binutils-gdb/bfd/elfxx-mips.c
Richard Sandiford 18ad015f6c * elfxx-mips.c (mips_elf_link_hash_entry): Remove min_dyn_reloc_index.
(bfd_mips_elf_swap_msym_in, bfd_mips_elf_swap_msym_out): Delete.
	(mips_elf_create_msym_section): Delete.
	(mips_elf_create_dynamic_relocation): Don't set min_dyn_reloc_index.
	(_bfd_mips_elf_copy_indirect_symbol): Likewise.
	(_bfd_mips_elf_create_dynamic_sections): Don't create .msym.
	(_bfd_mips_elf_size_dynamic_sections): Don't calculate its size.
	(_bfd_mips_elf_size_dynamic_sections): Don't add DT_MIPS_MSYM.
	(_bfd_mips_elf_finish_dynamic_symbol): Don't add symbols to .msym.
	(_bfd_mips_elf_finish_dynamic_sections): Likewise.
2003-07-09 11:55:49 +00:00

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/* MIPS-specific support for ELF
Copyright 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002,
2003 Free Software Foundation, Inc.
Most of the information added by Ian Lance Taylor, Cygnus Support,
<ian@cygnus.com>.
N32/64 ABI support added by Mark Mitchell, CodeSourcery, LLC.
<mark@codesourcery.com>
Traditional MIPS targets support added by Koundinya.K, Dansk Data
Elektronik & Operations Research Group. <kk@ddeorg.soft.net>
This file is part of BFD, the Binary File Descriptor library.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
/* This file handles functionality common to the different MIPS ABI's. */
#include "bfd.h"
#include "sysdep.h"
#include "libbfd.h"
#include "libiberty.h"
#include "elf-bfd.h"
#include "elfxx-mips.h"
#include "elf/mips.h"
/* Get the ECOFF swapping routines. */
#include "coff/sym.h"
#include "coff/symconst.h"
#include "coff/ecoff.h"
#include "coff/mips.h"
#include "hashtab.h"
/* This structure is used to hold .got entries while estimating got
sizes. */
struct mips_got_entry
{
/* The input bfd in which the symbol is defined. */
bfd *abfd;
/* The index of the symbol, as stored in the relocation r_info, if
we have a local symbol; -1 otherwise. */
long symndx;
union
{
/* If abfd == NULL, an address that must be stored in the got. */
bfd_vma address;
/* If abfd != NULL && symndx != -1, the addend of the relocation
that should be added to the symbol value. */
bfd_vma addend;
/* If abfd != NULL && symndx == -1, the hash table entry
corresponding to a global symbol in the got (or, local, if
h->forced_local). */
struct mips_elf_link_hash_entry *h;
} d;
/* The offset from the beginning of the .got section to the entry
corresponding to this symbol+addend. If it's a global symbol
whose offset is yet to be decided, it's going to be -1. */
long gotidx;
};
/* This structure is used to hold .got information when linking. */
struct mips_got_info
{
/* The global symbol in the GOT with the lowest index in the dynamic
symbol table. */
struct elf_link_hash_entry *global_gotsym;
/* The number of global .got entries. */
unsigned int global_gotno;
/* The number of local .got entries. */
unsigned int local_gotno;
/* The number of local .got entries we have used. */
unsigned int assigned_gotno;
/* A hash table holding members of the got. */
struct htab *got_entries;
/* A hash table mapping input bfds to other mips_got_info. NULL
unless multi-got was necessary. */
struct htab *bfd2got;
/* In multi-got links, a pointer to the next got (err, rather, most
of the time, it points to the previous got). */
struct mips_got_info *next;
};
/* Map an input bfd to a got in a multi-got link. */
struct mips_elf_bfd2got_hash {
bfd *bfd;
struct mips_got_info *g;
};
/* Structure passed when traversing the bfd2got hash table, used to
create and merge bfd's gots. */
struct mips_elf_got_per_bfd_arg
{
/* A hashtable that maps bfds to gots. */
htab_t bfd2got;
/* The output bfd. */
bfd *obfd;
/* The link information. */
struct bfd_link_info *info;
/* A pointer to the primary got, i.e., the one that's going to get
the implicit relocations from DT_MIPS_LOCAL_GOTNO and
DT_MIPS_GOTSYM. */
struct mips_got_info *primary;
/* A non-primary got we're trying to merge with other input bfd's
gots. */
struct mips_got_info *current;
/* The maximum number of got entries that can be addressed with a
16-bit offset. */
unsigned int max_count;
/* The number of local and global entries in the primary got. */
unsigned int primary_count;
/* The number of local and global entries in the current got. */
unsigned int current_count;
};
/* Another structure used to pass arguments for got entries traversal. */
struct mips_elf_set_global_got_offset_arg
{
struct mips_got_info *g;
int value;
unsigned int needed_relocs;
struct bfd_link_info *info;
};
struct _mips_elf_section_data
{
struct bfd_elf_section_data elf;
union
{
struct mips_got_info *got_info;
bfd_byte *tdata;
} u;
};
#define mips_elf_section_data(sec) \
((struct _mips_elf_section_data *) elf_section_data (sec))
/* This structure is passed to mips_elf_sort_hash_table_f when sorting
the dynamic symbols. */
struct mips_elf_hash_sort_data
{
/* The symbol in the global GOT with the lowest dynamic symbol table
index. */
struct elf_link_hash_entry *low;
/* The least dynamic symbol table index corresponding to a symbol
with a GOT entry. */
long min_got_dynindx;
/* The greatest dynamic symbol table index corresponding to a symbol
with a GOT entry that is not referenced (e.g., a dynamic symbol
with dynamic relocations pointing to it from non-primary GOTs). */
long max_unref_got_dynindx;
/* The greatest dynamic symbol table index not corresponding to a
symbol without a GOT entry. */
long max_non_got_dynindx;
};
/* The MIPS ELF linker needs additional information for each symbol in
the global hash table. */
struct mips_elf_link_hash_entry
{
struct elf_link_hash_entry root;
/* External symbol information. */
EXTR esym;
/* Number of R_MIPS_32, R_MIPS_REL32, or R_MIPS_64 relocs against
this symbol. */
unsigned int possibly_dynamic_relocs;
/* If the R_MIPS_32, R_MIPS_REL32, or R_MIPS_64 reloc is against
a readonly section. */
bfd_boolean readonly_reloc;
/* We must not create a stub for a symbol that has relocations
related to taking the function's address, i.e. any but
R_MIPS_CALL*16 ones -- see "MIPS ABI Supplement, 3rd Edition",
p. 4-20. */
bfd_boolean no_fn_stub;
/* If there is a stub that 32 bit functions should use to call this
16 bit function, this points to the section containing the stub. */
asection *fn_stub;
/* Whether we need the fn_stub; this is set if this symbol appears
in any relocs other than a 16 bit call. */
bfd_boolean need_fn_stub;
/* If there is a stub that 16 bit functions should use to call this
32 bit function, this points to the section containing the stub. */
asection *call_stub;
/* This is like the call_stub field, but it is used if the function
being called returns a floating point value. */
asection *call_fp_stub;
/* Are we forced local? .*/
bfd_boolean forced_local;
};
/* MIPS ELF linker hash table. */
struct mips_elf_link_hash_table
{
struct elf_link_hash_table root;
#if 0
/* We no longer use this. */
/* String section indices for the dynamic section symbols. */
bfd_size_type dynsym_sec_strindex[SIZEOF_MIPS_DYNSYM_SECNAMES];
#endif
/* The number of .rtproc entries. */
bfd_size_type procedure_count;
/* The size of the .compact_rel section (if SGI_COMPAT). */
bfd_size_type compact_rel_size;
/* This flag indicates that the value of DT_MIPS_RLD_MAP dynamic
entry is set to the address of __rld_obj_head as in IRIX5. */
bfd_boolean use_rld_obj_head;
/* This is the value of the __rld_map or __rld_obj_head symbol. */
bfd_vma rld_value;
/* This is set if we see any mips16 stub sections. */
bfd_boolean mips16_stubs_seen;
};
/* Structure used to pass information to mips_elf_output_extsym. */
struct extsym_info
{
bfd *abfd;
struct bfd_link_info *info;
struct ecoff_debug_info *debug;
const struct ecoff_debug_swap *swap;
bfd_boolean failed;
};
/* The names of the runtime procedure table symbols used on IRIX5. */
static const char * const mips_elf_dynsym_rtproc_names[] =
{
"_procedure_table",
"_procedure_string_table",
"_procedure_table_size",
NULL
};
/* These structures are used to generate the .compact_rel section on
IRIX5. */
typedef struct
{
unsigned long id1; /* Always one? */
unsigned long num; /* Number of compact relocation entries. */
unsigned long id2; /* Always two? */
unsigned long offset; /* The file offset of the first relocation. */
unsigned long reserved0; /* Zero? */
unsigned long reserved1; /* Zero? */
} Elf32_compact_rel;
typedef struct
{
bfd_byte id1[4];
bfd_byte num[4];
bfd_byte id2[4];
bfd_byte offset[4];
bfd_byte reserved0[4];
bfd_byte reserved1[4];
} Elf32_External_compact_rel;
typedef struct
{
unsigned int ctype : 1; /* 1: long 0: short format. See below. */
unsigned int rtype : 4; /* Relocation types. See below. */
unsigned int dist2to : 8;
unsigned int relvaddr : 19; /* (VADDR - vaddr of the previous entry)/ 4 */
unsigned long konst; /* KONST field. See below. */
unsigned long vaddr; /* VADDR to be relocated. */
} Elf32_crinfo;
typedef struct
{
unsigned int ctype : 1; /* 1: long 0: short format. See below. */
unsigned int rtype : 4; /* Relocation types. See below. */
unsigned int dist2to : 8;
unsigned int relvaddr : 19; /* (VADDR - vaddr of the previous entry)/ 4 */
unsigned long konst; /* KONST field. See below. */
} Elf32_crinfo2;
typedef struct
{
bfd_byte info[4];
bfd_byte konst[4];
bfd_byte vaddr[4];
} Elf32_External_crinfo;
typedef struct
{
bfd_byte info[4];
bfd_byte konst[4];
} Elf32_External_crinfo2;
/* These are the constants used to swap the bitfields in a crinfo. */
#define CRINFO_CTYPE (0x1)
#define CRINFO_CTYPE_SH (31)
#define CRINFO_RTYPE (0xf)
#define CRINFO_RTYPE_SH (27)
#define CRINFO_DIST2TO (0xff)
#define CRINFO_DIST2TO_SH (19)
#define CRINFO_RELVADDR (0x7ffff)
#define CRINFO_RELVADDR_SH (0)
/* A compact relocation info has long (3 words) or short (2 words)
formats. A short format doesn't have VADDR field and relvaddr
fields contains ((VADDR - vaddr of the previous entry) >> 2). */
#define CRF_MIPS_LONG 1
#define CRF_MIPS_SHORT 0
/* There are 4 types of compact relocation at least. The value KONST
has different meaning for each type:
(type) (konst)
CT_MIPS_REL32 Address in data
CT_MIPS_WORD Address in word (XXX)
CT_MIPS_GPHI_LO GP - vaddr
CT_MIPS_JMPAD Address to jump
*/
#define CRT_MIPS_REL32 0xa
#define CRT_MIPS_WORD 0xb
#define CRT_MIPS_GPHI_LO 0xc
#define CRT_MIPS_JMPAD 0xd
#define mips_elf_set_cr_format(x,format) ((x).ctype = (format))
#define mips_elf_set_cr_type(x,type) ((x).rtype = (type))
#define mips_elf_set_cr_dist2to(x,v) ((x).dist2to = (v))
#define mips_elf_set_cr_relvaddr(x,d) ((x).relvaddr = (d)<<2)
/* The structure of the runtime procedure descriptor created by the
loader for use by the static exception system. */
typedef struct runtime_pdr {
bfd_vma adr; /* Memory address of start of procedure. */
long regmask; /* Save register mask. */
long regoffset; /* Save register offset. */
long fregmask; /* Save floating point register mask. */
long fregoffset; /* Save floating point register offset. */
long frameoffset; /* Frame size. */
short framereg; /* Frame pointer register. */
short pcreg; /* Offset or reg of return pc. */
long irpss; /* Index into the runtime string table. */
long reserved;
struct exception_info *exception_info;/* Pointer to exception array. */
} RPDR, *pRPDR;
#define cbRPDR sizeof (RPDR)
#define rpdNil ((pRPDR) 0)
static struct bfd_hash_entry *mips_elf_link_hash_newfunc
PARAMS ((struct bfd_hash_entry *, struct bfd_hash_table *, const char *));
static void ecoff_swap_rpdr_out
PARAMS ((bfd *, const RPDR *, struct rpdr_ext *));
static bfd_boolean mips_elf_create_procedure_table
PARAMS ((PTR, bfd *, struct bfd_link_info *, asection *,
struct ecoff_debug_info *));
static bfd_boolean mips_elf_check_mips16_stubs
PARAMS ((struct mips_elf_link_hash_entry *, PTR));
static void bfd_mips_elf32_swap_gptab_in
PARAMS ((bfd *, const Elf32_External_gptab *, Elf32_gptab *));
static void bfd_mips_elf32_swap_gptab_out
PARAMS ((bfd *, const Elf32_gptab *, Elf32_External_gptab *));
static void bfd_elf32_swap_compact_rel_out
PARAMS ((bfd *, const Elf32_compact_rel *, Elf32_External_compact_rel *));
static void bfd_elf32_swap_crinfo_out
PARAMS ((bfd *, const Elf32_crinfo *, Elf32_External_crinfo *));
static int sort_dynamic_relocs
PARAMS ((const void *, const void *));
static int sort_dynamic_relocs_64
PARAMS ((const void *, const void *));
static bfd_boolean mips_elf_output_extsym
PARAMS ((struct mips_elf_link_hash_entry *, PTR));
static int gptab_compare PARAMS ((const void *, const void *));
static asection * mips_elf_rel_dyn_section PARAMS ((bfd *, bfd_boolean));
static asection * mips_elf_got_section PARAMS ((bfd *, bfd_boolean));
static struct mips_got_info *mips_elf_got_info
PARAMS ((bfd *, asection **));
static long mips_elf_get_global_gotsym_index PARAMS ((bfd *abfd));
static bfd_vma mips_elf_local_got_index
PARAMS ((bfd *, bfd *, struct bfd_link_info *, bfd_vma));
static bfd_vma mips_elf_global_got_index
PARAMS ((bfd *, bfd *, struct elf_link_hash_entry *));
static bfd_vma mips_elf_got_page
PARAMS ((bfd *, bfd *, struct bfd_link_info *, bfd_vma, bfd_vma *));
static bfd_vma mips_elf_got16_entry
PARAMS ((bfd *, bfd *, struct bfd_link_info *, bfd_vma, bfd_boolean));
static bfd_vma mips_elf_got_offset_from_index
PARAMS ((bfd *, bfd *, bfd *, bfd_vma));
static struct mips_got_entry *mips_elf_create_local_got_entry
PARAMS ((bfd *, bfd *, struct mips_got_info *, asection *, bfd_vma));
static bfd_boolean mips_elf_sort_hash_table
PARAMS ((struct bfd_link_info *, unsigned long));
static bfd_boolean mips_elf_sort_hash_table_f
PARAMS ((struct mips_elf_link_hash_entry *, PTR));
static bfd_boolean mips_elf_record_local_got_symbol
PARAMS ((bfd *, long, bfd_vma, struct mips_got_info *));
static bfd_boolean mips_elf_record_global_got_symbol
PARAMS ((struct elf_link_hash_entry *, bfd *, struct bfd_link_info *,
struct mips_got_info *));
static const Elf_Internal_Rela *mips_elf_next_relocation
PARAMS ((bfd *, unsigned int, const Elf_Internal_Rela *,
const Elf_Internal_Rela *));
static bfd_boolean mips_elf_local_relocation_p
PARAMS ((bfd *, const Elf_Internal_Rela *, asection **, bfd_boolean));
static bfd_boolean mips_elf_overflow_p PARAMS ((bfd_vma, int));
static bfd_vma mips_elf_high PARAMS ((bfd_vma));
static bfd_vma mips_elf_higher PARAMS ((bfd_vma));
static bfd_vma mips_elf_highest PARAMS ((bfd_vma));
static bfd_boolean mips_elf_create_compact_rel_section
PARAMS ((bfd *, struct bfd_link_info *));
static bfd_boolean mips_elf_create_got_section
PARAMS ((bfd *, struct bfd_link_info *, bfd_boolean));
static bfd_reloc_status_type mips_elf_calculate_relocation
PARAMS ((bfd *, bfd *, asection *, struct bfd_link_info *,
const Elf_Internal_Rela *, bfd_vma, reloc_howto_type *,
Elf_Internal_Sym *, asection **, bfd_vma *, const char **,
bfd_boolean *, bfd_boolean));
static bfd_vma mips_elf_obtain_contents
PARAMS ((reloc_howto_type *, const Elf_Internal_Rela *, bfd *, bfd_byte *));
static bfd_boolean mips_elf_perform_relocation
PARAMS ((struct bfd_link_info *, reloc_howto_type *,
const Elf_Internal_Rela *, bfd_vma, bfd *, asection *, bfd_byte *,
bfd_boolean));
static bfd_boolean mips_elf_stub_section_p
PARAMS ((bfd *, asection *));
static void mips_elf_allocate_dynamic_relocations
PARAMS ((bfd *, unsigned int));
static bfd_boolean mips_elf_create_dynamic_relocation
PARAMS ((bfd *, struct bfd_link_info *, const Elf_Internal_Rela *,
struct mips_elf_link_hash_entry *, asection *,
bfd_vma, bfd_vma *, asection *));
static void mips_set_isa_flags PARAMS ((bfd *));
static INLINE char* elf_mips_abi_name PARAMS ((bfd *));
static void mips_elf_irix6_finish_dynamic_symbol
PARAMS ((bfd *, const char *, Elf_Internal_Sym *));
static bfd_boolean mips_mach_extends_p PARAMS ((unsigned long, unsigned long));
static bfd_boolean mips_32bit_flags_p PARAMS ((flagword));
static INLINE hashval_t mips_elf_hash_bfd_vma PARAMS ((bfd_vma));
static hashval_t mips_elf_got_entry_hash PARAMS ((const PTR));
static int mips_elf_got_entry_eq PARAMS ((const PTR, const PTR));
static bfd_boolean mips_elf_multi_got
PARAMS ((bfd *, struct bfd_link_info *, struct mips_got_info *,
asection *, bfd_size_type));
static hashval_t mips_elf_multi_got_entry_hash PARAMS ((const PTR));
static int mips_elf_multi_got_entry_eq PARAMS ((const PTR, const PTR));
static hashval_t mips_elf_bfd2got_entry_hash PARAMS ((const PTR));
static int mips_elf_bfd2got_entry_eq PARAMS ((const PTR, const PTR));
static int mips_elf_make_got_per_bfd PARAMS ((void **, void *));
static int mips_elf_merge_gots PARAMS ((void **, void *));
static int mips_elf_set_global_got_offset PARAMS ((void**, void *));
static int mips_elf_resolve_final_got_entry PARAMS ((void**, void *));
static void mips_elf_resolve_final_got_entries
PARAMS ((struct mips_got_info *));
static bfd_vma mips_elf_adjust_gp
PARAMS ((bfd *, struct mips_got_info *, bfd *));
static struct mips_got_info *mips_elf_got_for_ibfd
PARAMS ((struct mips_got_info *, bfd *));
/* This will be used when we sort the dynamic relocation records. */
static bfd *reldyn_sorting_bfd;
/* Nonzero if ABFD is using the N32 ABI. */
#define ABI_N32_P(abfd) \
((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI2) != 0)
/* Nonzero if ABFD is using the N64 ABI. */
#define ABI_64_P(abfd) \
(get_elf_backend_data (abfd)->s->elfclass == ELFCLASS64)
/* Nonzero if ABFD is using NewABI conventions. */
#define NEWABI_P(abfd) (ABI_N32_P (abfd) || ABI_64_P (abfd))
/* The IRIX compatibility level we are striving for. */
#define IRIX_COMPAT(abfd) \
(get_elf_backend_data (abfd)->elf_backend_mips_irix_compat (abfd))
/* Whether we are trying to be compatible with IRIX at all. */
#define SGI_COMPAT(abfd) \
(IRIX_COMPAT (abfd) != ict_none)
/* The name of the options section. */
#define MIPS_ELF_OPTIONS_SECTION_NAME(abfd) \
(NEWABI_P (abfd) ? ".MIPS.options" : ".options")
/* The name of the stub section. */
#define MIPS_ELF_STUB_SECTION_NAME(abfd) \
(NEWABI_P (abfd) ? ".MIPS.stubs" : ".stub")
/* The size of an external REL relocation. */
#define MIPS_ELF_REL_SIZE(abfd) \
(get_elf_backend_data (abfd)->s->sizeof_rel)
/* The size of an external dynamic table entry. */
#define MIPS_ELF_DYN_SIZE(abfd) \
(get_elf_backend_data (abfd)->s->sizeof_dyn)
/* The size of a GOT entry. */
#define MIPS_ELF_GOT_SIZE(abfd) \
(get_elf_backend_data (abfd)->s->arch_size / 8)
/* The size of a symbol-table entry. */
#define MIPS_ELF_SYM_SIZE(abfd) \
(get_elf_backend_data (abfd)->s->sizeof_sym)
/* The default alignment for sections, as a power of two. */
#define MIPS_ELF_LOG_FILE_ALIGN(abfd) \
(get_elf_backend_data (abfd)->s->log_file_align)
/* Get word-sized data. */
#define MIPS_ELF_GET_WORD(abfd, ptr) \
(ABI_64_P (abfd) ? bfd_get_64 (abfd, ptr) : bfd_get_32 (abfd, ptr))
/* Put out word-sized data. */
#define MIPS_ELF_PUT_WORD(abfd, val, ptr) \
(ABI_64_P (abfd) \
? bfd_put_64 (abfd, val, ptr) \
: bfd_put_32 (abfd, val, ptr))
/* Add a dynamic symbol table-entry. */
#ifdef BFD64
#define MIPS_ELF_ADD_DYNAMIC_ENTRY(info, tag, val) \
(ABI_64_P (elf_hash_table (info)->dynobj) \
? bfd_elf64_add_dynamic_entry (info, (bfd_vma) tag, (bfd_vma) val) \
: bfd_elf32_add_dynamic_entry (info, (bfd_vma) tag, (bfd_vma) val))
#else
#define MIPS_ELF_ADD_DYNAMIC_ENTRY(info, tag, val) \
(ABI_64_P (elf_hash_table (info)->dynobj) \
? (abort (), FALSE) \
: bfd_elf32_add_dynamic_entry (info, (bfd_vma) tag, (bfd_vma) val))
#endif
#define MIPS_ELF_RTYPE_TO_HOWTO(abfd, rtype, rela) \
(get_elf_backend_data (abfd)->elf_backend_mips_rtype_to_howto (rtype, rela))
/* Determine whether the internal relocation of index REL_IDX is REL
(zero) or RELA (non-zero). The assumption is that, if there are
two relocation sections for this section, one of them is REL and
the other is RELA. If the index of the relocation we're testing is
in range for the first relocation section, check that the external
relocation size is that for RELA. It is also assumed that, if
rel_idx is not in range for the first section, and this first
section contains REL relocs, then the relocation is in the second
section, that is RELA. */
#define MIPS_RELOC_RELA_P(abfd, sec, rel_idx) \
((NUM_SHDR_ENTRIES (&elf_section_data (sec)->rel_hdr) \
* get_elf_backend_data (abfd)->s->int_rels_per_ext_rel \
> (bfd_vma)(rel_idx)) \
== (elf_section_data (sec)->rel_hdr.sh_entsize \
== (ABI_64_P (abfd) ? sizeof (Elf64_External_Rela) \
: sizeof (Elf32_External_Rela))))
/* In case we're on a 32-bit machine, construct a 64-bit "-1" value
from smaller values. Start with zero, widen, *then* decrement. */
#define MINUS_ONE (((bfd_vma)0) - 1)
/* The number of local .got entries we reserve. */
#define MIPS_RESERVED_GOTNO (2)
/* The offset of $gp from the beginning of the .got section. */
#define ELF_MIPS_GP_OFFSET(abfd) (0x7ff0)
/* The maximum size of the GOT for it to be addressable using 16-bit
offsets from $gp. */
#define MIPS_ELF_GOT_MAX_SIZE(abfd) (ELF_MIPS_GP_OFFSET(abfd) + 0x7fff)
/* Instructions which appear in a stub. For some reason the stub is
slightly different on an SGI system. */
#define STUB_LW(abfd) \
((ABI_64_P (abfd) \
? 0xdf998010 /* ld t9,0x8010(gp) */ \
: 0x8f998010)) /* lw t9,0x8010(gp) */
#define STUB_MOVE(abfd) \
(SGI_COMPAT (abfd) ? 0x03e07825 : 0x03e07821) /* move t7,ra */
#define STUB_JALR 0x0320f809 /* jal t9 */
#define STUB_LI16(abfd) \
(SGI_COMPAT (abfd) ? 0x34180000 : 0x24180000) /* ori t8,zero,0 */
#define MIPS_FUNCTION_STUB_SIZE (16)
/* The name of the dynamic interpreter. This is put in the .interp
section. */
#define ELF_DYNAMIC_INTERPRETER(abfd) \
(ABI_N32_P (abfd) ? "/usr/lib32/libc.so.1" \
: ABI_64_P (abfd) ? "/usr/lib64/libc.so.1" \
: "/usr/lib/libc.so.1")
#ifdef BFD64
#define MNAME(bfd,pre,pos) \
(ABI_64_P (bfd) ? CONCAT4 (pre,64,_,pos) : CONCAT4 (pre,32,_,pos))
#define ELF_R_SYM(bfd, i) \
(ABI_64_P (bfd) ? ELF64_R_SYM (i) : ELF32_R_SYM (i))
#define ELF_R_TYPE(bfd, i) \
(ABI_64_P (bfd) ? ELF64_MIPS_R_TYPE (i) : ELF32_R_TYPE (i))
#define ELF_R_INFO(bfd, s, t) \
(ABI_64_P (bfd) ? ELF64_R_INFO (s, t) : ELF32_R_INFO (s, t))
#else
#define MNAME(bfd,pre,pos) CONCAT4 (pre,32,_,pos)
#define ELF_R_SYM(bfd, i) \
(ELF32_R_SYM (i))
#define ELF_R_TYPE(bfd, i) \
(ELF32_R_TYPE (i))
#define ELF_R_INFO(bfd, s, t) \
(ELF32_R_INFO (s, t))
#endif
/* The mips16 compiler uses a couple of special sections to handle
floating point arguments.
Section names that look like .mips16.fn.FNNAME contain stubs that
copy floating point arguments from the fp regs to the gp regs and
then jump to FNNAME. If any 32 bit function calls FNNAME, the
call should be redirected to the stub instead. If no 32 bit
function calls FNNAME, the stub should be discarded. We need to
consider any reference to the function, not just a call, because
if the address of the function is taken we will need the stub,
since the address might be passed to a 32 bit function.
Section names that look like .mips16.call.FNNAME contain stubs
that copy floating point arguments from the gp regs to the fp
regs and then jump to FNNAME. If FNNAME is a 32 bit function,
then any 16 bit function that calls FNNAME should be redirected
to the stub instead. If FNNAME is not a 32 bit function, the
stub should be discarded.
.mips16.call.fp.FNNAME sections are similar, but contain stubs
which call FNNAME and then copy the return value from the fp regs
to the gp regs. These stubs store the return value in $18 while
calling FNNAME; any function which might call one of these stubs
must arrange to save $18 around the call. (This case is not
needed for 32 bit functions that call 16 bit functions, because
16 bit functions always return floating point values in both
$f0/$f1 and $2/$3.)
Note that in all cases FNNAME might be defined statically.
Therefore, FNNAME is not used literally. Instead, the relocation
information will indicate which symbol the section is for.
We record any stubs that we find in the symbol table. */
#define FN_STUB ".mips16.fn."
#define CALL_STUB ".mips16.call."
#define CALL_FP_STUB ".mips16.call.fp."
/* Look up an entry in a MIPS ELF linker hash table. */
#define mips_elf_link_hash_lookup(table, string, create, copy, follow) \
((struct mips_elf_link_hash_entry *) \
elf_link_hash_lookup (&(table)->root, (string), (create), \
(copy), (follow)))
/* Traverse a MIPS ELF linker hash table. */
#define mips_elf_link_hash_traverse(table, func, info) \
(elf_link_hash_traverse \
(&(table)->root, \
(bfd_boolean (*) PARAMS ((struct elf_link_hash_entry *, PTR))) (func), \
(info)))
/* Get the MIPS ELF linker hash table from a link_info structure. */
#define mips_elf_hash_table(p) \
((struct mips_elf_link_hash_table *) ((p)->hash))
/* Create an entry in a MIPS ELF linker hash table. */
static struct bfd_hash_entry *
mips_elf_link_hash_newfunc (entry, table, string)
struct bfd_hash_entry *entry;
struct bfd_hash_table *table;
const char *string;
{
struct mips_elf_link_hash_entry *ret =
(struct mips_elf_link_hash_entry *) entry;
/* Allocate the structure if it has not already been allocated by a
subclass. */
if (ret == (struct mips_elf_link_hash_entry *) NULL)
ret = ((struct mips_elf_link_hash_entry *)
bfd_hash_allocate (table,
sizeof (struct mips_elf_link_hash_entry)));
if (ret == (struct mips_elf_link_hash_entry *) NULL)
return (struct bfd_hash_entry *) ret;
/* Call the allocation method of the superclass. */
ret = ((struct mips_elf_link_hash_entry *)
_bfd_elf_link_hash_newfunc ((struct bfd_hash_entry *) ret,
table, string));
if (ret != (struct mips_elf_link_hash_entry *) NULL)
{
/* Set local fields. */
memset (&ret->esym, 0, sizeof (EXTR));
/* We use -2 as a marker to indicate that the information has
not been set. -1 means there is no associated ifd. */
ret->esym.ifd = -2;
ret->possibly_dynamic_relocs = 0;
ret->readonly_reloc = FALSE;
ret->no_fn_stub = FALSE;
ret->fn_stub = NULL;
ret->need_fn_stub = FALSE;
ret->call_stub = NULL;
ret->call_fp_stub = NULL;
ret->forced_local = FALSE;
}
return (struct bfd_hash_entry *) ret;
}
bfd_boolean
_bfd_mips_elf_new_section_hook (abfd, sec)
bfd *abfd;
asection *sec;
{
struct _mips_elf_section_data *sdata;
bfd_size_type amt = sizeof (*sdata);
sdata = (struct _mips_elf_section_data *) bfd_zalloc (abfd, amt);
if (sdata == NULL)
return FALSE;
sec->used_by_bfd = (PTR) sdata;
return _bfd_elf_new_section_hook (abfd, sec);
}
/* Read ECOFF debugging information from a .mdebug section into a
ecoff_debug_info structure. */
bfd_boolean
_bfd_mips_elf_read_ecoff_info (abfd, section, debug)
bfd *abfd;
asection *section;
struct ecoff_debug_info *debug;
{
HDRR *symhdr;
const struct ecoff_debug_swap *swap;
char *ext_hdr = NULL;
swap = get_elf_backend_data (abfd)->elf_backend_ecoff_debug_swap;
memset (debug, 0, sizeof (*debug));
ext_hdr = (char *) bfd_malloc (swap->external_hdr_size);
if (ext_hdr == NULL && swap->external_hdr_size != 0)
goto error_return;
if (! bfd_get_section_contents (abfd, section, ext_hdr, (file_ptr) 0,
swap->external_hdr_size))
goto error_return;
symhdr = &debug->symbolic_header;
(*swap->swap_hdr_in) (abfd, ext_hdr, symhdr);
/* The symbolic header contains absolute file offsets and sizes to
read. */
#define READ(ptr, offset, count, size, type) \
if (symhdr->count == 0) \
debug->ptr = NULL; \
else \
{ \
bfd_size_type amt = (bfd_size_type) size * symhdr->count; \
debug->ptr = (type) bfd_malloc (amt); \
if (debug->ptr == NULL) \
goto error_return; \
if (bfd_seek (abfd, (file_ptr) symhdr->offset, SEEK_SET) != 0 \
|| bfd_bread (debug->ptr, amt, abfd) != amt) \
goto error_return; \
}
READ (line, cbLineOffset, cbLine, sizeof (unsigned char), unsigned char *);
READ (external_dnr, cbDnOffset, idnMax, swap->external_dnr_size, PTR);
READ (external_pdr, cbPdOffset, ipdMax, swap->external_pdr_size, PTR);
READ (external_sym, cbSymOffset, isymMax, swap->external_sym_size, PTR);
READ (external_opt, cbOptOffset, ioptMax, swap->external_opt_size, PTR);
READ (external_aux, cbAuxOffset, iauxMax, sizeof (union aux_ext),
union aux_ext *);
READ (ss, cbSsOffset, issMax, sizeof (char), char *);
READ (ssext, cbSsExtOffset, issExtMax, sizeof (char), char *);
READ (external_fdr, cbFdOffset, ifdMax, swap->external_fdr_size, PTR);
READ (external_rfd, cbRfdOffset, crfd, swap->external_rfd_size, PTR);
READ (external_ext, cbExtOffset, iextMax, swap->external_ext_size, PTR);
#undef READ
debug->fdr = NULL;
debug->adjust = NULL;
return TRUE;
error_return:
if (ext_hdr != NULL)
free (ext_hdr);
if (debug->line != NULL)
free (debug->line);
if (debug->external_dnr != NULL)
free (debug->external_dnr);
if (debug->external_pdr != NULL)
free (debug->external_pdr);
if (debug->external_sym != NULL)
free (debug->external_sym);
if (debug->external_opt != NULL)
free (debug->external_opt);
if (debug->external_aux != NULL)
free (debug->external_aux);
if (debug->ss != NULL)
free (debug->ss);
if (debug->ssext != NULL)
free (debug->ssext);
if (debug->external_fdr != NULL)
free (debug->external_fdr);
if (debug->external_rfd != NULL)
free (debug->external_rfd);
if (debug->external_ext != NULL)
free (debug->external_ext);
return FALSE;
}
/* Swap RPDR (runtime procedure table entry) for output. */
static void
ecoff_swap_rpdr_out (abfd, in, ex)
bfd *abfd;
const RPDR *in;
struct rpdr_ext *ex;
{
H_PUT_S32 (abfd, in->adr, ex->p_adr);
H_PUT_32 (abfd, in->regmask, ex->p_regmask);
H_PUT_32 (abfd, in->regoffset, ex->p_regoffset);
H_PUT_32 (abfd, in->fregmask, ex->p_fregmask);
H_PUT_32 (abfd, in->fregoffset, ex->p_fregoffset);
H_PUT_32 (abfd, in->frameoffset, ex->p_frameoffset);
H_PUT_16 (abfd, in->framereg, ex->p_framereg);
H_PUT_16 (abfd, in->pcreg, ex->p_pcreg);
H_PUT_32 (abfd, in->irpss, ex->p_irpss);
#if 0 /* FIXME */
H_PUT_S32 (abfd, in->exception_info, ex->p_exception_info);
#endif
}
/* Create a runtime procedure table from the .mdebug section. */
static bfd_boolean
mips_elf_create_procedure_table (handle, abfd, info, s, debug)
PTR handle;
bfd *abfd;
struct bfd_link_info *info;
asection *s;
struct ecoff_debug_info *debug;
{
const struct ecoff_debug_swap *swap;
HDRR *hdr = &debug->symbolic_header;
RPDR *rpdr, *rp;
struct rpdr_ext *erp;
PTR rtproc;
struct pdr_ext *epdr;
struct sym_ext *esym;
char *ss, **sv;
char *str;
bfd_size_type size;
bfd_size_type count;
unsigned long sindex;
unsigned long i;
PDR pdr;
SYMR sym;
const char *no_name_func = _("static procedure (no name)");
epdr = NULL;
rpdr = NULL;
esym = NULL;
ss = NULL;
sv = NULL;
swap = get_elf_backend_data (abfd)->elf_backend_ecoff_debug_swap;
sindex = strlen (no_name_func) + 1;
count = hdr->ipdMax;
if (count > 0)
{
size = swap->external_pdr_size;
epdr = (struct pdr_ext *) bfd_malloc (size * count);
if (epdr == NULL)
goto error_return;
if (! _bfd_ecoff_get_accumulated_pdr (handle, (PTR) epdr))
goto error_return;
size = sizeof (RPDR);
rp = rpdr = (RPDR *) bfd_malloc (size * count);
if (rpdr == NULL)
goto error_return;
size = sizeof (char *);
sv = (char **) bfd_malloc (size * count);
if (sv == NULL)
goto error_return;
count = hdr->isymMax;
size = swap->external_sym_size;
esym = (struct sym_ext *) bfd_malloc (size * count);
if (esym == NULL)
goto error_return;
if (! _bfd_ecoff_get_accumulated_sym (handle, (PTR) esym))
goto error_return;
count = hdr->issMax;
ss = (char *) bfd_malloc (count);
if (ss == NULL)
goto error_return;
if (! _bfd_ecoff_get_accumulated_ss (handle, (PTR) ss))
goto error_return;
count = hdr->ipdMax;
for (i = 0; i < (unsigned long) count; i++, rp++)
{
(*swap->swap_pdr_in) (abfd, (PTR) (epdr + i), &pdr);
(*swap->swap_sym_in) (abfd, (PTR) &esym[pdr.isym], &sym);
rp->adr = sym.value;
rp->regmask = pdr.regmask;
rp->regoffset = pdr.regoffset;
rp->fregmask = pdr.fregmask;
rp->fregoffset = pdr.fregoffset;
rp->frameoffset = pdr.frameoffset;
rp->framereg = pdr.framereg;
rp->pcreg = pdr.pcreg;
rp->irpss = sindex;
sv[i] = ss + sym.iss;
sindex += strlen (sv[i]) + 1;
}
}
size = sizeof (struct rpdr_ext) * (count + 2) + sindex;
size = BFD_ALIGN (size, 16);
rtproc = (PTR) bfd_alloc (abfd, size);
if (rtproc == NULL)
{
mips_elf_hash_table (info)->procedure_count = 0;
goto error_return;
}
mips_elf_hash_table (info)->procedure_count = count + 2;
erp = (struct rpdr_ext *) rtproc;
memset (erp, 0, sizeof (struct rpdr_ext));
erp++;
str = (char *) rtproc + sizeof (struct rpdr_ext) * (count + 2);
strcpy (str, no_name_func);
str += strlen (no_name_func) + 1;
for (i = 0; i < count; i++)
{
ecoff_swap_rpdr_out (abfd, rpdr + i, erp + i);
strcpy (str, sv[i]);
str += strlen (sv[i]) + 1;
}
H_PUT_S32 (abfd, -1, (erp + count)->p_adr);
/* Set the size and contents of .rtproc section. */
s->_raw_size = size;
s->contents = (bfd_byte *) rtproc;
/* Skip this section later on (I don't think this currently
matters, but someday it might). */
s->link_order_head = (struct bfd_link_order *) NULL;
if (epdr != NULL)
free (epdr);
if (rpdr != NULL)
free (rpdr);
if (esym != NULL)
free (esym);
if (ss != NULL)
free (ss);
if (sv != NULL)
free (sv);
return TRUE;
error_return:
if (epdr != NULL)
free (epdr);
if (rpdr != NULL)
free (rpdr);
if (esym != NULL)
free (esym);
if (ss != NULL)
free (ss);
if (sv != NULL)
free (sv);
return FALSE;
}
/* Check the mips16 stubs for a particular symbol, and see if we can
discard them. */
static bfd_boolean
mips_elf_check_mips16_stubs (h, data)
struct mips_elf_link_hash_entry *h;
PTR data ATTRIBUTE_UNUSED;
{
if (h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
if (h->fn_stub != NULL
&& ! h->need_fn_stub)
{
/* We don't need the fn_stub; the only references to this symbol
are 16 bit calls. Clobber the size to 0 to prevent it from
being included in the link. */
h->fn_stub->_raw_size = 0;
h->fn_stub->_cooked_size = 0;
h->fn_stub->flags &= ~SEC_RELOC;
h->fn_stub->reloc_count = 0;
h->fn_stub->flags |= SEC_EXCLUDE;
}
if (h->call_stub != NULL
&& h->root.other == STO_MIPS16)
{
/* We don't need the call_stub; this is a 16 bit function, so
calls from other 16 bit functions are OK. Clobber the size
to 0 to prevent it from being included in the link. */
h->call_stub->_raw_size = 0;
h->call_stub->_cooked_size = 0;
h->call_stub->flags &= ~SEC_RELOC;
h->call_stub->reloc_count = 0;
h->call_stub->flags |= SEC_EXCLUDE;
}
if (h->call_fp_stub != NULL
&& h->root.other == STO_MIPS16)
{
/* We don't need the call_stub; this is a 16 bit function, so
calls from other 16 bit functions are OK. Clobber the size
to 0 to prevent it from being included in the link. */
h->call_fp_stub->_raw_size = 0;
h->call_fp_stub->_cooked_size = 0;
h->call_fp_stub->flags &= ~SEC_RELOC;
h->call_fp_stub->reloc_count = 0;
h->call_fp_stub->flags |= SEC_EXCLUDE;
}
return TRUE;
}
bfd_reloc_status_type
_bfd_mips_elf_gprel16_with_gp (abfd, symbol, reloc_entry, input_section,
relocatable, data, gp)
bfd *abfd;
asymbol *symbol;
arelent *reloc_entry;
asection *input_section;
bfd_boolean relocatable;
PTR data;
bfd_vma gp;
{
bfd_vma relocation;
unsigned long insn = 0;
bfd_signed_vma val;
if (bfd_is_com_section (symbol->section))
relocation = 0;
else
relocation = symbol->value;
relocation += symbol->section->output_section->vma;
relocation += symbol->section->output_offset;
if (reloc_entry->address > input_section->_cooked_size)
return bfd_reloc_outofrange;
/* Set val to the offset into the section or symbol. */
val = reloc_entry->addend;
if (reloc_entry->howto->partial_inplace)
{
insn = bfd_get_32 (abfd, (bfd_byte *) data + reloc_entry->address);
val += insn & 0xffff;
}
_bfd_mips_elf_sign_extend(val, 16);
/* Adjust val for the final section location and GP value. If we
are producing relocatable output, we don't want to do this for
an external symbol. */
if (! relocatable
|| (symbol->flags & BSF_SECTION_SYM) != 0)
val += relocation - gp;
if (reloc_entry->howto->partial_inplace)
{
insn = (insn & ~0xffff) | (val & 0xffff);
bfd_put_32 (abfd, (bfd_vma) insn,
(bfd_byte *) data + reloc_entry->address);
}
else
reloc_entry->addend = val;
if (relocatable)
reloc_entry->address += input_section->output_offset;
else if (((val & ~0xffff) != ~0xffff) && ((val & ~0xffff) != 0))
return bfd_reloc_overflow;
return bfd_reloc_ok;
}
/* Swap an entry in a .gptab section. Note that these routines rely
on the equivalence of the two elements of the union. */
static void
bfd_mips_elf32_swap_gptab_in (abfd, ex, in)
bfd *abfd;
const Elf32_External_gptab *ex;
Elf32_gptab *in;
{
in->gt_entry.gt_g_value = H_GET_32 (abfd, ex->gt_entry.gt_g_value);
in->gt_entry.gt_bytes = H_GET_32 (abfd, ex->gt_entry.gt_bytes);
}
static void
bfd_mips_elf32_swap_gptab_out (abfd, in, ex)
bfd *abfd;
const Elf32_gptab *in;
Elf32_External_gptab *ex;
{
H_PUT_32 (abfd, in->gt_entry.gt_g_value, ex->gt_entry.gt_g_value);
H_PUT_32 (abfd, in->gt_entry.gt_bytes, ex->gt_entry.gt_bytes);
}
static void
bfd_elf32_swap_compact_rel_out (abfd, in, ex)
bfd *abfd;
const Elf32_compact_rel *in;
Elf32_External_compact_rel *ex;
{
H_PUT_32 (abfd, in->id1, ex->id1);
H_PUT_32 (abfd, in->num, ex->num);
H_PUT_32 (abfd, in->id2, ex->id2);
H_PUT_32 (abfd, in->offset, ex->offset);
H_PUT_32 (abfd, in->reserved0, ex->reserved0);
H_PUT_32 (abfd, in->reserved1, ex->reserved1);
}
static void
bfd_elf32_swap_crinfo_out (abfd, in, ex)
bfd *abfd;
const Elf32_crinfo *in;
Elf32_External_crinfo *ex;
{
unsigned long l;
l = (((in->ctype & CRINFO_CTYPE) << CRINFO_CTYPE_SH)
| ((in->rtype & CRINFO_RTYPE) << CRINFO_RTYPE_SH)
| ((in->dist2to & CRINFO_DIST2TO) << CRINFO_DIST2TO_SH)
| ((in->relvaddr & CRINFO_RELVADDR) << CRINFO_RELVADDR_SH));
H_PUT_32 (abfd, l, ex->info);
H_PUT_32 (abfd, in->konst, ex->konst);
H_PUT_32 (abfd, in->vaddr, ex->vaddr);
}
/* A .reginfo section holds a single Elf32_RegInfo structure. These
routines swap this structure in and out. They are used outside of
BFD, so they are globally visible. */
void
bfd_mips_elf32_swap_reginfo_in (abfd, ex, in)
bfd *abfd;
const Elf32_External_RegInfo *ex;
Elf32_RegInfo *in;
{
in->ri_gprmask = H_GET_32 (abfd, ex->ri_gprmask);
in->ri_cprmask[0] = H_GET_32 (abfd, ex->ri_cprmask[0]);
in->ri_cprmask[1] = H_GET_32 (abfd, ex->ri_cprmask[1]);
in->ri_cprmask[2] = H_GET_32 (abfd, ex->ri_cprmask[2]);
in->ri_cprmask[3] = H_GET_32 (abfd, ex->ri_cprmask[3]);
in->ri_gp_value = H_GET_32 (abfd, ex->ri_gp_value);
}
void
bfd_mips_elf32_swap_reginfo_out (abfd, in, ex)
bfd *abfd;
const Elf32_RegInfo *in;
Elf32_External_RegInfo *ex;
{
H_PUT_32 (abfd, in->ri_gprmask, ex->ri_gprmask);
H_PUT_32 (abfd, in->ri_cprmask[0], ex->ri_cprmask[0]);
H_PUT_32 (abfd, in->ri_cprmask[1], ex->ri_cprmask[1]);
H_PUT_32 (abfd, in->ri_cprmask[2], ex->ri_cprmask[2]);
H_PUT_32 (abfd, in->ri_cprmask[3], ex->ri_cprmask[3]);
H_PUT_32 (abfd, in->ri_gp_value, ex->ri_gp_value);
}
/* In the 64 bit ABI, the .MIPS.options section holds register
information in an Elf64_Reginfo structure. These routines swap
them in and out. They are globally visible because they are used
outside of BFD. These routines are here so that gas can call them
without worrying about whether the 64 bit ABI has been included. */
void
bfd_mips_elf64_swap_reginfo_in (abfd, ex, in)
bfd *abfd;
const Elf64_External_RegInfo *ex;
Elf64_Internal_RegInfo *in;
{
in->ri_gprmask = H_GET_32 (abfd, ex->ri_gprmask);
in->ri_pad = H_GET_32 (abfd, ex->ri_pad);
in->ri_cprmask[0] = H_GET_32 (abfd, ex->ri_cprmask[0]);
in->ri_cprmask[1] = H_GET_32 (abfd, ex->ri_cprmask[1]);
in->ri_cprmask[2] = H_GET_32 (abfd, ex->ri_cprmask[2]);
in->ri_cprmask[3] = H_GET_32 (abfd, ex->ri_cprmask[3]);
in->ri_gp_value = H_GET_64 (abfd, ex->ri_gp_value);
}
void
bfd_mips_elf64_swap_reginfo_out (abfd, in, ex)
bfd *abfd;
const Elf64_Internal_RegInfo *in;
Elf64_External_RegInfo *ex;
{
H_PUT_32 (abfd, in->ri_gprmask, ex->ri_gprmask);
H_PUT_32 (abfd, in->ri_pad, ex->ri_pad);
H_PUT_32 (abfd, in->ri_cprmask[0], ex->ri_cprmask[0]);
H_PUT_32 (abfd, in->ri_cprmask[1], ex->ri_cprmask[1]);
H_PUT_32 (abfd, in->ri_cprmask[2], ex->ri_cprmask[2]);
H_PUT_32 (abfd, in->ri_cprmask[3], ex->ri_cprmask[3]);
H_PUT_64 (abfd, in->ri_gp_value, ex->ri_gp_value);
}
/* Swap in an options header. */
void
bfd_mips_elf_swap_options_in (abfd, ex, in)
bfd *abfd;
const Elf_External_Options *ex;
Elf_Internal_Options *in;
{
in->kind = H_GET_8 (abfd, ex->kind);
in->size = H_GET_8 (abfd, ex->size);
in->section = H_GET_16 (abfd, ex->section);
in->info = H_GET_32 (abfd, ex->info);
}
/* Swap out an options header. */
void
bfd_mips_elf_swap_options_out (abfd, in, ex)
bfd *abfd;
const Elf_Internal_Options *in;
Elf_External_Options *ex;
{
H_PUT_8 (abfd, in->kind, ex->kind);
H_PUT_8 (abfd, in->size, ex->size);
H_PUT_16 (abfd, in->section, ex->section);
H_PUT_32 (abfd, in->info, ex->info);
}
/* This function is called via qsort() to sort the dynamic relocation
entries by increasing r_symndx value. */
static int
sort_dynamic_relocs (arg1, arg2)
const PTR arg1;
const PTR arg2;
{
Elf_Internal_Rela int_reloc1;
Elf_Internal_Rela int_reloc2;
bfd_elf32_swap_reloc_in (reldyn_sorting_bfd, arg1, &int_reloc1);
bfd_elf32_swap_reloc_in (reldyn_sorting_bfd, arg2, &int_reloc2);
return ELF32_R_SYM (int_reloc1.r_info) - ELF32_R_SYM (int_reloc2.r_info);
}
/* Like sort_dynamic_relocs, but used for elf64 relocations. */
static int
sort_dynamic_relocs_64 (arg1, arg2)
const PTR arg1;
const PTR arg2;
{
Elf_Internal_Rela int_reloc1[3];
Elf_Internal_Rela int_reloc2[3];
(*get_elf_backend_data (reldyn_sorting_bfd)->s->swap_reloc_in)
(reldyn_sorting_bfd, arg1, int_reloc1);
(*get_elf_backend_data (reldyn_sorting_bfd)->s->swap_reloc_in)
(reldyn_sorting_bfd, arg2, int_reloc2);
return (ELF64_R_SYM (int_reloc1[0].r_info)
- ELF64_R_SYM (int_reloc2[0].r_info));
}
/* This routine is used to write out ECOFF debugging external symbol
information. It is called via mips_elf_link_hash_traverse. The
ECOFF external symbol information must match the ELF external
symbol information. Unfortunately, at this point we don't know
whether a symbol is required by reloc information, so the two
tables may wind up being different. We must sort out the external
symbol information before we can set the final size of the .mdebug
section, and we must set the size of the .mdebug section before we
can relocate any sections, and we can't know which symbols are
required by relocation until we relocate the sections.
Fortunately, it is relatively unlikely that any symbol will be
stripped but required by a reloc. In particular, it can not happen
when generating a final executable. */
static bfd_boolean
mips_elf_output_extsym (h, data)
struct mips_elf_link_hash_entry *h;
PTR data;
{
struct extsym_info *einfo = (struct extsym_info *) data;
bfd_boolean strip;
asection *sec, *output_section;
if (h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
if (h->root.indx == -2)
strip = FALSE;
else if (((h->root.elf_link_hash_flags & ELF_LINK_HASH_DEF_DYNAMIC) != 0
|| (h->root.elf_link_hash_flags & ELF_LINK_HASH_REF_DYNAMIC) != 0)
&& (h->root.elf_link_hash_flags & ELF_LINK_HASH_DEF_REGULAR) == 0
&& (h->root.elf_link_hash_flags & ELF_LINK_HASH_REF_REGULAR) == 0)
strip = TRUE;
else if (einfo->info->strip == strip_all
|| (einfo->info->strip == strip_some
&& bfd_hash_lookup (einfo->info->keep_hash,
h->root.root.root.string,
FALSE, FALSE) == NULL))
strip = TRUE;
else
strip = FALSE;
if (strip)
return TRUE;
if (h->esym.ifd == -2)
{
h->esym.jmptbl = 0;
h->esym.cobol_main = 0;
h->esym.weakext = 0;
h->esym.reserved = 0;
h->esym.ifd = ifdNil;
h->esym.asym.value = 0;
h->esym.asym.st = stGlobal;
if (h->root.root.type == bfd_link_hash_undefined
|| h->root.root.type == bfd_link_hash_undefweak)
{
const char *name;
/* Use undefined class. Also, set class and type for some
special symbols. */
name = h->root.root.root.string;
if (strcmp (name, mips_elf_dynsym_rtproc_names[0]) == 0
|| strcmp (name, mips_elf_dynsym_rtproc_names[1]) == 0)
{
h->esym.asym.sc = scData;
h->esym.asym.st = stLabel;
h->esym.asym.value = 0;
}
else if (strcmp (name, mips_elf_dynsym_rtproc_names[2]) == 0)
{
h->esym.asym.sc = scAbs;
h->esym.asym.st = stLabel;
h->esym.asym.value =
mips_elf_hash_table (einfo->info)->procedure_count;
}
else if (strcmp (name, "_gp_disp") == 0 && ! NEWABI_P (einfo->abfd))
{
h->esym.asym.sc = scAbs;
h->esym.asym.st = stLabel;
h->esym.asym.value = elf_gp (einfo->abfd);
}
else
h->esym.asym.sc = scUndefined;
}
else if (h->root.root.type != bfd_link_hash_defined
&& h->root.root.type != bfd_link_hash_defweak)
h->esym.asym.sc = scAbs;
else
{
const char *name;
sec = h->root.root.u.def.section;
output_section = sec->output_section;
/* When making a shared library and symbol h is the one from
the another shared library, OUTPUT_SECTION may be null. */
if (output_section == NULL)
h->esym.asym.sc = scUndefined;
else
{
name = bfd_section_name (output_section->owner, output_section);
if (strcmp (name, ".text") == 0)
h->esym.asym.sc = scText;
else if (strcmp (name, ".data") == 0)
h->esym.asym.sc = scData;
else if (strcmp (name, ".sdata") == 0)
h->esym.asym.sc = scSData;
else if (strcmp (name, ".rodata") == 0
|| strcmp (name, ".rdata") == 0)
h->esym.asym.sc = scRData;
else if (strcmp (name, ".bss") == 0)
h->esym.asym.sc = scBss;
else if (strcmp (name, ".sbss") == 0)
h->esym.asym.sc = scSBss;
else if (strcmp (name, ".init") == 0)
h->esym.asym.sc = scInit;
else if (strcmp (name, ".fini") == 0)
h->esym.asym.sc = scFini;
else
h->esym.asym.sc = scAbs;
}
}
h->esym.asym.reserved = 0;
h->esym.asym.index = indexNil;
}
if (h->root.root.type == bfd_link_hash_common)
h->esym.asym.value = h->root.root.u.c.size;
else if (h->root.root.type == bfd_link_hash_defined
|| h->root.root.type == bfd_link_hash_defweak)
{
if (h->esym.asym.sc == scCommon)
h->esym.asym.sc = scBss;
else if (h->esym.asym.sc == scSCommon)
h->esym.asym.sc = scSBss;
sec = h->root.root.u.def.section;
output_section = sec->output_section;
if (output_section != NULL)
h->esym.asym.value = (h->root.root.u.def.value
+ sec->output_offset
+ output_section->vma);
else
h->esym.asym.value = 0;
}
else if ((h->root.elf_link_hash_flags & ELF_LINK_HASH_NEEDS_PLT) != 0)
{
struct mips_elf_link_hash_entry *hd = h;
bfd_boolean no_fn_stub = h->no_fn_stub;
while (hd->root.root.type == bfd_link_hash_indirect)
{
hd = (struct mips_elf_link_hash_entry *)h->root.root.u.i.link;
no_fn_stub = no_fn_stub || hd->no_fn_stub;
}
if (!no_fn_stub)
{
/* Set type and value for a symbol with a function stub. */
h->esym.asym.st = stProc;
sec = hd->root.root.u.def.section;
if (sec == NULL)
h->esym.asym.value = 0;
else
{
output_section = sec->output_section;
if (output_section != NULL)
h->esym.asym.value = (hd->root.plt.offset
+ sec->output_offset
+ output_section->vma);
else
h->esym.asym.value = 0;
}
#if 0 /* FIXME? */
h->esym.ifd = 0;
#endif
}
}
if (! bfd_ecoff_debug_one_external (einfo->abfd, einfo->debug, einfo->swap,
h->root.root.root.string,
&h->esym))
{
einfo->failed = TRUE;
return FALSE;
}
return TRUE;
}
/* A comparison routine used to sort .gptab entries. */
static int
gptab_compare (p1, p2)
const PTR p1;
const PTR p2;
{
const Elf32_gptab *a1 = (const Elf32_gptab *) p1;
const Elf32_gptab *a2 = (const Elf32_gptab *) p2;
return a1->gt_entry.gt_g_value - a2->gt_entry.gt_g_value;
}
/* Functions to manage the got entry hash table. */
/* Use all 64 bits of a bfd_vma for the computation of a 32-bit
hash number. */
static INLINE hashval_t
mips_elf_hash_bfd_vma (addr)
bfd_vma addr;
{
#ifdef BFD64
return addr + (addr >> 32);
#else
return addr;
#endif
}
/* got_entries only match if they're identical, except for gotidx, so
use all fields to compute the hash, and compare the appropriate
union members. */
static hashval_t
mips_elf_got_entry_hash (entry_)
const PTR entry_;
{
const struct mips_got_entry *entry = (struct mips_got_entry *)entry_;
return entry->symndx
+ (! entry->abfd ? mips_elf_hash_bfd_vma (entry->d.address)
: entry->abfd->id
+ (entry->symndx >= 0 ? mips_elf_hash_bfd_vma (entry->d.addend)
: entry->d.h->root.root.root.hash));
}
static int
mips_elf_got_entry_eq (entry1, entry2)
const PTR entry1;
const PTR entry2;
{
const struct mips_got_entry *e1 = (struct mips_got_entry *)entry1;
const struct mips_got_entry *e2 = (struct mips_got_entry *)entry2;
return e1->abfd == e2->abfd && e1->symndx == e2->symndx
&& (! e1->abfd ? e1->d.address == e2->d.address
: e1->symndx >= 0 ? e1->d.addend == e2->d.addend
: e1->d.h == e2->d.h);
}
/* multi_got_entries are still a match in the case of global objects,
even if the input bfd in which they're referenced differs, so the
hash computation and compare functions are adjusted
accordingly. */
static hashval_t
mips_elf_multi_got_entry_hash (entry_)
const PTR entry_;
{
const struct mips_got_entry *entry = (struct mips_got_entry *)entry_;
return entry->symndx
+ (! entry->abfd
? mips_elf_hash_bfd_vma (entry->d.address)
: entry->symndx >= 0
? (entry->abfd->id
+ mips_elf_hash_bfd_vma (entry->d.addend))
: entry->d.h->root.root.root.hash);
}
static int
mips_elf_multi_got_entry_eq (entry1, entry2)
const PTR entry1;
const PTR entry2;
{
const struct mips_got_entry *e1 = (struct mips_got_entry *)entry1;
const struct mips_got_entry *e2 = (struct mips_got_entry *)entry2;
return e1->symndx == e2->symndx
&& (e1->symndx >= 0 ? e1->abfd == e2->abfd && e1->d.addend == e2->d.addend
: e1->abfd == NULL || e2->abfd == NULL
? e1->abfd == e2->abfd && e1->d.address == e2->d.address
: e1->d.h == e2->d.h);
}
/* Returns the dynamic relocation section for DYNOBJ. */
static asection *
mips_elf_rel_dyn_section (dynobj, create_p)
bfd *dynobj;
bfd_boolean create_p;
{
static const char dname[] = ".rel.dyn";
asection *sreloc;
sreloc = bfd_get_section_by_name (dynobj, dname);
if (sreloc == NULL && create_p)
{
sreloc = bfd_make_section (dynobj, dname);
if (sreloc == NULL
|| ! bfd_set_section_flags (dynobj, sreloc,
(SEC_ALLOC
| SEC_LOAD
| SEC_HAS_CONTENTS
| SEC_IN_MEMORY
| SEC_LINKER_CREATED
| SEC_READONLY))
|| ! bfd_set_section_alignment (dynobj, sreloc,
MIPS_ELF_LOG_FILE_ALIGN (dynobj)))
return NULL;
}
return sreloc;
}
/* Returns the GOT section for ABFD. */
static asection *
mips_elf_got_section (abfd, maybe_excluded)
bfd *abfd;
bfd_boolean maybe_excluded;
{
asection *sgot = bfd_get_section_by_name (abfd, ".got");
if (sgot == NULL
|| (! maybe_excluded && (sgot->flags & SEC_EXCLUDE) != 0))
return NULL;
return sgot;
}
/* Returns the GOT information associated with the link indicated by
INFO. If SGOTP is non-NULL, it is filled in with the GOT
section. */
static struct mips_got_info *
mips_elf_got_info (abfd, sgotp)
bfd *abfd;
asection **sgotp;
{
asection *sgot;
struct mips_got_info *g;
sgot = mips_elf_got_section (abfd, TRUE);
BFD_ASSERT (sgot != NULL);
BFD_ASSERT (mips_elf_section_data (sgot) != NULL);
g = mips_elf_section_data (sgot)->u.got_info;
BFD_ASSERT (g != NULL);
if (sgotp)
*sgotp = (sgot->flags & SEC_EXCLUDE) == 0 ? sgot : NULL;
return g;
}
/* Obtain the lowest dynamic index of a symbol that was assigned a
global GOT entry. */
static long
mips_elf_get_global_gotsym_index (abfd)
bfd *abfd;
{
asection *sgot;
struct mips_got_info *g;
if (abfd == NULL)
return 0;
sgot = mips_elf_got_section (abfd, TRUE);
if (sgot == NULL || mips_elf_section_data (sgot) == NULL)
return 0;
g = mips_elf_section_data (sgot)->u.got_info;
if (g == NULL || g->global_gotsym == NULL)
return 0;
return g->global_gotsym->dynindx;
}
/* Returns the GOT offset at which the indicated address can be found.
If there is not yet a GOT entry for this value, create one. Returns
-1 if no satisfactory GOT offset can be found. */
static bfd_vma
mips_elf_local_got_index (abfd, ibfd, info, value)
bfd *abfd, *ibfd;
struct bfd_link_info *info;
bfd_vma value;
{
asection *sgot;
struct mips_got_info *g;
struct mips_got_entry *entry;
g = mips_elf_got_info (elf_hash_table (info)->dynobj, &sgot);
entry = mips_elf_create_local_got_entry (abfd, ibfd, g, sgot, value);
if (entry)
return entry->gotidx;
else
return MINUS_ONE;
}
/* Returns the GOT index for the global symbol indicated by H. */
static bfd_vma
mips_elf_global_got_index (abfd, ibfd, h)
bfd *abfd, *ibfd;
struct elf_link_hash_entry *h;
{
bfd_vma index;
asection *sgot;
struct mips_got_info *g, *gg;
long global_got_dynindx = 0;
gg = g = mips_elf_got_info (abfd, &sgot);
if (g->bfd2got && ibfd)
{
struct mips_got_entry e, *p;
BFD_ASSERT (h->dynindx >= 0);
g = mips_elf_got_for_ibfd (g, ibfd);
if (g->next != gg)
{
e.abfd = ibfd;
e.symndx = -1;
e.d.h = (struct mips_elf_link_hash_entry *)h;
p = (struct mips_got_entry *) htab_find (g->got_entries, &e);
BFD_ASSERT (p->gotidx > 0);
return p->gotidx;
}
}
if (gg->global_gotsym != NULL)
global_got_dynindx = gg->global_gotsym->dynindx;
/* Once we determine the global GOT entry with the lowest dynamic
symbol table index, we must put all dynamic symbols with greater
indices into the GOT. That makes it easy to calculate the GOT
offset. */
BFD_ASSERT (h->dynindx >= global_got_dynindx);
index = ((h->dynindx - global_got_dynindx + g->local_gotno)
* MIPS_ELF_GOT_SIZE (abfd));
BFD_ASSERT (index < sgot->_raw_size);
return index;
}
/* Find a GOT entry that is within 32KB of the VALUE. These entries
are supposed to be placed at small offsets in the GOT, i.e.,
within 32KB of GP. Return the index into the GOT for this page,
and store the offset from this entry to the desired address in
OFFSETP, if it is non-NULL. */
static bfd_vma
mips_elf_got_page (abfd, ibfd, info, value, offsetp)
bfd *abfd, *ibfd;
struct bfd_link_info *info;
bfd_vma value;
bfd_vma *offsetp;
{
asection *sgot;
struct mips_got_info *g;
bfd_vma index;
struct mips_got_entry *entry;
g = mips_elf_got_info (elf_hash_table (info)->dynobj, &sgot);
entry = mips_elf_create_local_got_entry (abfd, ibfd, g, sgot,
(value + 0x8000)
& (~(bfd_vma)0xffff));
if (!entry)
return MINUS_ONE;
index = entry->gotidx;
if (offsetp)
*offsetp = value - entry->d.address;
return index;
}
/* Find a GOT entry whose higher-order 16 bits are the same as those
for value. Return the index into the GOT for this entry. */
static bfd_vma
mips_elf_got16_entry (abfd, ibfd, info, value, external)
bfd *abfd, *ibfd;
struct bfd_link_info *info;
bfd_vma value;
bfd_boolean external;
{
asection *sgot;
struct mips_got_info *g;
struct mips_got_entry *entry;
if (! external)
{
/* Although the ABI says that it is "the high-order 16 bits" that we
want, it is really the %high value. The complete value is
calculated with a `addiu' of a LO16 relocation, just as with a
HI16/LO16 pair. */
value = mips_elf_high (value) << 16;
}
g = mips_elf_got_info (elf_hash_table (info)->dynobj, &sgot);
entry = mips_elf_create_local_got_entry (abfd, ibfd, g, sgot, value);
if (entry)
return entry->gotidx;
else
return MINUS_ONE;
}
/* Returns the offset for the entry at the INDEXth position
in the GOT. */
static bfd_vma
mips_elf_got_offset_from_index (dynobj, output_bfd, input_bfd, index)
bfd *dynobj;
bfd *output_bfd;
bfd *input_bfd;
bfd_vma index;
{
asection *sgot;
bfd_vma gp;
struct mips_got_info *g;
g = mips_elf_got_info (dynobj, &sgot);
gp = _bfd_get_gp_value (output_bfd)
+ mips_elf_adjust_gp (output_bfd, g, input_bfd);
return sgot->output_section->vma + sgot->output_offset + index - gp;
}
/* Create a local GOT entry for VALUE. Return the index of the entry,
or -1 if it could not be created. */
static struct mips_got_entry *
mips_elf_create_local_got_entry (abfd, ibfd, gg, sgot, value)
bfd *abfd, *ibfd;
struct mips_got_info *gg;
asection *sgot;
bfd_vma value;
{
struct mips_got_entry entry, **loc;
struct mips_got_info *g;
entry.abfd = NULL;
entry.symndx = -1;
entry.d.address = value;
g = mips_elf_got_for_ibfd (gg, ibfd);
if (g == NULL)
{
g = mips_elf_got_for_ibfd (gg, abfd);
BFD_ASSERT (g != NULL);
}
loc = (struct mips_got_entry **) htab_find_slot (g->got_entries, &entry,
INSERT);
if (*loc)
return *loc;
entry.gotidx = MIPS_ELF_GOT_SIZE (abfd) * g->assigned_gotno++;
*loc = (struct mips_got_entry *)bfd_alloc (abfd, sizeof entry);
if (! *loc)
return NULL;
memcpy (*loc, &entry, sizeof entry);
if (g->assigned_gotno >= g->local_gotno)
{
(*loc)->gotidx = -1;
/* We didn't allocate enough space in the GOT. */
(*_bfd_error_handler)
(_("not enough GOT space for local GOT entries"));
bfd_set_error (bfd_error_bad_value);
return NULL;
}
MIPS_ELF_PUT_WORD (abfd, value,
(sgot->contents + entry.gotidx));
return *loc;
}
/* Sort the dynamic symbol table so that symbols that need GOT entries
appear towards the end. This reduces the amount of GOT space
required. MAX_LOCAL is used to set the number of local symbols
known to be in the dynamic symbol table. During
_bfd_mips_elf_size_dynamic_sections, this value is 1. Afterward, the
section symbols are added and the count is higher. */
static bfd_boolean
mips_elf_sort_hash_table (info, max_local)
struct bfd_link_info *info;
unsigned long max_local;
{
struct mips_elf_hash_sort_data hsd;
struct mips_got_info *g;
bfd *dynobj;
dynobj = elf_hash_table (info)->dynobj;
g = mips_elf_got_info (dynobj, NULL);
hsd.low = NULL;
hsd.max_unref_got_dynindx =
hsd.min_got_dynindx = elf_hash_table (info)->dynsymcount
/* In the multi-got case, assigned_gotno of the master got_info
indicate the number of entries that aren't referenced in the
primary GOT, but that must have entries because there are
dynamic relocations that reference it. Since they aren't
referenced, we move them to the end of the GOT, so that they
don't prevent other entries that are referenced from getting
too large offsets. */
- (g->next ? g->assigned_gotno : 0);
hsd.max_non_got_dynindx = max_local;
mips_elf_link_hash_traverse (((struct mips_elf_link_hash_table *)
elf_hash_table (info)),
mips_elf_sort_hash_table_f,
&hsd);
/* There should have been enough room in the symbol table to
accommodate both the GOT and non-GOT symbols. */
BFD_ASSERT (hsd.max_non_got_dynindx <= hsd.min_got_dynindx);
BFD_ASSERT ((unsigned long)hsd.max_unref_got_dynindx
<= elf_hash_table (info)->dynsymcount);
/* Now we know which dynamic symbol has the lowest dynamic symbol
table index in the GOT. */
g->global_gotsym = hsd.low;
return TRUE;
}
/* If H needs a GOT entry, assign it the highest available dynamic
index. Otherwise, assign it the lowest available dynamic
index. */
static bfd_boolean
mips_elf_sort_hash_table_f (h, data)
struct mips_elf_link_hash_entry *h;
PTR data;
{
struct mips_elf_hash_sort_data *hsd
= (struct mips_elf_hash_sort_data *) data;
if (h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
/* Symbols without dynamic symbol table entries aren't interesting
at all. */
if (h->root.dynindx == -1)
return TRUE;
/* Global symbols that need GOT entries that are not explicitly
referenced are marked with got offset 2. Those that are
referenced get a 1, and those that don't need GOT entries get
-1. */
if (h->root.got.offset == 2)
{
if (hsd->max_unref_got_dynindx == hsd->min_got_dynindx)
hsd->low = (struct elf_link_hash_entry *) h;
h->root.dynindx = hsd->max_unref_got_dynindx++;
}
else if (h->root.got.offset != 1)
h->root.dynindx = hsd->max_non_got_dynindx++;
else
{
h->root.dynindx = --hsd->min_got_dynindx;
hsd->low = (struct elf_link_hash_entry *) h;
}
return TRUE;
}
/* If H is a symbol that needs a global GOT entry, but has a dynamic
symbol table index lower than any we've seen to date, record it for
posterity. */
static bfd_boolean
mips_elf_record_global_got_symbol (h, abfd, info, g)
struct elf_link_hash_entry *h;
bfd *abfd;
struct bfd_link_info *info;
struct mips_got_info *g;
{
struct mips_got_entry entry, **loc;
/* A global symbol in the GOT must also be in the dynamic symbol
table. */
if (h->dynindx == -1)
{
switch (ELF_ST_VISIBILITY (h->other))
{
case STV_INTERNAL:
case STV_HIDDEN:
_bfd_mips_elf_hide_symbol (info, h, TRUE);
break;
}
if (!bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
}
entry.abfd = abfd;
entry.symndx = -1;
entry.d.h = (struct mips_elf_link_hash_entry *) h;
loc = (struct mips_got_entry **) htab_find_slot (g->got_entries, &entry,
INSERT);
/* If we've already marked this entry as needing GOT space, we don't
need to do it again. */
if (*loc)
return TRUE;
*loc = (struct mips_got_entry *)bfd_alloc (abfd, sizeof entry);
if (! *loc)
return FALSE;
entry.gotidx = -1;
memcpy (*loc, &entry, sizeof entry);
if (h->got.offset != MINUS_ONE)
return TRUE;
/* By setting this to a value other than -1, we are indicating that
there needs to be a GOT entry for H. Avoid using zero, as the
generic ELF copy_indirect_symbol tests for <= 0. */
h->got.offset = 1;
return TRUE;
}
/* Reserve space in G for a GOT entry containing the value of symbol
SYMNDX in input bfd ABDF, plus ADDEND. */
static bfd_boolean
mips_elf_record_local_got_symbol (abfd, symndx, addend, g)
bfd *abfd;
long symndx;
bfd_vma addend;
struct mips_got_info *g;
{
struct mips_got_entry entry, **loc;
entry.abfd = abfd;
entry.symndx = symndx;
entry.d.addend = addend;
loc = (struct mips_got_entry **)
htab_find_slot (g->got_entries, &entry, INSERT);
if (*loc)
return TRUE;
entry.gotidx = g->local_gotno++;
*loc = (struct mips_got_entry *)bfd_alloc (abfd, sizeof entry);
if (! *loc)
return FALSE;
memcpy (*loc, &entry, sizeof entry);
return TRUE;
}
/* Compute the hash value of the bfd in a bfd2got hash entry. */
static hashval_t
mips_elf_bfd2got_entry_hash (entry_)
const PTR entry_;
{
const struct mips_elf_bfd2got_hash *entry
= (struct mips_elf_bfd2got_hash *)entry_;
return entry->bfd->id;
}
/* Check whether two hash entries have the same bfd. */
static int
mips_elf_bfd2got_entry_eq (entry1, entry2)
const PTR entry1;
const PTR entry2;
{
const struct mips_elf_bfd2got_hash *e1
= (const struct mips_elf_bfd2got_hash *)entry1;
const struct mips_elf_bfd2got_hash *e2
= (const struct mips_elf_bfd2got_hash *)entry2;
return e1->bfd == e2->bfd;
}
/* In a multi-got link, determine the GOT to be used for IBDF. G must
be the master GOT data. */
static struct mips_got_info *
mips_elf_got_for_ibfd (g, ibfd)
struct mips_got_info *g;
bfd *ibfd;
{
struct mips_elf_bfd2got_hash e, *p;
if (! g->bfd2got)
return g;
e.bfd = ibfd;
p = (struct mips_elf_bfd2got_hash *) htab_find (g->bfd2got, &e);
return p ? p->g : NULL;
}
/* Create one separate got for each bfd that has entries in the global
got, such that we can tell how many local and global entries each
bfd requires. */
static int
mips_elf_make_got_per_bfd (entryp, p)
void **entryp;
void *p;
{
struct mips_got_entry *entry = (struct mips_got_entry *)*entryp;
struct mips_elf_got_per_bfd_arg *arg = (struct mips_elf_got_per_bfd_arg *)p;
htab_t bfd2got = arg->bfd2got;
struct mips_got_info *g;
struct mips_elf_bfd2got_hash bfdgot_entry, *bfdgot;
void **bfdgotp;
/* Find the got_info for this GOT entry's input bfd. Create one if
none exists. */
bfdgot_entry.bfd = entry->abfd;
bfdgotp = htab_find_slot (bfd2got, &bfdgot_entry, INSERT);
bfdgot = (struct mips_elf_bfd2got_hash *)*bfdgotp;
if (bfdgot != NULL)
g = bfdgot->g;
else
{
bfdgot = (struct mips_elf_bfd2got_hash *)bfd_alloc
(arg->obfd, sizeof (struct mips_elf_bfd2got_hash));
if (bfdgot == NULL)
{
arg->obfd = 0;
return 0;
}
*bfdgotp = bfdgot;
bfdgot->bfd = entry->abfd;
bfdgot->g = g = (struct mips_got_info *)
bfd_alloc (arg->obfd, sizeof (struct mips_got_info));
if (g == NULL)
{
arg->obfd = 0;
return 0;
}
g->global_gotsym = NULL;
g->global_gotno = 0;
g->local_gotno = 0;
g->assigned_gotno = -1;
g->got_entries = htab_try_create (1, mips_elf_multi_got_entry_hash,
mips_elf_multi_got_entry_eq,
(htab_del) NULL);
if (g->got_entries == NULL)
{
arg->obfd = 0;
return 0;
}
g->bfd2got = NULL;
g->next = NULL;
}
/* Insert the GOT entry in the bfd's got entry hash table. */
entryp = htab_find_slot (g->got_entries, entry, INSERT);
if (*entryp != NULL)
return 1;
*entryp = entry;
if (entry->symndx >= 0 || entry->d.h->forced_local)
++g->local_gotno;
else
++g->global_gotno;
return 1;
}
/* Attempt to merge gots of different input bfds. Try to use as much
as possible of the primary got, since it doesn't require explicit
dynamic relocations, but don't use bfds that would reference global
symbols out of the addressable range. Failing the primary got,
attempt to merge with the current got, or finish the current got
and then make make the new got current. */
static int
mips_elf_merge_gots (bfd2got_, p)
void **bfd2got_;
void *p;
{
struct mips_elf_bfd2got_hash *bfd2got
= (struct mips_elf_bfd2got_hash *)*bfd2got_;
struct mips_elf_got_per_bfd_arg *arg = (struct mips_elf_got_per_bfd_arg *)p;
unsigned int lcount = bfd2got->g->local_gotno;
unsigned int gcount = bfd2got->g->global_gotno;
unsigned int maxcnt = arg->max_count;
/* If we don't have a primary GOT and this is not too big, use it as
a starting point for the primary GOT. */
if (! arg->primary && lcount + gcount <= maxcnt)
{
arg->primary = bfd2got->g;
arg->primary_count = lcount + gcount;
}
/* If it looks like we can merge this bfd's entries with those of
the primary, merge them. The heuristics is conservative, but we
don't have to squeeze it too hard. */
else if (arg->primary
&& (arg->primary_count + lcount + gcount) <= maxcnt)
{
struct mips_got_info *g = bfd2got->g;
int old_lcount = arg->primary->local_gotno;
int old_gcount = arg->primary->global_gotno;
bfd2got->g = arg->primary;
htab_traverse (g->got_entries,
mips_elf_make_got_per_bfd,
arg);
if (arg->obfd == NULL)
return 0;
htab_delete (g->got_entries);
/* We don't have to worry about releasing memory of the actual
got entries, since they're all in the master got_entries hash
table anyway. */
BFD_ASSERT (old_lcount + lcount == arg->primary->local_gotno);
BFD_ASSERT (old_gcount + gcount >= arg->primary->global_gotno);
arg->primary_count = arg->primary->local_gotno
+ arg->primary->global_gotno;
}
/* If we can merge with the last-created got, do it. */
else if (arg->current
&& arg->current_count + lcount + gcount <= maxcnt)
{
struct mips_got_info *g = bfd2got->g;
int old_lcount = arg->current->local_gotno;
int old_gcount = arg->current->global_gotno;
bfd2got->g = arg->current;
htab_traverse (g->got_entries,
mips_elf_make_got_per_bfd,
arg);
if (arg->obfd == NULL)
return 0;
htab_delete (g->got_entries);
BFD_ASSERT (old_lcount + lcount == arg->current->local_gotno);
BFD_ASSERT (old_gcount + gcount >= arg->current->global_gotno);
arg->current_count = arg->current->local_gotno
+ arg->current->global_gotno;
}
/* Well, we couldn't merge, so create a new GOT. Don't check if it
fits; if it turns out that it doesn't, we'll get relocation
overflows anyway. */
else
{
bfd2got->g->next = arg->current;
arg->current = bfd2got->g;
arg->current_count = lcount + gcount;
}
return 1;
}
/* If passed a NULL mips_got_info in the argument, set the marker used
to tell whether a global symbol needs a got entry (in the primary
got) to the given VALUE.
If passed a pointer G to a mips_got_info in the argument (it must
not be the primary GOT), compute the offset from the beginning of
the (primary) GOT section to the entry in G corresponding to the
global symbol. G's assigned_gotno must contain the index of the
first available global GOT entry in G. VALUE must contain the size
of a GOT entry in bytes. For each global GOT entry that requires a
dynamic relocation, NEEDED_RELOCS is incremented, and the symbol is
marked as not elligible for lazy resolution through a function
stub. */
static int
mips_elf_set_global_got_offset (entryp, p)
void **entryp;
void *p;
{
struct mips_got_entry *entry = (struct mips_got_entry *)*entryp;
struct mips_elf_set_global_got_offset_arg *arg
= (struct mips_elf_set_global_got_offset_arg *)p;
struct mips_got_info *g = arg->g;
if (entry->abfd != NULL && entry->symndx == -1
&& entry->d.h->root.dynindx != -1)
{
if (g)
{
BFD_ASSERT (g->global_gotsym == NULL);
entry->gotidx = arg->value * (long) g->assigned_gotno++;
/* We can't do lazy update of GOT entries for
non-primary GOTs since the PLT entries don't use the
right offsets, so punt at it for now. */
entry->d.h->no_fn_stub = TRUE;
if (arg->info->shared
|| (elf_hash_table (arg->info)->dynamic_sections_created
&& ((entry->d.h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_DYNAMIC) != 0)
&& ((entry->d.h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0)))
++arg->needed_relocs;
}
else
entry->d.h->root.got.offset = arg->value;
}
return 1;
}
/* Follow indirect and warning hash entries so that each got entry
points to the final symbol definition. P must point to a pointer
to the hash table we're traversing. Since this traversal may
modify the hash table, we set this pointer to NULL to indicate
we've made a potentially-destructive change to the hash table, so
the traversal must be restarted. */
static int
mips_elf_resolve_final_got_entry (entryp, p)
void **entryp;
void *p;
{
struct mips_got_entry *entry = (struct mips_got_entry *)*entryp;
htab_t got_entries = *(htab_t *)p;
if (entry->abfd != NULL && entry->symndx == -1)
{
struct mips_elf_link_hash_entry *h = entry->d.h;
while (h->root.root.type == bfd_link_hash_indirect
|| h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
if (entry->d.h == h)
return 1;
entry->d.h = h;
/* If we can't find this entry with the new bfd hash, re-insert
it, and get the traversal restarted. */
if (! htab_find (got_entries, entry))
{
htab_clear_slot (got_entries, entryp);
entryp = htab_find_slot (got_entries, entry, INSERT);
if (! *entryp)
*entryp = entry;
/* Abort the traversal, since the whole table may have
moved, and leave it up to the parent to restart the
process. */
*(htab_t *)p = NULL;
return 0;
}
/* We might want to decrement the global_gotno count, but it's
either too early or too late for that at this point. */
}
return 1;
}
/* Turn indirect got entries in a got_entries table into their final
locations. */
static void
mips_elf_resolve_final_got_entries (g)
struct mips_got_info *g;
{
htab_t got_entries;
do
{
got_entries = g->got_entries;
htab_traverse (got_entries,
mips_elf_resolve_final_got_entry,
&got_entries);
}
while (got_entries == NULL);
}
/* Return the offset of an input bfd IBFD's GOT from the beginning of
the primary GOT. */
static bfd_vma
mips_elf_adjust_gp (abfd, g, ibfd)
bfd *abfd;
struct mips_got_info *g;
bfd *ibfd;
{
if (g->bfd2got == NULL)
return 0;
g = mips_elf_got_for_ibfd (g, ibfd);
if (! g)
return 0;
BFD_ASSERT (g->next);
g = g->next;
return (g->local_gotno + g->global_gotno) * MIPS_ELF_GOT_SIZE (abfd);
}
/* Turn a single GOT that is too big for 16-bit addressing into
a sequence of GOTs, each one 16-bit addressable. */
static bfd_boolean
mips_elf_multi_got (abfd, info, g, got, pages)
bfd *abfd;
struct bfd_link_info *info;
struct mips_got_info *g;
asection *got;
bfd_size_type pages;
{
struct mips_elf_got_per_bfd_arg got_per_bfd_arg;
struct mips_elf_set_global_got_offset_arg set_got_offset_arg;
struct mips_got_info *gg;
unsigned int assign;
g->bfd2got = htab_try_create (1, mips_elf_bfd2got_entry_hash,
mips_elf_bfd2got_entry_eq,
(htab_del) NULL);
if (g->bfd2got == NULL)
return FALSE;
got_per_bfd_arg.bfd2got = g->bfd2got;
got_per_bfd_arg.obfd = abfd;
got_per_bfd_arg.info = info;
/* Count how many GOT entries each input bfd requires, creating a
map from bfd to got info while at that. */
mips_elf_resolve_final_got_entries (g);
htab_traverse (g->got_entries, mips_elf_make_got_per_bfd, &got_per_bfd_arg);
if (got_per_bfd_arg.obfd == NULL)
return FALSE;
got_per_bfd_arg.current = NULL;
got_per_bfd_arg.primary = NULL;
/* Taking out PAGES entries is a worst-case estimate. We could
compute the maximum number of pages that each separate input bfd
uses, but it's probably not worth it. */
got_per_bfd_arg.max_count = ((MIPS_ELF_GOT_MAX_SIZE (abfd)
/ MIPS_ELF_GOT_SIZE (abfd))
- MIPS_RESERVED_GOTNO - pages);
/* Try to merge the GOTs of input bfds together, as long as they
don't seem to exceed the maximum GOT size, choosing one of them
to be the primary GOT. */
htab_traverse (g->bfd2got, mips_elf_merge_gots, &got_per_bfd_arg);
if (got_per_bfd_arg.obfd == NULL)
return FALSE;
/* If we find any suitable primary GOT, create an empty one. */
if (got_per_bfd_arg.primary == NULL)
{
g->next = (struct mips_got_info *)
bfd_alloc (abfd, sizeof (struct mips_got_info));
if (g->next == NULL)
return FALSE;
g->next->global_gotsym = NULL;
g->next->global_gotno = 0;
g->next->local_gotno = 0;
g->next->assigned_gotno = 0;
g->next->got_entries = htab_try_create (1, mips_elf_multi_got_entry_hash,
mips_elf_multi_got_entry_eq,
(htab_del) NULL);
if (g->next->got_entries == NULL)
return FALSE;
g->next->bfd2got = NULL;
}
else
g->next = got_per_bfd_arg.primary;
g->next->next = got_per_bfd_arg.current;
/* GG is now the master GOT, and G is the primary GOT. */
gg = g;
g = g->next;
/* Map the output bfd to the primary got. That's what we're going
to use for bfds that use GOT16 or GOT_PAGE relocations that we
didn't mark in check_relocs, and we want a quick way to find it.
We can't just use gg->next because we're going to reverse the
list. */
{
struct mips_elf_bfd2got_hash *bfdgot;
void **bfdgotp;
bfdgot = (struct mips_elf_bfd2got_hash *)bfd_alloc
(abfd, sizeof (struct mips_elf_bfd2got_hash));
if (bfdgot == NULL)
return FALSE;
bfdgot->bfd = abfd;
bfdgot->g = g;
bfdgotp = htab_find_slot (gg->bfd2got, bfdgot, INSERT);
BFD_ASSERT (*bfdgotp == NULL);
*bfdgotp = bfdgot;
}
/* The IRIX dynamic linker requires every symbol that is referenced
in a dynamic relocation to be present in the primary GOT, so
arrange for them to appear after those that are actually
referenced.
GNU/Linux could very well do without it, but it would slow down
the dynamic linker, since it would have to resolve every dynamic
symbol referenced in other GOTs more than once, without help from
the cache. Also, knowing that every external symbol has a GOT
helps speed up the resolution of local symbols too, so GNU/Linux
follows IRIX's practice.
The number 2 is used by mips_elf_sort_hash_table_f to count
global GOT symbols that are unreferenced in the primary GOT, with
an initial dynamic index computed from gg->assigned_gotno, where
the number of unreferenced global entries in the primary GOT is
preserved. */
if (1)
{
gg->assigned_gotno = gg->global_gotno - g->global_gotno;
g->global_gotno = gg->global_gotno;
set_got_offset_arg.value = 2;
}
else
{
/* This could be used for dynamic linkers that don't optimize
symbol resolution while applying relocations so as to use
primary GOT entries or assuming the symbol is locally-defined.
With this code, we assign lower dynamic indices to global
symbols that are not referenced in the primary GOT, so that
their entries can be omitted. */
gg->assigned_gotno = 0;
set_got_offset_arg.value = -1;
}
/* Reorder dynamic symbols as described above (which behavior
depends on the setting of VALUE). */
set_got_offset_arg.g = NULL;
htab_traverse (gg->got_entries, mips_elf_set_global_got_offset,
&set_got_offset_arg);
set_got_offset_arg.value = 1;
htab_traverse (g->got_entries, mips_elf_set_global_got_offset,
&set_got_offset_arg);
if (! mips_elf_sort_hash_table (info, 1))
return FALSE;
/* Now go through the GOTs assigning them offset ranges.
[assigned_gotno, local_gotno[ will be set to the range of local
entries in each GOT. We can then compute the end of a GOT by
adding local_gotno to global_gotno. We reverse the list and make
it circular since then we'll be able to quickly compute the
beginning of a GOT, by computing the end of its predecessor. To
avoid special cases for the primary GOT, while still preserving
assertions that are valid for both single- and multi-got links,
we arrange for the main got struct to have the right number of
global entries, but set its local_gotno such that the initial
offset of the primary GOT is zero. Remember that the primary GOT
will become the last item in the circular linked list, so it
points back to the master GOT. */
gg->local_gotno = -g->global_gotno;
gg->global_gotno = g->global_gotno;
assign = 0;
gg->next = gg;
do
{
struct mips_got_info *gn;
assign += MIPS_RESERVED_GOTNO;
g->assigned_gotno = assign;
g->local_gotno += assign + pages;
assign = g->local_gotno + g->global_gotno;
/* Take g out of the direct list, and push it onto the reversed
list that gg points to. */
gn = g->next;
g->next = gg->next;
gg->next = g;
g = gn;
}
while (g);
got->_raw_size = (gg->next->local_gotno
+ gg->next->global_gotno) * MIPS_ELF_GOT_SIZE (abfd);
return TRUE;
}
/* Returns the first relocation of type r_type found, beginning with
RELOCATION. RELEND is one-past-the-end of the relocation table. */
static const Elf_Internal_Rela *
mips_elf_next_relocation (abfd, r_type, relocation, relend)
bfd *abfd ATTRIBUTE_UNUSED;
unsigned int r_type;
const Elf_Internal_Rela *relocation;
const Elf_Internal_Rela *relend;
{
/* According to the MIPS ELF ABI, the R_MIPS_LO16 relocation must be
immediately following. However, for the IRIX6 ABI, the next
relocation may be a composed relocation consisting of several
relocations for the same address. In that case, the R_MIPS_LO16
relocation may occur as one of these. We permit a similar
extension in general, as that is useful for GCC. */
while (relocation < relend)
{
if (ELF_R_TYPE (abfd, relocation->r_info) == r_type)
return relocation;
++relocation;
}
/* We didn't find it. */
bfd_set_error (bfd_error_bad_value);
return NULL;
}
/* Return whether a relocation is against a local symbol. */
static bfd_boolean
mips_elf_local_relocation_p (input_bfd, relocation, local_sections,
check_forced)
bfd *input_bfd;
const Elf_Internal_Rela *relocation;
asection **local_sections;
bfd_boolean check_forced;
{
unsigned long r_symndx;
Elf_Internal_Shdr *symtab_hdr;
struct mips_elf_link_hash_entry *h;
size_t extsymoff;
r_symndx = ELF_R_SYM (input_bfd, relocation->r_info);
symtab_hdr = &elf_tdata (input_bfd)->symtab_hdr;
extsymoff = (elf_bad_symtab (input_bfd)) ? 0 : symtab_hdr->sh_info;
if (r_symndx < extsymoff)
return TRUE;
if (elf_bad_symtab (input_bfd) && local_sections[r_symndx] != NULL)
return TRUE;
if (check_forced)
{
/* Look up the hash table to check whether the symbol
was forced local. */
h = (struct mips_elf_link_hash_entry *)
elf_sym_hashes (input_bfd) [r_symndx - extsymoff];
/* Find the real hash-table entry for this symbol. */
while (h->root.root.type == bfd_link_hash_indirect
|| h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
if ((h->root.elf_link_hash_flags & ELF_LINK_FORCED_LOCAL) != 0)
return TRUE;
}
return FALSE;
}
/* Sign-extend VALUE, which has the indicated number of BITS. */
bfd_vma
_bfd_mips_elf_sign_extend (value, bits)
bfd_vma value;
int bits;
{
if (value & ((bfd_vma) 1 << (bits - 1)))
/* VALUE is negative. */
value |= ((bfd_vma) - 1) << bits;
return value;
}
/* Return non-zero if the indicated VALUE has overflowed the maximum
range expressable by a signed number with the indicated number of
BITS. */
static bfd_boolean
mips_elf_overflow_p (value, bits)
bfd_vma value;
int bits;
{
bfd_signed_vma svalue = (bfd_signed_vma) value;
if (svalue > (1 << (bits - 1)) - 1)
/* The value is too big. */
return TRUE;
else if (svalue < -(1 << (bits - 1)))
/* The value is too small. */
return TRUE;
/* All is well. */
return FALSE;
}
/* Calculate the %high function. */
static bfd_vma
mips_elf_high (value)
bfd_vma value;
{
return ((value + (bfd_vma) 0x8000) >> 16) & 0xffff;
}
/* Calculate the %higher function. */
static bfd_vma
mips_elf_higher (value)
bfd_vma value ATTRIBUTE_UNUSED;
{
#ifdef BFD64
return ((value + (bfd_vma) 0x80008000) >> 32) & 0xffff;
#else
abort ();
return (bfd_vma) -1;
#endif
}
/* Calculate the %highest function. */
static bfd_vma
mips_elf_highest (value)
bfd_vma value ATTRIBUTE_UNUSED;
{
#ifdef BFD64
return ((value + (((bfd_vma) 0x8000 << 32) | 0x80008000)) >> 48) & 0xffff;
#else
abort ();
return (bfd_vma) -1;
#endif
}
/* Create the .compact_rel section. */
static bfd_boolean
mips_elf_create_compact_rel_section (abfd, info)
bfd *abfd;
struct bfd_link_info *info ATTRIBUTE_UNUSED;
{
flagword flags;
register asection *s;
if (bfd_get_section_by_name (abfd, ".compact_rel") == NULL)
{
flags = (SEC_HAS_CONTENTS | SEC_IN_MEMORY | SEC_LINKER_CREATED
| SEC_READONLY);
s = bfd_make_section (abfd, ".compact_rel");
if (s == NULL
|| ! bfd_set_section_flags (abfd, s, flags)
|| ! bfd_set_section_alignment (abfd, s,
MIPS_ELF_LOG_FILE_ALIGN (abfd)))
return FALSE;
s->_raw_size = sizeof (Elf32_External_compact_rel);
}
return TRUE;
}
/* Create the .got section to hold the global offset table. */
static bfd_boolean
mips_elf_create_got_section (abfd, info, maybe_exclude)
bfd *abfd;
struct bfd_link_info *info;
bfd_boolean maybe_exclude;
{
flagword flags;
register asection *s;
struct elf_link_hash_entry *h;
struct bfd_link_hash_entry *bh;
struct mips_got_info *g;
bfd_size_type amt;
/* This function may be called more than once. */
s = mips_elf_got_section (abfd, TRUE);
if (s)
{
if (! maybe_exclude)
s->flags &= ~SEC_EXCLUDE;
return TRUE;
}
flags = (SEC_ALLOC | SEC_LOAD | SEC_HAS_CONTENTS | SEC_IN_MEMORY
| SEC_LINKER_CREATED);
if (maybe_exclude)
flags |= SEC_EXCLUDE;
/* We have to use an alignment of 2**4 here because this is hardcoded
in the function stub generation and in the linker script. */
s = bfd_make_section (abfd, ".got");
if (s == NULL
|| ! bfd_set_section_flags (abfd, s, flags)
|| ! bfd_set_section_alignment (abfd, s, 4))
return FALSE;
/* Define the symbol _GLOBAL_OFFSET_TABLE_. We don't do this in the
linker script because we don't want to define the symbol if we
are not creating a global offset table. */
bh = NULL;
if (! (_bfd_generic_link_add_one_symbol
(info, abfd, "_GLOBAL_OFFSET_TABLE_", BSF_GLOBAL, s,
(bfd_vma) 0, (const char *) NULL, FALSE,
get_elf_backend_data (abfd)->collect, &bh)))
return FALSE;
h = (struct elf_link_hash_entry *) bh;
h->elf_link_hash_flags &= ~ELF_LINK_NON_ELF;
h->elf_link_hash_flags |= ELF_LINK_HASH_DEF_REGULAR;
h->type = STT_OBJECT;
if (info->shared
&& ! bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
amt = sizeof (struct mips_got_info);
g = (struct mips_got_info *) bfd_alloc (abfd, amt);
if (g == NULL)
return FALSE;
g->global_gotsym = NULL;
g->local_gotno = MIPS_RESERVED_GOTNO;
g->assigned_gotno = MIPS_RESERVED_GOTNO;
g->bfd2got = NULL;
g->next = NULL;
g->got_entries = htab_try_create (1, mips_elf_got_entry_hash,
mips_elf_got_entry_eq,
(htab_del) NULL);
if (g->got_entries == NULL)
return FALSE;
mips_elf_section_data (s)->u.got_info = g;
mips_elf_section_data (s)->elf.this_hdr.sh_flags
|= SHF_ALLOC | SHF_WRITE | SHF_MIPS_GPREL;
return TRUE;
}
/* Calculate the value produced by the RELOCATION (which comes from
the INPUT_BFD). The ADDEND is the addend to use for this
RELOCATION; RELOCATION->R_ADDEND is ignored.
The result of the relocation calculation is stored in VALUEP.
REQUIRE_JALXP indicates whether or not the opcode used with this
relocation must be JALX.
This function returns bfd_reloc_continue if the caller need take no
further action regarding this relocation, bfd_reloc_notsupported if
something goes dramatically wrong, bfd_reloc_overflow if an
overflow occurs, and bfd_reloc_ok to indicate success. */
static bfd_reloc_status_type
mips_elf_calculate_relocation (abfd, input_bfd, input_section, info,
relocation, addend, howto, local_syms,
local_sections, valuep, namep,
require_jalxp, save_addend)
bfd *abfd;
bfd *input_bfd;
asection *input_section;
struct bfd_link_info *info;
const Elf_Internal_Rela *relocation;
bfd_vma addend;
reloc_howto_type *howto;
Elf_Internal_Sym *local_syms;
asection **local_sections;
bfd_vma *valuep;
const char **namep;
bfd_boolean *require_jalxp;
bfd_boolean save_addend;
{
/* The eventual value we will return. */
bfd_vma value;
/* The address of the symbol against which the relocation is
occurring. */
bfd_vma symbol = 0;
/* The final GP value to be used for the relocatable, executable, or
shared object file being produced. */
bfd_vma gp = MINUS_ONE;
/* The place (section offset or address) of the storage unit being
relocated. */
bfd_vma p;
/* The value of GP used to create the relocatable object. */
bfd_vma gp0 = MINUS_ONE;
/* The offset into the global offset table at which the address of
the relocation entry symbol, adjusted by the addend, resides
during execution. */
bfd_vma g = MINUS_ONE;
/* The section in which the symbol referenced by the relocation is
located. */
asection *sec = NULL;
struct mips_elf_link_hash_entry *h = NULL;
/* TRUE if the symbol referred to by this relocation is a local
symbol. */
bfd_boolean local_p, was_local_p;
/* TRUE if the symbol referred to by this relocation is "_gp_disp". */
bfd_boolean gp_disp_p = FALSE;
Elf_Internal_Shdr *symtab_hdr;
size_t extsymoff;
unsigned long r_symndx;
int r_type;
/* TRUE if overflow occurred during the calculation of the
relocation value. */
bfd_boolean overflowed_p;
/* TRUE if this relocation refers to a MIPS16 function. */
bfd_boolean target_is_16_bit_code_p = FALSE;
/* Parse the relocation. */
r_symndx = ELF_R_SYM (input_bfd, relocation->r_info);
r_type = ELF_R_TYPE (input_bfd, relocation->r_info);
p = (input_section->output_section->vma
+ input_section->output_offset
+ relocation->r_offset);
/* Assume that there will be no overflow. */
overflowed_p = FALSE;
/* Figure out whether or not the symbol is local, and get the offset
used in the array of hash table entries. */
symtab_hdr = &elf_tdata (input_bfd)->symtab_hdr;
local_p = mips_elf_local_relocation_p (input_bfd, relocation,
local_sections, FALSE);
was_local_p = local_p;
if (! elf_bad_symtab (input_bfd))
extsymoff = symtab_hdr->sh_info;
else
{
/* The symbol table does not follow the rule that local symbols
must come before globals. */
extsymoff = 0;
}
/* Figure out the value of the symbol. */
if (local_p)
{
Elf_Internal_Sym *sym;
sym = local_syms + r_symndx;
sec = local_sections[r_symndx];
symbol = sec->output_section->vma + sec->output_offset;
if (ELF_ST_TYPE (sym->st_info) != STT_SECTION
|| (sec->flags & SEC_MERGE))
symbol += sym->st_value;
if ((sec->flags & SEC_MERGE)
&& ELF_ST_TYPE (sym->st_info) == STT_SECTION)
{
addend = _bfd_elf_rel_local_sym (abfd, sym, &sec, addend);
addend -= symbol;
addend += sec->output_section->vma + sec->output_offset;
}
/* MIPS16 text labels should be treated as odd. */
if (sym->st_other == STO_MIPS16)
++symbol;
/* Record the name of this symbol, for our caller. */
*namep = bfd_elf_string_from_elf_section (input_bfd,
symtab_hdr->sh_link,
sym->st_name);
if (*namep == '\0')
*namep = bfd_section_name (input_bfd, sec);
target_is_16_bit_code_p = (sym->st_other == STO_MIPS16);
}
else
{
/* For global symbols we look up the symbol in the hash-table. */
h = ((struct mips_elf_link_hash_entry *)
elf_sym_hashes (input_bfd) [r_symndx - extsymoff]);
/* Find the real hash-table entry for this symbol. */
while (h->root.root.type == bfd_link_hash_indirect
|| h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
/* Record the name of this symbol, for our caller. */
*namep = h->root.root.root.string;
/* See if this is the special _gp_disp symbol. Note that such a
symbol must always be a global symbol. */
if (strcmp (h->root.root.root.string, "_gp_disp") == 0
&& ! NEWABI_P (input_bfd))
{
/* Relocations against _gp_disp are permitted only with
R_MIPS_HI16 and R_MIPS_LO16 relocations. */
if (r_type != R_MIPS_HI16 && r_type != R_MIPS_LO16)
return bfd_reloc_notsupported;
gp_disp_p = TRUE;
}
/* If this symbol is defined, calculate its address. Note that
_gp_disp is a magic symbol, always implicitly defined by the
linker, so it's inappropriate to check to see whether or not
its defined. */
else if ((h->root.root.type == bfd_link_hash_defined
|| h->root.root.type == bfd_link_hash_defweak)
&& h->root.root.u.def.section)
{
sec = h->root.root.u.def.section;
if (sec->output_section)
symbol = (h->root.root.u.def.value
+ sec->output_section->vma
+ sec->output_offset);
else
symbol = h->root.root.u.def.value;
}
else if (h->root.root.type == bfd_link_hash_undefweak)
/* We allow relocations against undefined weak symbols, giving
it the value zero, so that you can undefined weak functions
and check to see if they exist by looking at their
addresses. */
symbol = 0;
else if (info->shared
&& !info->no_undefined
&& ELF_ST_VISIBILITY (h->root.other) == STV_DEFAULT)
symbol = 0;
else if (strcmp (h->root.root.root.string, "_DYNAMIC_LINK") == 0 ||
strcmp (h->root.root.root.string, "_DYNAMIC_LINKING") == 0)
{
/* If this is a dynamic link, we should have created a
_DYNAMIC_LINK symbol or _DYNAMIC_LINKING(for normal mips) symbol
in in _bfd_mips_elf_create_dynamic_sections.
Otherwise, we should define the symbol with a value of 0.
FIXME: It should probably get into the symbol table
somehow as well. */
BFD_ASSERT (! info->shared);
BFD_ASSERT (bfd_get_section_by_name (abfd, ".dynamic") == NULL);
symbol = 0;
}
else
{
if (! ((*info->callbacks->undefined_symbol)
(info, h->root.root.root.string, input_bfd,
input_section, relocation->r_offset,
(!info->shared || info->no_undefined
|| ELF_ST_VISIBILITY (h->root.other)))))
return bfd_reloc_undefined;
symbol = 0;
}
target_is_16_bit_code_p = (h->root.other == STO_MIPS16);
}
/* If this is a 32- or 64-bit call to a 16-bit function with a stub, we
need to redirect the call to the stub, unless we're already *in*
a stub. */
if (r_type != R_MIPS16_26 && !info->relocatable
&& ((h != NULL && h->fn_stub != NULL)
|| (local_p && elf_tdata (input_bfd)->local_stubs != NULL
&& elf_tdata (input_bfd)->local_stubs[r_symndx] != NULL))
&& !mips_elf_stub_section_p (input_bfd, input_section))
{
/* This is a 32- or 64-bit call to a 16-bit function. We should
have already noticed that we were going to need the
stub. */
if (local_p)
sec = elf_tdata (input_bfd)->local_stubs[r_symndx];
else
{
BFD_ASSERT (h->need_fn_stub);
sec = h->fn_stub;
}
symbol = sec->output_section->vma + sec->output_offset;
}
/* If this is a 16-bit call to a 32- or 64-bit function with a stub, we
need to redirect the call to the stub. */
else if (r_type == R_MIPS16_26 && !info->relocatable
&& h != NULL
&& (h->call_stub != NULL || h->call_fp_stub != NULL)
&& !target_is_16_bit_code_p)
{
/* If both call_stub and call_fp_stub are defined, we can figure
out which one to use by seeing which one appears in the input
file. */
if (h->call_stub != NULL && h->call_fp_stub != NULL)
{
asection *o;
sec = NULL;
for (o = input_bfd->sections; o != NULL; o = o->next)
{
if (strncmp (bfd_get_section_name (input_bfd, o),
CALL_FP_STUB, sizeof CALL_FP_STUB - 1) == 0)
{
sec = h->call_fp_stub;
break;
}
}
if (sec == NULL)
sec = h->call_stub;
}
else if (h->call_stub != NULL)
sec = h->call_stub;
else
sec = h->call_fp_stub;
BFD_ASSERT (sec->_raw_size > 0);
symbol = sec->output_section->vma + sec->output_offset;
}
/* Calls from 16-bit code to 32-bit code and vice versa require the
special jalx instruction. */
*require_jalxp = (!info->relocatable
&& (((r_type == R_MIPS16_26) && !target_is_16_bit_code_p)
|| ((r_type == R_MIPS_26) && target_is_16_bit_code_p)));
local_p = mips_elf_local_relocation_p (input_bfd, relocation,
local_sections, TRUE);
/* If we haven't already determined the GOT offset, or the GP value,
and we're going to need it, get it now. */
switch (r_type)
{
case R_MIPS_GOT_PAGE:
case R_MIPS_GOT_OFST:
/* If this symbol got a global GOT entry, we have to decay
GOT_PAGE/GOT_OFST to GOT_DISP/addend. */
local_p = local_p || ! h
|| (h->root.dynindx
< mips_elf_get_global_gotsym_index (elf_hash_table (info)
->dynobj));
if (local_p || r_type == R_MIPS_GOT_OFST)
break;
/* Fall through. */
case R_MIPS_CALL16:
case R_MIPS_GOT16:
case R_MIPS_GOT_DISP:
case R_MIPS_GOT_HI16:
case R_MIPS_CALL_HI16:
case R_MIPS_GOT_LO16:
case R_MIPS_CALL_LO16:
/* Find the index into the GOT where this value is located. */
if (!local_p)
{
/* GOT_PAGE may take a non-zero addend, that is ignored in a
GOT_PAGE relocation that decays to GOT_DISP because the
symbol turns out to be global. The addend is then added
as GOT_OFST. */
BFD_ASSERT (addend == 0 || r_type == R_MIPS_GOT_PAGE);
g = mips_elf_global_got_index (elf_hash_table (info)->dynobj,
input_bfd,
(struct elf_link_hash_entry *) h);
if (! elf_hash_table(info)->dynamic_sections_created
|| (info->shared
&& (info->symbolic || h->root.dynindx == -1)
&& (h->root.elf_link_hash_flags & ELF_LINK_HASH_DEF_REGULAR)))
{
/* This is a static link or a -Bsymbolic link. The
symbol is defined locally, or was forced to be local.
We must initialize this entry in the GOT. */
bfd *tmpbfd = elf_hash_table (info)->dynobj;
asection *sgot = mips_elf_got_section (tmpbfd, FALSE);
MIPS_ELF_PUT_WORD (tmpbfd, symbol, sgot->contents + g);
}
}
else if (r_type == R_MIPS_GOT16 || r_type == R_MIPS_CALL16)
/* There's no need to create a local GOT entry here; the
calculation for a local GOT16 entry does not involve G. */
break;
else
{
g = mips_elf_local_got_index (abfd, input_bfd,
info, symbol + addend);
if (g == MINUS_ONE)
return bfd_reloc_outofrange;
}
/* Convert GOT indices to actual offsets. */
g = mips_elf_got_offset_from_index (elf_hash_table (info)->dynobj,
abfd, input_bfd, g);
break;
case R_MIPS_HI16:
case R_MIPS_LO16:
case R_MIPS16_GPREL:
case R_MIPS_GPREL16:
case R_MIPS_GPREL32:
case R_MIPS_LITERAL:
gp0 = _bfd_get_gp_value (input_bfd);
gp = _bfd_get_gp_value (abfd);
if (elf_hash_table (info)->dynobj)
gp += mips_elf_adjust_gp (abfd,
mips_elf_got_info
(elf_hash_table (info)->dynobj, NULL),
input_bfd);
break;
default:
break;
}
/* Figure out what kind of relocation is being performed. */
switch (r_type)
{
case R_MIPS_NONE:
return bfd_reloc_continue;
case R_MIPS_16:
value = symbol + _bfd_mips_elf_sign_extend (addend, 16);
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_32:
case R_MIPS_REL32:
case R_MIPS_64:
if ((info->shared
|| (elf_hash_table (info)->dynamic_sections_created
&& h != NULL
&& ((h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_DYNAMIC) != 0)
&& ((h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0)))
&& r_symndx != 0
&& (input_section->flags & SEC_ALLOC) != 0)
{
/* If we're creating a shared library, or this relocation is
against a symbol in a shared library, then we can't know
where the symbol will end up. So, we create a relocation
record in the output, and leave the job up to the dynamic
linker. */
value = addend;
if (!mips_elf_create_dynamic_relocation (abfd,
info,
relocation,
h,
sec,
symbol,
&value,
input_section))
return bfd_reloc_undefined;
}
else
{
if (r_type != R_MIPS_REL32)
value = symbol + addend;
else
value = addend;
}
value &= howto->dst_mask;
break;
case R_MIPS_PC32:
case R_MIPS_PC64:
case R_MIPS_GNU_REL_LO16:
value = symbol + addend - p;
value &= howto->dst_mask;
break;
case R_MIPS_GNU_REL16_S2:
value = symbol + _bfd_mips_elf_sign_extend (addend << 2, 18) - p;
overflowed_p = mips_elf_overflow_p (value, 18);
value = (value >> 2) & howto->dst_mask;
break;
case R_MIPS_GNU_REL_HI16:
/* Instead of subtracting 'p' here, we should be subtracting the
equivalent value for the LO part of the reloc, since the value
here is relative to that address. Because that's not easy to do,
we adjust 'addend' in _bfd_mips_elf_relocate_section(). See also
the comment there for more information. */
value = mips_elf_high (addend + symbol - p);
value &= howto->dst_mask;
break;
case R_MIPS16_26:
/* The calculation for R_MIPS16_26 is just the same as for an
R_MIPS_26. It's only the storage of the relocated field into
the output file that's different. That's handled in
mips_elf_perform_relocation. So, we just fall through to the
R_MIPS_26 case here. */
case R_MIPS_26:
if (local_p)
value = (((addend << 2) | ((p + 4) & 0xf0000000)) + symbol) >> 2;
else
value = (_bfd_mips_elf_sign_extend (addend << 2, 28) + symbol) >> 2;
value &= howto->dst_mask;
break;
case R_MIPS_HI16:
if (!gp_disp_p)
{
value = mips_elf_high (addend + symbol);
value &= howto->dst_mask;
}
else
{
value = mips_elf_high (addend + gp - p);
overflowed_p = mips_elf_overflow_p (value, 16);
}
break;
case R_MIPS_LO16:
if (!gp_disp_p)
value = (symbol + addend) & howto->dst_mask;
else
{
value = addend + gp - p + 4;
/* The MIPS ABI requires checking the R_MIPS_LO16 relocation
for overflow. But, on, say, IRIX5, relocations against
_gp_disp are normally generated from the .cpload
pseudo-op. It generates code that normally looks like
this:
lui $gp,%hi(_gp_disp)
addiu $gp,$gp,%lo(_gp_disp)
addu $gp,$gp,$t9
Here $t9 holds the address of the function being called,
as required by the MIPS ELF ABI. The R_MIPS_LO16
relocation can easily overflow in this situation, but the
R_MIPS_HI16 relocation will handle the overflow.
Therefore, we consider this a bug in the MIPS ABI, and do
not check for overflow here. */
}
break;
case R_MIPS_LITERAL:
/* Because we don't merge literal sections, we can handle this
just like R_MIPS_GPREL16. In the long run, we should merge
shared literals, and then we will need to additional work
here. */
/* Fall through. */
case R_MIPS16_GPREL:
/* The R_MIPS16_GPREL performs the same calculation as
R_MIPS_GPREL16, but stores the relocated bits in a different
order. We don't need to do anything special here; the
differences are handled in mips_elf_perform_relocation. */
case R_MIPS_GPREL16:
/* Only sign-extend the addend if it was extracted from the
instruction. If the addend was separate, leave it alone,
otherwise we may lose significant bits. */
if (howto->partial_inplace)
addend = _bfd_mips_elf_sign_extend (addend, 16);
value = symbol + addend - gp;
/* If the symbol was local, any earlier relocatable links will
have adjusted its addend with the gp offset, so compensate
for that now. Don't do it for symbols forced local in this
link, though, since they won't have had the gp offset applied
to them before. */
if (was_local_p)
value += gp0;
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_GOT16:
case R_MIPS_CALL16:
if (local_p)
{
bfd_boolean forced;
/* The special case is when the symbol is forced to be local. We
need the full address in the GOT since no R_MIPS_LO16 relocation
follows. */
forced = ! mips_elf_local_relocation_p (input_bfd, relocation,
local_sections, FALSE);
value = mips_elf_got16_entry (abfd, input_bfd, info,
symbol + addend, forced);
if (value == MINUS_ONE)
return bfd_reloc_outofrange;
value
= mips_elf_got_offset_from_index (elf_hash_table (info)->dynobj,
abfd, input_bfd, value);
overflowed_p = mips_elf_overflow_p (value, 16);
break;
}
/* Fall through. */
case R_MIPS_GOT_DISP:
got_disp:
value = g;
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_GPREL32:
value = (addend + symbol + gp0 - gp);
if (!save_addend)
value &= howto->dst_mask;
break;
case R_MIPS_PC16:
value = _bfd_mips_elf_sign_extend (addend, 16) + symbol - p;
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_GOT_HI16:
case R_MIPS_CALL_HI16:
/* We're allowed to handle these two relocations identically.
The dynamic linker is allowed to handle the CALL relocations
differently by creating a lazy evaluation stub. */
value = g;
value = mips_elf_high (value);
value &= howto->dst_mask;
break;
case R_MIPS_GOT_LO16:
case R_MIPS_CALL_LO16:
value = g & howto->dst_mask;
break;
case R_MIPS_GOT_PAGE:
/* GOT_PAGE relocations that reference non-local symbols decay
to GOT_DISP. The corresponding GOT_OFST relocation decays to
0. */
if (! local_p)
goto got_disp;
value = mips_elf_got_page (abfd, input_bfd, info, symbol + addend, NULL);
if (value == MINUS_ONE)
return bfd_reloc_outofrange;
value = mips_elf_got_offset_from_index (elf_hash_table (info)->dynobj,
abfd, input_bfd, value);
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_GOT_OFST:
if (local_p)
mips_elf_got_page (abfd, input_bfd, info, symbol + addend, &value);
else
value = addend;
overflowed_p = mips_elf_overflow_p (value, 16);
break;
case R_MIPS_SUB:
value = symbol - addend;
value &= howto->dst_mask;
break;
case R_MIPS_HIGHER:
value = mips_elf_higher (addend + symbol);
value &= howto->dst_mask;
break;
case R_MIPS_HIGHEST:
value = mips_elf_highest (addend + symbol);
value &= howto->dst_mask;
break;
case R_MIPS_SCN_DISP:
value = symbol + addend - sec->output_offset;
value &= howto->dst_mask;
break;
case R_MIPS_PJUMP:
case R_MIPS_JALR:
/* Both of these may be ignored. R_MIPS_JALR is an optimization
hint; we could improve performance by honoring that hint. */
return bfd_reloc_continue;
case R_MIPS_GNU_VTINHERIT:
case R_MIPS_GNU_VTENTRY:
/* We don't do anything with these at present. */
return bfd_reloc_continue;
default:
/* An unrecognized relocation type. */
return bfd_reloc_notsupported;
}
/* Store the VALUE for our caller. */
*valuep = value;
return overflowed_p ? bfd_reloc_overflow : bfd_reloc_ok;
}
/* Obtain the field relocated by RELOCATION. */
static bfd_vma
mips_elf_obtain_contents (howto, relocation, input_bfd, contents)
reloc_howto_type *howto;
const Elf_Internal_Rela *relocation;
bfd *input_bfd;
bfd_byte *contents;
{
bfd_vma x;
bfd_byte *location = contents + relocation->r_offset;
/* Obtain the bytes. */
x = bfd_get ((8 * bfd_get_reloc_size (howto)), input_bfd, location);
if ((ELF_R_TYPE (input_bfd, relocation->r_info) == R_MIPS16_26
|| ELF_R_TYPE (input_bfd, relocation->r_info) == R_MIPS16_GPREL)
&& bfd_little_endian (input_bfd))
/* The two 16-bit words will be reversed on a little-endian system.
See mips_elf_perform_relocation for more details. */
x = (((x & 0xffff) << 16) | ((x & 0xffff0000) >> 16));
return x;
}
/* It has been determined that the result of the RELOCATION is the
VALUE. Use HOWTO to place VALUE into the output file at the
appropriate position. The SECTION is the section to which the
relocation applies. If REQUIRE_JALX is TRUE, then the opcode used
for the relocation must be either JAL or JALX, and it is
unconditionally converted to JALX.
Returns FALSE if anything goes wrong. */
static bfd_boolean
mips_elf_perform_relocation (info, howto, relocation, value, input_bfd,
input_section, contents, require_jalx)
struct bfd_link_info *info;
reloc_howto_type *howto;
const Elf_Internal_Rela *relocation;
bfd_vma value;
bfd *input_bfd;
asection *input_section;
bfd_byte *contents;
bfd_boolean require_jalx;
{
bfd_vma x;
bfd_byte *location;
int r_type = ELF_R_TYPE (input_bfd, relocation->r_info);
/* Figure out where the relocation is occurring. */
location = contents + relocation->r_offset;
/* Obtain the current value. */
x = mips_elf_obtain_contents (howto, relocation, input_bfd, contents);
/* Clear the field we are setting. */
x &= ~howto->dst_mask;
/* If this is the R_MIPS16_26 relocation, we must store the
value in a funny way. */
if (r_type == R_MIPS16_26)
{
/* R_MIPS16_26 is used for the mips16 jal and jalx instructions.
Most mips16 instructions are 16 bits, but these instructions
are 32 bits.
The format of these instructions is:
+--------------+--------------------------------+
! JALX ! X! Imm 20:16 ! Imm 25:21 !
+--------------+--------------------------------+
! Immediate 15:0 !
+-----------------------------------------------+
JALX is the 5-bit value 00011. X is 0 for jal, 1 for jalx.
Note that the immediate value in the first word is swapped.
When producing a relocatable object file, R_MIPS16_26 is
handled mostly like R_MIPS_26. In particular, the addend is
stored as a straight 26-bit value in a 32-bit instruction.
(gas makes life simpler for itself by never adjusting a
R_MIPS16_26 reloc to be against a section, so the addend is
always zero). However, the 32 bit instruction is stored as 2
16-bit values, rather than a single 32-bit value. In a
big-endian file, the result is the same; in a little-endian
file, the two 16-bit halves of the 32 bit value are swapped.
This is so that a disassembler can recognize the jal
instruction.
When doing a final link, R_MIPS16_26 is treated as a 32 bit
instruction stored as two 16-bit values. The addend A is the
contents of the targ26 field. The calculation is the same as
R_MIPS_26. When storing the calculated value, reorder the
immediate value as shown above, and don't forget to store the
value as two 16-bit values.
To put it in MIPS ABI terms, the relocation field is T-targ26-16,
defined as
big-endian:
+--------+----------------------+
| | |
| | targ26-16 |
|31 26|25 0|
+--------+----------------------+
little-endian:
+----------+------+-------------+
| | | |
| sub1 | | sub2 |
|0 9|10 15|16 31|
+----------+--------------------+
where targ26-16 is sub1 followed by sub2 (i.e., the addend field A is
((sub1 << 16) | sub2)).
When producing a relocatable object file, the calculation is
(((A < 2) | ((P + 4) & 0xf0000000) + S) >> 2)
When producing a fully linked file, the calculation is
let R = (((A < 2) | ((P + 4) & 0xf0000000) + S) >> 2)
((R & 0x1f0000) << 5) | ((R & 0x3e00000) >> 5) | (R & 0xffff) */
if (!info->relocatable)
/* Shuffle the bits according to the formula above. */
value = (((value & 0x1f0000) << 5)
| ((value & 0x3e00000) >> 5)
| (value & 0xffff));
}
else if (r_type == R_MIPS16_GPREL)
{
/* R_MIPS16_GPREL is used for GP-relative addressing in mips16
mode. A typical instruction will have a format like this:
+--------------+--------------------------------+
! EXTEND ! Imm 10:5 ! Imm 15:11 !
+--------------+--------------------------------+
! Major ! rx ! ry ! Imm 4:0 !
+--------------+--------------------------------+
EXTEND is the five bit value 11110. Major is the instruction
opcode.
This is handled exactly like R_MIPS_GPREL16, except that the
addend is retrieved and stored as shown in this diagram; that
is, the Imm fields above replace the V-rel16 field.
All we need to do here is shuffle the bits appropriately. As
above, the two 16-bit halves must be swapped on a
little-endian system. */
value = (((value & 0x7e0) << 16)
| ((value & 0xf800) << 5)
| (value & 0x1f));
}
/* Set the field. */
x |= (value & howto->dst_mask);
/* If required, turn JAL into JALX. */
if (require_jalx)
{
bfd_boolean ok;
bfd_vma opcode = x >> 26;
bfd_vma jalx_opcode;
/* Check to see if the opcode is already JAL or JALX. */
if (r_type == R_MIPS16_26)
{
ok = ((opcode == 0x6) || (opcode == 0x7));
jalx_opcode = 0x7;
}
else
{
ok = ((opcode == 0x3) || (opcode == 0x1d));
jalx_opcode = 0x1d;
}
/* If the opcode is not JAL or JALX, there's a problem. */
if (!ok)
{
(*_bfd_error_handler)
(_("%s: %s+0x%lx: jump to stub routine which is not jal"),
bfd_archive_filename (input_bfd),
input_section->name,
(unsigned long) relocation->r_offset);
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
/* Make this the JALX opcode. */
x = (x & ~(0x3f << 26)) | (jalx_opcode << 26);
}
/* Swap the high- and low-order 16 bits on little-endian systems
when doing a MIPS16 relocation. */
if ((r_type == R_MIPS16_GPREL || r_type == R_MIPS16_26)
&& bfd_little_endian (input_bfd))
x = (((x & 0xffff) << 16) | ((x & 0xffff0000) >> 16));
/* Put the value into the output. */
bfd_put (8 * bfd_get_reloc_size (howto), input_bfd, x, location);
return TRUE;
}
/* Returns TRUE if SECTION is a MIPS16 stub section. */
static bfd_boolean
mips_elf_stub_section_p (abfd, section)
bfd *abfd ATTRIBUTE_UNUSED;
asection *section;
{
const char *name = bfd_get_section_name (abfd, section);
return (strncmp (name, FN_STUB, sizeof FN_STUB - 1) == 0
|| strncmp (name, CALL_STUB, sizeof CALL_STUB - 1) == 0
|| strncmp (name, CALL_FP_STUB, sizeof CALL_FP_STUB - 1) == 0);
}
/* Add room for N relocations to the .rel.dyn section in ABFD. */
static void
mips_elf_allocate_dynamic_relocations (abfd, n)
bfd *abfd;
unsigned int n;
{
asection *s;
s = mips_elf_rel_dyn_section (abfd, FALSE);
BFD_ASSERT (s != NULL);
if (s->_raw_size == 0)
{
/* Make room for a null element. */
s->_raw_size += MIPS_ELF_REL_SIZE (abfd);
++s->reloc_count;
}
s->_raw_size += n * MIPS_ELF_REL_SIZE (abfd);
}
/* Create a rel.dyn relocation for the dynamic linker to resolve. REL
is the original relocation, which is now being transformed into a
dynamic relocation. The ADDENDP is adjusted if necessary; the
caller should store the result in place of the original addend. */
static bfd_boolean
mips_elf_create_dynamic_relocation (output_bfd, info, rel, h, sec,
symbol, addendp, input_section)
bfd *output_bfd;
struct bfd_link_info *info;
const Elf_Internal_Rela *rel;
struct mips_elf_link_hash_entry *h;
asection *sec;
bfd_vma symbol;
bfd_vma *addendp;
asection *input_section;
{
Elf_Internal_Rela outrel[3];
bfd_boolean skip;
asection *sreloc;
bfd *dynobj;
int r_type;
r_type = ELF_R_TYPE (output_bfd, rel->r_info);
dynobj = elf_hash_table (info)->dynobj;
sreloc = mips_elf_rel_dyn_section (dynobj, FALSE);
BFD_ASSERT (sreloc != NULL);
BFD_ASSERT (sreloc->contents != NULL);
BFD_ASSERT (sreloc->reloc_count * MIPS_ELF_REL_SIZE (output_bfd)
< sreloc->_raw_size);
skip = FALSE;
outrel[0].r_offset =
_bfd_elf_section_offset (output_bfd, info, input_section, rel[0].r_offset);
outrel[1].r_offset =
_bfd_elf_section_offset (output_bfd, info, input_section, rel[1].r_offset);
outrel[2].r_offset =
_bfd_elf_section_offset (output_bfd, info, input_section, rel[2].r_offset);
#if 0
/* We begin by assuming that the offset for the dynamic relocation
is the same as for the original relocation. We'll adjust this
later to reflect the correct output offsets. */
if (input_section->sec_info_type != ELF_INFO_TYPE_STABS)
{
outrel[1].r_offset = rel[1].r_offset;
outrel[2].r_offset = rel[2].r_offset;
}
else
{
/* Except that in a stab section things are more complex.
Because we compress stab information, the offset given in the
relocation may not be the one we want; we must let the stabs
machinery tell us the offset. */
outrel[1].r_offset = outrel[0].r_offset;
outrel[2].r_offset = outrel[0].r_offset;
/* If we didn't need the relocation at all, this value will be
-1. */
if (outrel[0].r_offset == (bfd_vma) -1)
skip = TRUE;
}
#endif
if (outrel[0].r_offset == (bfd_vma) -1)
/* The relocation field has been deleted. */
skip = TRUE;
else if (outrel[0].r_offset == (bfd_vma) -2)
{
/* The relocation field has been converted into a relative value of
some sort. Functions like _bfd_elf_write_section_eh_frame expect
the field to be fully relocated, so add in the symbol's value. */
skip = TRUE;
*addendp += symbol;
}
/* If we've decided to skip this relocation, just output an empty
record. Note that R_MIPS_NONE == 0, so that this call to memset
is a way of setting R_TYPE to R_MIPS_NONE. */
if (skip)
memset (outrel, 0, sizeof (Elf_Internal_Rela) * 3);
else
{
long indx;
bfd_boolean defined_p;
/* We must now calculate the dynamic symbol table index to use
in the relocation. */
if (h != NULL
&& (! info->symbolic || (h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0)
/* h->root.dynindx may be -1 if this symbol was marked to
become local. */
&& h->root.dynindx != -1)
{
indx = h->root.dynindx;
if (SGI_COMPAT (output_bfd))
defined_p = ((h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) != 0);
else
/* ??? glibc's ld.so just adds the final GOT entry to the
relocation field. It therefore treats relocs against
defined symbols in the same way as relocs against
undefined symbols. */
defined_p = FALSE;
}
else
{
if (sec != NULL && bfd_is_abs_section (sec))
indx = 0;
else if (sec == NULL || sec->owner == NULL)
{
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
else
{
indx = elf_section_data (sec->output_section)->dynindx;
if (indx == 0)
abort ();
}
/* Instead of generating a relocation using the section
symbol, we may as well make it a fully relative
relocation. We want to avoid generating relocations to
local symbols because we used to generate them
incorrectly, without adding the original symbol value,
which is mandated by the ABI for section symbols. In
order to give dynamic loaders and applications time to
phase out the incorrect use, we refrain from emitting
section-relative relocations. It's not like they're
useful, after all. This should be a bit more efficient
as well. */
/* ??? Although this behavior is compatible with glibc's ld.so,
the ABI says that relocations against STN_UNDEF should have
a symbol value of 0. Irix rld honors this, so relocations
against STN_UNDEF have no effect. */
if (!SGI_COMPAT (output_bfd))
indx = 0;
defined_p = TRUE;
}
/* If the relocation was previously an absolute relocation and
this symbol will not be referred to by the relocation, we must
adjust it by the value we give it in the dynamic symbol table.
Otherwise leave the job up to the dynamic linker. */
if (defined_p && r_type != R_MIPS_REL32)
*addendp += symbol;
/* The relocation is always an REL32 relocation because we don't
know where the shared library will wind up at load-time. */
outrel[0].r_info = ELF_R_INFO (output_bfd, (unsigned long) indx,
R_MIPS_REL32);
/* For strict adherence to the ABI specification, we should
generate a R_MIPS_64 relocation record by itself before the
_REL32/_64 record as well, such that the addend is read in as
a 64-bit value (REL32 is a 32-bit relocation, after all).
However, since none of the existing ELF64 MIPS dynamic
loaders seems to care, we don't waste space with these
artificial relocations. If this turns out to not be true,
mips_elf_allocate_dynamic_relocation() should be tweaked so
as to make room for a pair of dynamic relocations per
invocation if ABI_64_P, and here we should generate an
additional relocation record with R_MIPS_64 by itself for a
NULL symbol before this relocation record. */
outrel[1].r_info = ELF_R_INFO (output_bfd, (unsigned long) 0,
ABI_64_P (output_bfd)
? R_MIPS_64
: R_MIPS_NONE);
outrel[2].r_info = ELF_R_INFO (output_bfd, (unsigned long) 0,
R_MIPS_NONE);
/* Adjust the output offset of the relocation to reference the
correct location in the output file. */
outrel[0].r_offset += (input_section->output_section->vma
+ input_section->output_offset);
outrel[1].r_offset += (input_section->output_section->vma
+ input_section->output_offset);
outrel[2].r_offset += (input_section->output_section->vma
+ input_section->output_offset);
}
/* Put the relocation back out. We have to use the special
relocation outputter in the 64-bit case since the 64-bit
relocation format is non-standard. */
if (ABI_64_P (output_bfd))
{
(*get_elf_backend_data (output_bfd)->s->swap_reloc_out)
(output_bfd, &outrel[0],
(sreloc->contents
+ sreloc->reloc_count * sizeof (Elf64_Mips_External_Rel)));
}
else
bfd_elf32_swap_reloc_out
(output_bfd, &outrel[0],
(sreloc->contents + sreloc->reloc_count * sizeof (Elf32_External_Rel)));
/* We've now added another relocation. */
++sreloc->reloc_count;
/* Make sure the output section is writable. The dynamic linker
will be writing to it. */
elf_section_data (input_section->output_section)->this_hdr.sh_flags
|= SHF_WRITE;
/* On IRIX5, make an entry of compact relocation info. */
if (! skip && IRIX_COMPAT (output_bfd) == ict_irix5)
{
asection *scpt = bfd_get_section_by_name (dynobj, ".compact_rel");
bfd_byte *cr;
if (scpt)
{
Elf32_crinfo cptrel;
mips_elf_set_cr_format (cptrel, CRF_MIPS_LONG);
cptrel.vaddr = (rel->r_offset
+ input_section->output_section->vma
+ input_section->output_offset);
if (r_type == R_MIPS_REL32)
mips_elf_set_cr_type (cptrel, CRT_MIPS_REL32);
else
mips_elf_set_cr_type (cptrel, CRT_MIPS_WORD);
mips_elf_set_cr_dist2to (cptrel, 0);
cptrel.konst = *addendp;
cr = (scpt->contents
+ sizeof (Elf32_External_compact_rel));
bfd_elf32_swap_crinfo_out (output_bfd, &cptrel,
((Elf32_External_crinfo *) cr
+ scpt->reloc_count));
++scpt->reloc_count;
}
}
return TRUE;
}
/* Return the MACH for a MIPS e_flags value. */
unsigned long
_bfd_elf_mips_mach (flags)
flagword flags;
{
switch (flags & EF_MIPS_MACH)
{
case E_MIPS_MACH_3900:
return bfd_mach_mips3900;
case E_MIPS_MACH_4010:
return bfd_mach_mips4010;
case E_MIPS_MACH_4100:
return bfd_mach_mips4100;
case E_MIPS_MACH_4111:
return bfd_mach_mips4111;
case E_MIPS_MACH_4120:
return bfd_mach_mips4120;
case E_MIPS_MACH_4650:
return bfd_mach_mips4650;
case E_MIPS_MACH_5400:
return bfd_mach_mips5400;
case E_MIPS_MACH_5500:
return bfd_mach_mips5500;
case E_MIPS_MACH_SB1:
return bfd_mach_mips_sb1;
default:
switch (flags & EF_MIPS_ARCH)
{
default:
case E_MIPS_ARCH_1:
return bfd_mach_mips3000;
break;
case E_MIPS_ARCH_2:
return bfd_mach_mips6000;
break;
case E_MIPS_ARCH_3:
return bfd_mach_mips4000;
break;
case E_MIPS_ARCH_4:
return bfd_mach_mips8000;
break;
case E_MIPS_ARCH_5:
return bfd_mach_mips5;
break;
case E_MIPS_ARCH_32:
return bfd_mach_mipsisa32;
break;
case E_MIPS_ARCH_64:
return bfd_mach_mipsisa64;
break;
case E_MIPS_ARCH_32R2:
return bfd_mach_mipsisa32r2;
break;
}
}
return 0;
}
/* Return printable name for ABI. */
static INLINE char *
elf_mips_abi_name (abfd)
bfd *abfd;
{
flagword flags;
flags = elf_elfheader (abfd)->e_flags;
switch (flags & EF_MIPS_ABI)
{
case 0:
if (ABI_N32_P (abfd))
return "N32";
else if (ABI_64_P (abfd))
return "64";
else
return "none";
case E_MIPS_ABI_O32:
return "O32";
case E_MIPS_ABI_O64:
return "O64";
case E_MIPS_ABI_EABI32:
return "EABI32";
case E_MIPS_ABI_EABI64:
return "EABI64";
default:
return "unknown abi";
}
}
/* MIPS ELF uses two common sections. One is the usual one, and the
other is for small objects. All the small objects are kept
together, and then referenced via the gp pointer, which yields
faster assembler code. This is what we use for the small common
section. This approach is copied from ecoff.c. */
static asection mips_elf_scom_section;
static asymbol mips_elf_scom_symbol;
static asymbol *mips_elf_scom_symbol_ptr;
/* MIPS ELF also uses an acommon section, which represents an
allocated common symbol which may be overridden by a
definition in a shared library. */
static asection mips_elf_acom_section;
static asymbol mips_elf_acom_symbol;
static asymbol *mips_elf_acom_symbol_ptr;
/* Handle the special MIPS section numbers that a symbol may use.
This is used for both the 32-bit and the 64-bit ABI. */
void
_bfd_mips_elf_symbol_processing (abfd, asym)
bfd *abfd;
asymbol *asym;
{
elf_symbol_type *elfsym;
elfsym = (elf_symbol_type *) asym;
switch (elfsym->internal_elf_sym.st_shndx)
{
case SHN_MIPS_ACOMMON:
/* This section is used in a dynamically linked executable file.
It is an allocated common section. The dynamic linker can
either resolve these symbols to something in a shared
library, or it can just leave them here. For our purposes,
we can consider these symbols to be in a new section. */
if (mips_elf_acom_section.name == NULL)
{
/* Initialize the acommon section. */
mips_elf_acom_section.name = ".acommon";
mips_elf_acom_section.flags = SEC_ALLOC;
mips_elf_acom_section.output_section = &mips_elf_acom_section;
mips_elf_acom_section.symbol = &mips_elf_acom_symbol;
mips_elf_acom_section.symbol_ptr_ptr = &mips_elf_acom_symbol_ptr;
mips_elf_acom_symbol.name = ".acommon";
mips_elf_acom_symbol.flags = BSF_SECTION_SYM;
mips_elf_acom_symbol.section = &mips_elf_acom_section;
mips_elf_acom_symbol_ptr = &mips_elf_acom_symbol;
}
asym->section = &mips_elf_acom_section;
break;
case SHN_COMMON:
/* Common symbols less than the GP size are automatically
treated as SHN_MIPS_SCOMMON symbols on IRIX5. */
if (asym->value > elf_gp_size (abfd)
|| IRIX_COMPAT (abfd) == ict_irix6)
break;
/* Fall through. */
case SHN_MIPS_SCOMMON:
if (mips_elf_scom_section.name == NULL)
{
/* Initialize the small common section. */
mips_elf_scom_section.name = ".scommon";
mips_elf_scom_section.flags = SEC_IS_COMMON;
mips_elf_scom_section.output_section = &mips_elf_scom_section;
mips_elf_scom_section.symbol = &mips_elf_scom_symbol;
mips_elf_scom_section.symbol_ptr_ptr = &mips_elf_scom_symbol_ptr;
mips_elf_scom_symbol.name = ".scommon";
mips_elf_scom_symbol.flags = BSF_SECTION_SYM;
mips_elf_scom_symbol.section = &mips_elf_scom_section;
mips_elf_scom_symbol_ptr = &mips_elf_scom_symbol;
}
asym->section = &mips_elf_scom_section;
asym->value = elfsym->internal_elf_sym.st_size;
break;
case SHN_MIPS_SUNDEFINED:
asym->section = bfd_und_section_ptr;
break;
#if 0 /* for SGI_COMPAT */
case SHN_MIPS_TEXT:
asym->section = mips_elf_text_section_ptr;
break;
case SHN_MIPS_DATA:
asym->section = mips_elf_data_section_ptr;
break;
#endif
}
}
/* Work over a section just before writing it out. This routine is
used by both the 32-bit and the 64-bit ABI. FIXME: We recognize
sections that need the SHF_MIPS_GPREL flag by name; there has to be
a better way. */
bfd_boolean
_bfd_mips_elf_section_processing (abfd, hdr)
bfd *abfd;
Elf_Internal_Shdr *hdr;
{
if (hdr->sh_type == SHT_MIPS_REGINFO
&& hdr->sh_size > 0)
{
bfd_byte buf[4];
BFD_ASSERT (hdr->sh_size == sizeof (Elf32_External_RegInfo));
BFD_ASSERT (hdr->contents == NULL);
if (bfd_seek (abfd,
hdr->sh_offset + sizeof (Elf32_External_RegInfo) - 4,
SEEK_SET) != 0)
return FALSE;
H_PUT_32 (abfd, elf_gp (abfd), buf);
if (bfd_bwrite (buf, (bfd_size_type) 4, abfd) != 4)
return FALSE;
}
if (hdr->sh_type == SHT_MIPS_OPTIONS
&& hdr->bfd_section != NULL
&& mips_elf_section_data (hdr->bfd_section) != NULL
&& mips_elf_section_data (hdr->bfd_section)->u.tdata != NULL)
{
bfd_byte *contents, *l, *lend;
/* We stored the section contents in the tdata field in the
set_section_contents routine. We save the section contents
so that we don't have to read them again.
At this point we know that elf_gp is set, so we can look
through the section contents to see if there is an
ODK_REGINFO structure. */
contents = mips_elf_section_data (hdr->bfd_section)->u.tdata;
l = contents;
lend = contents + hdr->sh_size;
while (l + sizeof (Elf_External_Options) <= lend)
{
Elf_Internal_Options intopt;
bfd_mips_elf_swap_options_in (abfd, (Elf_External_Options *) l,
&intopt);
if (ABI_64_P (abfd) && intopt.kind == ODK_REGINFO)
{
bfd_byte buf[8];
if (bfd_seek (abfd,
(hdr->sh_offset
+ (l - contents)
+ sizeof (Elf_External_Options)
+ (sizeof (Elf64_External_RegInfo) - 8)),
SEEK_SET) != 0)
return FALSE;
H_PUT_64 (abfd, elf_gp (abfd), buf);
if (bfd_bwrite (buf, (bfd_size_type) 8, abfd) != 8)
return FALSE;
}
else if (intopt.kind == ODK_REGINFO)
{
bfd_byte buf[4];
if (bfd_seek (abfd,
(hdr->sh_offset
+ (l - contents)
+ sizeof (Elf_External_Options)
+ (sizeof (Elf32_External_RegInfo) - 4)),
SEEK_SET) != 0)
return FALSE;
H_PUT_32 (abfd, elf_gp (abfd), buf);
if (bfd_bwrite (buf, (bfd_size_type) 4, abfd) != 4)
return FALSE;
}
l += intopt.size;
}
}
if (hdr->bfd_section != NULL)
{
const char *name = bfd_get_section_name (abfd, hdr->bfd_section);
if (strcmp (name, ".sdata") == 0
|| strcmp (name, ".lit8") == 0
|| strcmp (name, ".lit4") == 0)
{
hdr->sh_flags |= SHF_ALLOC | SHF_WRITE | SHF_MIPS_GPREL;
hdr->sh_type = SHT_PROGBITS;
}
else if (strcmp (name, ".sbss") == 0)
{
hdr->sh_flags |= SHF_ALLOC | SHF_WRITE | SHF_MIPS_GPREL;
hdr->sh_type = SHT_NOBITS;
}
else if (strcmp (name, ".srdata") == 0)
{
hdr->sh_flags |= SHF_ALLOC | SHF_MIPS_GPREL;
hdr->sh_type = SHT_PROGBITS;
}
else if (strcmp (name, ".compact_rel") == 0)
{
hdr->sh_flags = 0;
hdr->sh_type = SHT_PROGBITS;
}
else if (strcmp (name, ".rtproc") == 0)
{
if (hdr->sh_addralign != 0 && hdr->sh_entsize == 0)
{
unsigned int adjust;
adjust = hdr->sh_size % hdr->sh_addralign;
if (adjust != 0)
hdr->sh_size += hdr->sh_addralign - adjust;
}
}
}
return TRUE;
}
/* Handle a MIPS specific section when reading an object file. This
is called when elfcode.h finds a section with an unknown type.
This routine supports both the 32-bit and 64-bit ELF ABI.
FIXME: We need to handle the SHF_MIPS_GPREL flag, but I'm not sure
how to. */
bfd_boolean
_bfd_mips_elf_section_from_shdr (abfd, hdr, name)
bfd *abfd;
Elf_Internal_Shdr *hdr;
const char *name;
{
flagword flags = 0;
/* There ought to be a place to keep ELF backend specific flags, but
at the moment there isn't one. We just keep track of the
sections by their name, instead. Fortunately, the ABI gives
suggested names for all the MIPS specific sections, so we will
probably get away with this. */
switch (hdr->sh_type)
{
case SHT_MIPS_LIBLIST:
if (strcmp (name, ".liblist") != 0)
return FALSE;
break;
case SHT_MIPS_MSYM:
if (strcmp (name, ".msym") != 0)
return FALSE;
break;
case SHT_MIPS_CONFLICT:
if (strcmp (name, ".conflict") != 0)
return FALSE;
break;
case SHT_MIPS_GPTAB:
if (strncmp (name, ".gptab.", sizeof ".gptab." - 1) != 0)
return FALSE;
break;
case SHT_MIPS_UCODE:
if (strcmp (name, ".ucode") != 0)
return FALSE;
break;
case SHT_MIPS_DEBUG:
if (strcmp (name, ".mdebug") != 0)
return FALSE;
flags = SEC_DEBUGGING;
break;
case SHT_MIPS_REGINFO:
if (strcmp (name, ".reginfo") != 0
|| hdr->sh_size != sizeof (Elf32_External_RegInfo))
return FALSE;
flags = (SEC_LINK_ONCE | SEC_LINK_DUPLICATES_SAME_SIZE);
break;
case SHT_MIPS_IFACE:
if (strcmp (name, ".MIPS.interfaces") != 0)
return FALSE;
break;
case SHT_MIPS_CONTENT:
if (strncmp (name, ".MIPS.content", sizeof ".MIPS.content" - 1) != 0)
return FALSE;
break;
case SHT_MIPS_OPTIONS:
if (strcmp (name, MIPS_ELF_OPTIONS_SECTION_NAME (abfd)) != 0)
return FALSE;
break;
case SHT_MIPS_DWARF:
if (strncmp (name, ".debug_", sizeof ".debug_" - 1) != 0)
return FALSE;
break;
case SHT_MIPS_SYMBOL_LIB:
if (strcmp (name, ".MIPS.symlib") != 0)
return FALSE;
break;
case SHT_MIPS_EVENTS:
if (strncmp (name, ".MIPS.events", sizeof ".MIPS.events" - 1) != 0
&& strncmp (name, ".MIPS.post_rel",
sizeof ".MIPS.post_rel" - 1) != 0)
return FALSE;
break;
default:
return FALSE;
}
if (! _bfd_elf_make_section_from_shdr (abfd, hdr, name))
return FALSE;
if (flags)
{
if (! bfd_set_section_flags (abfd, hdr->bfd_section,
(bfd_get_section_flags (abfd,
hdr->bfd_section)
| flags)))
return FALSE;
}
/* FIXME: We should record sh_info for a .gptab section. */
/* For a .reginfo section, set the gp value in the tdata information
from the contents of this section. We need the gp value while
processing relocs, so we just get it now. The .reginfo section
is not used in the 64-bit MIPS ELF ABI. */
if (hdr->sh_type == SHT_MIPS_REGINFO)
{
Elf32_External_RegInfo ext;
Elf32_RegInfo s;
if (! bfd_get_section_contents (abfd, hdr->bfd_section, (PTR) &ext,
(file_ptr) 0,
(bfd_size_type) sizeof ext))
return FALSE;
bfd_mips_elf32_swap_reginfo_in (abfd, &ext, &s);
elf_gp (abfd) = s.ri_gp_value;
}
/* For a SHT_MIPS_OPTIONS section, look for a ODK_REGINFO entry, and
set the gp value based on what we find. We may see both
SHT_MIPS_REGINFO and SHT_MIPS_OPTIONS/ODK_REGINFO; in that case,
they should agree. */
if (hdr->sh_type == SHT_MIPS_OPTIONS)
{
bfd_byte *contents, *l, *lend;
contents = (bfd_byte *) bfd_malloc (hdr->sh_size);
if (contents == NULL)
return FALSE;
if (! bfd_get_section_contents (abfd, hdr->bfd_section, contents,
(file_ptr) 0, hdr->sh_size))
{
free (contents);
return FALSE;
}
l = contents;
lend = contents + hdr->sh_size;
while (l + sizeof (Elf_External_Options) <= lend)
{
Elf_Internal_Options intopt;
bfd_mips_elf_swap_options_in (abfd, (Elf_External_Options *) l,
&intopt);
if (ABI_64_P (abfd) && intopt.kind == ODK_REGINFO)
{
Elf64_Internal_RegInfo intreg;
bfd_mips_elf64_swap_reginfo_in
(abfd,
((Elf64_External_RegInfo *)
(l + sizeof (Elf_External_Options))),
&intreg);
elf_gp (abfd) = intreg.ri_gp_value;
}
else if (intopt.kind == ODK_REGINFO)
{
Elf32_RegInfo intreg;
bfd_mips_elf32_swap_reginfo_in
(abfd,
((Elf32_External_RegInfo *)
(l + sizeof (Elf_External_Options))),
&intreg);
elf_gp (abfd) = intreg.ri_gp_value;
}
l += intopt.size;
}
free (contents);
}
return TRUE;
}
/* Set the correct type for a MIPS ELF section. We do this by the
section name, which is a hack, but ought to work. This routine is
used by both the 32-bit and the 64-bit ABI. */
bfd_boolean
_bfd_mips_elf_fake_sections (abfd, hdr, sec)
bfd *abfd;
Elf_Internal_Shdr *hdr;
asection *sec;
{
register const char *name;
name = bfd_get_section_name (abfd, sec);
if (strcmp (name, ".liblist") == 0)
{
hdr->sh_type = SHT_MIPS_LIBLIST;
hdr->sh_info = sec->_raw_size / sizeof (Elf32_Lib);
/* The sh_link field is set in final_write_processing. */
}
else if (strcmp (name, ".conflict") == 0)
hdr->sh_type = SHT_MIPS_CONFLICT;
else if (strncmp (name, ".gptab.", sizeof ".gptab." - 1) == 0)
{
hdr->sh_type = SHT_MIPS_GPTAB;
hdr->sh_entsize = sizeof (Elf32_External_gptab);
/* The sh_info field is set in final_write_processing. */
}
else if (strcmp (name, ".ucode") == 0)
hdr->sh_type = SHT_MIPS_UCODE;
else if (strcmp (name, ".mdebug") == 0)
{
hdr->sh_type = SHT_MIPS_DEBUG;
/* In a shared object on IRIX 5.3, the .mdebug section has an
entsize of 0. FIXME: Does this matter? */
if (SGI_COMPAT (abfd) && (abfd->flags & DYNAMIC) != 0)
hdr->sh_entsize = 0;
else
hdr->sh_entsize = 1;
}
else if (strcmp (name, ".reginfo") == 0)
{
hdr->sh_type = SHT_MIPS_REGINFO;
/* In a shared object on IRIX 5.3, the .reginfo section has an
entsize of 0x18. FIXME: Does this matter? */
if (SGI_COMPAT (abfd))
{
if ((abfd->flags & DYNAMIC) != 0)
hdr->sh_entsize = sizeof (Elf32_External_RegInfo);
else
hdr->sh_entsize = 1;
}
else
hdr->sh_entsize = sizeof (Elf32_External_RegInfo);
}
else if (SGI_COMPAT (abfd)
&& (strcmp (name, ".hash") == 0
|| strcmp (name, ".dynamic") == 0
|| strcmp (name, ".dynstr") == 0))
{
if (SGI_COMPAT (abfd))
hdr->sh_entsize = 0;
#if 0
/* This isn't how the IRIX6 linker behaves. */
hdr->sh_info = SIZEOF_MIPS_DYNSYM_SECNAMES;
#endif
}
else if (strcmp (name, ".got") == 0
|| strcmp (name, ".srdata") == 0
|| strcmp (name, ".sdata") == 0
|| strcmp (name, ".sbss") == 0
|| strcmp (name, ".lit4") == 0
|| strcmp (name, ".lit8") == 0)
hdr->sh_flags |= SHF_MIPS_GPREL;
else if (strcmp (name, ".MIPS.interfaces") == 0)
{
hdr->sh_type = SHT_MIPS_IFACE;
hdr->sh_flags |= SHF_MIPS_NOSTRIP;
}
else if (strncmp (name, ".MIPS.content", strlen (".MIPS.content")) == 0)
{
hdr->sh_type = SHT_MIPS_CONTENT;
hdr->sh_flags |= SHF_MIPS_NOSTRIP;
/* The sh_info field is set in final_write_processing. */
}
else if (strcmp (name, MIPS_ELF_OPTIONS_SECTION_NAME (abfd)) == 0)
{
hdr->sh_type = SHT_MIPS_OPTIONS;
hdr->sh_entsize = 1;
hdr->sh_flags |= SHF_MIPS_NOSTRIP;
}
else if (strncmp (name, ".debug_", sizeof ".debug_" - 1) == 0)
hdr->sh_type = SHT_MIPS_DWARF;
else if (strcmp (name, ".MIPS.symlib") == 0)
{
hdr->sh_type = SHT_MIPS_SYMBOL_LIB;
/* The sh_link and sh_info fields are set in
final_write_processing. */
}
else if (strncmp (name, ".MIPS.events", sizeof ".MIPS.events" - 1) == 0
|| strncmp (name, ".MIPS.post_rel",
sizeof ".MIPS.post_rel" - 1) == 0)
{
hdr->sh_type = SHT_MIPS_EVENTS;
hdr->sh_flags |= SHF_MIPS_NOSTRIP;
/* The sh_link field is set in final_write_processing. */
}
else if (strcmp (name, ".msym") == 0)
{
hdr->sh_type = SHT_MIPS_MSYM;
hdr->sh_flags |= SHF_ALLOC;
hdr->sh_entsize = 8;
}
/* The generic elf_fake_sections will set up REL_HDR using the default
kind of relocations. We used to set up a second header for the
non-default kind of relocations here, but only NewABI would use
these, and the IRIX ld doesn't like resulting empty RELA sections.
Thus we create those header only on demand now. */
return TRUE;
}
/* Given a BFD section, try to locate the corresponding ELF section
index. This is used by both the 32-bit and the 64-bit ABI.
Actually, it's not clear to me that the 64-bit ABI supports these,
but for non-PIC objects we will certainly want support for at least
the .scommon section. */
bfd_boolean
_bfd_mips_elf_section_from_bfd_section (abfd, sec, retval)
bfd *abfd ATTRIBUTE_UNUSED;
asection *sec;
int *retval;
{
if (strcmp (bfd_get_section_name (abfd, sec), ".scommon") == 0)
{
*retval = SHN_MIPS_SCOMMON;
return TRUE;
}
if (strcmp (bfd_get_section_name (abfd, sec), ".acommon") == 0)
{
*retval = SHN_MIPS_ACOMMON;
return TRUE;
}
return FALSE;
}
/* Hook called by the linker routine which adds symbols from an object
file. We must handle the special MIPS section numbers here. */
bfd_boolean
_bfd_mips_elf_add_symbol_hook (abfd, info, sym, namep, flagsp, secp, valp)
bfd *abfd;
struct bfd_link_info *info;
const Elf_Internal_Sym *sym;
const char **namep;
flagword *flagsp ATTRIBUTE_UNUSED;
asection **secp;
bfd_vma *valp;
{
if (SGI_COMPAT (abfd)
&& (abfd->flags & DYNAMIC) != 0
&& strcmp (*namep, "_rld_new_interface") == 0)
{
/* Skip IRIX5 rld entry name. */
*namep = NULL;
return TRUE;
}
switch (sym->st_shndx)
{
case SHN_COMMON:
/* Common symbols less than the GP size are automatically
treated as SHN_MIPS_SCOMMON symbols. */
if (sym->st_size > elf_gp_size (abfd)
|| IRIX_COMPAT (abfd) == ict_irix6)
break;
/* Fall through. */
case SHN_MIPS_SCOMMON:
*secp = bfd_make_section_old_way (abfd, ".scommon");
(*secp)->flags |= SEC_IS_COMMON;
*valp = sym->st_size;
break;
case SHN_MIPS_TEXT:
/* This section is used in a shared object. */
if (elf_tdata (abfd)->elf_text_section == NULL)
{
asymbol *elf_text_symbol;
asection *elf_text_section;
bfd_size_type amt = sizeof (asection);
elf_text_section = bfd_zalloc (abfd, amt);
if (elf_text_section == NULL)
return FALSE;
amt = sizeof (asymbol);
elf_text_symbol = bfd_zalloc (abfd, amt);
if (elf_text_symbol == NULL)
return FALSE;
/* Initialize the section. */
elf_tdata (abfd)->elf_text_section = elf_text_section;
elf_tdata (abfd)->elf_text_symbol = elf_text_symbol;
elf_text_section->symbol = elf_text_symbol;
elf_text_section->symbol_ptr_ptr = &elf_tdata (abfd)->elf_text_symbol;
elf_text_section->name = ".text";
elf_text_section->flags = SEC_NO_FLAGS;
elf_text_section->output_section = NULL;
elf_text_section->owner = abfd;
elf_text_symbol->name = ".text";
elf_text_symbol->flags = BSF_SECTION_SYM | BSF_DYNAMIC;
elf_text_symbol->section = elf_text_section;
}
/* This code used to do *secp = bfd_und_section_ptr if
info->shared. I don't know why, and that doesn't make sense,
so I took it out. */
*secp = elf_tdata (abfd)->elf_text_section;
break;
case SHN_MIPS_ACOMMON:
/* Fall through. XXX Can we treat this as allocated data? */
case SHN_MIPS_DATA:
/* This section is used in a shared object. */
if (elf_tdata (abfd)->elf_data_section == NULL)
{
asymbol *elf_data_symbol;
asection *elf_data_section;
bfd_size_type amt = sizeof (asection);
elf_data_section = bfd_zalloc (abfd, amt);
if (elf_data_section == NULL)
return FALSE;
amt = sizeof (asymbol);
elf_data_symbol = bfd_zalloc (abfd, amt);
if (elf_data_symbol == NULL)
return FALSE;
/* Initialize the section. */
elf_tdata (abfd)->elf_data_section = elf_data_section;
elf_tdata (abfd)->elf_data_symbol = elf_data_symbol;
elf_data_section->symbol = elf_data_symbol;
elf_data_section->symbol_ptr_ptr = &elf_tdata (abfd)->elf_data_symbol;
elf_data_section->name = ".data";
elf_data_section->flags = SEC_NO_FLAGS;
elf_data_section->output_section = NULL;
elf_data_section->owner = abfd;
elf_data_symbol->name = ".data";
elf_data_symbol->flags = BSF_SECTION_SYM | BSF_DYNAMIC;
elf_data_symbol->section = elf_data_section;
}
/* This code used to do *secp = bfd_und_section_ptr if
info->shared. I don't know why, and that doesn't make sense,
so I took it out. */
*secp = elf_tdata (abfd)->elf_data_section;
break;
case SHN_MIPS_SUNDEFINED:
*secp = bfd_und_section_ptr;
break;
}
if (SGI_COMPAT (abfd)
&& ! info->shared
&& info->hash->creator == abfd->xvec
&& strcmp (*namep, "__rld_obj_head") == 0)
{
struct elf_link_hash_entry *h;
struct bfd_link_hash_entry *bh;
/* Mark __rld_obj_head as dynamic. */
bh = NULL;
if (! (_bfd_generic_link_add_one_symbol
(info, abfd, *namep, BSF_GLOBAL, *secp,
(bfd_vma) *valp, (const char *) NULL, FALSE,
get_elf_backend_data (abfd)->collect, &bh)))
return FALSE;
h = (struct elf_link_hash_entry *) bh;
h->elf_link_hash_flags &= ~ELF_LINK_NON_ELF;
h->elf_link_hash_flags |= ELF_LINK_HASH_DEF_REGULAR;
h->type = STT_OBJECT;
if (! bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
mips_elf_hash_table (info)->use_rld_obj_head = TRUE;
}
/* If this is a mips16 text symbol, add 1 to the value to make it
odd. This will cause something like .word SYM to come up with
the right value when it is loaded into the PC. */
if (sym->st_other == STO_MIPS16)
++*valp;
return TRUE;
}
/* This hook function is called before the linker writes out a global
symbol. We mark symbols as small common if appropriate. This is
also where we undo the increment of the value for a mips16 symbol. */
bfd_boolean
_bfd_mips_elf_link_output_symbol_hook (abfd, info, name, sym, input_sec)
bfd *abfd ATTRIBUTE_UNUSED;
struct bfd_link_info *info ATTRIBUTE_UNUSED;
const char *name ATTRIBUTE_UNUSED;
Elf_Internal_Sym *sym;
asection *input_sec;
{
/* If we see a common symbol, which implies a relocatable link, then
if a symbol was small common in an input file, mark it as small
common in the output file. */
if (sym->st_shndx == SHN_COMMON
&& strcmp (input_sec->name, ".scommon") == 0)
sym->st_shndx = SHN_MIPS_SCOMMON;
if (sym->st_other == STO_MIPS16
&& (sym->st_value & 1) != 0)
--sym->st_value;
return TRUE;
}
/* Functions for the dynamic linker. */
/* Create dynamic sections when linking against a dynamic object. */
bfd_boolean
_bfd_mips_elf_create_dynamic_sections (abfd, info)
bfd *abfd;
struct bfd_link_info *info;
{
struct elf_link_hash_entry *h;
struct bfd_link_hash_entry *bh;
flagword flags;
register asection *s;
const char * const *namep;
flags = (SEC_ALLOC | SEC_LOAD | SEC_HAS_CONTENTS | SEC_IN_MEMORY
| SEC_LINKER_CREATED | SEC_READONLY);
/* Mips ABI requests the .dynamic section to be read only. */
s = bfd_get_section_by_name (abfd, ".dynamic");
if (s != NULL)
{
if (! bfd_set_section_flags (abfd, s, flags))
return FALSE;
}
/* We need to create .got section. */
if (! mips_elf_create_got_section (abfd, info, FALSE))
return FALSE;
if (! mips_elf_rel_dyn_section (elf_hash_table (info)->dynobj, TRUE))
return FALSE;
/* Create .stub section. */
if (bfd_get_section_by_name (abfd,
MIPS_ELF_STUB_SECTION_NAME (abfd)) == NULL)
{
s = bfd_make_section (abfd, MIPS_ELF_STUB_SECTION_NAME (abfd));
if (s == NULL
|| ! bfd_set_section_flags (abfd, s, flags | SEC_CODE)
|| ! bfd_set_section_alignment (abfd, s,
MIPS_ELF_LOG_FILE_ALIGN (abfd)))
return FALSE;
}
if ((IRIX_COMPAT (abfd) == ict_irix5 || IRIX_COMPAT (abfd) == ict_none)
&& !info->shared
&& bfd_get_section_by_name (abfd, ".rld_map") == NULL)
{
s = bfd_make_section (abfd, ".rld_map");
if (s == NULL
|| ! bfd_set_section_flags (abfd, s, flags &~ (flagword) SEC_READONLY)
|| ! bfd_set_section_alignment (abfd, s,
MIPS_ELF_LOG_FILE_ALIGN (abfd)))
return FALSE;
}
/* On IRIX5, we adjust add some additional symbols and change the
alignments of several sections. There is no ABI documentation
indicating that this is necessary on IRIX6, nor any evidence that
the linker takes such action. */
if (IRIX_COMPAT (abfd) == ict_irix5)
{
for (namep = mips_elf_dynsym_rtproc_names; *namep != NULL; namep++)
{
bh = NULL;
if (! (_bfd_generic_link_add_one_symbol
(info, abfd, *namep, BSF_GLOBAL, bfd_und_section_ptr,
(bfd_vma) 0, (const char *) NULL, FALSE,
get_elf_backend_data (abfd)->collect, &bh)))
return FALSE;
h = (struct elf_link_hash_entry *) bh;
h->elf_link_hash_flags &= ~ELF_LINK_NON_ELF;
h->elf_link_hash_flags |= ELF_LINK_HASH_DEF_REGULAR;
h->type = STT_SECTION;
if (! bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
}
/* We need to create a .compact_rel section. */
if (SGI_COMPAT (abfd))
{
if (!mips_elf_create_compact_rel_section (abfd, info))
return FALSE;
}
/* Change alignments of some sections. */
s = bfd_get_section_by_name (abfd, ".hash");
if (s != NULL)
bfd_set_section_alignment (abfd, s, MIPS_ELF_LOG_FILE_ALIGN (abfd));
s = bfd_get_section_by_name (abfd, ".dynsym");
if (s != NULL)
bfd_set_section_alignment (abfd, s, MIPS_ELF_LOG_FILE_ALIGN (abfd));
s = bfd_get_section_by_name (abfd, ".dynstr");
if (s != NULL)
bfd_set_section_alignment (abfd, s, MIPS_ELF_LOG_FILE_ALIGN (abfd));
s = bfd_get_section_by_name (abfd, ".reginfo");
if (s != NULL)
bfd_set_section_alignment (abfd, s, MIPS_ELF_LOG_FILE_ALIGN (abfd));
s = bfd_get_section_by_name (abfd, ".dynamic");
if (s != NULL)
bfd_set_section_alignment (abfd, s, MIPS_ELF_LOG_FILE_ALIGN (abfd));
}
if (!info->shared)
{
const char *name;
name = SGI_COMPAT (abfd) ? "_DYNAMIC_LINK" : "_DYNAMIC_LINKING";
bh = NULL;
if (!(_bfd_generic_link_add_one_symbol
(info, abfd, name, BSF_GLOBAL, bfd_abs_section_ptr,
(bfd_vma) 0, (const char *) NULL, FALSE,
get_elf_backend_data (abfd)->collect, &bh)))
return FALSE;
h = (struct elf_link_hash_entry *) bh;
h->elf_link_hash_flags &= ~ELF_LINK_NON_ELF;
h->elf_link_hash_flags |= ELF_LINK_HASH_DEF_REGULAR;
h->type = STT_SECTION;
if (! bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
if (! mips_elf_hash_table (info)->use_rld_obj_head)
{
/* __rld_map is a four byte word located in the .data section
and is filled in by the rtld to contain a pointer to
the _r_debug structure. Its symbol value will be set in
_bfd_mips_elf_finish_dynamic_symbol. */
s = bfd_get_section_by_name (abfd, ".rld_map");
BFD_ASSERT (s != NULL);
name = SGI_COMPAT (abfd) ? "__rld_map" : "__RLD_MAP";
bh = NULL;
if (!(_bfd_generic_link_add_one_symbol
(info, abfd, name, BSF_GLOBAL, s,
(bfd_vma) 0, (const char *) NULL, FALSE,
get_elf_backend_data (abfd)->collect, &bh)))
return FALSE;
h = (struct elf_link_hash_entry *) bh;
h->elf_link_hash_flags &= ~ELF_LINK_NON_ELF;
h->elf_link_hash_flags |= ELF_LINK_HASH_DEF_REGULAR;
h->type = STT_OBJECT;
if (! bfd_elf32_link_record_dynamic_symbol (info, h))
return FALSE;
}
}
return TRUE;
}
/* Look through the relocs for a section during the first phase, and
allocate space in the global offset table. */
bfd_boolean
_bfd_mips_elf_check_relocs (abfd, info, sec, relocs)
bfd *abfd;
struct bfd_link_info *info;
asection *sec;
const Elf_Internal_Rela *relocs;
{
const char *name;
bfd *dynobj;
Elf_Internal_Shdr *symtab_hdr;
struct elf_link_hash_entry **sym_hashes;
struct mips_got_info *g;
size_t extsymoff;
const Elf_Internal_Rela *rel;
const Elf_Internal_Rela *rel_end;
asection *sgot;
asection *sreloc;
struct elf_backend_data *bed;
if (info->relocatable)
return TRUE;
dynobj = elf_hash_table (info)->dynobj;
symtab_hdr = &elf_tdata (abfd)->symtab_hdr;
sym_hashes = elf_sym_hashes (abfd);
extsymoff = (elf_bad_symtab (abfd)) ? 0 : symtab_hdr->sh_info;
/* Check for the mips16 stub sections. */
name = bfd_get_section_name (abfd, sec);
if (strncmp (name, FN_STUB, sizeof FN_STUB - 1) == 0)
{
unsigned long r_symndx;
/* Look at the relocation information to figure out which symbol
this is for. */
r_symndx = ELF_R_SYM (abfd, relocs->r_info);
if (r_symndx < extsymoff
|| sym_hashes[r_symndx - extsymoff] == NULL)
{
asection *o;
/* This stub is for a local symbol. This stub will only be
needed if there is some relocation in this BFD, other
than a 16 bit function call, which refers to this symbol. */
for (o = abfd->sections; o != NULL; o = o->next)
{
Elf_Internal_Rela *sec_relocs;
const Elf_Internal_Rela *r, *rend;
/* We can ignore stub sections when looking for relocs. */
if ((o->flags & SEC_RELOC) == 0
|| o->reloc_count == 0
|| strncmp (bfd_get_section_name (abfd, o), FN_STUB,
sizeof FN_STUB - 1) == 0
|| strncmp (bfd_get_section_name (abfd, o), CALL_STUB,
sizeof CALL_STUB - 1) == 0
|| strncmp (bfd_get_section_name (abfd, o), CALL_FP_STUB,
sizeof CALL_FP_STUB - 1) == 0)
continue;
sec_relocs
= _bfd_elf_link_read_relocs (abfd, o, (PTR) NULL,
(Elf_Internal_Rela *) NULL,
info->keep_memory);
if (sec_relocs == NULL)
return FALSE;
rend = sec_relocs + o->reloc_count;
for (r = sec_relocs; r < rend; r++)
if (ELF_R_SYM (abfd, r->r_info) == r_symndx
&& ELF_R_TYPE (abfd, r->r_info) != R_MIPS16_26)
break;
if (elf_section_data (o)->relocs != sec_relocs)
free (sec_relocs);
if (r < rend)
break;
}
if (o == NULL)
{
/* There is no non-call reloc for this stub, so we do
not need it. Since this function is called before
the linker maps input sections to output sections, we
can easily discard it by setting the SEC_EXCLUDE
flag. */
sec->flags |= SEC_EXCLUDE;
return TRUE;
}
/* Record this stub in an array of local symbol stubs for
this BFD. */
if (elf_tdata (abfd)->local_stubs == NULL)
{
unsigned long symcount;
asection **n;
bfd_size_type amt;
if (elf_bad_symtab (abfd))
symcount = NUM_SHDR_ENTRIES (symtab_hdr);
else
symcount = symtab_hdr->sh_info;
amt = symcount * sizeof (asection *);
n = (asection **) bfd_zalloc (abfd, amt);
if (n == NULL)
return FALSE;
elf_tdata (abfd)->local_stubs = n;
}
elf_tdata (abfd)->local_stubs[r_symndx] = sec;
/* We don't need to set mips16_stubs_seen in this case.
That flag is used to see whether we need to look through
the global symbol table for stubs. We don't need to set
it here, because we just have a local stub. */
}
else
{
struct mips_elf_link_hash_entry *h;
h = ((struct mips_elf_link_hash_entry *)
sym_hashes[r_symndx - extsymoff]);
/* H is the symbol this stub is for. */
h->fn_stub = sec;
mips_elf_hash_table (info)->mips16_stubs_seen = TRUE;
}
}
else if (strncmp (name, CALL_STUB, sizeof CALL_STUB - 1) == 0
|| strncmp (name, CALL_FP_STUB, sizeof CALL_FP_STUB - 1) == 0)
{
unsigned long r_symndx;
struct mips_elf_link_hash_entry *h;
asection **loc;
/* Look at the relocation information to figure out which symbol
this is for. */
r_symndx = ELF_R_SYM (abfd, relocs->r_info);
if (r_symndx < extsymoff
|| sym_hashes[r_symndx - extsymoff] == NULL)
{
/* This stub was actually built for a static symbol defined
in the same file. We assume that all static symbols in
mips16 code are themselves mips16, so we can simply
discard this stub. Since this function is called before
the linker maps input sections to output sections, we can
easily discard it by setting the SEC_EXCLUDE flag. */
sec->flags |= SEC_EXCLUDE;
return TRUE;
}
h = ((struct mips_elf_link_hash_entry *)
sym_hashes[r_symndx - extsymoff]);
/* H is the symbol this stub is for. */
if (strncmp (name, CALL_FP_STUB, sizeof CALL_FP_STUB - 1) == 0)
loc = &h->call_fp_stub;
else
loc = &h->call_stub;
/* If we already have an appropriate stub for this function, we
don't need another one, so we can discard this one. Since
this function is called before the linker maps input sections
to output sections, we can easily discard it by setting the
SEC_EXCLUDE flag. We can also discard this section if we
happen to already know that this is a mips16 function; it is
not necessary to check this here, as it is checked later, but
it is slightly faster to check now. */
if (*loc != NULL || h->root.other == STO_MIPS16)
{
sec->flags |= SEC_EXCLUDE;
return TRUE;
}
*loc = sec;
mips_elf_hash_table (info)->mips16_stubs_seen = TRUE;
}
if (dynobj == NULL)
{
sgot = NULL;
g = NULL;
}
else
{
sgot = mips_elf_got_section (dynobj, FALSE);
if (sgot == NULL)
g = NULL;
else
{
BFD_ASSERT (mips_elf_section_data (sgot) != NULL);
g = mips_elf_section_data (sgot)->u.got_info;
BFD_ASSERT (g != NULL);
}
}
sreloc = NULL;
bed = get_elf_backend_data (abfd);
rel_end = relocs + sec->reloc_count * bed->s->int_rels_per_ext_rel;
for (rel = relocs; rel < rel_end; ++rel)
{
unsigned long r_symndx;
unsigned int r_type;
struct elf_link_hash_entry *h;
r_symndx = ELF_R_SYM (abfd, rel->r_info);
r_type = ELF_R_TYPE (abfd, rel->r_info);
if (r_symndx < extsymoff)
h = NULL;
else if (r_symndx >= extsymoff + NUM_SHDR_ENTRIES (symtab_hdr))
{
(*_bfd_error_handler)
(_("%s: Malformed reloc detected for section %s"),
bfd_archive_filename (abfd), name);
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
else
{
h = sym_hashes[r_symndx - extsymoff];
/* This may be an indirect symbol created because of a version. */
if (h != NULL)
{
while (h->root.type == bfd_link_hash_indirect)
h = (struct elf_link_hash_entry *) h->root.u.i.link;
}
}
/* Some relocs require a global offset table. */
if (dynobj == NULL || sgot == NULL)
{
switch (r_type)
{
case R_MIPS_GOT16:
case R_MIPS_CALL16:
case R_MIPS_CALL_HI16:
case R_MIPS_CALL_LO16:
case R_MIPS_GOT_HI16:
case R_MIPS_GOT_LO16:
case R_MIPS_GOT_PAGE:
case R_MIPS_GOT_OFST:
case R_MIPS_GOT_DISP:
if (dynobj == NULL)
elf_hash_table (info)->dynobj = dynobj = abfd;
if (! mips_elf_create_got_section (dynobj, info, FALSE))
return FALSE;
g = mips_elf_got_info (dynobj, &sgot);
break;
case R_MIPS_32:
case R_MIPS_REL32:
case R_MIPS_64:
if (dynobj == NULL
&& (info->shared || h != NULL)
&& (sec->flags & SEC_ALLOC) != 0)
elf_hash_table (info)->dynobj = dynobj = abfd;
break;
default:
break;
}
}
if (!h && (r_type == R_MIPS_CALL_LO16
|| r_type == R_MIPS_GOT_LO16
|| r_type == R_MIPS_GOT_DISP))
{
/* We may need a local GOT entry for this relocation. We
don't count R_MIPS_GOT_PAGE because we can estimate the
maximum number of pages needed by looking at the size of
the segment. Similar comments apply to R_MIPS_GOT16 and
R_MIPS_CALL16. We don't count R_MIPS_GOT_HI16, or
R_MIPS_CALL_HI16 because these are always followed by an
R_MIPS_GOT_LO16 or R_MIPS_CALL_LO16. */
if (! mips_elf_record_local_got_symbol (abfd, r_symndx,
rel->r_addend, g))
return FALSE;
}
switch (r_type)
{
case R_MIPS_CALL16:
if (h == NULL)
{
(*_bfd_error_handler)
(_("%s: CALL16 reloc at 0x%lx not against global symbol"),
bfd_archive_filename (abfd), (unsigned long) rel->r_offset);
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
/* Fall through. */
case R_MIPS_CALL_HI16:
case R_MIPS_CALL_LO16:
if (h != NULL)
{
/* This symbol requires a global offset table entry. */
if (! mips_elf_record_global_got_symbol (h, abfd, info, g))
return FALSE;
/* We need a stub, not a plt entry for the undefined
function. But we record it as if it needs plt. See
elf_adjust_dynamic_symbol in elflink.h. */
h->elf_link_hash_flags |= ELF_LINK_HASH_NEEDS_PLT;
h->type = STT_FUNC;
}
break;
case R_MIPS_GOT_PAGE:
/* If this is a global, overridable symbol, GOT_PAGE will
decay to GOT_DISP, so we'll need a GOT entry for it. */
if (h == NULL)
break;
else
{
struct mips_elf_link_hash_entry *hmips =
(struct mips_elf_link_hash_entry *) h;
while (hmips->root.root.type == bfd_link_hash_indirect
|| hmips->root.root.type == bfd_link_hash_warning)
hmips = (struct mips_elf_link_hash_entry *)
hmips->root.root.u.i.link;
if ((hmips->root.root.type == bfd_link_hash_defined
|| hmips->root.root.type == bfd_link_hash_defweak)
&& hmips->root.root.u.def.section
&& ! (info->shared && ! info->symbolic
&& ! (hmips->root.elf_link_hash_flags
& ELF_LINK_FORCED_LOCAL))
/* If we've encountered any other relocation
referencing the symbol, we'll have marked it as
dynamic, and, even though we might be able to get
rid of the GOT entry should we know for sure all
previous relocations were GOT_PAGE ones, at this
point we can't tell, so just keep using the
symbol as dynamic. This is very important in the
multi-got case, since we don't decide whether to
decay GOT_PAGE to GOT_DISP on a per-GOT basis: if
the symbol is dynamic, we'll need a GOT entry for
every GOT in which the symbol is referenced with
a GOT_PAGE relocation. */
&& hmips->root.dynindx == -1)
break;
}
/* Fall through. */
case R_MIPS_GOT16:
case R_MIPS_GOT_HI16:
case R_MIPS_GOT_LO16:
case R_MIPS_GOT_DISP:
/* This symbol requires a global offset table entry. */
if (h && ! mips_elf_record_global_got_symbol (h, abfd, info, g))
return FALSE;
break;
case R_MIPS_32:
case R_MIPS_REL32:
case R_MIPS_64:
if ((info->shared || h != NULL)
&& (sec->flags & SEC_ALLOC) != 0)
{
if (sreloc == NULL)
{
sreloc = mips_elf_rel_dyn_section (dynobj, TRUE);
if (sreloc == NULL)
return FALSE;
}
#define MIPS_READONLY_SECTION (SEC_ALLOC | SEC_LOAD | SEC_READONLY)
if (info->shared)
{
/* When creating a shared object, we must copy these
reloc types into the output file as R_MIPS_REL32
relocs. We make room for this reloc in the
.rel.dyn reloc section. */
mips_elf_allocate_dynamic_relocations (dynobj, 1);
if ((sec->flags & MIPS_READONLY_SECTION)
== MIPS_READONLY_SECTION)
/* We tell the dynamic linker that there are
relocations against the text segment. */
info->flags |= DF_TEXTREL;
}
else
{
struct mips_elf_link_hash_entry *hmips;
/* We only need to copy this reloc if the symbol is
defined in a dynamic object. */
hmips = (struct mips_elf_link_hash_entry *) h;
++hmips->possibly_dynamic_relocs;
if ((sec->flags & MIPS_READONLY_SECTION)
== MIPS_READONLY_SECTION)
/* We need it to tell the dynamic linker if there
are relocations against the text segment. */
hmips->readonly_reloc = TRUE;
}
/* Even though we don't directly need a GOT entry for
this symbol, a symbol must have a dynamic symbol
table index greater that DT_MIPS_GOTSYM if there are
dynamic relocations against it. */
if (h != NULL)
{
if (dynobj == NULL)
elf_hash_table (info)->dynobj = dynobj = abfd;
if (! mips_elf_create_got_section (dynobj, info, TRUE))
return FALSE;
g = mips_elf_got_info (dynobj, &sgot);
if (! mips_elf_record_global_got_symbol (h, abfd, info, g))
return FALSE;
}
}
if (SGI_COMPAT (abfd))
mips_elf_hash_table (info)->compact_rel_size +=
sizeof (Elf32_External_crinfo);
break;
case R_MIPS_26:
case R_MIPS_GPREL16:
case R_MIPS_LITERAL:
case R_MIPS_GPREL32:
if (SGI_COMPAT (abfd))
mips_elf_hash_table (info)->compact_rel_size +=
sizeof (Elf32_External_crinfo);
break;
/* This relocation describes the C++ object vtable hierarchy.
Reconstruct it for later use during GC. */
case R_MIPS_GNU_VTINHERIT:
if (!_bfd_elf32_gc_record_vtinherit (abfd, sec, h, rel->r_offset))
return FALSE;
break;
/* This relocation describes which C++ vtable entries are actually
used. Record for later use during GC. */
case R_MIPS_GNU_VTENTRY:
if (!_bfd_elf32_gc_record_vtentry (abfd, sec, h, rel->r_offset))
return FALSE;
break;
default:
break;
}
/* We must not create a stub for a symbol that has relocations
related to taking the function's address. */
switch (r_type)
{
default:
if (h != NULL)
{
struct mips_elf_link_hash_entry *mh;
mh = (struct mips_elf_link_hash_entry *) h;
mh->no_fn_stub = TRUE;
}
break;
case R_MIPS_CALL16:
case R_MIPS_CALL_HI16:
case R_MIPS_CALL_LO16:
case R_MIPS_JALR:
break;
}
/* If this reloc is not a 16 bit call, and it has a global
symbol, then we will need the fn_stub if there is one.
References from a stub section do not count. */
if (h != NULL
&& r_type != R_MIPS16_26
&& strncmp (bfd_get_section_name (abfd, sec), FN_STUB,
sizeof FN_STUB - 1) != 0
&& strncmp (bfd_get_section_name (abfd, sec), CALL_STUB,
sizeof CALL_STUB - 1) != 0
&& strncmp (bfd_get_section_name (abfd, sec), CALL_FP_STUB,
sizeof CALL_FP_STUB - 1) != 0)
{
struct mips_elf_link_hash_entry *mh;
mh = (struct mips_elf_link_hash_entry *) h;
mh->need_fn_stub = TRUE;
}
}
return TRUE;
}
bfd_boolean
_bfd_mips_relax_section (abfd, sec, link_info, again)
bfd *abfd;
asection *sec;
struct bfd_link_info *link_info;
bfd_boolean *again;
{
Elf_Internal_Rela *internal_relocs;
Elf_Internal_Rela *irel, *irelend;
Elf_Internal_Shdr *symtab_hdr;
bfd_byte *contents = NULL;
bfd_byte *free_contents = NULL;
size_t extsymoff;
bfd_boolean changed_contents = FALSE;
bfd_vma sec_start = sec->output_section->vma + sec->output_offset;
Elf_Internal_Sym *isymbuf = NULL;
/* We are not currently changing any sizes, so only one pass. */
*again = FALSE;
if (link_info->relocatable)
return TRUE;
internal_relocs = _bfd_elf_link_read_relocs (abfd, sec, (PTR) NULL,
(Elf_Internal_Rela *) NULL,
link_info->keep_memory);
if (internal_relocs == NULL)
return TRUE;
irelend = internal_relocs + sec->reloc_count
* get_elf_backend_data (abfd)->s->int_rels_per_ext_rel;
symtab_hdr = &elf_tdata (abfd)->symtab_hdr;
extsymoff = (elf_bad_symtab (abfd)) ? 0 : symtab_hdr->sh_info;
for (irel = internal_relocs; irel < irelend; irel++)
{
bfd_vma symval;
bfd_signed_vma sym_offset;
unsigned int r_type;
unsigned long r_symndx;
asection *sym_sec;
unsigned long instruction;
/* Turn jalr into bgezal, and jr into beq, if they're marked
with a JALR relocation, that indicate where they jump to.
This saves some pipeline bubbles. */
r_type = ELF_R_TYPE (abfd, irel->r_info);
if (r_type != R_MIPS_JALR)
continue;
r_symndx = ELF_R_SYM (abfd, irel->r_info);
/* Compute the address of the jump target. */
if (r_symndx >= extsymoff)
{
struct mips_elf_link_hash_entry *h
= ((struct mips_elf_link_hash_entry *)
elf_sym_hashes (abfd) [r_symndx - extsymoff]);
while (h->root.root.type == bfd_link_hash_indirect
|| h->root.root.type == bfd_link_hash_warning)
h = (struct mips_elf_link_hash_entry *) h->root.root.u.i.link;
/* If a symbol is undefined, or if it may be overridden,
skip it. */
if (! ((h->root.root.type == bfd_link_hash_defined
|| h->root.root.type == bfd_link_hash_defweak)
&& h->root.root.u.def.section)
|| (link_info->shared && ! link_info->symbolic
&& ! (h->root.elf_link_hash_flags & ELF_LINK_FORCED_LOCAL)))
continue;
sym_sec = h->root.root.u.def.section;
if (sym_sec->output_section)
symval = (h->root.root.u.def.value
+ sym_sec->output_section->vma
+ sym_sec->output_offset);
else
symval = h->root.root.u.def.value;
}
else
{
Elf_Internal_Sym *isym;
/* Read this BFD's symbols if we haven't done so already. */
if (isymbuf == NULL && symtab_hdr->sh_info != 0)
{
isymbuf = (Elf_Internal_Sym *) symtab_hdr->contents;
if (isymbuf == NULL)
isymbuf = bfd_elf_get_elf_syms (abfd, symtab_hdr,
symtab_hdr->sh_info, 0,
NULL, NULL, NULL);
if (isymbuf == NULL)
goto relax_return;
}
isym = isymbuf + r_symndx;
if (isym->st_shndx == SHN_UNDEF)
continue;
else if (isym->st_shndx == SHN_ABS)
sym_sec = bfd_abs_section_ptr;
else if (isym->st_shndx == SHN_COMMON)
sym_sec = bfd_com_section_ptr;
else
sym_sec
= bfd_section_from_elf_index (abfd, isym->st_shndx);
symval = isym->st_value
+ sym_sec->output_section->vma
+ sym_sec->output_offset;
}
/* Compute branch offset, from delay slot of the jump to the
branch target. */
sym_offset = (symval + irel->r_addend)
- (sec_start + irel->r_offset + 4);
/* Branch offset must be properly aligned. */
if ((sym_offset & 3) != 0)
continue;
sym_offset >>= 2;
/* Check that it's in range. */
if (sym_offset < -0x8000 || sym_offset >= 0x8000)
continue;
/* Get the section contents if we haven't done so already. */
if (contents == NULL)
{
/* Get cached copy if it exists. */
if (elf_section_data (sec)->this_hdr.contents != NULL)
contents = elf_section_data (sec)->this_hdr.contents;
else
{
contents = (bfd_byte *) bfd_malloc (sec->_raw_size);
if (contents == NULL)
goto relax_return;
free_contents = contents;
if (! bfd_get_section_contents (abfd, sec, contents,
(file_ptr) 0, sec->_raw_size))
goto relax_return;
}
}
instruction = bfd_get_32 (abfd, contents + irel->r_offset);
/* If it was jalr <reg>, turn it into bgezal $zero, <target>. */
if ((instruction & 0xfc1fffff) == 0x0000f809)
instruction = 0x04110000;
/* If it was jr <reg>, turn it into b <target>. */
else if ((instruction & 0xfc1fffff) == 0x00000008)
instruction = 0x10000000;
else
continue;
instruction |= (sym_offset & 0xffff);
bfd_put_32 (abfd, instruction, contents + irel->r_offset);
changed_contents = TRUE;
}
if (contents != NULL
&& elf_section_data (sec)->this_hdr.contents != contents)
{
if (!changed_contents && !link_info->keep_memory)
free (contents);
else
{
/* Cache the section contents for elf_link_input_bfd. */
elf_section_data (sec)->this_hdr.contents = contents;
}
}
return TRUE;
relax_return:
if (free_contents != NULL)
free (free_contents);
return FALSE;
}
/* Adjust a symbol defined by a dynamic object and referenced by a
regular object. The current definition is in some section of the
dynamic object, but we're not including those sections. We have to
change the definition to something the rest of the link can
understand. */
bfd_boolean
_bfd_mips_elf_adjust_dynamic_symbol (info, h)
struct bfd_link_info *info;
struct elf_link_hash_entry *h;
{
bfd *dynobj;
struct mips_elf_link_hash_entry *hmips;
asection *s;
dynobj = elf_hash_table (info)->dynobj;
/* Make sure we know what is going on here. */
BFD_ASSERT (dynobj != NULL
&& ((h->elf_link_hash_flags & ELF_LINK_HASH_NEEDS_PLT)
|| h->weakdef != NULL
|| ((h->elf_link_hash_flags
& ELF_LINK_HASH_DEF_DYNAMIC) != 0
&& (h->elf_link_hash_flags
& ELF_LINK_HASH_REF_REGULAR) != 0
&& (h->elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0)));
/* If this symbol is defined in a dynamic object, we need to copy
any R_MIPS_32 or R_MIPS_REL32 relocs against it into the output
file. */
hmips = (struct mips_elf_link_hash_entry *) h;
if (! info->relocatable
&& hmips->possibly_dynamic_relocs != 0
&& (h->root.type == bfd_link_hash_defweak
|| (h->elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0))
{
mips_elf_allocate_dynamic_relocations (dynobj,
hmips->possibly_dynamic_relocs);
if (hmips->readonly_reloc)
/* We tell the dynamic linker that there are relocations
against the text segment. */
info->flags |= DF_TEXTREL;
}
/* For a function, create a stub, if allowed. */
if (! hmips->no_fn_stub
&& (h->elf_link_hash_flags & ELF_LINK_HASH_NEEDS_PLT) != 0)
{
if (! elf_hash_table (info)->dynamic_sections_created)
return TRUE;
/* If this symbol is not defined in a regular file, then set
the symbol to the stub location. This is required to make
function pointers compare as equal between the normal
executable and the shared library. */
if ((h->elf_link_hash_flags & ELF_LINK_HASH_DEF_REGULAR) == 0)
{
/* We need .stub section. */
s = bfd_get_section_by_name (dynobj,
MIPS_ELF_STUB_SECTION_NAME (dynobj));
BFD_ASSERT (s != NULL);
h->root.u.def.section = s;
h->root.u.def.value = s->_raw_size;
/* XXX Write this stub address somewhere. */
h->plt.offset = s->_raw_size;
/* Make room for this stub code. */
s->_raw_size += MIPS_FUNCTION_STUB_SIZE;
/* The last half word of the stub will be filled with the index
of this symbol in .dynsym section. */
return TRUE;
}
}
else if ((h->type == STT_FUNC)
&& (h->elf_link_hash_flags & ELF_LINK_HASH_NEEDS_PLT) == 0)
{
/* This will set the entry for this symbol in the GOT to 0, and
the dynamic linker will take care of this. */
h->root.u.def.value = 0;
return TRUE;
}
/* If this is a weak symbol, and there is a real definition, the
processor independent code will have arranged for us to see the
real definition first, and we can just use the same value. */
if (h->weakdef != NULL)
{
BFD_ASSERT (h->weakdef->root.type == bfd_link_hash_defined
|| h->weakdef->root.type == bfd_link_hash_defweak);
h->root.u.def.section = h->weakdef->root.u.def.section;
h->root.u.def.value = h->weakdef->root.u.def.value;
return TRUE;
}
/* This is a reference to a symbol defined by a dynamic object which
is not a function. */
return TRUE;
}
/* This function is called after all the input files have been read,
and the input sections have been assigned to output sections. We
check for any mips16 stub sections that we can discard. */
bfd_boolean
_bfd_mips_elf_always_size_sections (output_bfd, info)
bfd *output_bfd;
struct bfd_link_info *info;
{
asection *ri;
bfd *dynobj;
asection *s;
struct mips_got_info *g;
int i;
bfd_size_type loadable_size = 0;
bfd_size_type local_gotno;
bfd *sub;
/* The .reginfo section has a fixed size. */
ri = bfd_get_section_by_name (output_bfd, ".reginfo");
if (ri != NULL)
bfd_set_section_size (output_bfd, ri,
(bfd_size_type) sizeof (Elf32_External_RegInfo));
if (! (info->relocatable
|| ! mips_elf_hash_table (info)->mips16_stubs_seen))
mips_elf_link_hash_traverse (mips_elf_hash_table (info),
mips_elf_check_mips16_stubs,
(PTR) NULL);
dynobj = elf_hash_table (info)->dynobj;
if (dynobj == NULL)
/* Relocatable links don't have it. */
return TRUE;
g = mips_elf_got_info (dynobj, &s);
if (s == NULL)
return TRUE;
/* Calculate the total loadable size of the output. That
will give us the maximum number of GOT_PAGE entries
required. */
for (sub = info->input_bfds; sub; sub = sub->link_next)
{
asection *subsection;
for (subsection = sub->sections;
subsection;
subsection = subsection->next)
{
if ((subsection->flags & SEC_ALLOC) == 0)
continue;
loadable_size += ((subsection->_raw_size + 0xf)
&~ (bfd_size_type) 0xf);
}
}
/* There has to be a global GOT entry for every symbol with
a dynamic symbol table index of DT_MIPS_GOTSYM or
higher. Therefore, it make sense to put those symbols
that need GOT entries at the end of the symbol table. We
do that here. */
if (! mips_elf_sort_hash_table (info, 1))
return FALSE;
if (g->global_gotsym != NULL)
i = elf_hash_table (info)->dynsymcount - g->global_gotsym->dynindx;
else
/* If there are no global symbols, or none requiring
relocations, then GLOBAL_GOTSYM will be NULL. */
i = 0;
/* In the worst case, we'll get one stub per dynamic symbol, plus
one to account for the dummy entry at the end required by IRIX
rld. */
loadable_size += MIPS_FUNCTION_STUB_SIZE * (i + 1);
/* Assume there are two loadable segments consisting of
contiguous sections. Is 5 enough? */
local_gotno = (loadable_size >> 16) + 5;
g->local_gotno += local_gotno;
s->_raw_size += g->local_gotno * MIPS_ELF_GOT_SIZE (output_bfd);
g->global_gotno = i;
s->_raw_size += i * MIPS_ELF_GOT_SIZE (output_bfd);
if (s->_raw_size > MIPS_ELF_GOT_MAX_SIZE (output_bfd)
&& ! mips_elf_multi_got (output_bfd, info, g, s, local_gotno))
return FALSE;
return TRUE;
}
/* Set the sizes of the dynamic sections. */
bfd_boolean
_bfd_mips_elf_size_dynamic_sections (output_bfd, info)
bfd *output_bfd;
struct bfd_link_info *info;
{
bfd *dynobj;
asection *s;
bfd_boolean reltext;
dynobj = elf_hash_table (info)->dynobj;
BFD_ASSERT (dynobj != NULL);
if (elf_hash_table (info)->dynamic_sections_created)
{
/* Set the contents of the .interp section to the interpreter. */
if (! info->shared)
{
s = bfd_get_section_by_name (dynobj, ".interp");
BFD_ASSERT (s != NULL);
s->_raw_size
= strlen (ELF_DYNAMIC_INTERPRETER (output_bfd)) + 1;
s->contents
= (bfd_byte *) ELF_DYNAMIC_INTERPRETER (output_bfd);
}
}
/* The check_relocs and adjust_dynamic_symbol entry points have
determined the sizes of the various dynamic sections. Allocate
memory for them. */
reltext = FALSE;
for (s = dynobj->sections; s != NULL; s = s->next)
{
const char *name;
bfd_boolean strip;
/* It's OK to base decisions on the section name, because none
of the dynobj section names depend upon the input files. */
name = bfd_get_section_name (dynobj, s);
if ((s->flags & SEC_LINKER_CREATED) == 0)
continue;
strip = FALSE;
if (strncmp (name, ".rel", 4) == 0)
{
if (s->_raw_size == 0)
{
/* We only strip the section if the output section name
has the same name. Otherwise, there might be several
input sections for this output section. FIXME: This
code is probably not needed these days anyhow, since
the linker now does not create empty output sections. */
if (s->output_section != NULL
&& strcmp (name,
bfd_get_section_name (s->output_section->owner,
s->output_section)) == 0)
strip = TRUE;
}
else
{
const char *outname;
asection *target;
/* If this relocation section applies to a read only
section, then we probably need a DT_TEXTREL entry.
If the relocation section is .rel.dyn, we always
assert a DT_TEXTREL entry rather than testing whether
there exists a relocation to a read only section or
not. */
outname = bfd_get_section_name (output_bfd,
s->output_section);
target = bfd_get_section_by_name (output_bfd, outname + 4);
if ((target != NULL
&& (target->flags & SEC_READONLY) != 0
&& (target->flags & SEC_ALLOC) != 0)
|| strcmp (outname, ".rel.dyn") == 0)
reltext = TRUE;
/* We use the reloc_count field as a counter if we need
to copy relocs into the output file. */
if (strcmp (name, ".rel.dyn") != 0)
s->reloc_count = 0;
/* If combreloc is enabled, elf_link_sort_relocs() will
sort relocations, but in a different way than we do,
and before we're done creating relocations. Also, it
will move them around between input sections'
relocation's contents, so our sorting would be
broken, so don't let it run. */
info->combreloc = 0;
}
}
else if (strncmp (name, ".got", 4) == 0)
{
/* _bfd_mips_elf_always_size_sections() has already done
most of the work, but some symbols may have been mapped
to versions that we must now resolve in the got_entries
hash tables. */
struct mips_got_info *gg = mips_elf_got_info (dynobj, NULL);
struct mips_got_info *g = gg;
struct mips_elf_set_global_got_offset_arg set_got_offset_arg;
unsigned int needed_relocs = 0;
if (gg->next)
{
set_got_offset_arg.value = MIPS_ELF_GOT_SIZE (output_bfd);
set_got_offset_arg.info = info;
mips_elf_resolve_final_got_entries (gg);
for (g = gg->next; g && g->next != gg; g = g->next)
{
unsigned int save_assign;
mips_elf_resolve_final_got_entries (g);
/* Assign offsets to global GOT entries. */
save_assign = g->assigned_gotno;
g->assigned_gotno = g->local_gotno;
set_got_offset_arg.g = g;
set_got_offset_arg.needed_relocs = 0;
htab_traverse (g->got_entries,
mips_elf_set_global_got_offset,
&set_got_offset_arg);
needed_relocs += set_got_offset_arg.needed_relocs;
BFD_ASSERT (g->assigned_gotno - g->local_gotno
<= g->global_gotno);
g->assigned_gotno = save_assign;
if (info->shared)
{
needed_relocs += g->local_gotno - g->assigned_gotno;
BFD_ASSERT (g->assigned_gotno == g->next->local_gotno
+ g->next->global_gotno
+ MIPS_RESERVED_GOTNO);
}
}
if (needed_relocs)
mips_elf_allocate_dynamic_relocations (dynobj, needed_relocs);
}
}
else if (strcmp (name, MIPS_ELF_STUB_SECTION_NAME (output_bfd)) == 0)
{
/* IRIX rld assumes that the function stub isn't at the end
of .text section. So put a dummy. XXX */
s->_raw_size += MIPS_FUNCTION_STUB_SIZE;
}
else if (! info->shared
&& ! mips_elf_hash_table (info)->use_rld_obj_head
&& strncmp (name, ".rld_map", 8) == 0)
{
/* We add a room for __rld_map. It will be filled in by the
rtld to contain a pointer to the _r_debug structure. */
s->_raw_size += 4;
}
else if (SGI_COMPAT (output_bfd)
&& strncmp (name, ".compact_rel", 12) == 0)
s->_raw_size += mips_elf_hash_table (info)->compact_rel_size;
else if (strncmp (name, ".init", 5) != 0)
{
/* It's not one of our sections, so don't allocate space. */
continue;
}
if (strip)
{
_bfd_strip_section_from_output (info, s);
continue;
}
/* Allocate memory for the section contents. */
s->contents = (bfd_byte *) bfd_zalloc (dynobj, s->_raw_size);
if (s->contents == NULL && s->_raw_size != 0)
{
bfd_set_error (bfd_error_no_memory);
return FALSE;
}
}
if (elf_hash_table (info)->dynamic_sections_created)
{
/* Add some entries to the .dynamic section. We fill in the
values later, in _bfd_mips_elf_finish_dynamic_sections, but we
must add the entries now so that we get the correct size for
the .dynamic section. The DT_DEBUG entry is filled in by the
dynamic linker and used by the debugger. */
if (! info->shared)
{
/* SGI object has the equivalence of DT_DEBUG in the
DT_MIPS_RLD_MAP entry. */
if (!MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_RLD_MAP, 0))
return FALSE;
if (!SGI_COMPAT (output_bfd))
{
if (!MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_DEBUG, 0))
return FALSE;
}
}
else
{
/* Shared libraries on traditional mips have DT_DEBUG. */
if (!SGI_COMPAT (output_bfd))
{
if (!MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_DEBUG, 0))
return FALSE;
}
}
if (reltext && SGI_COMPAT (output_bfd))
info->flags |= DF_TEXTREL;
if ((info->flags & DF_TEXTREL) != 0)
{
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_TEXTREL, 0))
return FALSE;
}
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_PLTGOT, 0))
return FALSE;
if (mips_elf_rel_dyn_section (dynobj, FALSE))
{
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_REL, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_RELSZ, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_RELENT, 0))
return FALSE;
}
if (SGI_COMPAT (output_bfd))
{
if (!MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_CONFLICTNO, 0))
return FALSE;
}
if (SGI_COMPAT (output_bfd))
{
if (!MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_LIBLISTNO, 0))
return FALSE;
}
if (bfd_get_section_by_name (dynobj, ".conflict") != NULL)
{
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_CONFLICT, 0))
return FALSE;
s = bfd_get_section_by_name (dynobj, ".liblist");
BFD_ASSERT (s != NULL);
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_LIBLIST, 0))
return FALSE;
}
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_RLD_VERSION, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_FLAGS, 0))
return FALSE;
#if 0
/* Time stamps in executable files are a bad idea. */
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_TIME_STAMP, 0))
return FALSE;
#endif
#if 0 /* FIXME */
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_ICHECKSUM, 0))
return FALSE;
#endif
#if 0 /* FIXME */
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_IVERSION, 0))
return FALSE;
#endif
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_BASE_ADDRESS, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_LOCAL_GOTNO, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_SYMTABNO, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_UNREFEXTNO, 0))
return FALSE;
if (! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_GOTSYM, 0))
return FALSE;
if (IRIX_COMPAT (dynobj) == ict_irix5
&& ! MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_HIPAGENO, 0))
return FALSE;
if (IRIX_COMPAT (dynobj) == ict_irix6
&& (bfd_get_section_by_name
(dynobj, MIPS_ELF_OPTIONS_SECTION_NAME (dynobj)))
&& !MIPS_ELF_ADD_DYNAMIC_ENTRY (info, DT_MIPS_OPTIONS, 0))
return FALSE;
}
return TRUE;
}
/* Relocate a MIPS ELF section. */
bfd_boolean
_bfd_mips_elf_relocate_section (output_bfd, info, input_bfd, input_section,
contents, relocs, local_syms, local_sections)
bfd *output_bfd;
struct bfd_link_info *info;
bfd *input_bfd;
asection *input_section;
bfd_byte *contents;
Elf_Internal_Rela *relocs;
Elf_Internal_Sym *local_syms;
asection **local_sections;
{
Elf_Internal_Rela *rel;
const Elf_Internal_Rela *relend;
bfd_vma addend = 0;
bfd_boolean use_saved_addend_p = FALSE;
struct elf_backend_data *bed;
bed = get_elf_backend_data (output_bfd);
relend = relocs + input_section->reloc_count * bed->s->int_rels_per_ext_rel;
for (rel = relocs; rel < relend; ++rel)
{
const char *name;
bfd_vma value;
reloc_howto_type *howto;
bfd_boolean require_jalx;
/* TRUE if the relocation is a RELA relocation, rather than a
REL relocation. */
bfd_boolean rela_relocation_p = TRUE;
unsigned int r_type = ELF_R_TYPE (output_bfd, rel->r_info);
const char * msg = (const char *) NULL;
/* Find the relocation howto for this relocation. */
if (r_type == R_MIPS_64 && ! NEWABI_P (input_bfd))
{
/* Some 32-bit code uses R_MIPS_64. In particular, people use
64-bit code, but make sure all their addresses are in the
lowermost or uppermost 32-bit section of the 64-bit address
space. Thus, when they use an R_MIPS_64 they mean what is
usually meant by R_MIPS_32, with the exception that the
stored value is sign-extended to 64 bits. */
howto = MIPS_ELF_RTYPE_TO_HOWTO (input_bfd, R_MIPS_32, FALSE);
/* On big-endian systems, we need to lie about the position
of the reloc. */
if (bfd_big_endian (input_bfd))
rel->r_offset += 4;
}
else
/* NewABI defaults to RELA relocations. */
howto = MIPS_ELF_RTYPE_TO_HOWTO (input_bfd, r_type,
NEWABI_P (input_bfd)
&& (MIPS_RELOC_RELA_P
(input_bfd, input_section,
rel - relocs)));
if (!use_saved_addend_p)
{
Elf_Internal_Shdr *rel_hdr;
/* If these relocations were originally of the REL variety,
we must pull the addend out of the field that will be
relocated. Otherwise, we simply use the contents of the
RELA relocation. To determine which flavor or relocation
this is, we depend on the fact that the INPUT_SECTION's
REL_HDR is read before its REL_HDR2. */
rel_hdr = &elf_section_data (input_section)->rel_hdr;
if ((size_t) (rel - relocs)
>= (NUM_SHDR_ENTRIES (rel_hdr) * bed->s->int_rels_per_ext_rel))
rel_hdr = elf_section_data (input_section)->rel_hdr2;
if (rel_hdr->sh_entsize == MIPS_ELF_REL_SIZE (input_bfd))
{
/* Note that this is a REL relocation. */
rela_relocation_p = FALSE;
/* Get the addend, which is stored in the input file. */
addend = mips_elf_obtain_contents (howto, rel, input_bfd,
contents);
addend &= howto->src_mask;
addend <<= howto->rightshift;
/* For some kinds of relocations, the ADDEND is a
combination of the addend stored in two different
relocations. */
if (r_type == R_MIPS_HI16
|| r_type == R_MIPS_GNU_REL_HI16
|| (r_type == R_MIPS_GOT16
&& mips_elf_local_relocation_p (input_bfd, rel,
local_sections, FALSE)))
{
bfd_vma l;
const Elf_Internal_Rela *lo16_relocation;
reloc_howto_type *lo16_howto;
unsigned int lo;
/* The combined value is the sum of the HI16 addend,
left-shifted by sixteen bits, and the LO16
addend, sign extended. (Usually, the code does
a `lui' of the HI16 value, and then an `addiu' of
the LO16 value.)
Scan ahead to find a matching LO16 relocation. */
if (r_type == R_MIPS_GNU_REL_HI16)
lo = R_MIPS_GNU_REL_LO16;
else
lo = R_MIPS_LO16;
lo16_relocation = mips_elf_next_relocation (input_bfd, lo,
rel, relend);
if (lo16_relocation == NULL)
return FALSE;
/* Obtain the addend kept there. */
lo16_howto = MIPS_ELF_RTYPE_TO_HOWTO (input_bfd, lo, FALSE);
l = mips_elf_obtain_contents (lo16_howto, lo16_relocation,
input_bfd, contents);
l &= lo16_howto->src_mask;
l <<= lo16_howto->rightshift;
l = _bfd_mips_elf_sign_extend (l, 16);
addend <<= 16;
/* Compute the combined addend. */
addend += l;
/* If PC-relative, subtract the difference between the
address of the LO part of the reloc and the address of
the HI part. The relocation is relative to the LO
part, but mips_elf_calculate_relocation() doesn't
know its address or the difference from the HI part, so
we subtract that difference here. See also the
comment in mips_elf_calculate_relocation(). */
if (r_type == R_MIPS_GNU_REL_HI16)
addend -= (lo16_relocation->r_offset - rel->r_offset);
}
else if (r_type == R_MIPS16_GPREL)
{
/* The addend is scrambled in the object file. See
mips_elf_perform_relocation for details on the
format. */
addend = (((addend & 0x1f0000) >> 5)
| ((addend & 0x7e00000) >> 16)
| (addend & 0x1f));
}
}
else
addend = rel->r_addend;
}
if (info->relocatable)
{
Elf_Internal_Sym *sym;
unsigned long r_symndx;
if (r_type == R_MIPS_64 && ! NEWABI_P (output_bfd)
&& bfd_big_endian (input_bfd))
rel->r_offset -= 4;
/* Since we're just relocating, all we need to do is copy
the relocations back out to the object file, unless
they're against a section symbol, in which case we need
to adjust by the section offset, or unless they're GP
relative in which case we need to adjust by the amount
that we're adjusting GP in this relocatable object. */
if (! mips_elf_local_relocation_p (input_bfd, rel, local_sections,
FALSE))
/* There's nothing to do for non-local relocations. */
continue;
if (r_type == R_MIPS16_GPREL
|| r_type == R_MIPS_GPREL16
|| r_type == R_MIPS_GPREL32
|| r_type == R_MIPS_LITERAL)
addend -= (_bfd_get_gp_value (output_bfd)
- _bfd_get_gp_value (input_bfd));
r_symndx = ELF_R_SYM (output_bfd, rel->r_info);
sym = local_syms + r_symndx;
if (ELF_ST_TYPE (sym->st_info) == STT_SECTION)
/* Adjust the addend appropriately. */
addend += local_sections[r_symndx]->output_offset;
if (howto->partial_inplace)
{
/* If the relocation is for a R_MIPS_HI16 or R_MIPS_GOT16,
then we only want to write out the high-order 16 bits.
The subsequent R_MIPS_LO16 will handle the low-order bits.
*/
if (r_type == R_MIPS_HI16 || r_type == R_MIPS_GOT16
|| r_type == R_MIPS_GNU_REL_HI16)
addend = mips_elf_high (addend);
else if (r_type == R_MIPS_HIGHER)
addend = mips_elf_higher (addend);
else if (r_type == R_MIPS_HIGHEST)
addend = mips_elf_highest (addend);
}
if (rela_relocation_p)
/* If this is a RELA relocation, just update the addend.
We have to cast away constness for REL. */
rel->r_addend = addend;
else
{
/* Otherwise, we have to write the value back out. Note
that we use the source mask, rather than the
destination mask because the place to which we are
writing will be source of the addend in the final
link. */
addend >>= howto->rightshift;
addend &= howto->src_mask;
if (r_type == R_MIPS_64 && ! NEWABI_P (output_bfd))
/* See the comment above about using R_MIPS_64 in the 32-bit
ABI. Here, we need to update the addend. It would be
possible to get away with just using the R_MIPS_32 reloc
but for endianness. */
{
bfd_vma sign_bits;
bfd_vma low_bits;
bfd_vma high_bits;
if (addend & ((bfd_vma) 1 << 31))
#ifdef BFD64
sign_bits = ((bfd_vma) 1 << 32) - 1;
#else
sign_bits = -1;
#endif
else
sign_bits = 0;
/* If we don't know that we have a 64-bit type,
do two separate stores. */
if (bfd_big_endian (input_bfd))
{
/* Store the sign-bits (which are most significant)
first. */
low_bits = sign_bits;
high_bits = addend;
}
else
{
low_bits = addend;
high_bits = sign_bits;
}
bfd_put_32 (input_bfd, low_bits,
contents + rel->r_offset);
bfd_put_32 (input_bfd, high_bits,
contents + rel->r_offset + 4);
continue;
}
if (! mips_elf_perform_relocation (info, howto, rel, addend,
input_bfd, input_section,
contents, FALSE))
return FALSE;
}
/* Go on to the next relocation. */
continue;
}
/* In the N32 and 64-bit ABIs there may be multiple consecutive
relocations for the same offset. In that case we are
supposed to treat the output of each relocation as the addend
for the next. */
if (rel + 1 < relend
&& rel->r_offset == rel[1].r_offset
&& ELF_R_TYPE (input_bfd, rel[1].r_info) != R_MIPS_NONE)
use_saved_addend_p = TRUE;
else
use_saved_addend_p = FALSE;
addend >>= howto->rightshift;
/* Figure out what value we are supposed to relocate. */
switch (mips_elf_calculate_relocation (output_bfd, input_bfd,
input_section, info, rel,
addend, howto, local_syms,
local_sections, &value,
&name, &require_jalx,
use_saved_addend_p))
{
case bfd_reloc_continue:
/* There's nothing to do. */
continue;
case bfd_reloc_undefined:
/* mips_elf_calculate_relocation already called the
undefined_symbol callback. There's no real point in
trying to perform the relocation at this point, so we
just skip ahead to the next relocation. */
continue;
case bfd_reloc_notsupported:
msg = _("internal error: unsupported relocation error");
info->callbacks->warning
(info, msg, name, input_bfd, input_section, rel->r_offset);
return FALSE;
case bfd_reloc_overflow:
if (use_saved_addend_p)
/* Ignore overflow until we reach the last relocation for
a given location. */
;
else
{
BFD_ASSERT (name != NULL);
if (! ((*info->callbacks->reloc_overflow)
(info, name, howto->name, (bfd_vma) 0,
input_bfd, input_section, rel->r_offset)))
return FALSE;
}
break;
case bfd_reloc_ok:
break;
default:
abort ();
break;
}
/* If we've got another relocation for the address, keep going
until we reach the last one. */
if (use_saved_addend_p)
{
addend = value;
continue;
}
if (r_type == R_MIPS_64 && ! NEWABI_P (output_bfd))
/* See the comment above about using R_MIPS_64 in the 32-bit
ABI. Until now, we've been using the HOWTO for R_MIPS_32;
that calculated the right value. Now, however, we
sign-extend the 32-bit result to 64-bits, and store it as a
64-bit value. We are especially generous here in that we
go to extreme lengths to support this usage on systems with
only a 32-bit VMA. */
{
bfd_vma sign_bits;
bfd_vma low_bits;
bfd_vma high_bits;
if (value & ((bfd_vma) 1 << 31))
#ifdef BFD64
sign_bits = ((bfd_vma) 1 << 32) - 1;
#else
sign_bits = -1;
#endif
else
sign_bits = 0;
/* If we don't know that we have a 64-bit type,
do two separate stores. */
if (bfd_big_endian (input_bfd))
{
/* Undo what we did above. */
rel->r_offset -= 4;
/* Store the sign-bits (which are most significant)
first. */
low_bits = sign_bits;
high_bits = value;
}
else
{
low_bits = value;
high_bits = sign_bits;
}
bfd_put_32 (input_bfd, low_bits,
contents + rel->r_offset);
bfd_put_32 (input_bfd, high_bits,
contents + rel->r_offset + 4);
continue;
}
/* Actually perform the relocation. */
if (! mips_elf_perform_relocation (info, howto, rel, value,
input_bfd, input_section,
contents, require_jalx))
return FALSE;
}
return TRUE;
}
/* If NAME is one of the special IRIX6 symbols defined by the linker,
adjust it appropriately now. */
static void
mips_elf_irix6_finish_dynamic_symbol (abfd, name, sym)
bfd *abfd ATTRIBUTE_UNUSED;
const char *name;
Elf_Internal_Sym *sym;
{
/* The linker script takes care of providing names and values for
these, but we must place them into the right sections. */
static const char* const text_section_symbols[] = {
"_ftext",
"_etext",
"__dso_displacement",
"__elf_header",
"__program_header_table",
NULL
};
static const char* const data_section_symbols[] = {
"_fdata",
"_edata",
"_end",
"_fbss",
NULL
};
const char* const *p;
int i;
for (i = 0; i < 2; ++i)
for (p = (i == 0) ? text_section_symbols : data_section_symbols;
*p;
++p)
if (strcmp (*p, name) == 0)
{
/* All of these symbols are given type STT_SECTION by the
IRIX6 linker. */
sym->st_info = ELF_ST_INFO (STB_GLOBAL, STT_SECTION);
sym->st_other = STO_PROTECTED;
/* The IRIX linker puts these symbols in special sections. */
if (i == 0)
sym->st_shndx = SHN_MIPS_TEXT;
else
sym->st_shndx = SHN_MIPS_DATA;
break;
}
}
/* Finish up dynamic symbol handling. We set the contents of various
dynamic sections here. */
bfd_boolean
_bfd_mips_elf_finish_dynamic_symbol (output_bfd, info, h, sym)
bfd *output_bfd;
struct bfd_link_info *info;
struct elf_link_hash_entry *h;
Elf_Internal_Sym *sym;
{
bfd *dynobj;
bfd_vma gval;
asection *sgot;
struct mips_got_info *g, *gg;
const char *name;
dynobj = elf_hash_table (info)->dynobj;
gval = sym->st_value;
if (h->plt.offset != (bfd_vma) -1)
{
asection *s;
bfd_byte stub[MIPS_FUNCTION_STUB_SIZE];
/* This symbol has a stub. Set it up. */
BFD_ASSERT (h->dynindx != -1);
s = bfd_get_section_by_name (dynobj,
MIPS_ELF_STUB_SECTION_NAME (dynobj));
BFD_ASSERT (s != NULL);
/* FIXME: Can h->dynindex be more than 64K? */
if (h->dynindx & 0xffff0000)
return FALSE;
/* Fill the stub. */
bfd_put_32 (output_bfd, STUB_LW (output_bfd), stub);
bfd_put_32 (output_bfd, STUB_MOVE (output_bfd), stub + 4);
bfd_put_32 (output_bfd, STUB_JALR, stub + 8);
bfd_put_32 (output_bfd, STUB_LI16 (output_bfd) + h->dynindx, stub + 12);
BFD_ASSERT (h->plt.offset <= s->_raw_size);
memcpy (s->contents + h->plt.offset, stub, MIPS_FUNCTION_STUB_SIZE);
/* Mark the symbol as undefined. plt.offset != -1 occurs
only for the referenced symbol. */
sym->st_shndx = SHN_UNDEF;
/* The run-time linker uses the st_value field of the symbol
to reset the global offset table entry for this external
to its stub address when unlinking a shared object. */
gval = s->output_section->vma + s->output_offset + h->plt.offset;
sym->st_value = gval;
}
BFD_ASSERT (h->dynindx != -1
|| (h->elf_link_hash_flags & ELF_LINK_FORCED_LOCAL) != 0);
sgot = mips_elf_got_section (dynobj, FALSE);
BFD_ASSERT (sgot != NULL);
BFD_ASSERT (mips_elf_section_data (sgot) != NULL);
g = mips_elf_section_data (sgot)->u.got_info;
BFD_ASSERT (g != NULL);
/* Run through the global symbol table, creating GOT entries for all
the symbols that need them. */
if (g->global_gotsym != NULL
&& h->dynindx >= g->global_gotsym->dynindx)
{
bfd_vma offset;
bfd_vma value;
value = sym->st_value;
offset = mips_elf_global_got_index (dynobj, output_bfd, h);
MIPS_ELF_PUT_WORD (output_bfd, value, sgot->contents + offset);
}
if (g->next && h->dynindx != -1)
{
struct mips_got_entry e, *p;
bfd_vma offset;
bfd_vma value;
Elf_Internal_Rela rel[3];
bfd_vma addend = 0;
gg = g;
e.abfd = output_bfd;
e.symndx = -1;
e.d.h = (struct mips_elf_link_hash_entry *)h;
if (info->shared
|| h->root.type == bfd_link_hash_undefined
|| h->root.type == bfd_link_hash_undefweak)
value = 0;
else if (sym->st_value)
value = sym->st_value;
else
value = h->root.u.def.value;
memset (rel, 0, sizeof (rel));
rel[0].r_info = ELF_R_INFO (output_bfd, 0, R_MIPS_REL32);
for (g = g->next; g->next != gg; g = g->next)
{
if (g->got_entries
&& (p = (struct mips_got_entry *) htab_find (g->got_entries,
&e)))
{
offset = p->gotidx;
rel[0].r_offset = rel[1].r_offset = rel[2].r_offset = offset;
MIPS_ELF_PUT_WORD (output_bfd, value, sgot->contents + offset);
if ((info->shared
|| (elf_hash_table (info)->dynamic_sections_created
&& p->d.h != NULL
&& ((p->d.h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_DYNAMIC) != 0)
&& ((p->d.h->root.elf_link_hash_flags
& ELF_LINK_HASH_DEF_REGULAR) == 0)))
&& ! (mips_elf_create_dynamic_relocation
(output_bfd, info, rel,
e.d.h, NULL, value, &addend, sgot)))
return FALSE;
BFD_ASSERT (addend == 0);
}
}
}
/* Mark _DYNAMIC and _GLOBAL_OFFSET_TABLE_ as absolute. */
name = h->root.root.string;
if (strcmp (name, "_DYNAMIC") == 0
|| strcmp (name, "_GLOBAL_OFFSET_TABLE_") == 0)
sym->st_shndx = SHN_ABS;
else if (strcmp (name, "_DYNAMIC_LINK") == 0
|| strcmp (name, "_DYNAMIC_LINKING") == 0)
{
sym->st_shndx = SHN_ABS;
sym->st_info = ELF_ST_INFO (STB_GLOBAL, STT_SECTION);
sym->st_value = 1;
}
else if (strcmp (name, "_gp_disp") == 0 && ! NEWABI_P (output_bfd))
{
sym->st_shndx = SHN_ABS;
sym->st_info = ELF_ST_INFO (STB_GLOBAL, STT_SECTION);
sym->st_value = elf_gp (output_bfd);
}
else if (SGI_COMPAT (output_bfd))
{
if (strcmp (name, mips_elf_dynsym_rtproc_names[0]) == 0
|| strcmp (name, mips_elf_dynsym_rtproc_names[1]) == 0)
{
sym->st_info = ELF_ST_INFO (STB_GLOBAL, STT_SECTION);
sym->st_other = STO_PROTECTED;
sym->st_value = 0;
sym->st_shndx = SHN_MIPS_DATA;
}
else if (strcmp (name, mips_elf_dynsym_rtproc_names[2]) == 0)
{
sym->st_info = ELF_ST_INFO (STB_GLOBAL, STT_SECTION);
sym->st_other = STO_PROTECTED;
sym->st_value = mips_elf_hash_table (info)->procedure_count;
sym->st_shndx = SHN_ABS;
}
else if (sym->st_shndx != SHN_UNDEF && sym->st_shndx != SHN_ABS)
{
if (h->type == STT_FUNC)
sym->st_shndx = SHN_MIPS_TEXT;
else if (h->type == STT_OBJECT)
sym->st_shndx = SHN_MIPS_DATA;
}
}
/* Handle the IRIX6-specific symbols. */
if (IRIX_COMPAT (output_bfd) == ict_irix6)
mips_elf_irix6_finish_dynamic_symbol (output_bfd, name, sym);
if (! info->shared)
{
if (! mips_elf_hash_table (info)->use_rld_obj_head
&& (strcmp (name, "__rld_map") == 0
|| strcmp (name, "__RLD_MAP") == 0))
{
asection *s = bfd_get_section_by_name (dynobj, ".rld_map");
BFD_ASSERT (s != NULL);
sym->st_value = s->output_section->vma + s->output_offset;
bfd_put_32 (output_bfd, (bfd_vma) 0, s->contents);
if (mips_elf_hash_table (info)->rld_value == 0)
mips_elf_hash_table (info)->rld_value = sym->st_value;
}
else if (mips_elf_hash_table (info)->use_rld_obj_head
&& strcmp (name, "__rld_obj_head") == 0)
{
/* IRIX6 does not use a .rld_map section. */
if (IRIX_COMPAT (output_bfd) == ict_irix5
|| IRIX_COMPAT (output_bfd) == ict_none)
BFD_ASSERT (bfd_get_section_by_name (dynobj, ".rld_map")
!= NULL);
mips_elf_hash_table (info)->rld_value = sym->st_value;
}
}
/* If this is a mips16 symbol, force the value to be even. */
if (sym->st_other == STO_MIPS16
&& (sym->st_value & 1) != 0)
--sym->st_value;
return TRUE;
}
/* Finish up the dynamic sections. */
bfd_boolean
_bfd_mips_elf_finish_dynamic_sections (output_bfd, info)
bfd *output_bfd;
struct bfd_link_info *info;
{
bfd *dynobj;
asection *sdyn;
asection *sgot;
struct mips_got_info *gg, *g;
dynobj = elf_hash_table (info)->dynobj;
sdyn = bfd_get_section_by_name (dynobj, ".dynamic");
sgot = mips_elf_got_section (dynobj, FALSE);
if (sgot == NULL)
gg = g = NULL;
else
{
BFD_ASSERT (mips_elf_section_data (sgot) != NULL);
gg = mips_elf_section_data (sgot)->u.got_info;
BFD_ASSERT (gg != NULL);
g = mips_elf_got_for_ibfd (gg, output_bfd);
BFD_ASSERT (g != NULL);
}
if (elf_hash_table (info)->dynamic_sections_created)
{
bfd_byte *b;
BFD_ASSERT (sdyn != NULL);
BFD_ASSERT (g != NULL);
for (b = sdyn->contents;
b < sdyn->contents + sdyn->_raw_size;
b += MIPS_ELF_DYN_SIZE (dynobj))
{
Elf_Internal_Dyn dyn;
const char *name;
size_t elemsize;
asection *s;
bfd_boolean swap_out_p;
/* Read in the current dynamic entry. */
(*get_elf_backend_data (dynobj)->s->swap_dyn_in) (dynobj, b, &dyn);
/* Assume that we're going to modify it and write it out. */
swap_out_p = TRUE;
switch (dyn.d_tag)
{
case DT_RELENT:
s = mips_elf_rel_dyn_section (dynobj, FALSE);
BFD_ASSERT (s != NULL);
dyn.d_un.d_val = MIPS_ELF_REL_SIZE (dynobj);
break;
case DT_STRSZ:
/* Rewrite DT_STRSZ. */
dyn.d_un.d_val =
_bfd_elf_strtab_size (elf_hash_table (info)->dynstr);
break;
case DT_PLTGOT:
name = ".got";
goto get_vma;
case DT_MIPS_CONFLICT:
name = ".conflict";
goto get_vma;
case DT_MIPS_LIBLIST:
name = ".liblist";
get_vma:
s = bfd_get_section_by_name (output_bfd, name);
BFD_ASSERT (s != NULL);
dyn.d_un.d_ptr = s->vma;
break;
case DT_MIPS_RLD_VERSION:
dyn.d_un.d_val = 1; /* XXX */
break;
case DT_MIPS_FLAGS:
dyn.d_un.d_val = RHF_NOTPOT; /* XXX */
break;
case DT_MIPS_CONFLICTNO:
name = ".conflict";
elemsize = sizeof (Elf32_Conflict);
goto set_elemno;
case DT_MIPS_LIBLISTNO:
name = ".liblist";
elemsize = sizeof (Elf32_Lib);
set_elemno:
s = bfd_get_section_by_name (output_bfd, name);
if (s != NULL)
{
if (s->_cooked_size != 0)
dyn.d_un.d_val = s->_cooked_size / elemsize;
else
dyn.d_un.d_val = s->_raw_size / elemsize;
}
else
dyn.d_un.d_val = 0;
break;
case DT_MIPS_TIME_STAMP:
time ((time_t *) &dyn.d_un.d_val);
break;
case DT_MIPS_ICHECKSUM:
/* XXX FIXME: */
swap_out_p = FALSE;
break;
case DT_MIPS_IVERSION:
/* XXX FIXME: */
swap_out_p = FALSE;
break;
case DT_MIPS_BASE_ADDRESS:
s = output_bfd->sections;
BFD_ASSERT (s != NULL);
dyn.d_un.d_ptr = s->vma & ~(bfd_vma) 0xffff;
break;
case DT_MIPS_LOCAL_GOTNO:
dyn.d_un.d_val = g->local_gotno;
break;
case DT_MIPS_UNREFEXTNO:
/* The index into the dynamic symbol table which is the
entry of the first external symbol that is not
referenced within the same object. */
dyn.d_un.d_val = bfd_count_sections (output_bfd) + 1;
break;
case DT_MIPS_GOTSYM:
if (gg->global_gotsym)
{
dyn.d_un.d_val = gg->global_gotsym->dynindx;
break;
}
/* In case if we don't have global got symbols we default
to setting DT_MIPS_GOTSYM to the same value as
DT_MIPS_SYMTABNO, so we just fall through. */
case DT_MIPS_SYMTABNO:
name = ".dynsym";
elemsize = MIPS_ELF_SYM_SIZE (output_bfd);
s = bfd_get_section_by_name (output_bfd, name);
BFD_ASSERT (s != NULL);
if (s->_cooked_size != 0)
dyn.d_un.d_val = s->_cooked_size / elemsize;
else
dyn.d_un.d_val = s->_raw_size / elemsize;
break;
case DT_MIPS_HIPAGENO:
dyn.d_un.d_val = g->local_gotno - MIPS_RESERVED_GOTNO;
break;
case DT_MIPS_RLD_MAP:
dyn.d_un.d_ptr = mips_elf_hash_table (info)->rld_value;
break;
case DT_MIPS_OPTIONS:
s = (bfd_get_section_by_name
(output_bfd, MIPS_ELF_OPTIONS_SECTION_NAME (output_bfd)));
dyn.d_un.d_ptr = s->vma;
break;
case DT_MIPS_MSYM:
s = (bfd_get_section_by_name (output_bfd, ".msym"));
dyn.d_un.d_ptr = s->vma;
break;
default:
swap_out_p = FALSE;
break;
}
if (swap_out_p)
(*get_elf_backend_data (dynobj)->s->swap_dyn_out)
(dynobj, &dyn, b);
}
}
/* The first entry of the global offset table will be filled at
runtime. The second entry will be used by some runtime loaders.
This isn't the case of IRIX rld. */
if (sgot != NULL && sgot->_raw_size > 0)
{
MIPS_ELF_PUT_WORD (output_bfd, (bfd_vma) 0, sgot->contents);
MIPS_ELF_PUT_WORD (output_bfd, (bfd_vma) 0x80000000,
sgot->contents + MIPS_ELF_GOT_SIZE (output_bfd));
}
if (sgot != NULL)
elf_section_data (sgot->output_section)->this_hdr.sh_entsize
= MIPS_ELF_GOT_SIZE (output_bfd);
/* Generate dynamic relocations for the non-primary gots. */
if (gg != NULL && gg->next)
{
Elf_Internal_Rela rel[3];
bfd_vma addend = 0;
memset (rel, 0, sizeof (rel));
rel[0].r_info = ELF_R_INFO (output_bfd, 0, R_MIPS_REL32);
for (g = gg->next; g->next != gg; g = g->next)
{
bfd_vma index = g->next->local_gotno + g->next->global_gotno;
MIPS_ELF_PUT_WORD (output_bfd, (bfd_vma) 0, sgot->contents
+ index++ * MIPS_ELF_GOT_SIZE (output_bfd));
MIPS_ELF_PUT_WORD (output_bfd, (bfd_vma) 0x80000000, sgot->contents
+ index++ * MIPS_ELF_GOT_SIZE (output_bfd));
if (! info->shared)
continue;
while (index < g->assigned_gotno)
{
rel[0].r_offset = rel[1].r_offset = rel[2].r_offset
= index++ * MIPS_ELF_GOT_SIZE (output_bfd);
if (!(mips_elf_create_dynamic_relocation
(output_bfd, info, rel, NULL,
bfd_abs_section_ptr,
0, &addend, sgot)))
return FALSE;
BFD_ASSERT (addend == 0);
}
}
}
{
asection *s;
Elf32_compact_rel cpt;
if (SGI_COMPAT (output_bfd))
{
/* Write .compact_rel section out. */
s = bfd_get_section_by_name (dynobj, ".compact_rel");
if (s != NULL)
{
cpt.id1 = 1;
cpt.num = s->reloc_count;
cpt.id2 = 2;
cpt.offset = (s->output_section->filepos
+ sizeof (Elf32_External_compact_rel));
cpt.reserved0 = 0;
cpt.reserved1 = 0;
bfd_elf32_swap_compact_rel_out (output_bfd, &cpt,
((Elf32_External_compact_rel *)
s->contents));
/* Clean up a dummy stub function entry in .text. */
s = bfd_get_section_by_name (dynobj,
MIPS_ELF_STUB_SECTION_NAME (dynobj));
if (s != NULL)
{
file_ptr dummy_offset;
BFD_ASSERT (s->_raw_size >= MIPS_FUNCTION_STUB_SIZE);
dummy_offset = s->_raw_size - MIPS_FUNCTION_STUB_SIZE;
memset (s->contents + dummy_offset, 0,
MIPS_FUNCTION_STUB_SIZE);
}
}
}
/* We need to sort the entries of the dynamic relocation section. */
s = mips_elf_rel_dyn_section (dynobj, FALSE);
if (s != NULL
&& s->_raw_size > (bfd_vma)2 * MIPS_ELF_REL_SIZE (output_bfd))
{
reldyn_sorting_bfd = output_bfd;
if (ABI_64_P (output_bfd))
qsort ((Elf64_External_Rel *) s->contents + 1,
(size_t) s->reloc_count - 1,
sizeof (Elf64_Mips_External_Rel), sort_dynamic_relocs_64);
else
qsort ((Elf32_External_Rel *) s->contents + 1,
(size_t) s->reloc_count - 1,
sizeof (Elf32_External_Rel), sort_dynamic_relocs);
}
}
return TRUE;
}
/* Set ABFD's EF_MIPS_ARCH and EF_MIPS_MACH flags. */
static void
mips_set_isa_flags (abfd)
bfd *abfd;
{
flagword val;
switch (bfd_get_mach (abfd))
{
default:
case bfd_mach_mips3000:
val = E_MIPS_ARCH_1;
break;
case bfd_mach_mips3900:
val = E_MIPS_ARCH_1 | E_MIPS_MACH_3900;
break;
case bfd_mach_mips6000:
val = E_MIPS_ARCH_2;
break;
case bfd_mach_mips4000:
case bfd_mach_mips4300:
case bfd_mach_mips4400:
case bfd_mach_mips4600:
val = E_MIPS_ARCH_3;
break;
case bfd_mach_mips4010:
val = E_MIPS_ARCH_3 | E_MIPS_MACH_4010;
break;
case bfd_mach_mips4100:
val = E_MIPS_ARCH_3 | E_MIPS_MACH_4100;
break;
case bfd_mach_mips4111:
val = E_MIPS_ARCH_3 | E_MIPS_MACH_4111;
break;
case bfd_mach_mips4120:
val = E_MIPS_ARCH_3 | E_MIPS_MACH_4120;
break;
case bfd_mach_mips4650:
val = E_MIPS_ARCH_3 | E_MIPS_MACH_4650;
break;
case bfd_mach_mips5400:
val = E_MIPS_ARCH_4 | E_MIPS_MACH_5400;
break;
case bfd_mach_mips5500:
val = E_MIPS_ARCH_4 | E_MIPS_MACH_5500;
break;
case bfd_mach_mips5000:
case bfd_mach_mips8000:
case bfd_mach_mips10000:
case bfd_mach_mips12000:
val = E_MIPS_ARCH_4;
break;
case bfd_mach_mips5:
val = E_MIPS_ARCH_5;
break;
case bfd_mach_mips_sb1:
val = E_MIPS_ARCH_64 | E_MIPS_MACH_SB1;
break;
case bfd_mach_mipsisa32:
val = E_MIPS_ARCH_32;
break;
case bfd_mach_mipsisa64:
val = E_MIPS_ARCH_64;
break;
case bfd_mach_mipsisa32r2:
val = E_MIPS_ARCH_32R2;
break;
}
elf_elfheader (abfd)->e_flags &= ~(EF_MIPS_ARCH | EF_MIPS_MACH);
elf_elfheader (abfd)->e_flags |= val;
}
/* The final processing done just before writing out a MIPS ELF object
file. This gets the MIPS architecture right based on the machine
number. This is used by both the 32-bit and the 64-bit ABI. */
void
_bfd_mips_elf_final_write_processing (abfd, linker)
bfd *abfd;
bfd_boolean linker ATTRIBUTE_UNUSED;
{
unsigned int i;
Elf_Internal_Shdr **hdrpp;
const char *name;
asection *sec;
/* Keep the existing EF_MIPS_MACH and EF_MIPS_ARCH flags if the former
is nonzero. This is for compatibility with old objects, which used
a combination of a 32-bit EF_MIPS_ARCH and a 64-bit EF_MIPS_MACH. */
if ((elf_elfheader (abfd)->e_flags & EF_MIPS_MACH) == 0)
mips_set_isa_flags (abfd);
/* Set the sh_info field for .gptab sections and other appropriate
info for each special section. */
for (i = 1, hdrpp = elf_elfsections (abfd) + 1;
i < elf_numsections (abfd);
i++, hdrpp++)
{
switch ((*hdrpp)->sh_type)
{
case SHT_MIPS_MSYM:
case SHT_MIPS_LIBLIST:
sec = bfd_get_section_by_name (abfd, ".dynstr");
if (sec != NULL)
(*hdrpp)->sh_link = elf_section_data (sec)->this_idx;
break;
case SHT_MIPS_GPTAB:
BFD_ASSERT ((*hdrpp)->bfd_section != NULL);
name = bfd_get_section_name (abfd, (*hdrpp)->bfd_section);
BFD_ASSERT (name != NULL
&& strncmp (name, ".gptab.", sizeof ".gptab." - 1) == 0);
sec = bfd_get_section_by_name (abfd, name + sizeof ".gptab" - 1);
BFD_ASSERT (sec != NULL);
(*hdrpp)->sh_info = elf_section_data (sec)->this_idx;
break;
case SHT_MIPS_CONTENT:
BFD_ASSERT ((*hdrpp)->bfd_section != NULL);
name = bfd_get_section_name (abfd, (*hdrpp)->bfd_section);
BFD_ASSERT (name != NULL
&& strncmp (name, ".MIPS.content",
sizeof ".MIPS.content" - 1) == 0);
sec = bfd_get_section_by_name (abfd,
name + sizeof ".MIPS.content" - 1);
BFD_ASSERT (sec != NULL);
(*hdrpp)->sh_link = elf_section_data (sec)->this_idx;
break;
case SHT_MIPS_SYMBOL_LIB:
sec = bfd_get_section_by_name (abfd, ".dynsym");
if (sec != NULL)
(*hdrpp)->sh_link = elf_section_data (sec)->this_idx;
sec = bfd_get_section_by_name (abfd, ".liblist");
if (sec != NULL)
(*hdrpp)->sh_info = elf_section_data (sec)->this_idx;
break;
case SHT_MIPS_EVENTS:
BFD_ASSERT ((*hdrpp)->bfd_section != NULL);
name = bfd_get_section_name (abfd, (*hdrpp)->bfd_section);
BFD_ASSERT (name != NULL);
if (strncmp (name, ".MIPS.events", sizeof ".MIPS.events" - 1) == 0)
sec = bfd_get_section_by_name (abfd,
name + sizeof ".MIPS.events" - 1);
else
{
BFD_ASSERT (strncmp (name, ".MIPS.post_rel",
sizeof ".MIPS.post_rel" - 1) == 0);
sec = bfd_get_section_by_name (abfd,
(name
+ sizeof ".MIPS.post_rel" - 1));
}
BFD_ASSERT (sec != NULL);
(*hdrpp)->sh_link = elf_section_data (sec)->this_idx;
break;
}
}
}
/* When creating an IRIX5 executable, we need REGINFO and RTPROC
segments. */
int
_bfd_mips_elf_additional_program_headers (abfd)
bfd *abfd;
{
asection *s;
int ret = 0;
/* See if we need a PT_MIPS_REGINFO segment. */
s = bfd_get_section_by_name (abfd, ".reginfo");
if (s && (s->flags & SEC_LOAD))
++ret;
/* See if we need a PT_MIPS_OPTIONS segment. */
if (IRIX_COMPAT (abfd) == ict_irix6
&& bfd_get_section_by_name (abfd,
MIPS_ELF_OPTIONS_SECTION_NAME (abfd)))
++ret;
/* See if we need a PT_MIPS_RTPROC segment. */
if (IRIX_COMPAT (abfd) == ict_irix5
&& bfd_get_section_by_name (abfd, ".dynamic")
&& bfd_get_section_by_name (abfd, ".mdebug"))
++ret;
return ret;
}
/* Modify the segment map for an IRIX5 executable. */
bfd_boolean
_bfd_mips_elf_modify_segment_map (abfd)
bfd *abfd;
{
asection *s;
struct elf_segment_map *m, **pm;
bfd_size_type amt;
/* If there is a .reginfo section, we need a PT_MIPS_REGINFO
segment. */
s = bfd_get_section_by_name (abfd, ".reginfo");
if (s != NULL && (s->flags & SEC_LOAD) != 0)
{
for (m = elf_tdata (abfd)->segment_map; m != NULL; m = m->next)
if (m->p_type == PT_MIPS_REGINFO)
break;
if (m == NULL)
{
amt = sizeof *m;
m = (struct elf_segment_map *) bfd_zalloc (abfd, amt);
if (m == NULL)
return FALSE;
m->p_type = PT_MIPS_REGINFO;
m->count = 1;
m->sections[0] = s;
/* We want to put it after the PHDR and INTERP segments. */
pm = &elf_tdata (abfd)->segment_map;
while (*pm != NULL
&& ((*pm)->p_type == PT_PHDR
|| (*pm)->p_type == PT_INTERP))
pm = &(*pm)->next;
m->next = *pm;
*pm = m;
}
}
/* For IRIX 6, we don't have .mdebug sections, nor does anything but
.dynamic end up in PT_DYNAMIC. However, we do have to insert a
PT_OPTIONS segment immediately following the program header
table. */
if (NEWABI_P (abfd)
/* On non-IRIX6 new abi, we'll have already created a segment
for this section, so don't create another. I'm not sure this
is not also the case for IRIX 6, but I can't test it right
now. */
&& IRIX_COMPAT (abfd) == ict_irix6)
{
for (s = abfd->sections; s; s = s->next)
if (elf_section_data (s)->this_hdr.sh_type == SHT_MIPS_OPTIONS)
break;
if (s)
{
struct elf_segment_map *options_segment;
/* Usually, there's a program header table. But, sometimes
there's not (like when running the `ld' testsuite). So,
if there's no program header table, we just put the
options segment at the end. */
for (pm = &elf_tdata (abfd)->segment_map;
*pm != NULL;
pm = &(*pm)->next)
if ((*pm)->p_type == PT_PHDR)
break;
amt = sizeof (struct elf_segment_map);
options_segment = bfd_zalloc (abfd, amt);
options_segment->next = *pm;
options_segment->p_type = PT_MIPS_OPTIONS;
options_segment->p_flags = PF_R;
options_segment->p_flags_valid = TRUE;
options_segment->count = 1;
options_segment->sections[0] = s;
*pm = options_segment;
}
}
else
{
if (IRIX_COMPAT (abfd) == ict_irix5)
{
/* If there are .dynamic and .mdebug sections, we make a room
for the RTPROC header. FIXME: Rewrite without section names. */
if (bfd_get_section_by_name (abfd, ".interp") == NULL
&& bfd_get_section_by_name (abfd, ".dynamic") != NULL
&& bfd_get_section_by_name (abfd, ".mdebug") != NULL)
{
for (m = elf_tdata (abfd)->segment_map; m != NULL; m = m->next)
if (m->p_type == PT_MIPS_RTPROC)
break;
if (m == NULL)
{
amt = sizeof *m;
m = (struct elf_segment_map *) bfd_zalloc (abfd, amt);
if (m == NULL)
return FALSE;
m->p_type = PT_MIPS_RTPROC;
s = bfd_get_section_by_name (abfd, ".rtproc");
if (s == NULL)
{
m->count = 0;
m->p_flags = 0;
m->p_flags_valid = 1;
}
else
{
m->count = 1;
m->sections[0] = s;
}
/* We want to put it after the DYNAMIC segment. */
pm = &elf_tdata (abfd)->segment_map;
while (*pm != NULL && (*pm)->p_type != PT_DYNAMIC)
pm = &(*pm)->next;
if (*pm != NULL)
pm = &(*pm)->next;
m->next = *pm;
*pm = m;
}
}
}
/* On IRIX5, the PT_DYNAMIC segment includes the .dynamic,
.dynstr, .dynsym, and .hash sections, and everything in
between. */
for (pm = &elf_tdata (abfd)->segment_map; *pm != NULL;
pm = &(*pm)->next)
if ((*pm)->p_type == PT_DYNAMIC)
break;
m = *pm;
if (m != NULL && IRIX_COMPAT (abfd) == ict_none)
{
/* For a normal mips executable the permissions for the PT_DYNAMIC
segment are read, write and execute. We do that here since
the code in elf.c sets only the read permission. This matters
sometimes for the dynamic linker. */
if (bfd_get_section_by_name (abfd, ".dynamic") != NULL)
{
m->p_flags = PF_R | PF_W | PF_X;
m->p_flags_valid = 1;
}
}
if (m != NULL
&& m->count == 1 && strcmp (m->sections[0]->name, ".dynamic") == 0)
{
static const char *sec_names[] =
{
".dynamic", ".dynstr", ".dynsym", ".hash"
};
bfd_vma low, high;
unsigned int i, c;
struct elf_segment_map *n;
low = 0xffffffff;
high = 0;
for (i = 0; i < sizeof sec_names / sizeof sec_names[0]; i++)
{
s = bfd_get_section_by_name (abfd, sec_names[i]);
if (s != NULL && (s->flags & SEC_LOAD) != 0)
{
bfd_size_type sz;
if (low > s->vma)
low = s->vma;
sz = s->_cooked_size;
if (sz == 0)
sz = s->_raw_size;
if (high < s->vma + sz)
high = s->vma + sz;
}
}
c = 0;
for (s = abfd->sections; s != NULL; s = s->next)
if ((s->flags & SEC_LOAD) != 0
&& s->vma >= low
&& ((s->vma
+ (s->_cooked_size !=
0 ? s->_cooked_size : s->_raw_size)) <= high))
++c;
amt = sizeof *n + (bfd_size_type) (c - 1) * sizeof (asection *);
n = (struct elf_segment_map *) bfd_zalloc (abfd, amt);
if (n == NULL)
return FALSE;
*n = *m;
n->count = c;
i = 0;
for (s = abfd->sections; s != NULL; s = s->next)
{
if ((s->flags & SEC_LOAD) != 0
&& s->vma >= low
&& ((s->vma
+ (s->_cooked_size != 0 ?
s->_cooked_size : s->_raw_size)) <= high))
{
n->sections[i] = s;
++i;
}
}
*pm = n;
}
}
return TRUE;
}
/* Return the section that should be marked against GC for a given
relocation. */
asection *
_bfd_mips_elf_gc_mark_hook (sec, info, rel, h, sym)
asection *sec;
struct bfd_link_info *info ATTRIBUTE_UNUSED;
Elf_Internal_Rela *rel;
struct elf_link_hash_entry *h;
Elf_Internal_Sym *sym;
{
/* ??? Do mips16 stub sections need to be handled special? */
if (h != NULL)
{
switch (ELF_R_TYPE (sec->owner, rel->r_info))
{
case R_MIPS_GNU_VTINHERIT:
case R_MIPS_GNU_VTENTRY:
break;
default:
switch (h->root.type)
{
case bfd_link_hash_defined:
case bfd_link_hash_defweak:
return h->root.u.def.section;
case bfd_link_hash_common:
return h->root.u.c.p->section;
default:
break;
}
}
}
else
return bfd_section_from_elf_index (sec->owner, sym->st_shndx);
return NULL;
}
/* Update the got entry reference counts for the section being removed. */
bfd_boolean
_bfd_mips_elf_gc_sweep_hook (abfd, info, sec, relocs)
bfd *abfd ATTRIBUTE_UNUSED;
struct bfd_link_info *info ATTRIBUTE_UNUSED;
asection *sec ATTRIBUTE_UNUSED;
const Elf_Internal_Rela *relocs ATTRIBUTE_UNUSED;
{
#if 0
Elf_Internal_Shdr *symtab_hdr;
struct elf_link_hash_entry **sym_hashes;
bfd_signed_vma *local_got_refcounts;
const Elf_Internal_Rela *rel, *relend;
unsigned long r_symndx;
struct elf_link_hash_entry *h;
symtab_hdr = &elf_tdata (abfd)->symtab_hdr;
sym_hashes = elf_sym_hashes (abfd);
local_got_refcounts = elf_local_got_refcounts (abfd);
relend = relocs + sec->reloc_count;
for (rel = relocs; rel < relend; rel++)
switch (ELF_R_TYPE (abfd, rel->r_info))
{
case R_MIPS_GOT16:
case R_MIPS_CALL16:
case R_MIPS_CALL_HI16:
case R_MIPS_CALL_LO16:
case R_MIPS_GOT_HI16:
case R_MIPS_GOT_LO16:
case R_MIPS_GOT_DISP:
case R_MIPS_GOT_PAGE:
case R_MIPS_GOT_OFST:
/* ??? It would seem that the existing MIPS code does no sort
of reference counting or whatnot on its GOT and PLT entries,
so it is not possible to garbage collect them at this time. */
break;
default:
break;
}
#endif
return TRUE;
}
/* Copy data from a MIPS ELF indirect symbol to its direct symbol,
hiding the old indirect symbol. Process additional relocation
information. Also called for weakdefs, in which case we just let
_bfd_elf_link_hash_copy_indirect copy the flags for us. */
void
_bfd_mips_elf_copy_indirect_symbol (bed, dir, ind)
struct elf_backend_data *bed;
struct elf_link_hash_entry *dir, *ind;
{
struct mips_elf_link_hash_entry *dirmips, *indmips;
_bfd_elf_link_hash_copy_indirect (bed, dir, ind);
if (ind->root.type != bfd_link_hash_indirect)
return;
dirmips = (struct mips_elf_link_hash_entry *) dir;
indmips = (struct mips_elf_link_hash_entry *) ind;
dirmips->possibly_dynamic_relocs += indmips->possibly_dynamic_relocs;
if (indmips->readonly_reloc)
dirmips->readonly_reloc = TRUE;
if (indmips->no_fn_stub)
dirmips->no_fn_stub = TRUE;
}
void
_bfd_mips_elf_hide_symbol (info, entry, force_local)
struct bfd_link_info *info;
struct elf_link_hash_entry *entry;
bfd_boolean force_local;
{
bfd *dynobj;
asection *got;
struct mips_got_info *g;
struct mips_elf_link_hash_entry *h;
h = (struct mips_elf_link_hash_entry *) entry;
if (h->forced_local)
return;
h->forced_local = force_local;
dynobj = elf_hash_table (info)->dynobj;
if (dynobj != NULL && force_local)
{
got = mips_elf_got_section (dynobj, FALSE);
g = mips_elf_section_data (got)->u.got_info;
if (g->next)
{
struct mips_got_entry e;
struct mips_got_info *gg = g;
/* Since we're turning what used to be a global symbol into a
local one, bump up the number of local entries of each GOT
that had an entry for it. This will automatically decrease
the number of global entries, since global_gotno is actually
the upper limit of global entries. */
e.abfd = dynobj;
e.symndx = -1;
e.d.h = h;
for (g = g->next; g != gg; g = g->next)
if (htab_find (g->got_entries, &e))
{
BFD_ASSERT (g->global_gotno > 0);
g->local_gotno++;
g->global_gotno--;
}
/* If this was a global symbol forced into the primary GOT, we
no longer need an entry for it. We can't release the entry
at this point, but we must at least stop counting it as one
of the symbols that required a forced got entry. */
if (h->root.got.offset == 2)
{
BFD_ASSERT (gg->assigned_gotno > 0);
gg->assigned_gotno--;
}
}
else if (g->global_gotno == 0 && g->global_gotsym == NULL)
/* If we haven't got through GOT allocation yet, just bump up the
number of local entries, as this symbol won't be counted as
global. */
g->local_gotno++;
else if (h->root.got.offset == 1)
{
/* If we're past non-multi-GOT allocation and this symbol had
been marked for a global got entry, give it a local entry
instead. */
BFD_ASSERT (g->global_gotno > 0);
g->local_gotno++;
g->global_gotno--;
}
}
_bfd_elf_link_hash_hide_symbol (info, &h->root, force_local);
}
#define PDR_SIZE 32
bfd_boolean
_bfd_mips_elf_discard_info (abfd, cookie, info)
bfd *abfd;
struct elf_reloc_cookie *cookie;
struct bfd_link_info *info;
{
asection *o;
bfd_boolean ret = FALSE;
unsigned char *tdata;
size_t i, skip;
o = bfd_get_section_by_name (abfd, ".pdr");
if (! o)
return FALSE;
if (o->_raw_size == 0)
return FALSE;
if (o->_raw_size % PDR_SIZE != 0)
return FALSE;
if (o->output_section != NULL
&& bfd_is_abs_section (o->output_section))
return FALSE;
tdata = bfd_zmalloc (o->_raw_size / PDR_SIZE);
if (! tdata)
return FALSE;
cookie->rels = _bfd_elf_link_read_relocs (abfd, o, (PTR) NULL,
(Elf_Internal_Rela *) NULL,
info->keep_memory);
if (!cookie->rels)
{
free (tdata);
return FALSE;
}
cookie->rel = cookie->rels;
cookie->relend = cookie->rels + o->reloc_count;
for (i = 0, skip = 0; i < o->_raw_size / PDR_SIZE; i ++)
{
if (MNAME(abfd,_bfd_elf,reloc_symbol_deleted_p) (i * PDR_SIZE, cookie))
{
tdata[i] = 1;
skip ++;
}
}
if (skip != 0)
{
mips_elf_section_data (o)->u.tdata = tdata;
o->_cooked_size = o->_raw_size - skip * PDR_SIZE;
ret = TRUE;
}
else
free (tdata);
if (! info->keep_memory)
free (cookie->rels);
return ret;
}
bfd_boolean
_bfd_mips_elf_ignore_discarded_relocs (sec)
asection *sec;
{
if (strcmp (sec->name, ".pdr") == 0)
return TRUE;
return FALSE;
}
bfd_boolean
_bfd_mips_elf_write_section (output_bfd, sec, contents)
bfd *output_bfd;
asection *sec;
bfd_byte *contents;
{
bfd_byte *to, *from, *end;
int i;
if (strcmp (sec->name, ".pdr") != 0)
return FALSE;
if (mips_elf_section_data (sec)->u.tdata == NULL)
return FALSE;
to = contents;
end = contents + sec->_raw_size;
for (from = contents, i = 0;
from < end;
from += PDR_SIZE, i++)
{
if ((mips_elf_section_data (sec)->u.tdata)[i] == 1)
continue;
if (to != from)
memcpy (to, from, PDR_SIZE);
to += PDR_SIZE;
}
bfd_set_section_contents (output_bfd, sec->output_section, contents,
(file_ptr) sec->output_offset,
sec->_cooked_size);
return TRUE;
}
/* MIPS ELF uses a special find_nearest_line routine in order the
handle the ECOFF debugging information. */
struct mips_elf_find_line
{
struct ecoff_debug_info d;
struct ecoff_find_line i;
};
bfd_boolean
_bfd_mips_elf_find_nearest_line (abfd, section, symbols, offset, filename_ptr,
functionname_ptr, line_ptr)
bfd *abfd;
asection *section;
asymbol **symbols;
bfd_vma offset;
const char **filename_ptr;
const char **functionname_ptr;
unsigned int *line_ptr;
{
asection *msec;
if (_bfd_dwarf1_find_nearest_line (abfd, section, symbols, offset,
filename_ptr, functionname_ptr,
line_ptr))
return TRUE;
if (_bfd_dwarf2_find_nearest_line (abfd, section, symbols, offset,
filename_ptr, functionname_ptr,
line_ptr,
(unsigned) (ABI_64_P (abfd) ? 8 : 0),
&elf_tdata (abfd)->dwarf2_find_line_info))
return TRUE;
msec = bfd_get_section_by_name (abfd, ".mdebug");
if (msec != NULL)
{
flagword origflags;
struct mips_elf_find_line *fi;
const struct ecoff_debug_swap * const swap =
get_elf_backend_data (abfd)->elf_backend_ecoff_debug_swap;
/* If we are called during a link, mips_elf_final_link may have
cleared the SEC_HAS_CONTENTS field. We force it back on here
if appropriate (which it normally will be). */
origflags = msec->flags;
if (elf_section_data (msec)->this_hdr.sh_type != SHT_NOBITS)
msec->flags |= SEC_HAS_CONTENTS;
fi = elf_tdata (abfd)->find_line_info;
if (fi == NULL)
{
bfd_size_type external_fdr_size;
char *fraw_src;
char *fraw_end;
struct fdr *fdr_ptr;
bfd_size_type amt = sizeof (struct mips_elf_find_line);
fi = (struct mips_elf_find_line *) bfd_zalloc (abfd, amt);
if (fi == NULL)
{
msec->flags = origflags;
return FALSE;
}
if (! _bfd_mips_elf_read_ecoff_info (abfd, msec, &fi->d))
{
msec->flags = origflags;
return FALSE;
}
/* Swap in the FDR information. */
amt = fi->d.symbolic_header.ifdMax * sizeof (struct fdr);
fi->d.fdr = (struct fdr *) bfd_alloc (abfd, amt);
if (fi->d.fdr == NULL)
{
msec->flags = origflags;
return FALSE;
}
external_fdr_size = swap->external_fdr_size;
fdr_ptr = fi->d.fdr;
fraw_src = (char *) fi->d.external_fdr;
fraw_end = (fraw_src
+ fi->d.symbolic_header.ifdMax * external_fdr_size);
for (; fraw_src < fraw_end; fraw_src += external_fdr_size, fdr_ptr++)
(*swap->swap_fdr_in) (abfd, (PTR) fraw_src, fdr_ptr);
elf_tdata (abfd)->find_line_info = fi;
/* Note that we don't bother to ever free this information.
find_nearest_line is either called all the time, as in
objdump -l, so the information should be saved, or it is
rarely called, as in ld error messages, so the memory
wasted is unimportant. Still, it would probably be a
good idea for free_cached_info to throw it away. */
}
if (_bfd_ecoff_locate_line (abfd, section, offset, &fi->d, swap,
&fi->i, filename_ptr, functionname_ptr,
line_ptr))
{
msec->flags = origflags;
return TRUE;
}
msec->flags = origflags;
}
/* Fall back on the generic ELF find_nearest_line routine. */
return _bfd_elf_find_nearest_line (abfd, section, symbols, offset,
filename_ptr, functionname_ptr,
line_ptr);
}
/* When are writing out the .options or .MIPS.options section,
remember the bytes we are writing out, so that we can install the
GP value in the section_processing routine. */
bfd_boolean
_bfd_mips_elf_set_section_contents (abfd, section, location, offset, count)
bfd *abfd;
sec_ptr section;
PTR location;
file_ptr offset;
bfd_size_type count;
{
if (strcmp (section->name, MIPS_ELF_OPTIONS_SECTION_NAME (abfd)) == 0)
{
bfd_byte *c;
if (elf_section_data (section) == NULL)
{
bfd_size_type amt = sizeof (struct bfd_elf_section_data);
section->used_by_bfd = (PTR) bfd_zalloc (abfd, amt);
if (elf_section_data (section) == NULL)
return FALSE;
}
c = mips_elf_section_data (section)->u.tdata;
if (c == NULL)
{
bfd_size_type size;
if (section->_cooked_size != 0)
size = section->_cooked_size;
else
size = section->_raw_size;
c = (bfd_byte *) bfd_zalloc (abfd, size);
if (c == NULL)
return FALSE;
mips_elf_section_data (section)->u.tdata = c;
}
memcpy (c + offset, location, (size_t) count);
}
return _bfd_elf_set_section_contents (abfd, section, location, offset,
count);
}
/* This is almost identical to bfd_generic_get_... except that some
MIPS relocations need to be handled specially. Sigh. */
bfd_byte *
_bfd_elf_mips_get_relocated_section_contents (abfd, link_info, link_order,
data, relocatable, symbols)
bfd *abfd;
struct bfd_link_info *link_info;
struct bfd_link_order *link_order;
bfd_byte *data;
bfd_boolean relocatable;
asymbol **symbols;
{
/* Get enough memory to hold the stuff */
bfd *input_bfd = link_order->u.indirect.section->owner;
asection *input_section = link_order->u.indirect.section;
long reloc_size = bfd_get_reloc_upper_bound (input_bfd, input_section);
arelent **reloc_vector = NULL;
long reloc_count;
if (reloc_size < 0)
goto error_return;
reloc_vector = (arelent **) bfd_malloc ((bfd_size_type) reloc_size);
if (reloc_vector == NULL && reloc_size != 0)
goto error_return;
/* read in the section */
if (!bfd_get_section_contents (input_bfd,
input_section,
(PTR) data,
(file_ptr) 0,
input_section->_raw_size))
goto error_return;
/* We're not relaxing the section, so just copy the size info */
input_section->_cooked_size = input_section->_raw_size;
input_section->reloc_done = TRUE;
reloc_count = bfd_canonicalize_reloc (input_bfd,
input_section,
reloc_vector,
symbols);
if (reloc_count < 0)
goto error_return;
if (reloc_count > 0)
{
arelent **parent;
/* for mips */
int gp_found;
bfd_vma gp = 0x12345678; /* initialize just to shut gcc up */
{
struct bfd_hash_entry *h;
struct bfd_link_hash_entry *lh;
/* Skip all this stuff if we aren't mixing formats. */
if (abfd && input_bfd
&& abfd->xvec == input_bfd->xvec)
lh = 0;
else
{
h = bfd_hash_lookup (&link_info->hash->table, "_gp", FALSE, FALSE);
lh = (struct bfd_link_hash_entry *) h;
}
lookup:
if (lh)
{
switch (lh->type)
{
case bfd_link_hash_undefined:
case bfd_link_hash_undefweak:
case bfd_link_hash_common:
gp_found = 0;
break;
case bfd_link_hash_defined:
case bfd_link_hash_defweak:
gp_found = 1;
gp = lh->u.def.value;
break;
case bfd_link_hash_indirect:
case bfd_link_hash_warning:
lh = lh->u.i.link;
/* @@FIXME ignoring warning for now */
goto lookup;
case bfd_link_hash_new:
default:
abort ();
}
}
else
gp_found = 0;
}
/* end mips */
for (parent = reloc_vector; *parent != (arelent *) NULL;
parent++)
{
char *error_message = (char *) NULL;
bfd_reloc_status_type r;
/* Specific to MIPS: Deal with relocation types that require
knowing the gp of the output bfd. */
asymbol *sym = *(*parent)->sym_ptr_ptr;
if (bfd_is_abs_section (sym->section) && abfd)
{
/* The special_function wouldn't get called anyway. */
}
else if (!gp_found)
{
/* The gp isn't there; let the special function code
fall over on its own. */
}
else if ((*parent)->howto->special_function
== _bfd_mips_elf32_gprel16_reloc)
{
/* bypass special_function call */
r = _bfd_mips_elf_gprel16_with_gp (input_bfd, sym, *parent,
input_section, relocatable,
(PTR) data, gp);
goto skip_bfd_perform_relocation;
}
/* end mips specific stuff */
r = bfd_perform_relocation (input_bfd,
*parent,
(PTR) data,
input_section,
relocatable ? abfd : (bfd *) NULL,
&error_message);
skip_bfd_perform_relocation:
if (relocatable)
{
asection *os = input_section->output_section;
/* A partial link, so keep the relocs */
os->orelocation[os->reloc_count] = *parent;
os->reloc_count++;
}
if (r != bfd_reloc_ok)
{
switch (r)
{
case bfd_reloc_undefined:
if (!((*link_info->callbacks->undefined_symbol)
(link_info, bfd_asymbol_name (*(*parent)->sym_ptr_ptr),
input_bfd, input_section, (*parent)->address,
TRUE)))
goto error_return;
break;
case bfd_reloc_dangerous:
BFD_ASSERT (error_message != (char *) NULL);
if (!((*link_info->callbacks->reloc_dangerous)
(link_info, error_message, input_bfd, input_section,
(*parent)->address)))
goto error_return;
break;
case bfd_reloc_overflow:
if (!((*link_info->callbacks->reloc_overflow)
(link_info, bfd_asymbol_name (*(*parent)->sym_ptr_ptr),
(*parent)->howto->name, (*parent)->addend,
input_bfd, input_section, (*parent)->address)))
goto error_return;
break;
case bfd_reloc_outofrange:
default:
abort ();
break;
}
}
}
}
if (reloc_vector != NULL)
free (reloc_vector);
return data;
error_return:
if (reloc_vector != NULL)
free (reloc_vector);
return NULL;
}
/* Create a MIPS ELF linker hash table. */
struct bfd_link_hash_table *
_bfd_mips_elf_link_hash_table_create (abfd)
bfd *abfd;
{
struct mips_elf_link_hash_table *ret;
bfd_size_type amt = sizeof (struct mips_elf_link_hash_table);
ret = (struct mips_elf_link_hash_table *) bfd_malloc (amt);
if (ret == (struct mips_elf_link_hash_table *) NULL)
return NULL;
if (! _bfd_elf_link_hash_table_init (&ret->root, abfd,
mips_elf_link_hash_newfunc))
{
free (ret);
return NULL;
}
#if 0
/* We no longer use this. */
for (i = 0; i < SIZEOF_MIPS_DYNSYM_SECNAMES; i++)
ret->dynsym_sec_strindex[i] = (bfd_size_type) -1;
#endif
ret->procedure_count = 0;
ret->compact_rel_size = 0;
ret->use_rld_obj_head = FALSE;
ret->rld_value = 0;
ret->mips16_stubs_seen = FALSE;
return &ret->root.root;
}
/* We need to use a special link routine to handle the .reginfo and
the .mdebug sections. We need to merge all instances of these
sections together, not write them all out sequentially. */
bfd_boolean
_bfd_mips_elf_final_link (abfd, info)
bfd *abfd;
struct bfd_link_info *info;
{
asection **secpp;
asection *o;
struct bfd_link_order *p;
asection *reginfo_sec, *mdebug_sec, *gptab_data_sec, *gptab_bss_sec;
asection *rtproc_sec;
Elf32_RegInfo reginfo;
struct ecoff_debug_info debug;
const struct ecoff_debug_swap *swap
= get_elf_backend_data (abfd)->elf_backend_ecoff_debug_swap;
HDRR *symhdr = &debug.symbolic_header;
PTR mdebug_handle = NULL;
asection *s;
EXTR esym;
unsigned int i;
bfd_size_type amt;
static const char * const secname[] =
{
".text", ".init", ".fini", ".data",
".rodata", ".sdata", ".sbss", ".bss"
};
static const int sc[] =
{
scText, scInit, scFini, scData,
scRData, scSData, scSBss, scBss
};
/* We'd carefully arranged the dynamic symbol indices, and then the
generic size_dynamic_sections renumbered them out from under us.
Rather than trying somehow to prevent the renumbering, just do
the sort again. */
if (elf_hash_table (info)->dynamic_sections_created)
{
bfd *dynobj;
asection *got;
struct mips_got_info *g;
/* When we resort, we must tell mips_elf_sort_hash_table what
the lowest index it may use is. That's the number of section
symbols we're going to add. The generic ELF linker only
adds these symbols when building a shared object. Note that
we count the sections after (possibly) removing the .options
section above. */
if (! mips_elf_sort_hash_table (info, (info->shared
? bfd_count_sections (abfd) + 1
: 1)))
return FALSE;
/* Make sure we didn't grow the global .got region. */
dynobj = elf_hash_table (info)->dynobj;
got = mips_elf_got_section (dynobj, FALSE);
g = mips_elf_section_data (got)->u.got_info;
if (g->global_gotsym != NULL)
BFD_ASSERT ((elf_hash_table (info)->dynsymcount
- g->global_gotsym->dynindx)
<= g->global_gotno);
}
#if 0
/* We want to set the GP value for ld -r. */
/* On IRIX5, we omit the .options section. On IRIX6, however, we
include it, even though we don't process it quite right. (Some
entries are supposed to be merged.) Empirically, we seem to be
better off including it then not. */
if (IRIX_COMPAT (abfd) == ict_irix5 || IRIX_COMPAT (abfd) == ict_none)
for (secpp = &abfd->sections; *secpp != NULL; secpp = &(*secpp)->next)
{
if (strcmp ((*secpp)->name, MIPS_ELF_OPTIONS_SECTION_NAME (abfd)) == 0)
{
for (p = (*secpp)->link_order_head; p != NULL; p = p->next)
if (p->type == bfd_indirect_link_order)
p->u.indirect.section->flags &= ~SEC_HAS_CONTENTS;
(*secpp)->link_order_head = NULL;
bfd_section_list_remove (abfd, secpp);
--abfd->section_count;
break;
}
}
/* We include .MIPS.options, even though we don't process it quite right.
(Some entries are supposed to be merged.) At IRIX6 empirically we seem
to be better off including it than not. */
for (secpp = &abfd->sections; *secpp != NULL; secpp = &(*secpp)->next)
{
if (strcmp ((*secpp)->name, ".MIPS.options") == 0)
{
for (p = (*secpp)->link_order_head; p != NULL; p = p->next)
if (p->type == bfd_indirect_link_order)
p->u.indirect.section->flags &=~ SEC_HAS_CONTENTS;
(*secpp)->link_order_head = NULL;
bfd_section_list_remove (abfd, secpp);
--abfd->section_count;
break;
}
}
#endif
/* Get a value for the GP register. */
if (elf_gp (abfd) == 0)
{
struct bfd_link_hash_entry *h;
h = bfd_link_hash_lookup (info->hash, "_gp", FALSE, FALSE, TRUE);
if (h != (struct bfd_link_hash_entry *) NULL
&& h->type == bfd_link_hash_defined)
elf_gp (abfd) = (h->u.def.value
+ h->u.def.section->output_section->vma
+ h->u.def.section->output_offset);
else if (info->relocatable)
{
bfd_vma lo = MINUS_ONE;
/* Find the GP-relative section with the lowest offset. */
for (o = abfd->sections; o != (asection *) NULL; o = o->next)
if (o->vma < lo
&& (elf_section_data (o)->this_hdr.sh_flags & SHF_MIPS_GPREL))
lo = o->vma;
/* And calculate GP relative to that. */
elf_gp (abfd) = lo + ELF_MIPS_GP_OFFSET (abfd);
}
else
{
/* If the relocate_section function needs to do a reloc
involving the GP value, it should make a reloc_dangerous
callback to warn that GP is not defined. */
}
}
/* Go through the sections and collect the .reginfo and .mdebug
information. */
reginfo_sec = NULL;
mdebug_sec = NULL;
gptab_data_sec = NULL;
gptab_bss_sec = NULL;
for (o = abfd->sections; o != (asection *) NULL; o = o->next)
{
if (strcmp (o->name, ".reginfo") == 0)
{
memset (&reginfo, 0, sizeof reginfo);
/* We have found the .reginfo section in the output file.
Look through all the link_orders comprising it and merge
the information together. */
for (p = o->link_order_head;
p != (struct bfd_link_order *) NULL;
p = p->next)
{
asection *input_section;
bfd *input_bfd;
Elf32_External_RegInfo ext;
Elf32_RegInfo sub;
if (p->type != bfd_indirect_link_order)
{
if (p->type == bfd_data_link_order)
continue;
abort ();
}
input_section = p->u.indirect.section;
input_bfd = input_section->owner;
/* The linker emulation code has probably clobbered the
size to be zero bytes. */
if (input_section->_raw_size == 0)
input_section->_raw_size = sizeof (Elf32_External_RegInfo);
if (! bfd_get_section_contents (input_bfd, input_section,
(PTR) &ext,
(file_ptr) 0,
(bfd_size_type) sizeof ext))
return FALSE;
bfd_mips_elf32_swap_reginfo_in (input_bfd, &ext, &sub);
reginfo.ri_gprmask |= sub.ri_gprmask;
reginfo.ri_cprmask[0] |= sub.ri_cprmask[0];
reginfo.ri_cprmask[1] |= sub.ri_cprmask[1];
reginfo.ri_cprmask[2] |= sub.ri_cprmask[2];
reginfo.ri_cprmask[3] |= sub.ri_cprmask[3];
/* ri_gp_value is set by the function
mips_elf32_section_processing when the section is
finally written out. */
/* Hack: reset the SEC_HAS_CONTENTS flag so that
elf_link_input_bfd ignores this section. */
input_section->flags &= ~SEC_HAS_CONTENTS;
}
/* Size has been set in _bfd_mips_elf_always_size_sections. */
BFD_ASSERT(o->_raw_size == sizeof (Elf32_External_RegInfo));
/* Skip this section later on (I don't think this currently
matters, but someday it might). */
o->link_order_head = (struct bfd_link_order *) NULL;
reginfo_sec = o;
}
if (strcmp (o->name, ".mdebug") == 0)
{
struct extsym_info einfo;
bfd_vma last;
/* We have found the .mdebug section in the output file.
Look through all the link_orders comprising it and merge
the information together. */
symhdr->magic = swap->sym_magic;
/* FIXME: What should the version stamp be? */
symhdr->vstamp = 0;
symhdr->ilineMax = 0;
symhdr->cbLine = 0;
symhdr->idnMax = 0;
symhdr->ipdMax = 0;
symhdr->isymMax = 0;
symhdr->ioptMax = 0;
symhdr->iauxMax = 0;
symhdr->issMax = 0;
symhdr->issExtMax = 0;
symhdr->ifdMax = 0;
symhdr->crfd = 0;
symhdr->iextMax = 0;
/* We accumulate the debugging information itself in the
debug_info structure. */
debug.line = NULL;
debug.external_dnr = NULL;
debug.external_pdr = NULL;
debug.external_sym = NULL;
debug.external_opt = NULL;
debug.external_aux = NULL;
debug.ss = NULL;
debug.ssext = debug.ssext_end = NULL;
debug.external_fdr = NULL;
debug.external_rfd = NULL;
debug.external_ext = debug.external_ext_end = NULL;
mdebug_handle = bfd_ecoff_debug_init (abfd, &debug, swap, info);
if (mdebug_handle == (PTR) NULL)
return FALSE;
esym.jmptbl = 0;
esym.cobol_main = 0;
esym.weakext = 0;
esym.reserved = 0;
esym.ifd = ifdNil;
esym.asym.iss = issNil;
esym.asym.st = stLocal;
esym.asym.reserved = 0;
esym.asym.index = indexNil;
last = 0;
for (i = 0; i < sizeof (secname) / sizeof (secname[0]); i++)
{
esym.asym.sc = sc[i];
s = bfd_get_section_by_name (abfd, secname[i]);
if (s != NULL)
{
esym.asym.value = s->vma;
last = s->vma + s->_raw_size;
}
else
esym.asym.value = last;
if (!bfd_ecoff_debug_one_external (abfd, &debug, swap,
secname[i], &esym))
return FALSE;
}
for (p = o->link_order_head;
p != (struct bfd_link_order *) NULL;
p = p->next)
{
asection *input_section;
bfd *input_bfd;
const struct ecoff_debug_swap *input_swap;
struct ecoff_debug_info input_debug;
char *eraw_src;
char *eraw_end;
if (p->type != bfd_indirect_link_order)
{
if (p->type == bfd_data_link_order)
continue;
abort ();
}
input_section = p->u.indirect.section;
input_bfd = input_section->owner;
if (bfd_get_flavour (input_bfd) != bfd_target_elf_flavour
|| (get_elf_backend_data (input_bfd)
->elf_backend_ecoff_debug_swap) == NULL)
{
/* I don't know what a non MIPS ELF bfd would be
doing with a .mdebug section, but I don't really
want to deal with it. */
continue;
}
input_swap = (get_elf_backend_data (input_bfd)
->elf_backend_ecoff_debug_swap);
BFD_ASSERT (p->size == input_section->_raw_size);
/* The ECOFF linking code expects that we have already
read in the debugging information and set up an
ecoff_debug_info structure, so we do that now. */
if (! _bfd_mips_elf_read_ecoff_info (input_bfd, input_section,
&input_debug))
return FALSE;
if (! (bfd_ecoff_debug_accumulate
(mdebug_handle, abfd, &debug, swap, input_bfd,
&input_debug, input_swap, info)))
return FALSE;
/* Loop through the external symbols. For each one with
interesting information, try to find the symbol in
the linker global hash table and save the information
for the output external symbols. */
eraw_src = input_debug.external_ext;
eraw_end = (eraw_src
+ (input_debug.symbolic_header.iextMax
* input_swap->external_ext_size));
for (;
eraw_src < eraw_end;
eraw_src += input_swap->external_ext_size)
{
EXTR ext;
const char *name;
struct mips_elf_link_hash_entry *h;
(*input_swap->swap_ext_in) (input_bfd, (PTR) eraw_src, &ext);
if (ext.asym.sc == scNil
|| ext.asym.sc == scUndefined
|| ext.asym.sc == scSUndefined)
continue;
name = input_debug.ssext + ext.asym.iss;
h = mips_elf_link_hash_lookup (mips_elf_hash_table (info),
name, FALSE, FALSE, TRUE);
if (h == NULL || h->esym.ifd != -2)
continue;
if (ext.ifd != -1)
{
BFD_ASSERT (ext.ifd
< input_debug.symbolic_header.ifdMax);
ext.ifd = input_debug.ifdmap[ext.ifd];
}
h->esym = ext;
}
/* Free up the information we just read. */
free (input_debug.line);
free (input_debug.external_dnr);
free (input_debug.external_pdr);
free (input_debug.external_sym);
free (input_debug.external_opt);
free (input_debug.external_aux);
free (input_debug.ss);
free (input_debug.ssext);
free (input_debug.external_fdr);
free (input_debug.external_rfd);
free (input_debug.external_ext);
/* Hack: reset the SEC_HAS_CONTENTS flag so that
elf_link_input_bfd ignores this section. */
input_section->flags &= ~SEC_HAS_CONTENTS;
}
if (SGI_COMPAT (abfd) && info->shared)
{
/* Create .rtproc section. */
rtproc_sec = bfd_get_section_by_name (abfd, ".rtproc");
if (rtproc_sec == NULL)
{
flagword flags = (SEC_HAS_CONTENTS | SEC_IN_MEMORY
| SEC_LINKER_CREATED | SEC_READONLY);
rtproc_sec = bfd_make_section (abfd, ".rtproc");
if (rtproc_sec == NULL
|| ! bfd_set_section_flags (abfd, rtproc_sec, flags)
|| ! bfd_set_section_alignment (abfd, rtproc_sec, 4))
return FALSE;
}
if (! mips_elf_create_procedure_table (mdebug_handle, abfd,
info, rtproc_sec,
&debug))
return FALSE;
}
/* Build the external symbol information. */
einfo.abfd = abfd;
einfo.info = info;
einfo.debug = &debug;
einfo.swap = swap;
einfo.failed = FALSE;
mips_elf_link_hash_traverse (mips_elf_hash_table (info),
mips_elf_output_extsym,
(PTR) &einfo);
if (einfo.failed)
return FALSE;
/* Set the size of the .mdebug section. */
o->_raw_size = bfd_ecoff_debug_size (abfd, &debug, swap);
/* Skip this section later on (I don't think this currently
matters, but someday it might). */
o->link_order_head = (struct bfd_link_order *) NULL;
mdebug_sec = o;
}
if (strncmp (o->name, ".gptab.", sizeof ".gptab." - 1) == 0)
{
const char *subname;
unsigned int c;
Elf32_gptab *tab;
Elf32_External_gptab *ext_tab;
unsigned int j;
/* The .gptab.sdata and .gptab.sbss sections hold
information describing how the small data area would
change depending upon the -G switch. These sections
not used in executables files. */
if (! info->relocatable)
{
for (p = o->link_order_head;
p != (struct bfd_link_order *) NULL;
p = p->next)
{
asection *input_section;
if (p->type != bfd_indirect_link_order)
{
if (p->type == bfd_data_link_order)
continue;
abort ();
}
input_section = p->u.indirect.section;
/* Hack: reset the SEC_HAS_CONTENTS flag so that
elf_link_input_bfd ignores this section. */
input_section->flags &= ~SEC_HAS_CONTENTS;
}
/* Skip this section later on (I don't think this
currently matters, but someday it might). */
o->link_order_head = (struct bfd_link_order *) NULL;
/* Really remove the section. */
for (secpp = &abfd->sections;
*secpp != o;
secpp = &(*secpp)->next)
;
bfd_section_list_remove (abfd, secpp);
--abfd->section_count;
continue;
}
/* There is one gptab for initialized data, and one for
uninitialized data. */
if (strcmp (o->name, ".gptab.sdata") == 0)
gptab_data_sec = o;
else if (strcmp (o->name, ".gptab.sbss") == 0)
gptab_bss_sec = o;
else
{
(*_bfd_error_handler)
(_("%s: illegal section name `%s'"),
bfd_get_filename (abfd), o->name);
bfd_set_error (bfd_error_nonrepresentable_section);
return FALSE;
}
/* The linker script always combines .gptab.data and
.gptab.sdata into .gptab.sdata, and likewise for
.gptab.bss and .gptab.sbss. It is possible that there is
no .sdata or .sbss section in the output file, in which
case we must change the name of the output section. */
subname = o->name + sizeof ".gptab" - 1;
if (bfd_get_section_by_name (abfd, subname) == NULL)
{
if (o == gptab_data_sec)
o->name = ".gptab.data";
else
o->name = ".gptab.bss";
subname = o->name + sizeof ".gptab" - 1;
BFD_ASSERT (bfd_get_section_by_name (abfd, subname) != NULL);
}
/* Set up the first entry. */
c = 1;
amt = c * sizeof (Elf32_gptab);
tab = (Elf32_gptab *) bfd_malloc (amt);
if (tab == NULL)
return FALSE;
tab[0].gt_header.gt_current_g_value = elf_gp_size (abfd);
tab[0].gt_header.gt_unused = 0;
/* Combine the input sections. */
for (p = o->link_order_head;
p != (struct bfd_link_order *) NULL;
p = p->next)
{
asection *input_section;
bfd *input_bfd;
bfd_size_type size;
unsigned long last;
bfd_size_type gpentry;
if (p->type != bfd_indirect_link_order)
{
if (p->type == bfd_data_link_order)
continue;
abort ();
}
input_section = p->u.indirect.section;
input_bfd = input_section->owner;
/* Combine the gptab entries for this input section one
by one. We know that the input gptab entries are
sorted by ascending -G value. */
size = bfd_section_size (input_bfd, input_section);
last = 0;
for (gpentry = sizeof (Elf32_External_gptab);
gpentry < size;
gpentry += sizeof (Elf32_External_gptab))
{
Elf32_External_gptab ext_gptab;
Elf32_gptab int_gptab;
unsigned long val;
unsigned long add;
bfd_boolean exact;
unsigned int look;
if (! (bfd_get_section_contents
(input_bfd, input_section, (PTR) &ext_gptab,
(file_ptr) gpentry,
(bfd_size_type) sizeof (Elf32_External_gptab))))
{
free (tab);
return FALSE;
}
bfd_mips_elf32_swap_gptab_in (input_bfd, &ext_gptab,
&int_gptab);
val = int_gptab.gt_entry.gt_g_value;
add = int_gptab.gt_entry.gt_bytes - last;
exact = FALSE;
for (look = 1; look < c; look++)
{
if (tab[look].gt_entry.gt_g_value >= val)
tab[look].gt_entry.gt_bytes += add;
if (tab[look].gt_entry.gt_g_value == val)
exact = TRUE;
}
if (! exact)
{
Elf32_gptab *new_tab;
unsigned int max;
/* We need a new table entry. */
amt = (bfd_size_type) (c + 1) * sizeof (Elf32_gptab);
new_tab = (Elf32_gptab *) bfd_realloc ((PTR) tab, amt);
if (new_tab == NULL)
{
free (tab);
return FALSE;
}
tab = new_tab;
tab[c].gt_entry.gt_g_value = val;
tab[c].gt_entry.gt_bytes = add;
/* Merge in the size for the next smallest -G
value, since that will be implied by this new
value. */
max = 0;
for (look = 1; look < c; look++)
{
if (tab[look].gt_entry.gt_g_value < val
&& (max == 0
|| (tab[look].gt_entry.gt_g_value
> tab[max].gt_entry.gt_g_value)))
max = look;
}
if (max != 0)
tab[c].gt_entry.gt_bytes +=
tab[max].gt_entry.gt_bytes;
++c;
}
last = int_gptab.gt_entry.gt_bytes;
}
/* Hack: reset the SEC_HAS_CONTENTS flag so that
elf_link_input_bfd ignores this section. */
input_section->flags &= ~SEC_HAS_CONTENTS;
}
/* The table must be sorted by -G value. */
if (c > 2)
qsort (tab + 1, c - 1, sizeof (tab[0]), gptab_compare);
/* Swap out the table. */
amt = (bfd_size_type) c * sizeof (Elf32_External_gptab);
ext_tab = (Elf32_External_gptab *) bfd_alloc (abfd, amt);
if (ext_tab == NULL)
{
free (tab);
return FALSE;
}
for (j = 0; j < c; j++)
bfd_mips_elf32_swap_gptab_out (abfd, tab + j, ext_tab + j);
free (tab);
o->_raw_size = c * sizeof (Elf32_External_gptab);
o->contents = (bfd_byte *) ext_tab;
/* Skip this section later on (I don't think this currently
matters, but someday it might). */
o->link_order_head = (struct bfd_link_order *) NULL;
}
}
/* Invoke the regular ELF backend linker to do all the work. */
if (!MNAME(abfd,bfd_elf,bfd_final_link) (abfd, info))
return FALSE;
/* Now write out the computed sections. */
if (reginfo_sec != (asection *) NULL)
{
Elf32_External_RegInfo ext;
bfd_mips_elf32_swap_reginfo_out (abfd, &reginfo, &ext);
if (! bfd_set_section_contents (abfd, reginfo_sec, (PTR) &ext,
(file_ptr) 0,
(bfd_size_type) sizeof ext))
return FALSE;
}
if (mdebug_sec != (asection *) NULL)
{
BFD_ASSERT (abfd->output_has_begun);
if (! bfd_ecoff_write_accumulated_debug (mdebug_handle, abfd, &debug,
swap, info,
mdebug_sec->filepos))
return FALSE;
bfd_ecoff_debug_free (mdebug_handle, abfd, &debug, swap, info);
}
if (gptab_data_sec != (asection *) NULL)
{
if (! bfd_set_section_contents (abfd, gptab_data_sec,
gptab_data_sec->contents,
(file_ptr) 0,
gptab_data_sec->_raw_size))
return FALSE;
}
if (gptab_bss_sec != (asection *) NULL)
{
if (! bfd_set_section_contents (abfd, gptab_bss_sec,
gptab_bss_sec->contents,
(file_ptr) 0,
gptab_bss_sec->_raw_size))
return FALSE;
}
if (SGI_COMPAT (abfd))
{
rtproc_sec = bfd_get_section_by_name (abfd, ".rtproc");
if (rtproc_sec != NULL)
{
if (! bfd_set_section_contents (abfd, rtproc_sec,
rtproc_sec->contents,
(file_ptr) 0,
rtproc_sec->_raw_size))
return FALSE;
}
}
return TRUE;
}
/* Structure for saying that BFD machine EXTENSION extends BASE. */
struct mips_mach_extension {
unsigned long extension, base;
};
/* An array describing how BFD machines relate to one another. The entries
are ordered topologically with MIPS I extensions listed last. */
static const struct mips_mach_extension mips_mach_extensions[] = {
/* MIPS64 extensions. */
{ bfd_mach_mips_sb1, bfd_mach_mipsisa64 },
/* MIPS V extensions. */
{ bfd_mach_mipsisa64, bfd_mach_mips5 },
/* R10000 extensions. */
{ bfd_mach_mips12000, bfd_mach_mips10000 },
/* R5000 extensions. Note: the vr5500 ISA is an extension of the core
vr5400 ISA, but doesn't include the multimedia stuff. It seems
better to allow vr5400 and vr5500 code to be merged anyway, since
many libraries will just use the core ISA. Perhaps we could add
some sort of ASE flag if this ever proves a problem. */
{ bfd_mach_mips5500, bfd_mach_mips5400 },
{ bfd_mach_mips5400, bfd_mach_mips5000 },
/* MIPS IV extensions. */
{ bfd_mach_mips5, bfd_mach_mips8000 },
{ bfd_mach_mips10000, bfd_mach_mips8000 },
{ bfd_mach_mips5000, bfd_mach_mips8000 },
/* VR4100 extensions. */
{ bfd_mach_mips4120, bfd_mach_mips4100 },
{ bfd_mach_mips4111, bfd_mach_mips4100 },
/* MIPS III extensions. */
{ bfd_mach_mips8000, bfd_mach_mips4000 },
{ bfd_mach_mips4650, bfd_mach_mips4000 },
{ bfd_mach_mips4600, bfd_mach_mips4000 },
{ bfd_mach_mips4400, bfd_mach_mips4000 },
{ bfd_mach_mips4300, bfd_mach_mips4000 },
{ bfd_mach_mips4100, bfd_mach_mips4000 },
{ bfd_mach_mips4010, bfd_mach_mips4000 },
/* MIPS32 extensions. */
{ bfd_mach_mipsisa32r2, bfd_mach_mipsisa32 },
/* MIPS II extensions. */
{ bfd_mach_mips4000, bfd_mach_mips6000 },
{ bfd_mach_mipsisa32, bfd_mach_mips6000 },
/* MIPS I extensions. */
{ bfd_mach_mips6000, bfd_mach_mips3000 },
{ bfd_mach_mips3900, bfd_mach_mips3000 }
};
/* Return true if bfd machine EXTENSION is an extension of machine BASE. */
static bfd_boolean
mips_mach_extends_p (base, extension)
unsigned long base, extension;
{
size_t i;
for (i = 0; extension != base && i < ARRAY_SIZE (mips_mach_extensions); i++)
if (extension == mips_mach_extensions[i].extension)
extension = mips_mach_extensions[i].base;
return extension == base;
}
/* Return true if the given ELF header flags describe a 32-bit binary. */
static bfd_boolean
mips_32bit_flags_p (flags)
flagword flags;
{
return ((flags & EF_MIPS_32BITMODE) != 0
|| (flags & EF_MIPS_ABI) == E_MIPS_ABI_O32
|| (flags & EF_MIPS_ABI) == E_MIPS_ABI_EABI32
|| (flags & EF_MIPS_ARCH) == E_MIPS_ARCH_1
|| (flags & EF_MIPS_ARCH) == E_MIPS_ARCH_2
|| (flags & EF_MIPS_ARCH) == E_MIPS_ARCH_32
|| (flags & EF_MIPS_ARCH) == E_MIPS_ARCH_32R2);
}
/* Merge backend specific data from an object file to the output
object file when linking. */
bfd_boolean
_bfd_mips_elf_merge_private_bfd_data (ibfd, obfd)
bfd *ibfd;
bfd *obfd;
{
flagword old_flags;
flagword new_flags;
bfd_boolean ok;
bfd_boolean null_input_bfd = TRUE;
asection *sec;
/* Check if we have the same endianess */
if (! _bfd_generic_verify_endian_match (ibfd, obfd))
{
(*_bfd_error_handler)
(_("%s: endianness incompatible with that of the selected emulation"),
bfd_archive_filename (ibfd));
return FALSE;
}
if (bfd_get_flavour (ibfd) != bfd_target_elf_flavour
|| bfd_get_flavour (obfd) != bfd_target_elf_flavour)
return TRUE;
if (strcmp (bfd_get_target (ibfd), bfd_get_target (obfd)) != 0)
{
(*_bfd_error_handler)
(_("%s: ABI is incompatible with that of the selected emulation"),
bfd_archive_filename (ibfd));
return FALSE;
}
new_flags = elf_elfheader (ibfd)->e_flags;
elf_elfheader (obfd)->e_flags |= new_flags & EF_MIPS_NOREORDER;
old_flags = elf_elfheader (obfd)->e_flags;
if (! elf_flags_init (obfd))
{
elf_flags_init (obfd) = TRUE;
elf_elfheader (obfd)->e_flags = new_flags;
elf_elfheader (obfd)->e_ident[EI_CLASS]
= elf_elfheader (ibfd)->e_ident[EI_CLASS];
if (bfd_get_arch (obfd) == bfd_get_arch (ibfd)
&& bfd_get_arch_info (obfd)->the_default)
{
if (! bfd_set_arch_mach (obfd, bfd_get_arch (ibfd),
bfd_get_mach (ibfd)))
return FALSE;
}
return TRUE;
}
/* Check flag compatibility. */
new_flags &= ~EF_MIPS_NOREORDER;
old_flags &= ~EF_MIPS_NOREORDER;
/* Some IRIX 6 BSD-compatibility objects have this bit set. It
doesn't seem to matter. */
new_flags &= ~EF_MIPS_XGOT;
old_flags &= ~EF_MIPS_XGOT;
if (new_flags == old_flags)
return TRUE;
/* Check to see if the input BFD actually contains any sections.
If not, its flags may not have been initialised either, but it cannot
actually cause any incompatibility. */
for (sec = ibfd->sections; sec != NULL; sec = sec->next)
{
/* Ignore synthetic sections and empty .text, .data and .bss sections
which are automatically generated by gas. */
if (strcmp (sec->name, ".reginfo")
&& strcmp (sec->name, ".mdebug")
&& ((!strcmp (sec->name, ".text")
|| !strcmp (sec->name, ".data")
|| !strcmp (sec->name, ".bss"))
&& sec->_raw_size != 0))
{
null_input_bfd = FALSE;
break;
}
}
if (null_input_bfd)
return TRUE;
ok = TRUE;
if (((new_flags & (EF_MIPS_PIC | EF_MIPS_CPIC)) != 0)
!= ((old_flags & (EF_MIPS_PIC | EF_MIPS_CPIC)) != 0))
{
(*_bfd_error_handler)
(_("%s: warning: linking PIC files with non-PIC files"),
bfd_archive_filename (ibfd));
ok = TRUE;
}
if (new_flags & (EF_MIPS_PIC | EF_MIPS_CPIC))
elf_elfheader (obfd)->e_flags |= EF_MIPS_CPIC;
if (! (new_flags & EF_MIPS_PIC))
elf_elfheader (obfd)->e_flags &= ~EF_MIPS_PIC;
new_flags &= ~ (EF_MIPS_PIC | EF_MIPS_CPIC);
old_flags &= ~ (EF_MIPS_PIC | EF_MIPS_CPIC);
/* Compare the ISAs. */
if (mips_32bit_flags_p (old_flags) != mips_32bit_flags_p (new_flags))
{
(*_bfd_error_handler)
(_("%s: linking 32-bit code with 64-bit code"),
bfd_archive_filename (ibfd));
ok = FALSE;
}
else if (!mips_mach_extends_p (bfd_get_mach (ibfd), bfd_get_mach (obfd)))
{
/* OBFD's ISA isn't the same as, or an extension of, IBFD's. */
if (mips_mach_extends_p (bfd_get_mach (obfd), bfd_get_mach (ibfd)))
{
/* Copy the architecture info from IBFD to OBFD. Also copy
the 32-bit flag (if set) so that we continue to recognise
OBFD as a 32-bit binary. */
bfd_set_arch_info (obfd, bfd_get_arch_info (ibfd));
elf_elfheader (obfd)->e_flags &= ~(EF_MIPS_ARCH | EF_MIPS_MACH);
elf_elfheader (obfd)->e_flags
|= new_flags & (EF_MIPS_ARCH | EF_MIPS_MACH | EF_MIPS_32BITMODE);
/* Copy across the ABI flags if OBFD doesn't use them
and if that was what caused us to treat IBFD as 32-bit. */
if ((old_flags & EF_MIPS_ABI) == 0
&& mips_32bit_flags_p (new_flags)
&& !mips_32bit_flags_p (new_flags & ~EF_MIPS_ABI))
elf_elfheader (obfd)->e_flags |= new_flags & EF_MIPS_ABI;
}
else
{
/* The ISAs aren't compatible. */
(*_bfd_error_handler)
(_("%s: linking %s module with previous %s modules"),
bfd_archive_filename (ibfd),
bfd_printable_name (ibfd),
bfd_printable_name (obfd));
ok = FALSE;
}
}
new_flags &= ~(EF_MIPS_ARCH | EF_MIPS_MACH | EF_MIPS_32BITMODE);
old_flags &= ~(EF_MIPS_ARCH | EF_MIPS_MACH | EF_MIPS_32BITMODE);
/* Compare ABIs. The 64-bit ABI does not use EF_MIPS_ABI. But, it
does set EI_CLASS differently from any 32-bit ABI. */
if ((new_flags & EF_MIPS_ABI) != (old_flags & EF_MIPS_ABI)
|| (elf_elfheader (ibfd)->e_ident[EI_CLASS]
!= elf_elfheader (obfd)->e_ident[EI_CLASS]))
{
/* Only error if both are set (to different values). */
if (((new_flags & EF_MIPS_ABI) && (old_flags & EF_MIPS_ABI))
|| (elf_elfheader (ibfd)->e_ident[EI_CLASS]
!= elf_elfheader (obfd)->e_ident[EI_CLASS]))
{
(*_bfd_error_handler)
(_("%s: ABI mismatch: linking %s module with previous %s modules"),
bfd_archive_filename (ibfd),
elf_mips_abi_name (ibfd),
elf_mips_abi_name (obfd));
ok = FALSE;
}
new_flags &= ~EF_MIPS_ABI;
old_flags &= ~EF_MIPS_ABI;
}
/* For now, allow arbitrary mixing of ASEs (retain the union). */
if ((new_flags & EF_MIPS_ARCH_ASE) != (old_flags & EF_MIPS_ARCH_ASE))
{
elf_elfheader (obfd)->e_flags |= new_flags & EF_MIPS_ARCH_ASE;
new_flags &= ~ EF_MIPS_ARCH_ASE;
old_flags &= ~ EF_MIPS_ARCH_ASE;
}
/* Warn about any other mismatches */
if (new_flags != old_flags)
{
(*_bfd_error_handler)
(_("%s: uses different e_flags (0x%lx) fields than previous modules (0x%lx)"),
bfd_archive_filename (ibfd), (unsigned long) new_flags,
(unsigned long) old_flags);
ok = FALSE;
}
if (! ok)
{
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
return TRUE;
}
/* Function to keep MIPS specific file flags like as EF_MIPS_PIC. */
bfd_boolean
_bfd_mips_elf_set_private_flags (abfd, flags)
bfd *abfd;
flagword flags;
{
BFD_ASSERT (!elf_flags_init (abfd)
|| elf_elfheader (abfd)->e_flags == flags);
elf_elfheader (abfd)->e_flags = flags;
elf_flags_init (abfd) = TRUE;
return TRUE;
}
bfd_boolean
_bfd_mips_elf_print_private_bfd_data (abfd, ptr)
bfd *abfd;
PTR ptr;
{
FILE *file = (FILE *) ptr;
BFD_ASSERT (abfd != NULL && ptr != NULL);
/* Print normal ELF private data. */
_bfd_elf_print_private_bfd_data (abfd, ptr);
/* xgettext:c-format */
fprintf (file, _("private flags = %lx:"), elf_elfheader (abfd)->e_flags);
if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI) == E_MIPS_ABI_O32)
fprintf (file, _(" [abi=O32]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI) == E_MIPS_ABI_O64)
fprintf (file, _(" [abi=O64]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI) == E_MIPS_ABI_EABI32)
fprintf (file, _(" [abi=EABI32]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI) == E_MIPS_ABI_EABI64)
fprintf (file, _(" [abi=EABI64]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ABI))
fprintf (file, _(" [abi unknown]"));
else if (ABI_N32_P (abfd))
fprintf (file, _(" [abi=N32]"));
else if (ABI_64_P (abfd))
fprintf (file, _(" [abi=64]"));
else
fprintf (file, _(" [no abi set]"));
if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_1)
fprintf (file, _(" [mips1]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_2)
fprintf (file, _(" [mips2]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_3)
fprintf (file, _(" [mips3]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_4)
fprintf (file, _(" [mips4]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_5)
fprintf (file, _(" [mips5]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_32)
fprintf (file, _(" [mips32]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_64)
fprintf (file, _(" [mips64]"));
else if ((elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH) == E_MIPS_ARCH_32R2)
fprintf (file, _(" [mips32r2]"));
else
fprintf (file, _(" [unknown ISA]"));
if (elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH_ASE_MDMX)
fprintf (file, _(" [mdmx]"));
if (elf_elfheader (abfd)->e_flags & EF_MIPS_ARCH_ASE_M16)
fprintf (file, _(" [mips16]"));
if (elf_elfheader (abfd)->e_flags & EF_MIPS_32BITMODE)
fprintf (file, _(" [32bitmode]"));
else
fprintf (file, _(" [not 32bitmode]"));
fputc ('\n', file);
return TRUE;
}