_table (info
)->dynamic_sections_created
)
7372 /* Set the contents of the .interp section to the interpreter. */
7373 if (info
->executable
)
7375 s
= bfd_get_section_by_name (dynobj
, ".interp");
7376 BFD_ASSERT (s
!= NULL
);
7378 = strlen (ELF_DYNAMIC_INTERPRETER (output_bfd
)) + 1;
7380 = (bfd_byte
*) ELF_DYNAMIC_INTERPRETER (output_bfd
);
7384 /* The check_relocs and adjust_dynamic_symbol entry points have
7385 determined the sizes of the various dynamic sections. Allocate
7389 for (s
= dynobj
->sections
; s
!= NULL
; s
= s
->next
)
7393 /* It's OK to base decisions on the section name, because none
7394 of the dynobj section names depend upon the input files. */
7395 name
= bfd_get_section_name (dynobj
, s
);
7397 if ((s
->flags
& SEC_LINKER_CREATED
) == 0)
7400 if (CONST_STRNEQ (name
, ".rel"))
7404 const char *outname
;
7407 /* If this relocation section applies to a read only
7408 section, then we probably need a DT_TEXTREL entry.
7409 If the relocation section is .rel(a).dyn, we always
7410 assert a DT_TEXTREL entry rather than testing whether
7411 there exists a relocation to a read only section or
7413 outname
= bfd_get_section_name (output_bfd
,
7415 target
= bfd_get_section_by_name (output_bfd
, outname
+ 4);
7417 && (target
->flags
& SEC_READONLY
) != 0
7418 && (target
->flags
& SEC_ALLOC
) != 0)
7419 || strcmp (outname
, MIPS_ELF_REL_DYN_NAME (info
)) == 0)
7422 /* We use the reloc_count field as a counter if we need
7423 to copy relocs into the output file. */
7424 if (strcmp (name
, MIPS_ELF_REL_DYN_NAME (info
)) != 0)
7427 /* If combreloc is enabled, elf_link_sort_relocs() will
7428 sort relocations, but in a different way than we do,
7429 and before we're done creating relocations. Also, it
7430 will move them around between input sections'
7431 relocation's contents, so our sorting would be
7432 broken, so don't let it run. */
7433 info
->combreloc
= 0;
7436 else if (htab
->is_vxworks
&& strcmp (name
, ".got") == 0)
7438 /* Executables do not need a GOT. */
7441 /* Allocate relocations for all but the reserved entries. */
7442 struct mips_got_info
*g
;
7445 g
= mips_elf_got_info (dynobj
, NULL
);
7446 count
= (g
->global_gotno
7448 - MIPS_RESERVED_GOTNO (info
));
7449 mips_elf_allocate_dynamic_relocations (dynobj
, info
, count
);
7452 else if (!htab
->is_vxworks
&& CONST_STRNEQ (name
, ".got"))
7454 /* _bfd_mips_elf_always_size_sections() has already done
7455 most of the work, but some symbols may have been mapped
7456 to versions that we must now resolve in the got_entries
7458 struct mips_got_info
*gg
= mips_elf_got_info (dynobj
, NULL
);
7459 struct mips_got_info
*g
= gg
;
7460 struct mips_elf_set_global_got_offset_arg set_got_offset_arg
;
7461 unsigned int needed_relocs
= 0;
7465 set_got_offset_arg
.value
= MIPS_ELF_GOT_SIZE (output_bfd
);
7466 set_got_offset_arg
.info
= info
;
7468 /* NOTE 2005-02-03: How can this call, or the next, ever
7469 find any indirect entries to resolve? They were all
7470 resolved in mips_elf_multi_got. */
7471 mips_elf_resolve_final_got_entries (gg
);
7472 for (g
= gg
->next
; g
&& g
->next
!= gg
; g
= g
->next
)
7474 unsigned int save_assign
;
7476 mips_elf_resolve_final_got_entries (g
);
7478 /* Assign offsets to global GOT entries. */
7479 save_assign
= g
->assigned_gotno
;
7480 g
->assigned_gotno
= g
->local_gotno
;
7481 set_got_offset_arg
.g
= g
;
7482 set_got_offset_arg
.needed_relocs
= 0;
7483 htab_traverse (g
->got_entries
,
7484 mips_elf_set_global_got_offset
,
7485 &set_got_offset_arg
);
7486 needed_relocs
+= set_got_offset_arg
.needed_relocs
;
7487 BFD_ASSERT (g
->assigned_gotno
- g
->local_gotno
7488 <= g
->global_gotno
);
7490 g
->assigned_gotno
= save_assign
;
7493 needed_relocs
+= g
->local_gotno
- g
->assigned_gotno
;
7494 BFD_ASSERT (g
->assigned_gotno
== g
->next
->local_gotno
7495 + g
->next
->global_gotno
7496 + g
->next
->tls_gotno
7497 + MIPS_RESERVED_GOTNO (info
));
7503 struct mips_elf_count_tls_arg arg
;
7507 htab_traverse (gg
->got_entries
, mips_elf_count_local_tls_relocs
,
7509 elf_link_hash_traverse (elf_hash_table (info
),
7510 mips_elf_count_global_tls_relocs
,
7513 needed_relocs
+= arg
.needed
;
7517 mips_elf_allocate_dynamic_relocations (dynobj
, info
,
7520 else if (strcmp (name
, MIPS_ELF_STUB_SECTION_NAME (output_bfd
)) == 0)
7522 /* IRIX rld assumes that the function stub isn't at the end
7523 of .text section. So put a dummy. XXX */
7524 s
->size
+= htab
->function_stub_size
;
7526 else if (! info
->shared
7527 && ! mips_elf_hash_table (info
)->use_rld_obj_head
7528 && CONST_STRNEQ (name
, ".rld_map"))
7530 /* We add a room for __rld_map. It will be filled in by the
7531 rtld to contain a pointer to the _r_debug structure. */
7534 else if (SGI_COMPAT (output_bfd
)
7535 && CONST_STRNEQ (name
, ".compact_rel"))
7536 s
->size
+= mips_elf_hash_table (info
)->compact_rel_size
;
7537 else if (! CONST_STRNEQ (name
, ".init")
7538 && s
!= htab
->sgotplt
7541 /* It's not one of our sections, so don't allocate space. */
7547 s
->flags
|= SEC_EXCLUDE
;
7551 if ((s
->flags
& SEC_HAS_CONTENTS
) == 0)
7554 /* Allocate memory for this section last, since we may increase its
7556 if (strcmp (name
, MIPS_ELF_REL_DYN_NAME (info
)) == 0)
7562 /* Allocate memory for the section contents. */
7563 s
->contents
= bfd_zalloc (dynobj
, s
->size
);
7564 if (s
->contents
== NULL
)
7566 bfd_set_error (bfd_error_no_memory
);
7571 /* Allocate memory for the .rel(a).dyn section. */
7572 if (sreldyn
!= NULL
)
7574 sreldyn
->contents
= bfd_zalloc (dynobj
, sreldyn
->size
);
7575 if (sreldyn
->contents
== NULL
)
7577 bfd_set_error (bfd_error_no_memory
);
7582 if (elf_hash_table (info
)->dynamic_sections_created
)
7584 /* Add some entries to the .dynamic section. We fill in the
7585 values later, in _bfd_mips_elf_finish_dynamic_sections, but we
7586 must add the entries now so that we get the correct size for
7587 the .dynamic section. The DT_DEBUG entry is filled in by the
7588 dynamic linker and used by the debugger. */
7589 if (info
->executable
7590 && !SGI_COMPAT (output_bfd
)
7591 && !MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_DEBUG
, 0))
7594 /* SGI object has the equivalence of DT_DEBUG in the
7595 DT_MIPS_RLD_MAP entry. */
7597 && !MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_RLD_MAP
, 0))
7600 if (reltext
&& (SGI_COMPAT (output_bfd
) || htab
->is_vxworks
))
7601 info
->flags
|= DF_TEXTREL
;
7603 if ((info
->flags
& DF_TEXTREL
) != 0)
7605 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_TEXTREL
, 0))
7608 /* Clear the DF_TEXTREL flag. It will be set again if we
7609 write out an actual text relocation; we may not, because
7610 at this point we do not know whether e.g. any .eh_frame
7611 absolute relocations have been converted to PC-relative. */
7612 info
->flags
&= ~DF_TEXTREL
;
7615 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_PLTGOT
, 0))
7618 if (htab
->is_vxworks
)
7620 /* VxWorks uses .rela.dyn instead of .rel.dyn. It does not
7621 use any of the DT_MIPS_* tags. */
7622 if (mips_elf_rel_dyn_section (info
, FALSE
))
7624 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_RELA
, 0))
7627 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_RELASZ
, 0))
7630 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_RELAENT
, 0))
7633 if (htab
->splt
->size
> 0)
7635 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_PLTREL
, 0))
7638 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_JMPREL
, 0))
7641 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_PLTRELSZ
, 0))
7647 if (mips_elf_rel_dyn_section (info
, FALSE
))
7649 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_REL
, 0))
7652 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_RELSZ
, 0))
7655 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_RELENT
, 0))
7659 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_RLD_VERSION
, 0))
7662 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_FLAGS
, 0))
7665 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_BASE_ADDRESS
, 0))
7668 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_LOCAL_GOTNO
, 0))
7671 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_SYMTABNO
, 0))
7674 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_UNREFEXTNO
, 0))
7677 if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_GOTSYM
, 0))
7680 if (IRIX_COMPAT (dynobj
) == ict_irix5
7681 && ! MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_HIPAGENO
, 0))
7684 if (IRIX_COMPAT (dynobj
) == ict_irix6
7685 && (bfd_get_section_by_name
7686 (dynobj
, MIPS_ELF_OPTIONS_SECTION_NAME (dynobj
)))
7687 && !MIPS_ELF_ADD_DYNAMIC_ENTRY (info
, DT_MIPS_OPTIONS
, 0))
7695 /* REL is a relocation in INPUT_BFD that is being copied to OUTPUT_BFD.
7696 Adjust its R_ADDEND field so that it is correct for the output file.
7697 LOCAL_SYMS and LOCAL_SECTIONS are arrays of INPUT_BFD's local symbols
7698 and sections respectively; both use symbol indexes. */
7701 mips_elf_adjust_addend (bfd
*output_bfd
, struct bfd_link_info
*info
,
7702 bfd
*input_bfd
, Elf_Internal_Sym
*local_syms
,
7703 asection
**local_sections
, Elf_Internal_Rela
*rel
)
7705 unsigned int r_type
, r_symndx
;
7706 Elf_Internal_Sym
*sym
;
7709 if (mips_elf_local_relocation_p (input_bfd
, rel
, local_sections
, FALSE
))
7711 r_type
= ELF_R_TYPE (output_bfd
, rel
->r_info
);
7712 if (r_type
== R_MIPS16_GPREL
7713 || r_type
== R_MIPS_GPREL16
7714 || r_type
== R_MIPS_GPREL32
7715 || r_type
== R_MIPS_LITERAL
)
7717 rel
->r_addend
+= _bfd_get_gp_value (input_bfd
);
7718 rel
->r_addend
-= _bfd_get_gp_value (output_bfd
);
7721 r_symndx
= ELF_R_SYM (output_bfd
, rel
->r_info
);
7722 sym
= local_syms
+ r_symndx
;
7724 /* Adjust REL's addend to account for section merging. */
7725 if (!info
->relocatable
)
7727 sec
= local_sections
[r_symndx
];
7728 _bfd_elf_rela_local_sym (output_bfd
, sym
, &sec
, rel
);
7731 /* This would normally be done by the rela_normal code in elflink.c. */
7732 if (ELF_ST_TYPE (sym
->st_info
) == STT_SECTION
)
7733 rel
->r_addend
+= local_sections
[r_symndx
]->output_offset
;
7737 /* Relocate a MIPS ELF section. */
7740 _bfd_mips_elf_relocate_section (bfd
*output_bfd
, struct bfd_link_info
*info
,
7741 bfd
*input_bfd
, asection
*input_section
,
7742 bfd_byte
*contents
, Elf_Internal_Rela
*relocs
,
7743 Elf_Internal_Sym
*local_syms
,
7744 asection
**local_sections
)
7746 Elf_Internal_Rela
*rel
;
7747 const Elf_Internal_Rela
*relend
;
7749 bfd_boolean use_saved_addend_p
= FALSE
;
7750 const struct elf_backend_data
*bed
;
7752 bed
= get_elf_backend_data (output_bfd
);
7753 relend
= relocs
+ input_section
->reloc_count
* bed
->s
->int_rels_per_ext_rel
;
7754 for (rel
= relocs
; rel
< relend
; ++rel
)
7758 reloc_howto_type
*howto
;
7759 bfd_boolean require_jalx
;
7760 /* TRUE if the relocation is a RELA relocation, rather than a
7762 bfd_boolean rela_relocation_p
= TRUE
;
7763 unsigned int r_type
= ELF_R_TYPE (output_bfd
, rel
->r_info
);
7765 unsigned long r_symndx
;
7767 Elf_Internal_Shdr
*symtab_hdr
;
7768 struct elf_link_hash_entry
*h
;
7770 /* Find the relocation howto for this relocation. */
7771 howto
= MIPS_ELF_RTYPE_TO_HOWTO (input_bfd
, r_type
,
7772 NEWABI_P (input_bfd
)
7773 && (MIPS_RELOC_RELA_P
7774 (input_bfd
, input_section
,
7777 r_symndx
= ELF_R_SYM (input_bfd
, rel
->r_info
);
7778 symtab_hdr
= &elf_tdata (input_bfd
)->symtab_hdr
;
7779 if (mips_elf_local_relocation_p (input_bfd
, rel
, local_sections
, FALSE
))
7781 sec
= local_sections
[r_symndx
];
7786 unsigned long extsymoff
;
7789 if (!elf_bad_symtab (input_bfd
))
7790 extsymoff
= symtab_hdr
->sh_info
;
7791 h
= elf_sym_hashes (input_bfd
) [r_symndx
- extsymoff
];
7792 while (h
->root
.type
== bfd_link_hash_indirect
7793 || h
->root
.type
== bfd_link_hash_warning
)
7794 h
= (struct elf_link_hash_entry
*) h
->root
.u
.i
.link
;
7797 if (h
->root
.type
== bfd_link_hash_defined
7798 || h
->root
.type
== bfd_link_hash_defweak
)
7799 sec
= h
->root
.u
.def
.section
;
7802 if (sec
!= NULL
&& elf_discarded_section (sec
))
7804 /* For relocs against symbols from removed linkonce sections,
7805 or sections discarded by a linker script, we just want the
7806 section contents zeroed. Avoid any special processing. */
7807 _bfd_clear_contents (howto
, input_bfd
, contents
+ rel
->r_offset
);
7813 if (r_type
== R_MIPS_64
&& ! NEWABI_P (input_bfd
))
7815 /* Some 32-bit code uses R_MIPS_64. In particular, people use
7816 64-bit code, but make sure all their addresses are in the
7817 lowermost or uppermost 32-bit section of the 64-bit address
7818 space. Thus, when they use an R_MIPS_64 they mean what is
7819 usually meant by R_MIPS_32, with the exception that the
7820 stored value is sign-extended to 64 bits. */
7821 howto
= MIPS_ELF_RTYPE_TO_HOWTO (input_bfd
, R_MIPS_32
, FALSE
);
7823 /* On big-endian systems, we need to lie about the position
7825 if (bfd_big_endian (input_bfd
))
7829 if (!use_saved_addend_p
)
7831 Elf_Internal_Shdr
*rel_hdr
;
7833 /* If these relocations were originally of the REL variety,
7834 we must pull the addend out of the field that will be
7835 relocated. Otherwise, we simply use the contents of the
7836 RELA relocation. To determine which flavor or relocation
7837 this is, we depend on the fact that the INPUT_SECTION's
7838 REL_HDR is read before its REL_HDR2. */
7839 rel_hdr
= &elf_section_data (input_section
)->rel_hdr
;
7840 if ((size_t) (rel
- relocs
)
7841 >= (NUM_SHDR_ENTRIES (rel_hdr
) * bed
->s
->int_rels_per_ext_rel
))
7842 rel_hdr
= elf_section_data (input_section
)->rel_hdr2
;
7843 if (rel_hdr
->sh_entsize
== MIPS_ELF_REL_SIZE (input_bfd
))
7845 bfd_byte
*location
= contents
+ rel
->r_offset
;
7847 /* Note that this is a REL relocation. */
7848 rela_relocation_p
= FALSE
;
7850 /* Get the addend, which is stored in the input file. */
7851 _bfd_mips16_elf_reloc_unshuffle (input_bfd
, r_type
, FALSE
,
7853 addend
= mips_elf_obtain_contents (howto
, rel
, input_bfd
,
7855 _bfd_mips16_elf_reloc_shuffle(input_bfd
, r_type
, FALSE
,
7858 addend
&= howto
->src_mask
;
7860 /* For some kinds of relocations, the ADDEND is a
7861 combination of the addend stored in two different
7863 if (r_type
== R_MIPS_HI16
|| r_type
== R_MIPS16_HI16
7864 || (r_type
== R_MIPS_GOT16
7865 && mips_elf_local_relocation_p (input_bfd
, rel
,
7866 local_sections
, FALSE
)))
7868 const Elf_Internal_Rela
*lo16_relocation
;
7869 reloc_howto_type
*lo16_howto
;
7872 if (r_type
== R_MIPS16_HI16
)
7873 lo16_type
= R_MIPS16_LO16
;
7875 lo16_type
= R_MIPS_LO16
;
7877 /* The combined value is the sum of the HI16 addend,
7878 left-shifted by sixteen bits, and the LO16
7879 addend, sign extended. (Usually, the code does
7880 a `lui' of the HI16 value, and then an `addiu' of
7883 Scan ahead to find a matching LO16 relocation.
7885 According to the MIPS ELF ABI, the R_MIPS_LO16
7886 relocation must be immediately following.
7887 However, for the IRIX6 ABI, the next relocation
7888 may be a composed relocation consisting of
7889 several relocations for the same address. In
7890 that case, the R_MIPS_LO16 relocation may occur
7891 as one of these. We permit a similar extension
7892 in general, as that is useful for GCC.
7894 In some cases GCC dead code elimination removes
7895 the LO16 but keeps the corresponding HI16. This
7896 is strictly speaking a violation of the ABI but
7897 not immediately harmful. */
7898 lo16_relocation
= mips_elf_next_relocation (input_bfd
,
7901 if (lo16_relocation
== NULL
)
7906 name
= h
->root
.root
.string
;
7908 name
= bfd_elf_sym_name (input_bfd
, symtab_hdr
,
7909 local_syms
+ r_symndx
,
7911 (*_bfd_error_handler
)
7912 (_("%B: Can't find matching LO16 reloc against `%s' for %s at 0x%lx in section `%A'"),
7913 input_bfd
, input_section
, name
, howto
->name
,
7918 bfd_byte
*lo16_location
;
7921 lo16_location
= contents
+ lo16_relocation
->r_offset
;
7923 /* Obtain the addend kept there. */
7924 lo16_howto
= MIPS_ELF_RTYPE_TO_HOWTO (input_bfd
,
7926 _bfd_mips16_elf_reloc_unshuffle (input_bfd
, lo16_type
,
7927 FALSE
, lo16_location
);
7928 l
= mips_elf_obtain_contents (lo16_howto
,
7930 input_bfd
, contents
);
7931 _bfd_mips16_elf_reloc_shuffle (input_bfd
, lo16_type
,
7932 FALSE
, lo16_location
);
7933 l
&= lo16_howto
->src_mask
;
7934 l
<<= lo16_howto
->rightshift
;
7935 l
= _bfd_mips_elf_sign_extend (l
, 16);
7939 /* Compute the combined addend. */
7944 addend
<<= howto
->rightshift
;
7947 addend
= rel
->r_addend
;
7948 mips_elf_adjust_addend (output_bfd
, info
, input_bfd
,
7949 local_syms
, local_sections
, rel
);
7952 if (info
->relocatable
)
7954 if (r_type
== R_MIPS_64
&& ! NEWABI_P (output_bfd
)
7955 && bfd_big_endian (input_bfd
))
7958 if (!rela_relocation_p
&& rel
->r_addend
)
7960 addend
+= rel
->r_addend
;
7961 if (r_type
== R_MIPS_HI16
7962 || r_type
== R_MIPS_GOT16
)
7963 addend
= mips_elf_high (addend
);
7964 else if (r_type
== R_MIPS_HIGHER
)
7965 addend
= mips_elf_higher (addend
);
7966 else if (r_type
== R_MIPS_HIGHEST
)
7967 addend
= mips_elf_highest (addend
);
7969 addend
>>= howto
->rightshift
;
7971 /* We use the source mask, rather than the destination
7972 mask because the place to which we are writing will be
7973 source of the addend in the final link. */
7974 addend
&= howto
->src_mask
;
7976 if (r_type
== R_MIPS_64
&& ! NEWABI_P (output_bfd
))
7977 /* See the comment above about using R_MIPS_64 in the 32-bit
7978 ABI. Here, we need to update the addend. It would be
7979 possible to get away with just using the R_MIPS_32 reloc
7980 but for endianness. */
7986 if (addend
& ((bfd_vma
) 1 << 31))
7988 sign_bits
= ((bfd_vma
) 1 << 32) - 1;
7995 /* If we don't know that we have a 64-bit type,
7996 do two separate stores. */
7997 if (bfd_big_endian (input_bfd
))
7999 /* Store the sign-bits (which are most significant)
8001 low_bits
= sign_bits
;
8007 high_bits
= sign_bits
;
8009 bfd_put_32 (input_bfd
, low_bits
,
8010 contents
+ rel
->r_offset
);
8011 bfd_put_32 (input_bfd
, high_bits
,
8012 contents
+ rel
->r_offset
+ 4);
8016 if (! mips_elf_perform_relocation (info
, howto
, rel
, addend
,
8017 input_bfd
, input_section
,
8022 /* Go on to the next relocation. */
8026 /* In the N32 and 64-bit ABIs there may be multiple consecutive
8027 relocations for the same offset. In that case we are
8028 supposed to treat the output of each relocation as the addend
8030 if (rel
+ 1 < relend
8031 && rel
->r_offset
== rel
[1].r_offset
8032 && ELF_R_TYPE (input_bfd
, rel
[1].r_info
) != R_MIPS_NONE
)
8033 use_saved_addend_p
= TRUE
;
8035 use_saved_addend_p
= FALSE
;
8037 /* Figure out what value we are supposed to relocate. */
8038 switch (mips_elf_calculate_relocation (output_bfd
, input_bfd
,
8039 input_section
, info
, rel
,
8040 addend
, howto
, local_syms
,
8041 local_sections
, &value
,
8042 &name
, &require_jalx
,
8043 use_saved_addend_p
))
8045 case bfd_reloc_continue
:
8046 /* There's nothing to do. */
8049 case bfd_reloc_undefined
:
8050 /* mips_elf_calculate_relocation already called the
8051 undefined_symbol callback. There's no real point in
8052 trying to perform the relocation at this point, so we
8053 just skip ahead to the next relocation. */
8056 case bfd_reloc_notsupported
:
8057 msg
= _("internal error: unsupported relocation error");
8058 info
->callbacks
->warning
8059 (info
, msg
, name
, input_bfd
, input_section
, rel
->r_offset
);
8062 case bfd_reloc_overflow
:
8063 if (use_saved_addend_p
)
8064 /* Ignore overflow until we reach the last relocation for
8065 a given location. */
8069 BFD_ASSERT (name
!= NULL
);
8070 if (! ((*info
->callbacks
->reloc_overflow
)
8071 (info
, NULL
, name
, howto
->name
, (bfd_vma
) 0,
8072 input_bfd
, input_section
, rel
->r_offset
)))
8085 /* If we've got another relocation for the address, keep going
8086 until we reach the last one. */
8087 if (use_saved_addend_p
)
8093 if (r_type
== R_MIPS_64
&& ! NEWABI_P (output_bfd
))
8094 /* See the comment above about using R_MIPS_64 in the 32-bit
8095 ABI. Until now, we've been using the HOWTO for R_MIPS_32;
8096 that calculated the right value. Now, however, we
8097 sign-extend the 32-bit result to 64-bits, and store it as a
8098 64-bit value. We are especially generous here in that we
8099 go to extreme lengths to support this usage on systems with
8100 only a 32-bit VMA. */
8106 if (value
& ((bfd_vma
) 1 << 31))
8108 sign_bits
= ((bfd_vma
) 1 << 32) - 1;
8115 /* If we don't know that we have a 64-bit type,
8116 do two separate stores. */
8117 if (bfd_big_endian (input_bfd
))
8119 /* Undo what we did above. */
8121 /* Store the sign-bits (which are most significant)
8123 low_bits
= sign_bits
;
8129 high_bits
= sign_bits
;
8131 bfd_put_32 (input_bfd
, low_bits
,
8132 contents
+ rel
->r_offset
);
8133 bfd_put_32 (input_bfd
, high_bits
,
8134 contents
+ rel
->r_offset
+ 4);
8138 /* Actually perform the relocation. */
8139 if (! mips_elf_perform_relocation (info
, howto
, rel
, value
,
8140 input_bfd
, input_section
,
8141 contents
, require_jalx
))
8148 /* If NAME is one of the special IRIX6 symbols defined by the linker,
8149 adjust it appropriately now. */
8152 mips_elf_irix6_finish_dynamic_symbol (bfd
*abfd ATTRIBUTE_UNUSED
,
8153 const char *name
, Elf_Internal_Sym
*sym
)
8155 /* The linker script takes care of providing names and values for
8156 these, but we must place them into the right sections. */
8157 static const char* const text_section_symbols
[] = {
8160 "__dso_displacement",
8162 "__program_header_table",
8166 static const char* const data_section_symbols
[] = {
8174 const char* const *p
;
8177 for (i
= 0; i
< 2; ++i
)
8178 for (p
= (i
== 0) ? text_section_symbols
: data_section_symbols
;
8181 if (strcmp (*p
, name
) == 0)
8183 /* All of these symbols are given type STT_SECTION by the
8185 sym
->st_info
= ELF_ST_INFO (STB_GLOBAL
, STT_SECTION
);
8186 sym
->st_other
= STO_PROTECTED
;
8188 /* The IRIX linker puts these symbols in special sections. */
8190 sym
->st_shndx
= SHN_MIPS_TEXT
;
8192 sym
->st_shndx
= SHN_MIPS_DATA
;
8198 /* Finish up dynamic symbol handling. We set the contents of various
8199 dynamic sections here. */
8202 _bfd_mips_elf_finish_dynamic_symbol (bfd
*output_bfd
,
8203 struct bfd_link_info
*info
,
8204 struct elf_link_hash_entry
*h
,
8205 Elf_Internal_Sym
*sym
)
8209 struct mips_got_info
*g
, *gg
;
8212 struct mips_elf_link_hash_table
*htab
;
8214 htab
= mips_elf_hash_table (info
);
8215 dynobj
= elf_hash_table (info
)->dynobj
;
8217 if (h
->plt
.offset
!= MINUS_ONE
)
8220 bfd_byte stub
[MIPS_FUNCTION_STUB_BIG_SIZE
];
8222 /* This symbol has a stub. Set it up. */
8224 BFD_ASSERT (h
->dynindx
!= -1);
8226 s
= bfd_get_section_by_name (dynobj
,
8227 MIPS_ELF_STUB_SECTION_NAME (dynobj
));
8228 BFD_ASSERT (s
!= NULL
);
8230 BFD_ASSERT ((htab
->function_stub_size
== MIPS_FUNCTION_STUB_BIG_SIZE
)
8231 || (h
->dynindx
<= 0xffff));
8233 /* Values up to 2^31 - 1 are allowed. Larger values would cause
8234 sign extension at runtime in the stub, resulting in a negative
8236 if (h
->dynindx
& ~0x7fffffff)
8239 /* Fill the stub. */
8241 bfd_put_32 (output_bfd
, STUB_LW (output_bfd
), stub
+ idx
);
8243 bfd_put_32 (output_bfd
, STUB_MOVE (output_bfd
), stub
+ idx
);
8245 if (htab
->function_stub_size
== MIPS_FUNCTION_STUB_BIG_SIZE
)
8247 bfd_put_32 (output_bfd
, STUB_LUI ((h
->dynindx
>> 16) & 0x7fff),
8251 bfd_put_32 (output_bfd
, STUB_JALR
, stub
+ idx
);
8254 /* If a large stub is not required and sign extension is not a
8255 problem, then use legacy code in the stub. */
8256 if (htab
->function_stub_size
== MIPS_FUNCTION_STUB_BIG_SIZE
)
8257 bfd_put_32 (output_bfd
, STUB_ORI (h
->dynindx
& 0xffff), stub
+ idx
);
8258 else if (h
->dynindx
& ~0x7fff)
8259 bfd_put_32 (output_bfd
, STUB_LI16U (h
->dynindx
& 0xffff), stub
+ idx
);
8261 bfd_put_32 (output_bfd
, STUB_LI16S (output_bfd
, h
->dynindx
),
8264 BFD_ASSERT (h
->plt
.offset
<= s
->size
);
8265 memcpy (s
->contents
+ h
->plt
.offset
, stub
, htab
->function_stub_size
);
8267 /* Mark the symbol as undefined. plt.offset != -1 occurs
8268 only for the referenced symbol. */
8269 sym
->st_shndx
= SHN_UNDEF
;
8271 /* The run-time linker uses the st_value field of the symbol
8272 to reset the global offset table entry for this external
8273 to its stub address when unlinking a shared object. */
8274 sym
->st_value
= (s
->output_section
->vma
+ s
->output_offset
8278 BFD_ASSERT (h
->dynindx
!= -1
8279 || h
->forced_local
);
8281 sgot
= mips_elf_got_section (dynobj
, FALSE
);
8282 BFD_ASSERT (sgot
!= NULL
);
8283 BFD_ASSERT (mips_elf_section_data (sgot
) != NULL
);
8284 g
= mips_elf_section_data (sgot
)->u
.got_info
;
8285 BFD_ASSERT (g
!= NULL
);
8287 /* Run through the global symbol table, creating GOT entries for all
8288 the symbols that need them. */
8289 if (g
->global_gotsym
!= NULL
8290 && h
->dynindx
>= g
->global_gotsym
->dynindx
)
8295 value
= sym
->st_value
;
8296 offset
= mips_elf_global_got_index (dynobj
, output_bfd
, h
, R_MIPS_GOT16
, info
);
8297 MIPS_ELF_PUT_WORD (output_bfd
, value
, sgot
->contents
+ offset
);
8300 if (g
->next
&& h
->dynindx
!= -1 && h
->type
!= STT_TLS
)
8302 struct mips_got_entry e
, *p
;
8308 e
.abfd
= output_bfd
;
8310 e
.d
.h
= (struct mips_elf_link_hash_entry
*)h
;
8313 for (g
= g
->next
; g
->next
!= gg
; g
= g
->next
)
8316 && (p
= (struct mips_got_entry
*) htab_find (g
->got_entries
,
8321 || (elf_hash_table (info
)->dynamic_sections_created
8323 && p
->d
.h
->root
.def_dynamic
8324 && !p
->d
.h
->root
.def_regular
))
8326 /* Create an R_MIPS_REL32 relocation for this entry. Due to
8327 the various compatibility problems, it's easier to mock
8328 up an R_MIPS_32 or R_MIPS_64 relocation and leave
8329 mips_elf_create_dynamic_relocation to calculate the
8330 appropriate addend. */
8331 Elf_Internal_Rela rel
[3];
8333 memset (rel
, 0, sizeof (rel
));
8334 if (ABI_64_P (output_bfd
))
8335 rel
[0].r_info
= ELF_R_INFO (output_bfd
, 0, R_MIPS_64
);
8337 rel
[0].r_info
= ELF_R_INFO (output_bfd
, 0, R_MIPS_32
);
8338 rel
[0].r_offset
= rel
[1].r_offset
= rel
[2].r_offset
= offset
;
8341 if (! (mips_elf_create_dynamic_relocation
8342 (output_bfd
, info
, rel
,
8343 e
.d
.h
, NULL
, sym
->st_value
, &entry
, sgot
)))
8347 entry
= sym
->st_value
;
8348 MIPS_ELF_PUT_WORD (output_bfd
, entry
, sgot
->contents
+ offset
);
8353 /* Mark _DYNAMIC and _GLOBAL_OFFSET_TABLE_ as absolute. */
8354 name
= h
->root
.root
.string
;
8355 if (strcmp (name
, "_DYNAMIC") == 0
8356 || h
== elf_hash_table (info
)->hgot
)
8357 sym
->st_shndx
= SHN_ABS
;
8358 else if (strcmp (name
, "_DYNAMIC_LINK") == 0
8359 || strcmp (name
, "_DYNAMIC_LINKING") == 0)
8361 sym
->st_shndx
= SHN_ABS
;
8362 sym
->st_info
= ELF_ST_INFO (STB_GLOBAL
, STT_SECTION
);
8365 else if (strcmp (name
, "_gp_disp") == 0 && ! NEWABI_P (output_bfd
))
8367 sym
->st_shndx
= SHN_ABS
;
8368 sym
->st_info
= ELF_ST_INFO (STB_GLOBAL
, STT_SECTION
);
8369 sym
->st_value
= elf_gp (output_bfd
);
8371 else if (SGI_COMPAT (output_bfd
))
8373 if (strcmp (name
, mips_elf_dynsym_rtproc_names
[0]) == 0
8374 || strcmp (name
, mips_elf_dynsym_rtproc_names
[1]) == 0)
8376 sym
->st_info
= ELF_ST_INFO (STB_GLOBAL
, STT_SECTION
);
8377 sym
->st_other
= STO_PROTECTED
;
8379 sym
->st_shndx
= SHN_MIPS_DATA
;
8381 else if (strcmp (name
, mips_elf_dynsym_rtproc_names
[2]) == 0)
8383 sym
->st_info
= ELF_ST_INFO (STB_GLOBAL
, STT_SECTION
);
8384 sym
->st_other
= STO_PROTECTED
;
8385 sym
->st_value
= mips_elf_hash_table (info
)->procedure_count
;
8386 sym
->st_shndx
= SHN_ABS
;
8388 else if (sym
->st_shndx
!= SHN_UNDEF
&& sym
->st_shndx
!= SHN_ABS
)
8390 if (h
->type
== STT_FUNC
)
8391 sym
->st_shndx
= SHN_MIPS_TEXT
;
8392 else if (h
->type
== STT_OBJECT
)
8393 sym
->st_shndx
= SHN_MIPS_DATA
;
8397 /* Handle the IRIX6-specific symbols. */
8398 if (IRIX_COMPAT (output_bfd
) == ict_irix6
)
8399 mips_elf_irix6_finish_dynamic_symbol (output_bfd
, name
, sym
);
8403 if (! mips_elf_hash_table (info
)->use_rld_obj_head
8404 && (strcmp (name
, "__rld_map") == 0
8405 || strcmp (name
, "__RLD_MAP") == 0))
8407 asection
*s
= bfd_get_section_by_name (dynobj
, ".rld_map");
8408 BFD_ASSERT (s
!= NULL
);
8409 sym
->st_value
= s
->output_section
->vma
+ s
->output_offset
;
8410 bfd_put_32 (output_bfd
, 0, s
->contents
);
8411 if (mips_elf_hash_table (info
)->rld_value
== 0)
8412 mips_elf_hash_table (info
)->rld_value
= sym
->st_value
;
8414 else if (mips_elf_hash_table (info
)->use_rld_obj_head
8415 && strcmp (name
, "__rld_obj_head") == 0)
8417 /* IRIX6 does not use a .rld_map section. */
8418 if (IRIX_COMPAT (output_bfd
) == ict_irix5
8419 || IRIX_COMPAT (output_bfd
) == ict_none
)
8420 BFD_ASSERT (bfd_get_section_by_name (dynobj
, ".rld_map")
8422 mips_elf_hash_table (info
)->rld_value
= sym
->st_value
;
8426 /* If this is a mips16 symbol, force the value to be even. */
8427 if (sym
->st_other
== STO_MIPS16
)
8428 sym
->st_value
&= ~1;
8433 /* Likewise, for VxWorks. */
8436 _bfd_mips_vxworks_finish_dynamic_symbol (bfd
*output_bfd
,
8437 struct bfd_link_info
*info
,
8438 struct elf_link_hash_entry
*h
,
8439 Elf_Internal_Sym
*sym
)
8443 struct mips_got_info
*g
;
8444 struct mips_elf_link_hash_table
*htab
;
8446 htab
= mips_elf_hash_table (info
);
8447 dynobj
= elf_hash_table (info
)->dynobj
;
8449 if (h
->plt
.offset
!= (bfd_vma
) -1)
8452 bfd_vma plt_address
, plt_index
, got_address
, got_offset
, branch_offset
;
8453 Elf_Internal_Rela rel
;
8454 static const bfd_vma
*plt_entry
;
8456 BFD_ASSERT (h
->dynindx
!= -1);
8457 BFD_ASSERT (htab
->splt
!= NULL
);
8458 BFD_ASSERT (h
->plt
.offset
<= htab
->splt
->size
);
8460 /* Calculate the address of the .plt entry. */
8461 plt_address
= (htab
->splt
->output_section
->vma
8462 + htab
->splt
->output_offset
8465 /* Calculate the index of the entry. */
8466 plt_index
= ((h
->plt
.offset
- htab
->plt_header_size
)
8467 / htab
->plt_entry_size
);
8469 /* Calculate the address of the .got.plt entry. */
8470 got_address
= (htab
->sgotplt
->output_section
->vma
8471 + htab
->sgotplt
->output_offset
8474 /* Calculate the offset of the .got.plt entry from
8475 _GLOBAL_OFFSET_TABLE_. */
8476 got_offset
= mips_elf_gotplt_index (info
, h
);
8478 /* Calculate the offset for the branch at the start of the PLT
8479 entry. The branch jumps to the beginning of .plt. */
8480 branch_offset
= -(h
->plt
.offset
/ 4 + 1) & 0xffff;
8482 /* Fill in the initial value of the .got.plt entry. */
8483 bfd_put_32 (output_bfd
, plt_address
,
8484 htab
->sgotplt
->contents
+ plt_index
* 4);
8486 /* Find out where the .plt entry should go. */
8487 loc
= htab
->splt
->contents
+ h
->plt
.offset
;
8491 plt_entry
= mips_vxworks_shared_plt_entry
;
8492 bfd_put_32 (output_bfd
, plt_entry
[0] | branch_offset
, loc
);
8493 bfd_put_32 (output_bfd
, plt_entry
[1] | plt_index
, loc
+ 4);
8497 bfd_vma got_address_high
, got_address_low
;
8499 plt_entry
= mips_vxworks_exec_plt_entry
;
8500 got_address_high
= ((got_address
+ 0x8000) >> 16) & 0xffff;
8501 got_address_low
= got_address
& 0xffff;
8503 bfd_put_32 (output_bfd
, plt_entry
[0] | branch_offset
, loc
);
8504 bfd_put_32 (output_bfd
, plt_entry
[1] | plt_index
, loc
+ 4);
8505 bfd_put_32 (output_bfd
, plt_entry
[2] | got_address_high
, loc
+ 8);
8506 bfd_put_32 (output_bfd
, plt_entry
[3] | got_address_low
, loc
+ 12);
8507 bfd_put_32 (output_bfd
, plt_entry
[4], loc
+ 16);
8508 bfd_put_32 (output_bfd
, plt_entry
[5], loc
+ 20);
8509 bfd_put_32 (output_bfd
, plt_entry
[6], loc
+ 24);
8510 bfd_put_32 (output_bfd
, plt_entry
[7], loc
+ 28);
8512 loc
= (htab
->srelplt2
->contents
8513 + (plt_index
* 3 + 2) * sizeof (Elf32_External_Rela
));
8515 /* Emit a relocation for the .got.plt entry. */
8516 rel
.r_offset
= got_address
;
8517 rel
.r_info
= ELF32_R_INFO (htab
->root
.hplt
->indx
, R_MIPS_32
);
8518 rel
.r_addend
= h
->plt
.offset
;
8519 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8521 /* Emit a relocation for the lui of %hi(<.got.plt slot>). */
8522 loc
+= sizeof (Elf32_External_Rela
);
8523 rel
.r_offset
= plt_address
+ 8;
8524 rel
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_HI16
);
8525 rel
.r_addend
= got_offset
;
8526 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8528 /* Emit a relocation for the addiu of %lo(<.got.plt slot>). */
8529 loc
+= sizeof (Elf32_External_Rela
);
8531 rel
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_LO16
);
8532 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8535 /* Emit an R_MIPS_JUMP_SLOT relocation against the .got.plt entry. */
8536 loc
= htab
->srelplt
->contents
+ plt_index
* sizeof (Elf32_External_Rela
);
8537 rel
.r_offset
= got_address
;
8538 rel
.r_info
= ELF32_R_INFO (h
->dynindx
, R_MIPS_JUMP_SLOT
);
8540 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8542 if (!h
->def_regular
)
8543 sym
->st_shndx
= SHN_UNDEF
;
8546 BFD_ASSERT (h
->dynindx
!= -1 || h
->forced_local
);
8548 sgot
= mips_elf_got_section (dynobj
, FALSE
);
8549 BFD_ASSERT (sgot
!= NULL
);
8550 BFD_ASSERT (mips_elf_section_data (sgot
) != NULL
);
8551 g
= mips_elf_section_data (sgot
)->u
.got_info
;
8552 BFD_ASSERT (g
!= NULL
);
8554 /* See if this symbol has an entry in the GOT. */
8555 if (g
->global_gotsym
!= NULL
8556 && h
->dynindx
>= g
->global_gotsym
->dynindx
)
8559 Elf_Internal_Rela outrel
;
8563 /* Install the symbol value in the GOT. */
8564 offset
= mips_elf_global_got_index (dynobj
, output_bfd
, h
,
8565 R_MIPS_GOT16
, info
);
8566 MIPS_ELF_PUT_WORD (output_bfd
, sym
->st_value
, sgot
->contents
+ offset
);
8568 /* Add a dynamic relocation for it. */
8569 s
= mips_elf_rel_dyn_section (info
, FALSE
);
8570 loc
= s
->contents
+ (s
->reloc_count
++ * sizeof (Elf32_External_Rela
));
8571 outrel
.r_offset
= (sgot
->output_section
->vma
8572 + sgot
->output_offset
8574 outrel
.r_info
= ELF32_R_INFO (h
->dynindx
, R_MIPS_32
);
8575 outrel
.r_addend
= 0;
8576 bfd_elf32_swap_reloca_out (dynobj
, &outrel
, loc
);
8579 /* Emit a copy reloc, if needed. */
8582 Elf_Internal_Rela rel
;
8584 BFD_ASSERT (h
->dynindx
!= -1);
8586 rel
.r_offset
= (h
->root
.u
.def
.section
->output_section
->vma
8587 + h
->root
.u
.def
.section
->output_offset
8588 + h
->root
.u
.def
.value
);
8589 rel
.r_info
= ELF32_R_INFO (h
->dynindx
, R_MIPS_COPY
);
8591 bfd_elf32_swap_reloca_out (output_bfd
, &rel
,
8592 htab
->srelbss
->contents
8593 + (htab
->srelbss
->reloc_count
8594 * sizeof (Elf32_External_Rela
)));
8595 ++htab
->srelbss
->reloc_count
;
8598 /* If this is a mips16 symbol, force the value to be even. */
8599 if (sym
->st_other
== STO_MIPS16
)
8600 sym
->st_value
&= ~1;
8605 /* Install the PLT header for a VxWorks executable and finalize the
8606 contents of .rela.plt.unloaded. */
8609 mips_vxworks_finish_exec_plt (bfd
*output_bfd
, struct bfd_link_info
*info
)
8611 Elf_Internal_Rela rela
;
8613 bfd_vma got_value
, got_value_high
, got_value_low
, plt_address
;
8614 static const bfd_vma
*plt_entry
;
8615 struct mips_elf_link_hash_table
*htab
;
8617 htab
= mips_elf_hash_table (info
);
8618 plt_entry
= mips_vxworks_exec_plt0_entry
;
8620 /* Calculate the value of _GLOBAL_OFFSET_TABLE_. */
8621 got_value
= (htab
->root
.hgot
->root
.u
.def
.section
->output_section
->vma
8622 + htab
->root
.hgot
->root
.u
.def
.section
->output_offset
8623 + htab
->root
.hgot
->root
.u
.def
.value
);
8625 got_value_high
= ((got_value
+ 0x8000) >> 16) & 0xffff;
8626 got_value_low
= got_value
& 0xffff;
8628 /* Calculate the address of the PLT header. */
8629 plt_address
= htab
->splt
->output_section
->vma
+ htab
->splt
->output_offset
;
8631 /* Install the PLT header. */
8632 loc
= htab
->splt
->contents
;
8633 bfd_put_32 (output_bfd
, plt_entry
[0] | got_value_high
, loc
);
8634 bfd_put_32 (output_bfd
, plt_entry
[1] | got_value_low
, loc
+ 4);
8635 bfd_put_32 (output_bfd
, plt_entry
[2], loc
+ 8);
8636 bfd_put_32 (output_bfd
, plt_entry
[3], loc
+ 12);
8637 bfd_put_32 (output_bfd
, plt_entry
[4], loc
+ 16);
8638 bfd_put_32 (output_bfd
, plt_entry
[5], loc
+ 20);
8640 /* Output the relocation for the lui of %hi(_GLOBAL_OFFSET_TABLE_). */
8641 loc
= htab
->srelplt2
->contents
;
8642 rela
.r_offset
= plt_address
;
8643 rela
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_HI16
);
8645 bfd_elf32_swap_reloca_out (output_bfd
, &rela
, loc
);
8646 loc
+= sizeof (Elf32_External_Rela
);
8648 /* Output the relocation for the following addiu of
8649 %lo(_GLOBAL_OFFSET_TABLE_). */
8651 rela
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_LO16
);
8652 bfd_elf32_swap_reloca_out (output_bfd
, &rela
, loc
);
8653 loc
+= sizeof (Elf32_External_Rela
);
8655 /* Fix up the remaining relocations. They may have the wrong
8656 symbol index for _G_O_T_ or _P_L_T_ depending on the order
8657 in which symbols were output. */
8658 while (loc
< htab
->srelplt2
->contents
+ htab
->srelplt2
->size
)
8660 Elf_Internal_Rela rel
;
8662 bfd_elf32_swap_reloca_in (output_bfd
, loc
, &rel
);
8663 rel
.r_info
= ELF32_R_INFO (htab
->root
.hplt
->indx
, R_MIPS_32
);
8664 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8665 loc
+= sizeof (Elf32_External_Rela
);
8667 bfd_elf32_swap_reloca_in (output_bfd
, loc
, &rel
);
8668 rel
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_HI16
);
8669 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8670 loc
+= sizeof (Elf32_External_Rela
);
8672 bfd_elf32_swap_reloca_in (output_bfd
, loc
, &rel
);
8673 rel
.r_info
= ELF32_R_INFO (htab
->root
.hgot
->indx
, R_MIPS_LO16
);
8674 bfd_elf32_swap_reloca_out (output_bfd
, &rel
, loc
);
8675 loc
+= sizeof (Elf32_External_Rela
);
8679 /* Install the PLT header for a VxWorks shared library. */
8682 mips_vxworks_finish_shared_plt (bfd
*output_bfd
, struct bfd_link_info
*info
)
8685 struct mips_elf_link_hash_table
*htab
;
8687 htab
= mips_elf_hash_table (info
);
8689 /* We just need to copy the entry byte-by-byte. */
8690 for (i
= 0; i
< ARRAY_SIZE (mips_vxworks_shared_plt0_entry
); i
++)
8691 bfd_put_32 (output_bfd
, mips_vxworks_shared_plt0_entry
[i
],
8692 htab
->splt
->contents
+ i
* 4);
8695 /* Finish up the dynamic sections. */
8698 _bfd_mips_elf_finish_dynamic_sections (bfd
*output_bfd
,
8699 struct bfd_link_info
*info
)
8704 struct mips_got_info
*gg
, *g
;
8705 struct mips_elf_link_hash_table
*htab
;
8707 htab
= mips_elf_hash_table (info
);
8708 dynobj
= elf_hash_table (info
)->dynobj
;
8710 sdyn
= bfd_get_section_by_name (dynobj
, ".dynamic");
8712 sgot
= mips_elf_got_section (dynobj
, FALSE
);
8717 BFD_ASSERT (mips_elf_section_data (sgot
) != NULL
);
8718 gg
= mips_elf_section_data (sgot
)->u
.got_info
;
8719 BFD_ASSERT (gg
!= NULL
);
8720 g
= mips_elf_got_for_ibfd (gg
, output_bfd
);
8721 BFD_ASSERT (g
!= NULL
);
8724 if (elf_hash_table (info
)->dynamic_sections_created
)
8727 int dyn_to_skip
= 0, dyn_skipped
= 0;
8729 BFD_ASSERT (sdyn
!= NULL
);
8730 BFD_ASSERT (g
!= NULL
);
8732 for (b
= sdyn
->contents
;
8733 b
< sdyn
->contents
+ sdyn
->size
;
8734 b
+= MIPS_ELF_DYN_SIZE (dynobj
))
8736 Elf_Internal_Dyn dyn
;
8740 bfd_boolean swap_out_p
;
8742 /* Read in the current dynamic entry. */
8743 (*get_elf_backend_data (dynobj
)->s
->swap_dyn_in
) (dynobj
, b
, &dyn
);
8745 /* Assume that we're going to modify it and write it out. */
8751 dyn
.d_un
.d_val
= MIPS_ELF_REL_SIZE (dynobj
);
8755 BFD_ASSERT (htab
->is_vxworks
);
8756 dyn
.d_un
.d_val
= MIPS_ELF_RELA_SIZE (dynobj
);
8760 /* Rewrite DT_STRSZ. */
8762 _bfd_elf_strtab_size (elf_hash_table (info
)->dynstr
);
8767 if (htab
->is_vxworks
)
8769 /* _GLOBAL_OFFSET_TABLE_ is defined to be the beginning
8770 of the ".got" section in DYNOBJ. */
8771 s
= bfd_get_section_by_name (dynobj
, name
);
8772 BFD_ASSERT (s
!= NULL
);
8773 dyn
.d_un
.d_ptr
= s
->output_section
->vma
+ s
->output_offset
;
8777 s
= bfd_get_section_by_name (output_bfd
, name
);
8778 BFD_ASSERT (s
!= NULL
);
8779 dyn
.d_un
.d_ptr
= s
->vma
;
8783 case DT_MIPS_RLD_VERSION
:
8784 dyn
.d_un
.d_val
= 1; /* XXX */
8788 dyn
.d_un
.d_val
= RHF_NOTPOT
; /* XXX */
8791 case DT_MIPS_TIME_STAMP
:
8799 case DT_MIPS_ICHECKSUM
:
8804 case DT_MIPS_IVERSION
:
8809 case DT_MIPS_BASE_ADDRESS
:
8810 s
= output_bfd
->sections
;
8811 BFD_ASSERT (s
!= NULL
);
8812 dyn
.d_un
.d_ptr
= s
->vma
& ~(bfd_vma
) 0xffff;
8815 case DT_MIPS_LOCAL_GOTNO
:
8816 dyn
.d_un
.d_val
= g
->local_gotno
;
8819 case DT_MIPS_UNREFEXTNO
:
8820 /* The index into the dynamic symbol table which is the
8821 entry of the first external symbol that is not
8822 referenced within the same object. */
8823 dyn
.d_un
.d_val
= bfd_count_sections (output_bfd
) + 1;
8826 case DT_MIPS_GOTSYM
:
8827 if (gg
->global_gotsym
)
8829 dyn
.d_un
.d_val
= gg
->global_gotsym
->dynindx
;
8832 /* In case if we don't have global got symbols we default
8833 to setting DT_MIPS_GOTSYM to the same value as
8834 DT_MIPS_SYMTABNO, so we just fall through. */
8836 case DT_MIPS_SYMTABNO
:
8838 elemsize
= MIPS_ELF_SYM_SIZE (output_bfd
);
8839 s
= bfd_get_section_by_name (output_bfd
, name
);
8840 BFD_ASSERT (s
!= NULL
);
8842 dyn
.d_un
.d_val
= s
->size
/ elemsize
;
8845 case DT_MIPS_HIPAGENO
:
8846 dyn
.d_un
.d_val
= g
->local_gotno
- MIPS_RESERVED_GOTNO (info
);
8849 case DT_MIPS_RLD_MAP
:
8850 dyn
.d_un
.d_ptr
= mips_elf_hash_table (info
)->rld_value
;
8853 case DT_MIPS_OPTIONS
:
8854 s
= (bfd_get_section_by_name
8855 (output_bfd
, MIPS_ELF_OPTIONS_SECTION_NAME (output_bfd
)));
8856 dyn
.d_un
.d_ptr
= s
->vma
;
8860 BFD_ASSERT (htab
->is_vxworks
);
8861 /* The count does not include the JUMP_SLOT relocations. */
8863 dyn
.d_un
.d_val
-= htab
->srelplt
->size
;
8867 BFD_ASSERT (htab
->is_vxworks
);
8868 dyn
.d_un
.d_val
= DT_RELA
;
8872 BFD_ASSERT (htab
->is_vxworks
);
8873 dyn
.d_un
.d_val
= htab
->srelplt
->size
;
8877 BFD_ASSERT (htab
->is_vxworks
);
8878 dyn
.d_un
.d_val
= (htab
->srelplt
->output_section
->vma
8879 + htab
->srelplt
->output_offset
);
8883 /* If we didn't need any text relocations after all, delete
8885 if (!(info
->flags
& DF_TEXTREL
))
8887 dyn_to_skip
= MIPS_ELF_DYN_SIZE (dynobj
);
8893 /* If we didn't need any text relocations after all, clear
8894 DF_TEXTREL from DT_FLAGS. */
8895 if (!(info
->flags
& DF_TEXTREL
))
8896 dyn
.d_un
.d_val
&= ~DF_TEXTREL
;
8906 if (swap_out_p
|| dyn_skipped
)
8907 (*get_elf_backend_data (dynobj
)->s
->swap_dyn_out
)
8908 (dynobj
, &dyn
, b
- dyn_skipped
);
8912 dyn_skipped
+= dyn_to_skip
;
8917 /* Wipe out any trailing entries if we shifted down a dynamic tag. */
8918 if (dyn_skipped
> 0)
8919 memset (b
- dyn_skipped
, 0, dyn_skipped
);
8922 if (sgot
!= NULL
&& sgot
->size
> 0)
8924 if (htab
->is_vxworks
)
8926 /* The first entry of the global offset table points to the
8927 ".dynamic" section. The second is initialized by the
8928 loader and contains the shared library identifier.
8929 The third is also initialized by the loader and points
8930 to the lazy resolution stub. */
8931 MIPS_ELF_PUT_WORD (output_bfd
,
8932 sdyn
->output_offset
+ sdyn
->output_section
->vma
,
8934 MIPS_ELF_PUT_WORD (output_bfd
, 0,
8935 sgot
->contents
+ MIPS_ELF_GOT_SIZE (output_bfd
));
8936 MIPS_ELF_PUT_WORD (output_bfd
, 0,
8938 + 2 * MIPS_ELF_GOT_SIZE (output_bfd
));
8942 /* The first entry of the global offset table will be filled at
8943 runtime. The second entry will be used by some runtime loaders.
8944 This isn't the case of IRIX rld. */
8945 MIPS_ELF_PUT_WORD (output_bfd
, (bfd_vma
) 0, sgot
->contents
);
8946 MIPS_ELF_PUT_WORD (output_bfd
, (bfd_vma
) 0x80000000,
8947 sgot
->contents
+ MIPS_ELF_GOT_SIZE (output_bfd
));
8950 elf_section_data (sgot
->output_section
)->this_hdr
.sh_entsize
8951 = MIPS_ELF_GOT_SIZE (output_bfd
);
8954 /* Generate dynamic relocations for the non-primary gots. */
8955 if (gg
!= NULL
&& gg
->next
)
8957 Elf_Internal_Rela rel
[3];
8960 memset (rel
, 0, sizeof (rel
));
8961 rel
[0].r_info
= ELF_R_INFO (output_bfd
, 0, R_MIPS_REL32
);
8963 for (g
= gg
->next
; g
->next
!= gg
; g
= g
->next
)
8965 bfd_vma index
= g
->next
->local_gotno
+ g
->next
->global_gotno
8966 + g
->next
->tls_gotno
;
8968 MIPS_ELF_PUT_WORD (output_bfd
, 0, sgot
->contents
8969 + index
++ * MIPS_ELF_GOT_SIZE (output_bfd
));
8970 MIPS_ELF_PUT_WORD (output_bfd
, 0x80000000, sgot
->contents
8971 + index
++ * MIPS_ELF_GOT_SIZE (output_bfd
));
8976 while (index
< g
->assigned_gotno
)
8978 rel
[0].r_offset
= rel
[1].r_offset
= rel
[2].r_offset
8979 = index
++ * MIPS_ELF_GOT_SIZE (output_bfd
);
8980 if (!(mips_elf_create_dynamic_relocation
8981 (output_bfd
, info
, rel
, NULL
,
8982 bfd_abs_section_ptr
,
8985 BFD_ASSERT (addend
== 0);
8990 /* The generation of dynamic relocations for the non-primary gots
8991 adds more dynamic relocations. We cannot count them until
8994 if (elf_hash_table (info
)->dynamic_sections_created
)
8997 bfd_boolean swap_out_p
;
8999 BFD_ASSERT (sdyn
!= NULL
);
9001 for (b
= sdyn
->contents
;
9002 b
< sdyn
->contents
+ sdyn
->size
;
9003 b
+= MIPS_ELF_DYN_SIZE (dynobj
))
9005 Elf_Internal_Dyn dyn
;
9008 /* Read in the current dynamic entry. */
9009 (*get_elf_backend_data (dynobj
)->s
->swap_dyn_in
) (dynobj
, b
, &dyn
);
9011 /* Assume that we're going to modify it and write it out. */
9017 /* Reduce DT_RELSZ to account for any relocations we
9018 decided not to make. This is for the n64 irix rld,
9019 which doesn't seem to apply any relocations if there
9020 are trailing null entries. */
9021 s
= mips_elf_rel_dyn_section (info
, FALSE
);
9022 dyn
.d_un
.d_val
= (s
->reloc_count
9023 * (ABI_64_P (output_bfd
)
9024 ? sizeof (Elf64_Mips_External_Rel
)
9025 : sizeof (Elf32_External_Rel
)));
9026 /* Adjust the section size too. Tools like the prelinker
9027 can reasonably expect the values to the same. */
9028 elf_section_data (s
->output_section
)->this_hdr
.sh_size
9038 (*get_elf_backend_data (dynobj
)->s
->swap_dyn_out
)
9045 Elf32_compact_rel cpt
;
9047 if (SGI_COMPAT (output_bfd
))
9049 /* Write .compact_rel section out. */
9050 s
= bfd_get_section_by_name (dynobj
, ".compact_rel");
9054 cpt
.num
= s
->reloc_count
;
9056 cpt
.offset
= (s
->output_section
->filepos
9057 + sizeof (Elf32_External_compact_rel
));
9060 bfd_elf32_swap_compact_rel_out (output_bfd
, &cpt
,
9061 ((Elf32_External_compact_rel
*)
9064 /* Clean up a dummy stub function entry in .text. */
9065 s
= bfd_get_section_by_name (dynobj
,
9066 MIPS_ELF_STUB_SECTION_NAME (dynobj
));
9069 file_ptr dummy_offset
;
9071 BFD_ASSERT (s
->size
>= htab
->function_stub_size
);
9072 dummy_offset
= s
->size
- htab
->function_stub_size
;
9073 memset (s
->contents
+ dummy_offset
, 0,
9074 htab
->function_stub_size
);
9079 /* The psABI says that the dynamic relocations must be sorted in
9080 increasing order of r_symndx. The VxWorks EABI doesn't require
9081 this, and because the code below handles REL rather than RELA
9082 relocations, using it for VxWorks would be outright harmful. */
9083 if (!htab
->is_vxworks
)
9085 s
= mips_elf_rel_dyn_section (info
, FALSE
);
9087 && s
->size
> (bfd_vma
)2 * MIPS_ELF_REL_SIZE (output_bfd
))
9089 reldyn_sorting_bfd
= output_bfd
;
9091 if (ABI_64_P (output_bfd
))
9092 qsort ((Elf64_External_Rel
*) s
->contents
+ 1,
9093 s
->reloc_count
- 1, sizeof (Elf64_Mips_External_Rel
),
9094 sort_dynamic_relocs_64
);
9096 qsort ((Elf32_External_Rel
*) s
->contents
+ 1,
9097 s
->reloc_count
- 1, sizeof (Elf32_External_Rel
),
9098 sort_dynamic_relocs
);
9103 if (htab
->is_vxworks
&& htab
->splt
->size
> 0)
9106 mips_vxworks_finish_shared_plt (output_bfd
, info
);
9108 mips_vxworks_finish_exec_plt (output_bfd
, info
);
9114 /* Set ABFD's EF_MIPS_ARCH and EF_MIPS_MACH flags. */
9117 mips_set_isa_flags (bfd
*abfd
)
9121 switch (bfd_get_mach (abfd
))
9124 case bfd_mach_mips3000
:
9125 val
= E_MIPS_ARCH_1
;
9128 case bfd_mach_mips3900
:
9129 val
= E_MIPS_ARCH_1
| E_MIPS_MACH_3900
;
9132 case bfd_mach_mips6000
:
9133 val
= E_MIPS_ARCH_2
;
9136 case bfd_mach_mips4000
:
9137 case bfd_mach_mips4300
:
9138 case bfd_mach_mips4400
:
9139 case bfd_mach_mips4600
:
9140 val
= E_MIPS_ARCH_3
;
9143 case bfd_mach_mips4010
:
9144 val
= E_MIPS_ARCH_3
| E_MIPS_MACH_4010
;
9147 case bfd_mach_mips4100
:
9148 val
= E_MIPS_ARCH_3
| E_MIPS_MACH_4100
;
9151 case bfd_mach_mips4111
:
9152 val
= E_MIPS_ARCH_3
| E_MIPS_MACH_4111
;
9155 case bfd_mach_mips4120
:
9156 val
= E_MIPS_ARCH_3
| E_MIPS_MACH_4120
;
9159 case bfd_mach_mips4650
:
9160 val
= E_MIPS_ARCH_3
| E_MIPS_MACH_4650
;
9163 case bfd_mach_mips5400
:
9164 val
= E_MIPS_ARCH_4
| E_MIPS_MACH_5400
;
9167 case bfd_mach_mips5500
:
9168 val
= E_MIPS_ARCH_4
| E_MIPS_MACH_5500
;
9171 case bfd_mach_mips9000
:
9172 val
= E_MIPS_ARCH_4
| E_MIPS_MACH_9000
;
9175 case bfd_mach_mips5000
:
9176 case bfd_mach_mips7000
:
9177 case bfd_mach_mips8000
:
9178 case bfd_mach_mips10000
:
9179 case bfd_mach_mips12000
:
9180 val
= E_MIPS_ARCH_4
;
9183 case bfd_mach_mips5
:
9184 val
= E_MIPS_ARCH_5
;
9187 case bfd_mach_mips_sb1
:
9188 val
= E_MIPS_ARCH_64
| E_MIPS_MACH_SB1
;
9191 case bfd_mach_mipsisa32
:
9192 val
= E_MIPS_ARCH_32
;
9195 case bfd_mach_mipsisa64
:
9196 val
= E_MIPS_ARCH_64
;
9199 case bfd_mach_mipsisa32r2
:
9200 val
= E_MIPS_ARCH_32R2
;
9203 case bfd_mach_mipsisa64r2
:
9204 val
= E_MIPS_ARCH_64R2
;
9207 elf_elfheader (abfd
)->e_flags
&= ~(EF_MIPS_ARCH
| EF_MIPS_MACH
);
9208 elf_elfheader (abfd
)->e_flags
|= val
;
9213 /* The final processing done just before writing out a MIPS ELF object
9214 file. This gets the MIPS architecture right based on the machine
9215 number. This is used by both the 32-bit and the 64-bit ABI. */
9218 _bfd_mips_elf_final_write_processing (bfd
*abfd
,
9219 bfd_boolean linker ATTRIBUTE_UNUSED
)
9222 Elf_Internal_Shdr
**hdrpp
;
9226 /* Keep the existing EF_MIPS_MACH and EF_MIPS_ARCH flags if the former
9227 is nonzero. This is for compatibility with old objects, which used
9228 a combination of a 32-bit EF_MIPS_ARCH and a 64-bit EF_MIPS_MACH. */
9229 if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_MACH
) == 0)
9230 mips_set_isa_flags (abfd
);
9232 /* Set the sh_info field for .gptab sections and other appropriate
9233 info for each special section. */
9234 for (i
= 1, hdrpp
= elf_elfsections (abfd
) + 1;
9235 i
< elf_numsections (abfd
);
9238 switch ((*hdrpp
)->sh_type
)
9241 case SHT_MIPS_LIBLIST
:
9242 sec
= bfd_get_section_by_name (abfd
, ".dynstr");
9244 (*hdrpp
)->sh_link
= elf_section_data (sec
)->this_idx
;
9247 case SHT_MIPS_GPTAB
:
9248 BFD_ASSERT ((*hdrpp
)->bfd_section
!= NULL
);
9249 name
= bfd_get_section_name (abfd
, (*hdrpp
)->bfd_section
);
9250 BFD_ASSERT (name
!= NULL
9251 && CONST_STRNEQ (name
, ".gptab."));
9252 sec
= bfd_get_section_by_name (abfd
, name
+ sizeof ".gptab" - 1);
9253 BFD_ASSERT (sec
!= NULL
);
9254 (*hdrpp
)->sh_info
= elf_section_data (sec
)->this_idx
;
9257 case SHT_MIPS_CONTENT
:
9258 BFD_ASSERT ((*hdrpp
)->bfd_section
!= NULL
);
9259 name
= bfd_get_section_name (abfd
, (*hdrpp
)->bfd_section
);
9260 BFD_ASSERT (name
!= NULL
9261 && CONST_STRNEQ (name
, ".MIPS.content"));
9262 sec
= bfd_get_section_by_name (abfd
,
9263 name
+ sizeof ".MIPS.content" - 1);
9264 BFD_ASSERT (sec
!= NULL
);
9265 (*hdrpp
)->sh_link
= elf_section_data (sec
)->this_idx
;
9268 case SHT_MIPS_SYMBOL_LIB
:
9269 sec
= bfd_get_section_by_name (abfd
, ".dynsym");
9271 (*hdrpp
)->sh_link
= elf_section_data (sec
)->this_idx
;
9272 sec
= bfd_get_section_by_name (abfd
, ".liblist");
9274 (*hdrpp
)->sh_info
= elf_section_data (sec
)->this_idx
;
9277 case SHT_MIPS_EVENTS
:
9278 BFD_ASSERT ((*hdrpp
)->bfd_section
!= NULL
);
9279 name
= bfd_get_section_name (abfd
, (*hdrpp
)->bfd_section
);
9280 BFD_ASSERT (name
!= NULL
);
9281 if (CONST_STRNEQ (name
, ".MIPS.events"))
9282 sec
= bfd_get_section_by_name (abfd
,
9283 name
+ sizeof ".MIPS.events" - 1);
9286 BFD_ASSERT (CONST_STRNEQ (name
, ".MIPS.post_rel"));
9287 sec
= bfd_get_section_by_name (abfd
,
9289 + sizeof ".MIPS.post_rel" - 1));
9291 BFD_ASSERT (sec
!= NULL
);
9292 (*hdrpp
)->sh_link
= elf_section_data (sec
)->this_idx
;
9299 /* When creating an IRIX5 executable, we need REGINFO and RTPROC
9303 _bfd_mips_elf_additional_program_headers (bfd
*abfd
,
9304 struct bfd_link_info
*info ATTRIBUTE_UNUSED
)
9309 /* See if we need a PT_MIPS_REGINFO segment. */
9310 s
= bfd_get_section_by_name (abfd
, ".reginfo");
9311 if (s
&& (s
->flags
& SEC_LOAD
))
9314 /* See if we need a PT_MIPS_OPTIONS segment. */
9315 if (IRIX_COMPAT (abfd
) == ict_irix6
9316 && bfd_get_section_by_name (abfd
,
9317 MIPS_ELF_OPTIONS_SECTION_NAME (abfd
)))
9320 /* See if we need a PT_MIPS_RTPROC segment. */
9321 if (IRIX_COMPAT (abfd
) == ict_irix5
9322 && bfd_get_section_by_name (abfd
, ".dynamic")
9323 && bfd_get_section_by_name (abfd
, ".mdebug"))
9326 /* Allocate a PT_NULL header in dynamic objects. See
9327 _bfd_mips_elf_modify_segment_map for details. */
9328 if (!SGI_COMPAT (abfd
)
9329 && bfd_get_section_by_name (abfd
, ".dynamic"))
9335 /* Modify the segment map for an IRIX5 executable. */
9338 _bfd_mips_elf_modify_segment_map (bfd
*abfd
,
9339 struct bfd_link_info
*info ATTRIBUTE_UNUSED
)
9342 struct elf_segment_map
*m
, **pm
;
9345 /* If there is a .reginfo section, we need a PT_MIPS_REGINFO
9347 s
= bfd_get_section_by_name (abfd
, ".reginfo");
9348 if (s
!= NULL
&& (s
->flags
& SEC_LOAD
) != 0)
9350 for (m
= elf_tdata (abfd
)->segment_map
; m
!= NULL
; m
= m
->next
)
9351 if (m
->p_type
== PT_MIPS_REGINFO
)
9356 m
= bfd_zalloc (abfd
, amt
);
9360 m
->p_type
= PT_MIPS_REGINFO
;
9364 /* We want to put it after the PHDR and INTERP segments. */
9365 pm
= &elf_tdata (abfd
)->segment_map
;
9367 && ((*pm
)->p_type
== PT_PHDR
9368 || (*pm
)->p_type
== PT_INTERP
))
9376 /* For IRIX 6, we don't have .mdebug sections, nor does anything but
9377 .dynamic end up in PT_DYNAMIC. However, we do have to insert a
9378 PT_MIPS_OPTIONS segment immediately following the program header
9381 /* On non-IRIX6 new abi, we'll have already created a segment
9382 for this section, so don't create another. I'm not sure this
9383 is not also the case for IRIX 6, but I can't test it right
9385 && IRIX_COMPAT (abfd
) == ict_irix6
)
9387 for (s
= abfd
->sections
; s
; s
= s
->next
)
9388 if (elf_section_data (s
)->this_hdr
.sh_type
== SHT_MIPS_OPTIONS
)
9393 struct elf_segment_map
*options_segment
;
9395 pm
= &elf_tdata (abfd
)->segment_map
;
9397 && ((*pm
)->p_type
== PT_PHDR
9398 || (*pm
)->p_type
== PT_INTERP
))
9401 if (*pm
== NULL
|| (*pm
)->p_type
!= PT_MIPS_OPTIONS
)
9403 amt
= sizeof (struct elf_segment_map
);
9404 options_segment
= bfd_zalloc (abfd
, amt
);
9405 options_segment
->next
= *pm
;
9406 options_segment
->p_type
= PT_MIPS_OPTIONS
;
9407 options_segment
->p_flags
= PF_R
;
9408 options_segment
->p_flags_valid
= TRUE
;
9409 options_segment
->count
= 1;
9410 options_segment
->sections
[0] = s
;
9411 *pm
= options_segment
;
9417 if (IRIX_COMPAT (abfd
) == ict_irix5
)
9419 /* If there are .dynamic and .mdebug sections, we make a room
9420 for the RTPROC header. FIXME: Rewrite without section names. */
9421 if (bfd_get_section_by_name (abfd
, ".interp") == NULL
9422 && bfd_get_section_by_name (abfd
, ".dynamic") != NULL
9423 && bfd_get_section_by_name (abfd
, ".mdebug") != NULL
)
9425 for (m
= elf_tdata (abfd
)->segment_map
; m
!= NULL
; m
= m
->next
)
9426 if (m
->p_type
== PT_MIPS_RTPROC
)
9431 m
= bfd_zalloc (abfd
, amt
);
9435 m
->p_type
= PT_MIPS_RTPROC
;
9437 s
= bfd_get_section_by_name (abfd
, ".rtproc");
9442 m
->p_flags_valid
= 1;
9450 /* We want to put it after the DYNAMIC segment. */
9451 pm
= &elf_tdata (abfd
)->segment_map
;
9452 while (*pm
!= NULL
&& (*pm
)->p_type
!= PT_DYNAMIC
)
9462 /* On IRIX5, the PT_DYNAMIC segment includes the .dynamic,
9463 .dynstr, .dynsym, and .hash sections, and everything in
9465 for (pm
= &elf_tdata (abfd
)->segment_map
; *pm
!= NULL
;
9467 if ((*pm
)->p_type
== PT_DYNAMIC
)
9470 if (m
!= NULL
&& IRIX_COMPAT (abfd
) == ict_none
)
9472 /* For a normal mips executable the permissions for the PT_DYNAMIC
9473 segment are read, write and execute. We do that here since
9474 the code in elf.c sets only the read permission. This matters
9475 sometimes for the dynamic linker. */
9476 if (bfd_get_section_by_name (abfd
, ".dynamic") != NULL
)
9478 m
->p_flags
= PF_R
| PF_W
| PF_X
;
9479 m
->p_flags_valid
= 1;
9482 /* GNU/Linux binaries do not need the extended PT_DYNAMIC section.
9483 glibc's dynamic linker has traditionally derived the number of
9484 tags from the p_filesz field, and sometimes allocates stack
9485 arrays of that size. An overly-big PT_DYNAMIC segment can
9486 be actively harmful in such cases. Making PT_DYNAMIC contain
9487 other sections can also make life hard for the prelinker,
9488 which might move one of the other sections to a different
9490 if (SGI_COMPAT (abfd
)
9493 && strcmp (m
->sections
[0]->name
, ".dynamic") == 0)
9495 static const char *sec_names
[] =
9497 ".dynamic", ".dynstr", ".dynsym", ".hash"
9501 struct elf_segment_map
*n
;
9505 for (i
= 0; i
< sizeof sec_names
/ sizeof sec_names
[0]; i
++)
9507 s
= bfd_get_section_by_name (abfd
, sec_names
[i
]);
9508 if (s
!= NULL
&& (s
->flags
& SEC_LOAD
) != 0)
9515 if (high
< s
->vma
+ sz
)
9521 for (s
= abfd
->sections
; s
!= NULL
; s
= s
->next
)
9522 if ((s
->flags
& SEC_LOAD
) != 0
9524 && s
->vma
+ s
->size
<= high
)
9527 amt
= sizeof *n
+ (bfd_size_type
) (c
- 1) * sizeof (asection
*);
9528 n
= bfd_zalloc (abfd
, amt
);
9535 for (s
= abfd
->sections
; s
!= NULL
; s
= s
->next
)
9537 if ((s
->flags
& SEC_LOAD
) != 0
9539 && s
->vma
+ s
->size
<= high
)
9550 /* Allocate a spare program header in dynamic objects so that tools
9551 like the prelinker can add an extra PT_LOAD entry.
9553 If the prelinker needs to make room for a new PT_LOAD entry, its
9554 standard procedure is to move the first (read-only) sections into
9555 the new (writable) segment. However, the MIPS ABI requires
9556 .dynamic to be in a read-only segment, and the section will often
9557 start within sizeof (ElfNN_Phdr) bytes of the last program header.
9559 Although the prelinker could in principle move .dynamic to a
9560 writable segment, it seems better to allocate a spare program
9561 header instead, and avoid the need to move any sections.
9562 There is a long tradition of allocating spare dynamic tags,
9563 so allocating a spare program header seems like a natural
9565 if (!SGI_COMPAT (abfd
)
9566 && bfd_get_section_by_name (abfd
, ".dynamic"))
9568 for (pm
= &elf_tdata (abfd
)->segment_map
; *pm
!= NULL
; pm
= &(*pm
)->next
)
9569 if ((*pm
)->p_type
== PT_NULL
)
9573 m
= bfd_zalloc (abfd
, sizeof (*m
));
9577 m
->p_type
= PT_NULL
;
9585 /* Return the section that should be marked against GC for a given
9589 _bfd_mips_elf_gc_mark_hook (asection
*sec
,
9590 struct bfd_link_info
*info
,
9591 Elf_Internal_Rela
*rel
,
9592 struct elf_link_hash_entry
*h
,
9593 Elf_Internal_Sym
*sym
)
9595 /* ??? Do mips16 stub sections need to be handled special? */
9598 switch (ELF_R_TYPE (sec
->owner
, rel
->r_info
))
9600 case R_MIPS_GNU_VTINHERIT
:
9601 case R_MIPS_GNU_VTENTRY
:
9605 return _bfd_elf_gc_mark_hook (sec
, info
, rel
, h
, sym
);
9608 /* Update the got entry reference counts for the section being removed. */
9611 _bfd_mips_elf_gc_sweep_hook (bfd
*abfd ATTRIBUTE_UNUSED
,
9612 struct bfd_link_info
*info ATTRIBUTE_UNUSED
,
9613 asection
*sec ATTRIBUTE_UNUSED
,
9614 const Elf_Internal_Rela
*relocs ATTRIBUTE_UNUSED
)
9617 Elf_Internal_Shdr
*symtab_hdr
;
9618 struct elf_link_hash_entry
**sym_hashes
;
9619 bfd_signed_vma
*local_got_refcounts
;
9620 const Elf_Internal_Rela
*rel
, *relend
;
9621 unsigned long r_symndx
;
9622 struct elf_link_hash_entry
*h
;
9624 symtab_hdr
= &elf_tdata (abfd
)->symtab_hdr
;
9625 sym_hashes
= elf_sym_hashes (abfd
);
9626 local_got_refcounts
= elf_local_got_refcounts (abfd
);
9628 relend
= relocs
+ sec
->reloc_count
;
9629 for (rel
= relocs
; rel
< relend
; rel
++)
9630 switch (ELF_R_TYPE (abfd
, rel
->r_info
))
9634 case R_MIPS_CALL_HI16
:
9635 case R_MIPS_CALL_LO16
:
9636 case R_MIPS_GOT_HI16
:
9637 case R_MIPS_GOT_LO16
:
9638 case R_MIPS_GOT_DISP
:
9639 case R_MIPS_GOT_PAGE
:
9640 case R_MIPS_GOT_OFST
:
9641 /* ??? It would seem that the existing MIPS code does no sort
9642 of reference counting or whatnot on its GOT and PLT entries,
9643 so it is not possible to garbage collect them at this time. */
9654 /* Copy data from a MIPS ELF indirect symbol to its direct symbol,
9655 hiding the old indirect symbol. Process additional relocation
9656 information. Also called for weakdefs, in which case we just let
9657 _bfd_elf_link_hash_copy_indirect copy the flags for us. */
9660 _bfd_mips_elf_copy_indirect_symbol (struct bfd_link_info
*info
,
9661 struct elf_link_hash_entry
*dir
,
9662 struct elf_link_hash_entry
*ind
)
9664 struct mips_elf_link_hash_entry
*dirmips
, *indmips
;
9666 _bfd_elf_link_hash_copy_indirect (info
, dir
, ind
);
9668 if (ind
->root
.type
!= bfd_link_hash_indirect
)
9671 dirmips
= (struct mips_elf_link_hash_entry
*) dir
;
9672 indmips
= (struct mips_elf_link_hash_entry
*) ind
;
9673 dirmips
->possibly_dynamic_relocs
+= indmips
->possibly_dynamic_relocs
;
9674 if (indmips
->readonly_reloc
)
9675 dirmips
->readonly_reloc
= TRUE
;
9676 if (indmips
->no_fn_stub
)
9677 dirmips
->no_fn_stub
= TRUE
;
9679 if (dirmips
->tls_type
== 0)
9680 dirmips
->tls_type
= indmips
->tls_type
;
9684 _bfd_mips_elf_hide_symbol (struct bfd_link_info
*info
,
9685 struct elf_link_hash_entry
*entry
,
9686 bfd_boolean force_local
)
9690 struct mips_got_info
*g
;
9691 struct mips_elf_link_hash_entry
*h
;
9693 h
= (struct mips_elf_link_hash_entry
*) entry
;
9694 if (h
->forced_local
)
9696 h
->forced_local
= force_local
;
9698 dynobj
= elf_hash_table (info
)->dynobj
;
9699 if (dynobj
!= NULL
&& force_local
&& h
->root
.type
!= STT_TLS
9700 && (got
= mips_elf_got_section (dynobj
, TRUE
)) != NULL
9701 && (g
= mips_elf_section_data (got
)->u
.got_info
) != NULL
)
9705 struct mips_got_entry e
;
9706 struct mips_got_info
*gg
= g
;
9708 /* Since we're turning what used to be a global symbol into a
9709 local one, bump up the number of local entries of each GOT
9710 that had an entry for it. This will automatically decrease
9711 the number of global entries, since global_gotno is actually
9712 the upper limit of global entries. */
9718 for (g
= g
->next
; g
!= gg
; g
= g
->next
)
9719 if (htab_find (g
->got_entries
, &e
))
9721 BFD_ASSERT (g
->global_gotno
> 0);
9726 /* If this was a global symbol forced into the primary GOT, we
9727 no longer need an entry for it. We can't release the entry
9728 at this point, but we must at least stop counting it as one
9729 of the symbols that required a forced got entry. */
9730 if (h
->root
.got
.offset
== 2)
9732 BFD_ASSERT (gg
->assigned_gotno
> 0);
9733 gg
->assigned_gotno
--;
9736 else if (g
->global_gotno
== 0 && g
->global_gotsym
== NULL
)
9737 /* If we haven't got through GOT allocation yet, just bump up the
9738 number of local entries, as this symbol won't be counted as
9741 else if (h
->root
.got
.offset
== 1)
9743 /* If we're past non-multi-GOT allocation and this symbol had
9744 been marked for a global got entry, give it a local entry
9746 BFD_ASSERT (g
->global_gotno
> 0);
9752 _bfd_elf_link_hash_hide_symbol (info
, &h
->root
, force_local
);
9758 _bfd_mips_elf_discard_info (bfd
*abfd
, struct elf_reloc_cookie
*cookie
,
9759 struct bfd_link_info
*info
)
9762 bfd_boolean ret
= FALSE
;
9763 unsigned char *tdata
;
9766 o
= bfd_get_section_by_name (abfd
, ".pdr");
9771 if (o
->size
% PDR_SIZE
!= 0)
9773 if (o
->output_section
!= NULL
9774 && bfd_is_abs_section (o
->output_section
))
9777 tdata
= bfd_zmalloc (o
->size
/ PDR_SIZE
);
9781 cookie
->rels
= _bfd_elf_link_read_relocs (abfd
, o
, NULL
, NULL
,
9789 cookie
->rel
= cookie
->rels
;
9790 cookie
->relend
= cookie
->rels
+ o
->reloc_count
;
9792 for (i
= 0, skip
= 0; i
< o
->size
/ PDR_SIZE
; i
++)
9794 if (bfd_elf_reloc_symbol_deleted_p (i
* PDR_SIZE
, cookie
))
9803 mips_elf_section_data (o
)->u
.tdata
= tdata
;
9804 o
->size
-= skip
* PDR_SIZE
;
9810 if (! info
->keep_memory
)
9811 free (cookie
->rels
);
9817 _bfd_mips_elf_ignore_discarded_relocs (asection
*sec
)
9819 if (strcmp (sec
->name
, ".pdr") == 0)
9825 _bfd_mips_elf_write_section (bfd
*output_bfd
,
9826 struct bfd_link_info
*link_info ATTRIBUTE_UNUSED
,
9827 asection
*sec
, bfd_byte
*contents
)
9829 bfd_byte
*to
, *from
, *end
;
9832 if (strcmp (sec
->name
, ".pdr") != 0)
9835 if (mips_elf_section_data (sec
)->u
.tdata
== NULL
)
9839 end
= contents
+ sec
->size
;
9840 for (from
= contents
, i
= 0;
9842 from
+= PDR_SIZE
, i
++)
9844 if ((mips_elf_section_data (sec
)->u
.tdata
)[i
] == 1)
9847 memcpy (to
, from
, PDR_SIZE
);
9850 bfd_set_section_contents (output_bfd
, sec
->output_section
, contents
,
9851 sec
->output_offset
, sec
->size
);
9855 /* MIPS ELF uses a special find_nearest_line routine in order the
9856 handle the ECOFF debugging information. */
9858 struct mips_elf_find_line
9860 struct ecoff_debug_info d
;
9861 struct ecoff_find_line i
;
9865 _bfd_mips_elf_find_nearest_line (bfd
*abfd
, asection
*section
,
9866 asymbol
**symbols
, bfd_vma offset
,
9867 const char **filename_ptr
,
9868 const char **functionname_ptr
,
9869 unsigned int *line_ptr
)
9873 if (_bfd_dwarf1_find_nearest_line (abfd
, section
, symbols
, offset
,
9874 filename_ptr
, functionname_ptr
,
9878 if (_bfd_dwarf2_find_nearest_line (abfd
, section
, symbols
, offset
,
9879 filename_ptr
, functionname_ptr
,
9880 line_ptr
, ABI_64_P (abfd
) ? 8 : 0,
9881 &elf_tdata (abfd
)->dwarf2_find_line_info
))
9884 msec
= bfd_get_section_by_name (abfd
, ".mdebug");
9888 struct mips_elf_find_line
*fi
;
9889 const struct ecoff_debug_swap
* const swap
=
9890 get_elf_backend_data (abfd
)->elf_backend_ecoff_debug_swap
;
9892 /* If we are called during a link, mips_elf_final_link may have
9893 cleared the SEC_HAS_CONTENTS field. We force it back on here
9894 if appropriate (which it normally will be). */
9895 origflags
= msec
->flags
;
9896 if (elf_section_data (msec
)->this_hdr
.sh_type
!= SHT_NOBITS
)
9897 msec
->flags
|= SEC_HAS_CONTENTS
;
9899 fi
= elf_tdata (abfd
)->find_line_info
;
9902 bfd_size_type external_fdr_size
;
9905 struct fdr
*fdr_ptr
;
9906 bfd_size_type amt
= sizeof (struct mips_elf_find_line
);
9908 fi
= bfd_zalloc (abfd
, amt
);
9911 msec
->flags
= origflags
;
9915 if (! _bfd_mips_elf_read_ecoff_info (abfd
, msec
, &fi
->d
))
9917 msec
->flags
= origflags
;
9921 /* Swap in the FDR information. */
9922 amt
= fi
->d
.symbolic_header
.ifdMax
* sizeof (struct fdr
);
9923 fi
->d
.fdr
= bfd_alloc (abfd
, amt
);
9924 if (fi
->d
.fdr
== NULL
)
9926 msec
->flags
= origflags
;
9929 external_fdr_size
= swap
->external_fdr_size
;
9930 fdr_ptr
= fi
->d
.fdr
;
9931 fraw_src
= (char *) fi
->d
.external_fdr
;
9932 fraw_end
= (fraw_src
9933 + fi
->d
.symbolic_header
.ifdMax
* external_fdr_size
);
9934 for (; fraw_src
< fraw_end
; fraw_src
+= external_fdr_size
, fdr_ptr
++)
9935 (*swap
->swap_fdr_in
) (abfd
, fraw_src
, fdr_ptr
);
9937 elf_tdata (abfd
)->find_line_info
= fi
;
9939 /* Note that we don't bother to ever free this information.
9940 find_nearest_line is either called all the time, as in
9941 objdump -l, so the information should be saved, or it is
9942 rarely called, as in ld error messages, so the memory
9943 wasted is unimportant. Still, it would probably be a
9944 good idea for free_cached_info to throw it away. */
9947 if (_bfd_ecoff_locate_line (abfd
, section
, offset
, &fi
->d
, swap
,
9948 &fi
->i
, filename_ptr
, functionname_ptr
,
9951 msec
->flags
= origflags
;
9955 msec
->flags
= origflags
;
9958 /* Fall back on the generic ELF find_nearest_line routine. */
9960 return _bfd_elf_find_nearest_line (abfd
, section
, symbols
, offset
,
9961 filename_ptr
, functionname_ptr
,
9966 _bfd_mips_elf_find_inliner_info (bfd
*abfd
,
9967 const char **filename_ptr
,
9968 const char **functionname_ptr
,
9969 unsigned int *line_ptr
)
9972 found
= _bfd_dwarf2_find_inliner_info (abfd
, filename_ptr
,
9973 functionname_ptr
, line_ptr
,
9974 & elf_tdata (abfd
)->dwarf2_find_line_info
);
9979 /* When are writing out the .options or .MIPS.options section,
9980 remember the bytes we are writing out, so that we can install the
9981 GP value in the section_processing routine. */
9984 _bfd_mips_elf_set_section_contents (bfd
*abfd
, sec_ptr section
,
9985 const void *location
,
9986 file_ptr offset
, bfd_size_type count
)
9988 if (MIPS_ELF_OPTIONS_SECTION_NAME_P (section
->name
))
9992 if (elf_section_data (section
) == NULL
)
9994 bfd_size_type amt
= sizeof (struct bfd_elf_section_data
);
9995 section
->used_by_bfd
= bfd_zalloc (abfd
, amt
);
9996 if (elf_section_data (section
) == NULL
)
9999 c
= mips_elf_section_data (section
)->u
.tdata
;
10002 c
= bfd_zalloc (abfd
, section
->size
);
10005 mips_elf_section_data (section
)->u
.tdata
= c
;
10008 memcpy (c
+ offset
, location
, count
);
10011 return _bfd_elf_set_section_contents (abfd
, section
, location
, offset
,
10015 /* This is almost identical to bfd_generic_get_... except that some
10016 MIPS relocations need to be handled specially. Sigh. */
10019 _bfd_elf_mips_get_relocated_section_contents
10021 struct bfd_link_info
*link_info
,
10022 struct bfd_link_order
*link_order
,
10024 bfd_boolean relocatable
,
10027 /* Get enough memory to hold the stuff */
10028 bfd
*input_bfd
= link_order
->u
.indirect
.section
->owner
;
10029 asection
*input_section
= link_order
->u
.indirect
.section
;
10032 long reloc_size
= bfd_get_reloc_upper_bound (input_bfd
, input_section
);
10033 arelent
**reloc_vector
= NULL
;
10036 if (reloc_size
< 0)
10039 reloc_vector
= bfd_malloc (reloc_size
);
10040 if (reloc_vector
== NULL
&& reloc_size
!= 0)
10043 /* read in the section */
10044 sz
= input_section
->rawsize
? input_section
->rawsize
: input_section
->size
;
10045 if (!bfd_get_section_contents (input_bfd
, input_section
, data
, 0, sz
))
10048 reloc_count
= bfd_canonicalize_reloc (input_bfd
,
10052 if (reloc_count
< 0)
10055 if (reloc_count
> 0)
10060 bfd_vma gp
= 0x12345678; /* initialize just to shut gcc up */
10063 struct bfd_hash_entry
*h
;
10064 struct bfd_link_hash_entry
*lh
;
10065 /* Skip all this stuff if we aren't mixing formats. */
10066 if (abfd
&& input_bfd
10067 && abfd
->xvec
== input_bfd
->xvec
)
10071 h
= bfd_hash_lookup (&link_info
->hash
->table
, "_gp", FALSE
, FALSE
);
10072 lh
= (struct bfd_link_hash_entry
*) h
;
10079 case bfd_link_hash_undefined
:
10080 case bfd_link_hash_undefweak
:
10081 case bfd_link_hash_common
:
10084 case bfd_link_hash_defined
:
10085 case bfd_link_hash_defweak
:
10087 gp
= lh
->u
.def
.value
;
10089 case bfd_link_hash_indirect
:
10090 case bfd_link_hash_warning
:
10092 /* @@FIXME ignoring warning for now */
10094 case bfd_link_hash_new
:
10103 for (parent
= reloc_vector
; *parent
!= NULL
; parent
++)
10105 char *error_message
= NULL
;
10106 bfd_reloc_status_type r
;
10108 /* Specific to MIPS: Deal with relocation types that require
10109 knowing the gp of the output bfd. */
10110 asymbol
*sym
= *(*parent
)->sym_ptr_ptr
;
10112 /* If we've managed to find the gp and have a special
10113 function for the relocation then go ahead, else default
10114 to the generic handling. */
10116 && (*parent
)->howto
->special_function
10117 == _bfd_mips_elf32_gprel16_reloc
)
10118 r
= _bfd_mips_elf_gprel16_with_gp (input_bfd
, sym
, *parent
,
10119 input_section
, relocatable
,
10122 r
= bfd_perform_relocation (input_bfd
, *parent
, data
,
10124 relocatable
? abfd
: NULL
,
10129 asection
*os
= input_section
->output_section
;
10131 /* A partial link, so keep the relocs */
10132 os
->orelocation
[os
->reloc_count
] = *parent
;
10136 if (r
!= bfd_reloc_ok
)
10140 case bfd_reloc_undefined
:
10141 if (!((*link_info
->callbacks
->undefined_symbol
)
10142 (link_info
, bfd_asymbol_name (*(*parent
)->sym_ptr_ptr
),
10143 input_bfd
, input_section
, (*parent
)->address
, TRUE
)))
10146 case bfd_reloc_dangerous
:
10147 BFD_ASSERT (error_message
!= NULL
);
10148 if (!((*link_info
->callbacks
->reloc_dangerous
)
10149 (link_info
, error_message
, input_bfd
, input_section
,
10150 (*parent
)->address
)))
10153 case bfd_reloc_overflow
:
10154 if (!((*link_info
->callbacks
->reloc_overflow
)
10156 bfd_asymbol_name (*(*parent
)->sym_ptr_ptr
),
10157 (*parent
)->howto
->name
, (*parent
)->addend
,
10158 input_bfd
, input_section
, (*parent
)->address
)))
10161 case bfd_reloc_outofrange
:
10170 if (reloc_vector
!= NULL
)
10171 free (reloc_vector
);
10175 if (reloc_vector
!= NULL
)
10176 free (reloc_vector
);
10180 /* Create a MIPS ELF linker hash table. */
10182 struct bfd_link_hash_table
*
10183 _bfd_mips_elf_link_hash_table_create (bfd
*abfd
)
10185 struct mips_elf_link_hash_table
*ret
;
10186 bfd_size_type amt
= sizeof (struct mips_elf_link_hash_table
);
10188 ret
= bfd_malloc (amt
);
10192 if (!_bfd_elf_link_hash_table_init (&ret
->root
, abfd
,
10193 mips_elf_link_hash_newfunc
,
10194 sizeof (struct mips_elf_link_hash_entry
)))
10201 /* We no longer use this. */
10202 for (i
= 0; i
< SIZEOF_MIPS_DYNSYM_SECNAMES
; i
++)
10203 ret
->dynsym_sec_strindex
[i
] = (bfd_size_type
) -1;
10205 ret
->procedure_count
= 0;
10206 ret
->compact_rel_size
= 0;
10207 ret
->use_rld_obj_head
= FALSE
;
10208 ret
->rld_value
= 0;
10209 ret
->mips16_stubs_seen
= FALSE
;
10210 ret
->is_vxworks
= FALSE
;
10211 ret
->srelbss
= NULL
;
10212 ret
->sdynbss
= NULL
;
10213 ret
->srelplt
= NULL
;
10214 ret
->srelplt2
= NULL
;
10215 ret
->sgotplt
= NULL
;
10217 ret
->plt_header_size
= 0;
10218 ret
->plt_entry_size
= 0;
10219 ret
->function_stub_size
= 0;
10221 return &ret
->root
.root
;
10224 /* Likewise, but indicate that the target is VxWorks. */
10226 struct bfd_link_hash_table
*
10227 _bfd_mips_vxworks_link_hash_table_create (bfd
*abfd
)
10229 struct bfd_link_hash_table
*ret
;
10231 ret
= _bfd_mips_elf_link_hash_table_create (abfd
);
10234 struct mips_elf_link_hash_table
*htab
;
10236 htab
= (struct mips_elf_link_hash_table
*) ret
;
10237 htab
->is_vxworks
= 1;
10242 /* We need to use a special link routine to handle the .reginfo and
10243 the .mdebug sections. We need to merge all instances of these
10244 sections together, not write them all out sequentially. */
10247 _bfd_mips_elf_final_link (bfd
*abfd
, struct bfd_link_info
*info
)
10250 struct bfd_link_order
*p
;
10251 asection
*reginfo_sec
, *mdebug_sec
, *gptab_data_sec
, *gptab_bss_sec
;
10252 asection
*rtproc_sec
;
10253 Elf32_RegInfo reginfo
;
10254 struct ecoff_debug_info debug
;
10255 const struct elf_backend_data
*bed
= get_elf_backend_data (abfd
);
10256 const struct ecoff_debug_swap
*swap
= bed
->elf_backend_ecoff_debug_swap
;
10257 HDRR
*symhdr
= &debug
.symbolic_header
;
10258 void *mdebug_handle
= NULL
;
10263 struct mips_elf_link_hash_table
*htab
;
10265 static const char * const secname
[] =
10267 ".text", ".init", ".fini", ".data",
10268 ".rodata", ".sdata", ".sbss", ".bss"
10270 static const int sc
[] =
10272 scText
, scInit
, scFini
, scData
,
10273 scRData
, scSData
, scSBss
, scBss
10276 /* We'd carefully arranged the dynamic symbol indices, and then the
10277 generic size_dynamic_sections renumbered them out from under us.
10278 Rather than trying somehow to prevent the renumbering, just do
10280 htab
= mips_elf_hash_table (info
);
10281 if (elf_hash_table (info
)->dynamic_sections_created
)
10285 struct mips_got_info
*g
;
10286 bfd_size_type dynsecsymcount
;
10288 /* When we resort, we must tell mips_elf_sort_hash_table what
10289 the lowest index it may use is. That's the number of section
10290 symbols we're going to add. The generic ELF linker only
10291 adds these symbols when building a shared object. Note that
10292 we count the sections after (possibly) removing the .options
10295 dynsecsymcount
= count_section_dynsyms (abfd
, info
);
10296 if (! mips_elf_sort_hash_table (info
, dynsecsymcount
+ 1))
10299 /* Make sure we didn't grow the global .got region. */
10300 dynobj
= elf_hash_table (info
)->dynobj
;
10301 got
= mips_elf_got_section (dynobj
, FALSE
);
10302 g
= mips_elf_section_data (got
)->u
.got_info
;
10304 if (g
->global_gotsym
!= NULL
)
10305 BFD_ASSERT ((elf_hash_table (info
)->dynsymcount
10306 - g
->global_gotsym
->dynindx
)
10307 <= g
->global_gotno
);
10310 /* Get a value for the GP register. */
10311 if (elf_gp (abfd
) == 0)
10313 struct bfd_link_hash_entry
*h
;
10315 h
= bfd_link_hash_lookup (info
->hash
, "_gp", FALSE
, FALSE
, TRUE
);
10316 if (h
!= NULL
&& h
->type
== bfd_link_hash_defined
)
10317 elf_gp (abfd
) = (h
->u
.def
.value
10318 + h
->u
.def
.section
->output_section
->vma
10319 + h
->u
.def
.section
->output_offset
);
10320 else if (htab
->is_vxworks
10321 && (h
= bfd_link_hash_lookup (info
->hash
,
10322 "_GLOBAL_OFFSET_TABLE_",
10323 FALSE
, FALSE
, TRUE
))
10324 && h
->type
== bfd_link_hash_defined
)
10325 elf_gp (abfd
) = (h
->u
.def
.section
->output_section
->vma
10326 + h
->u
.def
.section
->output_offset
10328 else if (info
->relocatable
)
10330 bfd_vma lo
= MINUS_ONE
;
10332 /* Find the GP-relative section with the lowest offset. */
10333 for (o
= abfd
->sections
; o
!= NULL
; o
= o
->next
)
10335 && (elf_section_data (o
)->this_hdr
.sh_flags
& SHF_MIPS_GPREL
))
10338 /* And calculate GP relative to that. */
10339 elf_gp (abfd
) = lo
+ ELF_MIPS_GP_OFFSET (info
);
10343 /* If the relocate_section function needs to do a reloc
10344 involving the GP value, it should make a reloc_dangerous
10345 callback to warn that GP is not defined. */
10349 /* Go through the sections and collect the .reginfo and .mdebug
10351 reginfo_sec
= NULL
;
10353 gptab_data_sec
= NULL
;
10354 gptab_bss_sec
= NULL
;
10355 for (o
= abfd
->sections
; o
!= NULL
; o
= o
->next
)
10357 if (strcmp (o
->name
, ".reginfo") == 0)
10359 memset (®info
, 0, sizeof reginfo
);
10361 /* We have found the .reginfo section in the output file.
10362 Look through all the link_orders comprising it and merge
10363 the information together. */
10364 for (p
= o
->map_head
.link_order
; p
!= NULL
; p
= p
->next
)
10366 asection
*input_section
;
10368 Elf32_External_RegInfo ext
;
10371 if (p
->type
!= bfd_indirect_link_order
)
10373 if (p
->type
== bfd_data_link_order
)
10378 input_section
= p
->u
.indirect
.section
;
10379 input_bfd
= input_section
->owner
;
10381 if (! bfd_get_section_contents (input_bfd
, input_section
,
10382 &ext
, 0, sizeof ext
))
10385 bfd_mips_elf32_swap_reginfo_in (input_bfd
, &ext
, &sub
);
10387 reginfo
.ri_gprmask
|= sub
.ri_gprmask
;
10388 reginfo
.ri_cprmask
[0] |= sub
.ri_cprmask
[0];
10389 reginfo
.ri_cprmask
[1] |= sub
.ri_cprmask
[1];
10390 reginfo
.ri_cprmask
[2] |= sub
.ri_cprmask
[2];
10391 reginfo
.ri_cprmask
[3] |= sub
.ri_cprmask
[3];
10393 /* ri_gp_value is set by the function
10394 mips_elf32_section_processing when the section is
10395 finally written out. */
10397 /* Hack: reset the SEC_HAS_CONTENTS flag so that
10398 elf_link_input_bfd ignores this section. */
10399 input_section
->flags
&= ~SEC_HAS_CONTENTS
;
10402 /* Size has been set in _bfd_mips_elf_always_size_sections. */
10403 BFD_ASSERT(o
->size
== sizeof (Elf32_External_RegInfo
));
10405 /* Skip this section later on (I don't think this currently
10406 matters, but someday it might). */
10407 o
->map_head
.link_order
= NULL
;
10412 if (strcmp (o
->name
, ".mdebug") == 0)
10414 struct extsym_info einfo
;
10417 /* We have found the .mdebug section in the output file.
10418 Look through all the link_orders comprising it and merge
10419 the information together. */
10420 symhdr
->magic
= swap
->sym_magic
;
10421 /* FIXME: What should the version stamp be? */
10422 symhdr
->vstamp
= 0;
10423 symhdr
->ilineMax
= 0;
10424 symhdr
->cbLine
= 0;
10425 symhdr
->idnMax
= 0;
10426 symhdr
->ipdMax
= 0;
10427 symhdr
->isymMax
= 0;
10428 symhdr
->ioptMax
= 0;
10429 symhdr
->iauxMax
= 0;
10430 symhdr
->issMax
= 0;
10431 symhdr
->issExtMax
= 0;
10432 symhdr
->ifdMax
= 0;
10434 symhdr
->iextMax
= 0;
10436 /* We accumulate the debugging information itself in the
10437 debug_info structure. */
10439 debug
.external_dnr
= NULL
;
10440 debug
.external_pdr
= NULL
;
10441 debug
.external_sym
= NULL
;
10442 debug
.external_opt
= NULL
;
10443 debug
.external_aux
= NULL
;
10445 debug
.ssext
= debug
.ssext_end
= NULL
;
10446 debug
.external_fdr
= NULL
;
10447 debug
.external_rfd
= NULL
;
10448 debug
.external_ext
= debug
.external_ext_end
= NULL
;
10450 mdebug_handle
= bfd_ecoff_debug_init (abfd
, &debug
, swap
, info
);
10451 if (mdebug_handle
== NULL
)
10455 esym
.cobol_main
= 0;
10459 esym
.asym
.iss
= issNil
;
10460 esym
.asym
.st
= stLocal
;
10461 esym
.asym
.reserved
= 0;
10462 esym
.asym
.index
= indexNil
;
10464 for (i
= 0; i
< sizeof (secname
) / sizeof (secname
[0]); i
++)
10466 esym
.asym
.sc
= sc
[i
];
10467 s
= bfd_get_section_by_name (abfd
, secname
[i
]);
10470 esym
.asym
.value
= s
->vma
;
10471 last
= s
->vma
+ s
->size
;
10474 esym
.asym
.value
= last
;
10475 if (!bfd_ecoff_debug_one_external (abfd
, &debug
, swap
,
10476 secname
[i
], &esym
))
10480 for (p
= o
->map_head
.link_order
; p
!= NULL
; p
= p
->next
)
10482 asection
*input_section
;
10484 const struct ecoff_debug_swap
*input_swap
;
10485 struct ecoff_debug_info input_debug
;
10489 if (p
->type
!= bfd_indirect_link_order
)
10491 if (p
->type
== bfd_data_link_order
)
10496 input_section
= p
->u
.indirect
.section
;
10497 input_bfd
= input_section
->owner
;
10499 if (bfd_get_flavour (input_bfd
) != bfd_target_elf_flavour
10500 || (get_elf_backend_data (input_bfd
)
10501 ->elf_backend_ecoff_debug_swap
) == NULL
)
10503 /* I don't know what a non MIPS ELF bfd would be
10504 doing with a .mdebug section, but I don't really
10505 want to deal with it. */
10509 input_swap
= (get_elf_backend_data (input_bfd
)
10510 ->elf_backend_ecoff_debug_swap
);
10512 BFD_ASSERT (p
->size
== input_section
->size
);
10514 /* The ECOFF linking code expects that we have already
10515 read in the debugging information and set up an
10516 ecoff_debug_info structure, so we do that now. */
10517 if (! _bfd_mips_elf_read_ecoff_info (input_bfd
, input_section
,
10521 if (! (bfd_ecoff_debug_accumulate
10522 (mdebug_handle
, abfd
, &debug
, swap
, input_bfd
,
10523 &input_debug
, input_swap
, info
)))
10526 /* Loop through the external symbols. For each one with
10527 interesting information, try to find the symbol in
10528 the linker global hash table and save the information
10529 for the output external symbols. */
10530 eraw_src
= input_debug
.external_ext
;
10531 eraw_end
= (eraw_src
10532 + (input_debug
.symbolic_header
.iextMax
10533 * input_swap
->external_ext_size
));
10535 eraw_src
< eraw_end
;
10536 eraw_src
+= input_swap
->external_ext_size
)
10540 struct mips_elf_link_hash_entry
*h
;
10542 (*input_swap
->swap_ext_in
) (input_bfd
, eraw_src
, &ext
);
10543 if (ext
.asym
.sc
== scNil
10544 || ext
.asym
.sc
== scUndefined
10545 || ext
.asym
.sc
== scSUndefined
)
10548 name
= input_debug
.ssext
+ ext
.asym
.iss
;
10549 h
= mips_elf_link_hash_lookup (mips_elf_hash_table (info
),
10550 name
, FALSE
, FALSE
, TRUE
);
10551 if (h
== NULL
|| h
->esym
.ifd
!= -2)
10556 BFD_ASSERT (ext
.ifd
10557 < input_debug
.symbolic_header
.ifdMax
);
10558 ext
.ifd
= input_debug
.ifdmap
[ext
.ifd
];
10564 /* Free up the information we just read. */
10565 free (input_debug
.line
);
10566 free (input_debug
.external_dnr
);
10567 free (input_debug
.external_pdr
);
10568 free (input_debug
.external_sym
);
10569 free (input_debug
.external_opt
);
10570 free (input_debug
.external_aux
);
10571 free (input_debug
.ss
);
10572 free (input_debug
.ssext
);
10573 free (input_debug
.external_fdr
);
10574 free (input_debug
.external_rfd
);
10575 free (input_debug
.external_ext
);
10577 /* Hack: reset the SEC_HAS_CONTENTS flag so that
10578 elf_link_input_bfd ignores this section. */
10579 input_section
->flags
&= ~SEC_HAS_CONTENTS
;
10582 if (SGI_COMPAT (abfd
) && info
->shared
)
10584 /* Create .rtproc section. */
10585 rtproc_sec
= bfd_get_section_by_name (abfd
, ".rtproc");
10586 if (rtproc_sec
== NULL
)
10588 flagword flags
= (SEC_HAS_CONTENTS
| SEC_IN_MEMORY
10589 | SEC_LINKER_CREATED
| SEC_READONLY
);
10591 rtproc_sec
= bfd_make_section_with_flags (abfd
,
10594 if (rtproc_sec
== NULL
10595 || ! bfd_set_section_alignment (abfd
, rtproc_sec
, 4))
10599 if (! mips_elf_create_procedure_table (mdebug_handle
, abfd
,
10605 /* Build the external symbol information. */
10608 einfo
.debug
= &debug
;
10610 einfo
.failed
= FALSE
;
10611 mips_elf_link_hash_traverse (mips_elf_hash_table (info
),
10612 mips_elf_output_extsym
, &einfo
);
10616 /* Set the size of the .mdebug section. */
10617 o
->size
= bfd_ecoff_debug_size (abfd
, &debug
, swap
);
10619 /* Skip this section later on (I don't think this currently
10620 matters, but someday it might). */
10621 o
->map_head
.link_order
= NULL
;
10626 if (CONST_STRNEQ (o
->name
, ".gptab."))
10628 const char *subname
;
10631 Elf32_External_gptab
*ext_tab
;
10634 /* The .gptab.sdata and .gptab.sbss sections hold
10635 information describing how the small data area would
10636 change depending upon the -G switch. These sections
10637 not used in executables files. */
10638 if (! info
->relocatable
)
10640 for (p
= o
->map_head
.link_order
; p
!= NULL
; p
= p
->next
)
10642 asection
*input_section
;
10644 if (p
->type
!= bfd_indirect_link_order
)
10646 if (p
->type
== bfd_data_link_order
)
10651 input_section
= p
->u
.indirect
.section
;
10653 /* Hack: reset the SEC_HAS_CONTENTS flag so that
10654 elf_link_input_bfd ignores this section. */
10655 input_section
->flags
&= ~SEC_HAS_CONTENTS
;
10658 /* Skip this section later on (I don't think this
10659 currently matters, but someday it might). */
10660 o
->map_head
.link_order
= NULL
;
10662 /* Really remove the section. */
10663 bfd_section_list_remove (abfd
, o
);
10664 --abfd
->section_count
;
10669 /* There is one gptab for initialized data, and one for
10670 uninitialized data. */
10671 if (strcmp (o
->name
, ".gptab.sdata") == 0)
10672 gptab_data_sec
= o
;
10673 else if (strcmp (o
->name
, ".gptab.sbss") == 0)
10677 (*_bfd_error_handler
)
10678 (_("%s: illegal section name `%s'"),
10679 bfd_get_filename (abfd
), o
->name
);
10680 bfd_set_error (bfd_error_nonrepresentable_section
);
10684 /* The linker script always combines .gptab.data and
10685 .gptab.sdata into .gptab.sdata, and likewise for
10686 .gptab.bss and .gptab.sbss. It is possible that there is
10687 no .sdata or .sbss section in the output file, in which
10688 case we must change the name of the output section. */
10689 subname
= o
->name
+ sizeof ".gptab" - 1;
10690 if (bfd_get_section_by_name (abfd
, subname
) == NULL
)
10692 if (o
== gptab_data_sec
)
10693 o
->name
= ".gptab.data";
10695 o
->name
= ".gptab.bss";
10696 subname
= o
->name
+ sizeof ".gptab" - 1;
10697 BFD_ASSERT (bfd_get_section_by_name (abfd
, subname
) != NULL
);
10700 /* Set up the first entry. */
10702 amt
= c
* sizeof (Elf32_gptab
);
10703 tab
= bfd_malloc (amt
);
10706 tab
[0].gt_header
.gt_current_g_value
= elf_gp_size (abfd
);
10707 tab
[0].gt_header
.gt_unused
= 0;
10709 /* Combine the input sections. */
10710 for (p
= o
->map_head
.link_order
; p
!= NULL
; p
= p
->next
)
10712 asection
*input_section
;
10714 bfd_size_type size
;
10715 unsigned long last
;
10716 bfd_size_type gpentry
;
10718 if (p
->type
!= bfd_indirect_link_order
)
10720 if (p
->type
== bfd_data_link_order
)
10725 input_section
= p
->u
.indirect
.section
;
10726 input_bfd
= input_section
->owner
;
10728 /* Combine the gptab entries for this input section one
10729 by one. We know that the input gptab entries are
10730 sorted by ascending -G value. */
10731 size
= input_section
->size
;
10733 for (gpentry
= sizeof (Elf32_External_gptab
);
10735 gpentry
+= sizeof (Elf32_External_gptab
))
10737 Elf32_External_gptab ext_gptab
;
10738 Elf32_gptab int_gptab
;
10744 if (! (bfd_get_section_contents
10745 (input_bfd
, input_section
, &ext_gptab
, gpentry
,
10746 sizeof (Elf32_External_gptab
))))
10752 bfd_mips_elf32_swap_gptab_in (input_bfd
, &ext_gptab
,
10754 val
= int_gptab
.gt_entry
.gt_g_value
;
10755 add
= int_gptab
.gt_entry
.gt_bytes
- last
;
10758 for (look
= 1; look
< c
; look
++)
10760 if (tab
[look
].gt_entry
.gt_g_value
>= val
)
10761 tab
[look
].gt_entry
.gt_bytes
+= add
;
10763 if (tab
[look
].gt_entry
.gt_g_value
== val
)
10769 Elf32_gptab
*new_tab
;
10772 /* We need a new table entry. */
10773 amt
= (bfd_size_type
) (c
+ 1) * sizeof (Elf32_gptab
);
10774 new_tab
= bfd_realloc (tab
, amt
);
10775 if (new_tab
== NULL
)
10781 tab
[c
].gt_entry
.gt_g_value
= val
;
10782 tab
[c
].gt_entry
.gt_bytes
= add
;
10784 /* Merge in the size for the next smallest -G
10785 value, since that will be implied by this new
10788 for (look
= 1; look
< c
; look
++)
10790 if (tab
[look
].gt_entry
.gt_g_value
< val
10792 || (tab
[look
].gt_entry
.gt_g_value
10793 > tab
[max
].gt_entry
.gt_g_value
)))
10797 tab
[c
].gt_entry
.gt_bytes
+=
10798 tab
[max
].gt_entry
.gt_bytes
;
10803 last
= int_gptab
.gt_entry
.gt_bytes
;
10806 /* Hack: reset the SEC_HAS_CONTENTS flag so that
10807 elf_link_input_bfd ignores this section. */
10808 input_section
->flags
&= ~SEC_HAS_CONTENTS
;
10811 /* The table must be sorted by -G value. */
10813 qsort (tab
+ 1, c
- 1, sizeof (tab
[0]), gptab_compare
);
10815 /* Swap out the table. */
10816 amt
= (bfd_size_type
) c
* sizeof (Elf32_External_gptab
);
10817 ext_tab
= bfd_alloc (abfd
, amt
);
10818 if (ext_tab
== NULL
)
10824 for (j
= 0; j
< c
; j
++)
10825 bfd_mips_elf32_swap_gptab_out (abfd
, tab
+ j
, ext_tab
+ j
);
10828 o
->size
= c
* sizeof (Elf32_External_gptab
);
10829 o
->contents
= (bfd_byte
*) ext_tab
;
10831 /* Skip this section later on (I don't think this currently
10832 matters, but someday it might). */
10833 o
->map_head
.link_order
= NULL
;
10837 /* Invoke the regular ELF backend linker to do all the work. */
10838 if (!bfd_elf_final_link (abfd
, info
))
10841 /* Now write out the computed sections. */
10843 if (reginfo_sec
!= NULL
)
10845 Elf32_External_RegInfo ext
;
10847 bfd_mips_elf32_swap_reginfo_out (abfd
, ®info
, &ext
);
10848 if (! bfd_set_section_contents (abfd
, reginfo_sec
, &ext
, 0, sizeof ext
))
10852 if (mdebug_sec
!= NULL
)
10854 BFD_ASSERT (abfd
->output_has_begun
);
10855 if (! bfd_ecoff_write_accumulated_debug (mdebug_handle
, abfd
, &debug
,
10857 mdebug_sec
->filepos
))
10860 bfd_ecoff_debug_free (mdebug_handle
, abfd
, &debug
, swap
, info
);
10863 if (gptab_data_sec
!= NULL
)
10865 if (! bfd_set_section_contents (abfd
, gptab_data_sec
,
10866 gptab_data_sec
->contents
,
10867 0, gptab_data_sec
->size
))
10871 if (gptab_bss_sec
!= NULL
)
10873 if (! bfd_set_section_contents (abfd
, gptab_bss_sec
,
10874 gptab_bss_sec
->contents
,
10875 0, gptab_bss_sec
->size
))
10879 if (SGI_COMPAT (abfd
))
10881 rtproc_sec
= bfd_get_section_by_name (abfd
, ".rtproc");
10882 if (rtproc_sec
!= NULL
)
10884 if (! bfd_set_section_contents (abfd
, rtproc_sec
,
10885 rtproc_sec
->contents
,
10886 0, rtproc_sec
->size
))
10894 /* Structure for saying that BFD machine EXTENSION extends BASE. */
10896 struct mips_mach_extension
{
10897 unsigned long extension
, base
;
10901 /* An array describing how BFD machines relate to one another. The entries
10902 are ordered topologically with MIPS I extensions listed last. */
10904 static const struct mips_mach_extension mips_mach_extensions
[] = {
10905 /* MIPS64 extensions. */
10906 { bfd_mach_mipsisa64r2
, bfd_mach_mipsisa64
},
10907 { bfd_mach_mips_sb1
, bfd_mach_mipsisa64
},
10909 /* MIPS V extensions. */
10910 { bfd_mach_mipsisa64
, bfd_mach_mips5
},
10912 /* R10000 extensions. */
10913 { bfd_mach_mips12000
, bfd_mach_mips10000
},
10915 /* R5000 extensions. Note: the vr5500 ISA is an extension of the core
10916 vr5400 ISA, but doesn't include the multimedia stuff. It seems
10917 better to allow vr5400 and vr5500 code to be merged anyway, since
10918 many libraries will just use the core ISA. Perhaps we could add
10919 some sort of ASE flag if this ever proves a problem. */
10920 { bfd_mach_mips5500
, bfd_mach_mips5400
},
10921 { bfd_mach_mips5400
, bfd_mach_mips5000
},
10923 /* MIPS IV extensions. */
10924 { bfd_mach_mips5
, bfd_mach_mips8000
},
10925 { bfd_mach_mips10000
, bfd_mach_mips8000
},
10926 { bfd_mach_mips5000
, bfd_mach_mips8000
},
10927 { bfd_mach_mips7000
, bfd_mach_mips8000
},
10928 { bfd_mach_mips9000
, bfd_mach_mips8000
},
10930 /* VR4100 extensions. */
10931 { bfd_mach_mips4120
, bfd_mach_mips4100
},
10932 { bfd_mach_mips4111
, bfd_mach_mips4100
},
10934 /* MIPS III extensions. */
10935 { bfd_mach_mips8000
, bfd_mach_mips4000
},
10936 { bfd_mach_mips4650
, bfd_mach_mips4000
},
10937 { bfd_mach_mips4600
, bfd_mach_mips4000
},
10938 { bfd_mach_mips4400
, bfd_mach_mips4000
},
10939 { bfd_mach_mips4300
, bfd_mach_mips4000
},
10940 { bfd_mach_mips4100
, bfd_mach_mips4000
},
10941 { bfd_mach_mips4010
, bfd_mach_mips4000
},
10943 /* MIPS32 extensions. */
10944 { bfd_mach_mipsisa32r2
, bfd_mach_mipsisa32
},
10946 /* MIPS II extensions. */
10947 { bfd_mach_mips4000
, bfd_mach_mips6000
},
10948 { bfd_mach_mipsisa32
, bfd_mach_mips6000
},
10950 /* MIPS I extensions. */
10951 { bfd_mach_mips6000
, bfd_mach_mips3000
},
10952 { bfd_mach_mips3900
, bfd_mach_mips3000
}
10956 /* Return true if bfd machine EXTENSION is an extension of machine BASE. */
10959 mips_mach_extends_p (unsigned long base
, unsigned long extension
)
10963 if (extension
== base
)
10966 if (base
== bfd_mach_mipsisa32
10967 && mips_mach_extends_p (bfd_mach_mipsisa64
, extension
))
10970 if (base
== bfd_mach_mipsisa32r2
10971 && mips_mach_extends_p (bfd_mach_mipsisa64r2
, extension
))
10974 for (i
= 0; i
< ARRAY_SIZE (mips_mach_extensions
); i
++)
10975 if (extension
== mips_mach_extensions
[i
].extension
)
10977 extension
= mips_mach_extensions
[i
].base
;
10978 if (extension
== base
)
10986 /* Return true if the given ELF header flags describe a 32-bit binary. */
10989 mips_32bit_flags_p (flagword flags
)
10991 return ((flags
& EF_MIPS_32BITMODE
) != 0
10992 || (flags
& EF_MIPS_ABI
) == E_MIPS_ABI_O32
10993 || (flags
& EF_MIPS_ABI
) == E_MIPS_ABI_EABI32
10994 || (flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_1
10995 || (flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_2
10996 || (flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_32
10997 || (flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_32R2
);
11001 /* Merge backend specific data from an object file to the output
11002 object file when linking. */
11005 _bfd_mips_elf_merge_private_bfd_data (bfd
*ibfd
, bfd
*obfd
)
11007 flagword old_flags
;
11008 flagword new_flags
;
11010 bfd_boolean null_input_bfd
= TRUE
;
11013 /* Check if we have the same endianess */
11014 if (! _bfd_generic_verify_endian_match (ibfd
, obfd
))
11016 (*_bfd_error_handler
)
11017 (_("%B: endianness incompatible with that of the selected emulation"),
11022 if (bfd_get_flavour (ibfd
) != bfd_target_elf_flavour
11023 || bfd_get_flavour (obfd
) != bfd_target_elf_flavour
)
11026 if (strcmp (bfd_get_target (ibfd
), bfd_get_target (obfd
)) != 0)
11028 (*_bfd_error_handler
)
11029 (_("%B: ABI is incompatible with that of the selected emulation"),
11034 new_flags
= elf_elfheader (ibfd
)->e_flags
;
11035 elf_elfheader (obfd
)->e_flags
|= new_flags
& EF_MIPS_NOREORDER
;
11036 old_flags
= elf_elfheader (obfd
)->e_flags
;
11038 if (! elf_flags_init (obfd
))
11040 elf_flags_init (obfd
) = TRUE
;
11041 elf_elfheader (obfd
)->e_flags
= new_flags
;
11042 elf_elfheader (obfd
)->e_ident
[EI_CLASS
]
11043 = elf_elfheader (ibfd
)->e_ident
[EI_CLASS
];
11045 if (bfd_get_arch (obfd
) == bfd_get_arch (ibfd
)
11046 && (bfd_get_arch_info (obfd
)->the_default
11047 || mips_mach_extends_p (bfd_get_mach (obfd
),
11048 bfd_get_mach (ibfd
))))
11050 if (! bfd_set_arch_mach (obfd
, bfd_get_arch (ibfd
),
11051 bfd_get_mach (ibfd
)))
11058 /* Check flag compatibility. */
11060 new_flags
&= ~EF_MIPS_NOREORDER
;
11061 old_flags
&= ~EF_MIPS_NOREORDER
;
11063 /* Some IRIX 6 BSD-compatibility objects have this bit set. It
11064 doesn't seem to matter. */
11065 new_flags
&= ~EF_MIPS_XGOT
;
11066 old_flags
&= ~EF_MIPS_XGOT
;
11068 /* MIPSpro generates ucode info in n64 objects. Again, we should
11069 just be able to ignore this. */
11070 new_flags
&= ~EF_MIPS_UCODE
;
11071 old_flags
&= ~EF_MIPS_UCODE
;
11073 /* Don't care about the PIC flags from dynamic objects; they are
11075 if ((new_flags
& (EF_MIPS_PIC
| EF_MIPS_CPIC
)) != 0
11076 && (ibfd
->flags
& DYNAMIC
) != 0)
11077 new_flags
&= ~ (EF_MIPS_PIC
| EF_MIPS_CPIC
);
11079 if (new_flags
== old_flags
)
11082 /* Check to see if the input BFD actually contains any sections.
11083 If not, its flags may not have been initialised either, but it cannot
11084 actually cause any incompatibility. */
11085 for (sec
= ibfd
->sections
; sec
!= NULL
; sec
= sec
->next
)
11087 /* Ignore synthetic sections and empty .text, .data and .bss sections
11088 which are automatically generated by gas. */
11089 if (strcmp (sec
->name
, ".reginfo")
11090 && strcmp (sec
->name
, ".mdebug")
11092 || (strcmp (sec
->name
, ".text")
11093 && strcmp (sec
->name
, ".data")
11094 && strcmp (sec
->name
, ".bss"))))
11096 null_input_bfd
= FALSE
;
11100 if (null_input_bfd
)
11105 if (((new_flags
& (EF_MIPS_PIC
| EF_MIPS_CPIC
)) != 0)
11106 != ((old_flags
& (EF_MIPS_PIC
| EF_MIPS_CPIC
)) != 0))
11108 (*_bfd_error_handler
)
11109 (_("%B: warning: linking PIC files with non-PIC files"),
11114 if (new_flags
& (EF_MIPS_PIC
| EF_MIPS_CPIC
))
11115 elf_elfheader (obfd
)->e_flags
|= EF_MIPS_CPIC
;
11116 if (! (new_flags
& EF_MIPS_PIC
))
11117 elf_elfheader (obfd
)->e_flags
&= ~EF_MIPS_PIC
;
11119 new_flags
&= ~ (EF_MIPS_PIC
| EF_MIPS_CPIC
);
11120 old_flags
&= ~ (EF_MIPS_PIC
| EF_MIPS_CPIC
);
11122 /* Compare the ISAs. */
11123 if (mips_32bit_flags_p (old_flags
) != mips_32bit_flags_p (new_flags
))
11125 (*_bfd_error_handler
)
11126 (_("%B: linking 32-bit code with 64-bit code"),
11130 else if (!mips_mach_extends_p (bfd_get_mach (ibfd
), bfd_get_mach (obfd
)))
11132 /* OBFD's ISA isn't the same as, or an extension of, IBFD's. */
11133 if (mips_mach_extends_p (bfd_get_mach (obfd
), bfd_get_mach (ibfd
)))
11135 /* Copy the architecture info from IBFD to OBFD. Also copy
11136 the 32-bit flag (if set) so that we continue to recognise
11137 OBFD as a 32-bit binary. */
11138 bfd_set_arch_info (obfd
, bfd_get_arch_info (ibfd
));
11139 elf_elfheader (obfd
)->e_flags
&= ~(EF_MIPS_ARCH
| EF_MIPS_MACH
);
11140 elf_elfheader (obfd
)->e_flags
11141 |= new_flags
& (EF_MIPS_ARCH
| EF_MIPS_MACH
| EF_MIPS_32BITMODE
);
11143 /* Copy across the ABI flags if OBFD doesn't use them
11144 and if that was what caused us to treat IBFD as 32-bit. */
11145 if ((old_flags
& EF_MIPS_ABI
) == 0
11146 && mips_32bit_flags_p (new_flags
)
11147 && !mips_32bit_flags_p (new_flags
& ~EF_MIPS_ABI
))
11148 elf_elfheader (obfd
)->e_flags
|= new_flags
& EF_MIPS_ABI
;
11152 /* The ISAs aren't compatible. */
11153 (*_bfd_error_handler
)
11154 (_("%B: linking %s module with previous %s modules"),
11156 bfd_printable_name (ibfd
),
11157 bfd_printable_name (obfd
));
11162 new_flags
&= ~(EF_MIPS_ARCH
| EF_MIPS_MACH
| EF_MIPS_32BITMODE
);
11163 old_flags
&= ~(EF_MIPS_ARCH
| EF_MIPS_MACH
| EF_MIPS_32BITMODE
);
11165 /* Compare ABIs. The 64-bit ABI does not use EF_MIPS_ABI. But, it
11166 does set EI_CLASS differently from any 32-bit ABI. */
11167 if ((new_flags
& EF_MIPS_ABI
) != (old_flags
& EF_MIPS_ABI
)
11168 || (elf_elfheader (ibfd
)->e_ident
[EI_CLASS
]
11169 != elf_elfheader (obfd
)->e_ident
[EI_CLASS
]))
11171 /* Only error if both are set (to different values). */
11172 if (((new_flags
& EF_MIPS_ABI
) && (old_flags
& EF_MIPS_ABI
))
11173 || (elf_elfheader (ibfd
)->e_ident
[EI_CLASS
]
11174 != elf_elfheader (obfd
)->e_ident
[EI_CLASS
]))
11176 (*_bfd_error_handler
)
11177 (_("%B: ABI mismatch: linking %s module with previous %s modules"),
11179 elf_mips_abi_name (ibfd
),
11180 elf_mips_abi_name (obfd
));
11183 new_flags
&= ~EF_MIPS_ABI
;
11184 old_flags
&= ~EF_MIPS_ABI
;
11187 /* For now, allow arbitrary mixing of ASEs (retain the union). */
11188 if ((new_flags
& EF_MIPS_ARCH_ASE
) != (old_flags
& EF_MIPS_ARCH_ASE
))
11190 elf_elfheader (obfd
)->e_flags
|= new_flags
& EF_MIPS_ARCH_ASE
;
11192 new_flags
&= ~ EF_MIPS_ARCH_ASE
;
11193 old_flags
&= ~ EF_MIPS_ARCH_ASE
;
11196 /* Warn about any other mismatches */
11197 if (new_flags
!= old_flags
)
11199 (*_bfd_error_handler
)
11200 (_("%B: uses different e_flags (0x%lx) fields than previous modules (0x%lx)"),
11201 ibfd
, (unsigned long) new_flags
,
11202 (unsigned long) old_flags
);
11208 bfd_set_error (bfd_error_bad_value
);
11215 /* Function to keep MIPS specific file flags like as EF_MIPS_PIC. */
11218 _bfd_mips_elf_set_private_flags (bfd
*abfd
, flagword flags
)
11220 BFD_ASSERT (!elf_flags_init (abfd
)
11221 || elf_elfheader (abfd
)->e_flags
== flags
);
11223 elf_elfheader (abfd
)->e_flags
= flags
;
11224 elf_flags_init (abfd
) = TRUE
;
11229 _bfd_mips_elf_print_private_bfd_data (bfd
*abfd
, void *ptr
)
11233 BFD_ASSERT (abfd
!= NULL
&& ptr
!= NULL
);
11235 /* Print normal ELF private data. */
11236 _bfd_elf_print_private_bfd_data (abfd
, ptr
);
11238 /* xgettext:c-format */
11239 fprintf (file
, _("private flags = %lx:"), elf_elfheader (abfd
)->e_flags
);
11241 if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
) == E_MIPS_ABI_O32
)
11242 fprintf (file
, _(" [abi=O32]"));
11243 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
) == E_MIPS_ABI_O64
)
11244 fprintf (file
, _(" [abi=O64]"));
11245 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
) == E_MIPS_ABI_EABI32
)
11246 fprintf (file
, _(" [abi=EABI32]"));
11247 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
) == E_MIPS_ABI_EABI64
)
11248 fprintf (file
, _(" [abi=EABI64]"));
11249 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ABI
))
11250 fprintf (file
, _(" [abi unknown]"));
11251 else if (ABI_N32_P (abfd
))
11252 fprintf (file
, _(" [abi=N32]"));
11253 else if (ABI_64_P (abfd
))
11254 fprintf (file
, _(" [abi=64]"));
11256 fprintf (file
, _(" [no abi set]"));
11258 if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_1
)
11259 fprintf (file
, " [mips1]");
11260 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_2
)
11261 fprintf (file
, " [mips2]");
11262 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_3
)
11263 fprintf (file
, " [mips3]");
11264 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_4
)
11265 fprintf (file
, " [mips4]");
11266 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_5
)
11267 fprintf (file
, " [mips5]");
11268 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_32
)
11269 fprintf (file
, " [mips32]");
11270 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_64
)
11271 fprintf (file
, " [mips64]");
11272 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_32R2
)
11273 fprintf (file
, " [mips32r2]");
11274 else if ((elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH
) == E_MIPS_ARCH_64R2
)
11275 fprintf (file
, " [mips64r2]");
11277 fprintf (file
, _(" [unknown ISA]"));
11279 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH_ASE_MDMX
)
11280 fprintf (file
, " [mdmx]");
11282 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_ARCH_ASE_M16
)
11283 fprintf (file
, " [mips16]");
11285 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_32BITMODE
)
11286 fprintf (file
, " [32bitmode]");
11288 fprintf (file
, _(" [not 32bitmode]"));
11290 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_NOREORDER
)
11291 fprintf (file
, " [noreorder]");
11293 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_PIC
)
11294 fprintf (file
, " [PIC]");
11296 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_CPIC
)
11297 fprintf (file
, " [CPIC]");
11299 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_XGOT
)
11300 fprintf (file
, " [XGOT]");
11302 if (elf_elfheader (abfd
)->e_flags
& EF_MIPS_UCODE
)
11303 fprintf (file
, " [UCODE]");
11305 fputc ('\n', file
);
11310 const struct bfd_elf_special_section _bfd_mips_elf_special_sections
[] =
11312 { STRING_COMMA_LEN (".lit4"), 0, SHT_PROGBITS
, SHF_ALLOC
+ SHF_WRITE
+ SHF_MIPS_GPREL
},
11313 { STRING_COMMA_LEN (".lit8"), 0, SHT_PROGBITS
, SHF_ALLOC
+ SHF_WRITE
+ SHF_MIPS_GPREL
},
11314 { STRING_COMMA_LEN (".mdebug"), 0, SHT_MIPS_DEBUG
, 0 },
11315 { STRING_COMMA_LEN (".sbss"), -2, SHT_NOBITS
, SHF_ALLOC
+ SHF_WRITE
+ SHF_MIPS_GPREL
},
11316 { STRING_COMMA_LEN (".sdata"), -2, SHT_PROGBITS
, SHF_ALLOC
+ SHF_WRITE
+ SHF_MIPS_GPREL
},
11317 { STRING_COMMA_LEN (".ucode"), 0, SHT_MIPS_UCODE
, 0 },
11318 { NULL
, 0, 0, 0, 0 }
11321 /* Merge non visibility st_other attributes. Ensure that the
11322 STO_OPTIONAL flag is copied into h->other, even if this is not a
11323 definiton of the symbol. */
11325 _bfd_mips_elf_merge_symbol_attribute (struct elf_link_hash_entry
*h
,
11326 const Elf_Internal_Sym
*isym
,
11327 bfd_boolean definition
,
11328 bfd_boolean dynamic ATTRIBUTE_UNUSED
)
11330 if ((isym
->st_other
& ~ELF_ST_VISIBILITY (-1)) != 0)
11332 unsigned char other
;
11334 other
= (definition
? isym
->st_other
: h
->other
);
11335 other
&= ~ELF_ST_VISIBILITY (-1);
11336 h
->other
= other
| ELF_ST_VISIBILITY (h
->other
);
11340 && ELF_MIPS_IS_OPTIONAL (isym
->st_other
))
11341 h
->other
|= STO_OPTIONAL
;
11344 /* Decide whether an undefined symbol is special and can be ignored.
11345 This is the case for OPTIONAL symbols on IRIX. */
11347 _bfd_mips_elf_ignore_undef_symbol (struct elf_link_hash_entry
*h
)
11349 return ELF_MIPS_IS_OPTIONAL (h
->other
) ? TRUE
: FALSE
;
11353 _bfd_mips_elf_common_definition (Elf_Internal_Sym
*sym
)
11355 return (sym
->st_shndx
== SHN_COMMON
11356 || sym
->st_shndx
== SHN_MIPS_ACOMMON
11357 || sym
->st_shndx
== SHN_MIPS_SCOMMON
);