darling-gdb/bfd/aoutf1.h

/* Copyright (C) 1990, 1991 Free Software Foundation, Inc.

This file is part of BFD, the Binary File Diddler.

BFD 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 1, or (at your option)
any later version.

BFD 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 BFD; see the file COPYING.  If not, write to
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.  */


#include <ansidecl.h>
#include <sysdep.h>
struct external_exec;
#include <a.out.sun4.h>
#include "bfd.h"
#include "libaout.h"           
#include "libbfd.h"



#include "aout64.h"
#include "stab.gnu.h"
#include "ar.h"


/*
inheritd two core files and various implimentation files. 
The file @code{aoutf1.h} contains the code for BFD's
a.out back end. Control over the generated back end is given by these
three preprocessor names:
@table @code
@item ARCH
This value should be either 32 or 64, depending upon the size of an
int in the target format. It changes the sizes of the structs which
perform the memory/disk mapping of structures.

The 64 bit backend may only be used if the host compiler supports 64
ints (eg with gcc), by defining the name @code{HOST_64_BIT}. With this
name defined, @emph{all} bfd operations are performed with 64bit
arithmetic, not just those to a 64bit target.

@item TARGETNAME
bit long longsIf bfd is being compiled with gcc, (or any other compiler which gives
64 bit long longs), 
@item
It is structured in such a way that @code{#define}ing
the size of the architecture into a  @code{#include}ing
it with different @code{#define}s present will alter the definitions
of various structures in include files and generate correct code for
th

*/

void (*bfd_error_trap)();

static bfd_target *sunos4_callback ();

/*SUPPRESS558*/
/*SUPPRESS529*/

bfd_target *
DEFUN(NAME(sunos,object_p), (abfd),
     bfd *abfd)
{
  unsigned char magicbuf[4];	/* Raw bytes of magic number from file */
  unsigned long magic;		/* Swapped magic number */

  bfd_error = system_call_error;

  if (bfd_read ((PTR)magicbuf, 1 , 4, abfd) !=
      sizeof (magicbuf))
    return 0;
  magic = bfd_h_get_32 (abfd, magicbuf);

  if (N_BADMAG (*((struct internal_exec *) &magic))) return 0;

  return NAME(aout,some_aout_object_p) (abfd, sunos4_callback);
}

  /* Determine the size of a relocation entry, based on the architecture */
static void
DEFUN(choose_reloc_size,(abfd),
bfd *abfd)
  {
    switch (abfd->obj_arch) {
    case bfd_arch_sparc:
    case bfd_arch_a29k:
      obj_reloc_entry_size (abfd) = RELOC_EXT_SIZE;
      break;
    default:
      obj_reloc_entry_size (abfd) = RELOC_STD_SIZE;
      break;
    }
  }

/* Set parameters about this a.out file that are machine-dependent.
   This routine is called from some_aout_object_p just before it returns.  */

static bfd_target *
sunos4_callback (abfd)
     bfd *abfd;
{
  struct internal_exec *execp = exec_hdr (abfd);

  WORK_OUT_FILE_POSITIONS(abfd, execp);  

  /* Determine the architecture and machine type of the object file.  */
  switch (N_MACHTYPE (*exec_hdr (abfd))) {
    
  case M_UNKNOWN:
    abfd->obj_arch = bfd_arch_unknown;
    abfd->obj_machine = 0;
    break;
    
  case M_68010:
    abfd->obj_arch = bfd_arch_m68k;
    abfd->obj_machine = 68010;
    break;
    
  case M_68020:
    abfd->obj_arch = bfd_arch_m68k;
    abfd->obj_machine = 68020;
    break;
    
  case M_SPARC:
    abfd->obj_arch = bfd_arch_sparc;
    abfd->obj_machine = 0;
    break;
    
  case M_386:
    abfd->obj_arch = bfd_arch_i386;
    abfd->obj_machine = 0;
    break;
    
  case M_29K:
    abfd->obj_arch = bfd_arch_a29k;
    abfd->obj_machine = 0;
    break;
    
  default:
    abfd->obj_arch = bfd_arch_obscure;
    abfd->obj_machine = 0;
    break;
  }
  
  choose_reloc_size(abfd);
  return abfd->xvec;
}


/* Write an object file in SunOS format.
Section contents have already been written.  We write the
file header, symbols, and relocation.  */

boolean
DEFUN(NAME(aout,sunos4_write_object_contents),(abfd),
      bfd *abfd)

  {
    bfd_size_type data_pad = 0;
    struct external_exec exec_bytes;
    struct internal_exec *execp = exec_hdr (abfd);
    
    
    
    execp->a_text = obj_textsec (abfd)->size;
    
    /* Magic number, maestro, please!  */
    switch (bfd_get_architecture(abfd)) {
    case bfd_arch_m68k:
      switch (bfd_get_machine(abfd)) {
      case 68010:
	N_SET_MACHTYPE(*execp, M_68010);
	break;
      default:
      case 68020:
	N_SET_MACHTYPE(*execp, M_68020);
	break;
      }
      break;
    case bfd_arch_sparc:
      N_SET_MACHTYPE(*execp, M_SPARC);
      break;
    case bfd_arch_i386:
      N_SET_MACHTYPE(*execp, M_386);
      break;
    case bfd_arch_a29k:
      N_SET_MACHTYPE(*execp, M_29K);
      break;
    default:
      N_SET_MACHTYPE(*execp, M_UNKNOWN);
    }
    
    choose_reloc_size(abfd);

    /* FIXME */
    N_SET_FLAGS (*execp, 0x1);
    
    WRITE_HEADERS(abfd, execp);

  return true;
}

/* core files */

#define CORE_MAGIC 0x080456
#define CORE_NAMELEN 16

/* The core structure is taken from the Sun documentation.
Unfortunately, they don't document the FPA structure, or at least I
can't find it easily.  Fortunately the core header contains its own
length.  So this shouldn't cause problems, except for c_ucode, which
so far we don't use but is easy to find with a little arithmetic. */

/* But the reg structure can be gotten from the SPARC processor handbook.
This really should be in a GNU include file though so that gdb can use
the same info. */
struct regs {
  int r_psr;
  int r_pc;
  int r_npc;
  int r_y;
  int r_g1;
  int r_g2;
  int r_g3;
  int r_g4;
  int r_g5;
  int r_g6;
  int r_g7;
  int r_o0;
  int r_o1;
  int r_o2;
  int r_o3;
  int r_o4;
  int r_o5;
  int r_o6;
  int r_o7;
};

/* Taken from Sun documentation: */

/* FIXME:  It's worse than we expect.  This struct contains TWO substructs
neither of whose size we know, WITH STUFF IN BETWEEN THEM!  We can't
even portably access the stuff in between!  */

struct core {
  int c_magic;			/* Corefile magic number */
  int c_len;			/* Sizeof (struct core) */
  struct regs c_regs;		/* General purpose registers -- MACHDEP SIZE */
  struct internal_exec c_aouthdr;	/* A.out header */
  int c_signo;			/* Killing signal, if any */
  int c_tsize;			/* Text size (bytes) */
  int c_dsize;			/* Data size (bytes) */
  int c_ssize;			/* Stack size (bytes) */
  char c_cmdname[CORE_NAMELEN + 1]; /* Command name */
  double fp_stuff[1];		    /* external FPU state (size unknown by us) */
  /* The type "double" is critical here, for alignment.
    SunOS declares a struct here, but the struct's alignment
      is double since it contains doubles.  */
  int c_ucode;			/* Exception no. from u_code */
  /* (this member is not accessible by name since we don't
    portably know the size of fp_stuff.) */
};

/* Supposedly the user stack grows downward from the bottom of kernel memory.
Presuming that this remains true, this definition will work. */
#define USRSTACK (-(128*1024*1024))

PROTO (static void, swapcore, (bfd *abfd, struct core *core));

/* need this cast b/c ptr is really void * */
#define core_hdr(bfd) (((struct suncordata *) (bfd->tdata))->hdr)
#define core_datasec(bfd) (((struct suncordata *) ((bfd)->tdata))->data_section)
#define core_stacksec(bfd) (((struct suncordata*)((bfd)->tdata))->stack_section)
#define core_regsec(bfd) (((struct suncordata *) ((bfd)->tdata))->reg_section)
#define core_reg2sec(bfd) (((struct suncordata *) ((bfd)->tdata))->reg2_section)

/* These are stored in the bfd's tdata */
struct suncordata {
struct core *hdr;             /* core file header */
asection *data_section;
asection *stack_section;
asection *reg_section;
asection *reg2_section;
};

static bfd_target *
DEFUN(sunos4_core_file_p,(abfd),
      bfd *abfd)
{
  unsigned char longbuf[4];	/* Raw bytes of various header fields */
  int core_size;
  int core_mag;
  struct core *core;
  char *rawptr;
  
  bfd_error = system_call_error;
  
  if (bfd_read ((PTR)longbuf, 1, sizeof (longbuf), abfd) !=
      sizeof (longbuf))
    return 0;
  core_mag = bfd_h_get_32 (abfd, longbuf);

  if (core_mag != CORE_MAGIC) return 0;

  /* SunOS core headers can vary in length; second word is size; */
  if (bfd_read ((PTR)longbuf, 1, sizeof (longbuf), abfd) !=
      sizeof (longbuf))
    return 0;
  core_size = bfd_h_get_32 (abfd, longbuf);
  /* Sanity check */
  if (core_size > 20000)
    return 0;

  if (bfd_seek (abfd, 0L, false) < 0) return 0;

  rawptr = bfd_zalloc (abfd, core_size + sizeof (struct suncordata));
  if (rawptr == NULL) {
    bfd_error = no_memory;
    return 0;
  }

  core = (struct core *) (rawptr + sizeof (struct suncordata));

  if ((bfd_read ((PTR) core, 1, core_size, abfd)) != core_size) {
    bfd_error = system_call_error;
    bfd_release (abfd, rawptr);
    return 0;
  }

  swapcore (abfd, core);
  set_tdata (abfd, ((struct suncordata *) rawptr));
  core_hdr (abfd) = core;

  /* create the sections.  This is raunchy, but bfd_close wants to reclaim
     them */
  core_stacksec (abfd) = (asection *) bfd_zalloc (abfd, sizeof (asection));
  if (core_stacksec (abfd) == NULL) {
  loser:
    bfd_error = no_memory;
    bfd_release (abfd, rawptr);
    return 0;
  }
  core_datasec (abfd) = (asection *) bfd_zalloc (abfd, sizeof (asection));
  if (core_datasec (abfd) == NULL) {
  loser1:
    bfd_release (abfd, core_stacksec (abfd));
    goto loser;
  }
  core_regsec (abfd) = (asection *) bfd_zalloc (abfd, sizeof (asection));
  if (core_regsec (abfd) == NULL) {
  loser2:
    bfd_release (abfd, core_datasec (abfd));
    goto loser1;
  }
  core_reg2sec (abfd) = (asection *) bfd_zalloc (abfd, sizeof (asection));
  if (core_reg2sec (abfd) == NULL) {
    bfd_release (abfd, core_regsec (abfd));
    goto loser2;
  }

  core_stacksec (abfd)->name = ".stack";
  core_datasec (abfd)->name = ".data";
  core_regsec (abfd)->name = ".reg";
  core_reg2sec (abfd)->name = ".reg2";

  core_stacksec (abfd)->flags = SEC_ALLOC + SEC_LOAD;
  core_datasec (abfd)->flags = SEC_ALLOC + SEC_LOAD;
  core_regsec (abfd)->flags = SEC_ALLOC;
  core_reg2sec (abfd)->flags = SEC_ALLOC;

  core_stacksec (abfd)->size = core->c_ssize;
  core_datasec (abfd)->size = core->c_dsize;
  core_regsec (abfd)->size = (sizeof core->c_regs);
  /* Float regs take up end of struct, except c_ucode.  */
  core_reg2sec (abfd)->size = core_size - (sizeof core->c_ucode) -
    (file_ptr)(((struct core *)0)->fp_stuff);

  core_stacksec (abfd)->vma = (USRSTACK - core->c_ssize);
  core_datasec (abfd)->vma = N_DATADDR(core->c_aouthdr);
  core_regsec (abfd)->vma = -1;
  core_reg2sec (abfd)->vma = -1;

  core_stacksec (abfd)->filepos = core->c_len + core->c_dsize;
  core_datasec (abfd)->filepos = core->c_len;
  /* In file header: */
  core_regsec (abfd)->filepos = (file_ptr)(&((struct core *)0)->c_regs);
  core_reg2sec (abfd)->filepos = (file_ptr)(((struct core *)0)->fp_stuff);

  /* Align to word at least */
  core_stacksec (abfd)->alignment_power = 2;
  core_datasec (abfd)->alignment_power = 2;
  core_regsec (abfd)->alignment_power = 2;
  core_reg2sec (abfd)->alignment_power = 2;

  abfd->sections = core_stacksec (abfd);
  core_stacksec (abfd)->next = core_datasec (abfd);
  core_datasec (abfd)->next = core_regsec (abfd);
  core_regsec (abfd)->next = core_reg2sec (abfd);

  abfd->section_count = 4;

  return abfd->xvec;
}

static char *sunos4_core_file_failing_command (abfd)
bfd *abfd;
  {
  return core_hdr (abfd)->c_cmdname;
}

static int
DEFUN(sunos4_core_file_failing_signal,(abfd),
      bfd *abfd)
{
  return core_hdr (abfd)->c_signo;
}

static boolean
DEFUN(sunos4_core_file_matches_executable_p, (core_bfd, exec_bfd),
      bfd *core_bfd AND
      bfd *exec_bfd)
{
  if (core_bfd->xvec != exec_bfd->xvec) {
    bfd_error = system_call_error;
    return false;
  }

  return (bcmp ((char *)&core_hdr (core_bfd), (char*) &exec_hdr (exec_bfd),
		sizeof (struct internal_exec)) == 0) ? true : false;
}

/* byte-swap core structure */
/* FIXME, this needs more work to swap IN a core struct from raw bytes */
static void
DEFUN(swapcore,(abfd, core),
      bfd *abfd AND
      struct core *core)
{
  struct external_exec exec_bytes;
  
  core->c_magic = bfd_h_get_32 (abfd, (unsigned char *)&core->c_magic);
  core->c_len   = bfd_h_get_32 (abfd, (unsigned char *)&core->c_len  );
  /* Leave integer registers in target byte order.  */
  bcopy ((char *)&(core->c_aouthdr), (char *)&exec_bytes, EXEC_BYTES_SIZE);
  NAME(aout,swap_exec_header_in)(abfd, &exec_bytes, &core->c_aouthdr);
  core->c_signo = bfd_h_get_32 (abfd, (unsigned char *)&core->c_signo);
  core->c_tsize = bfd_h_get_32 (abfd, (unsigned char *)&core->c_tsize);
  core->c_dsize = bfd_h_get_32 (abfd, (unsigned char *)&core->c_dsize);
  core->c_ssize = bfd_h_get_32 (abfd, (unsigned char *)&core->c_ssize);
  /* Leave FP registers in target byte order.  */
  /* Leave "c_ucode" unswapped for now, since we can't find it easily.  */
}

/* We use BFD generic archive files.  */
#define	aout_32_openr_next_archived_file	bfd_generic_openr_next_archived_file
#define	aout_32_generic_stat_arch_elt		bfd_generic_stat_arch_elt
#define	aout_32_slurp_armap			bfd_slurp_bsd_armap
#define	aout_32_slurp_extended_name_table	bfd_true
#define	aout_32_write_armap			bsd_write_armap
#define	aout_32_truncate_arname			bfd_bsd_truncate_arname
#define aout_32_machine_type 			sunos_machine_type

#define	aout_32_core_file_failing_command 	sunos4_core_file_failing_command
#define	aout_32_core_file_failing_signal	sunos4_core_file_failing_signal
#define	aout_32_core_file_matches_executable_p	sunos4_core_file_matches_executable_p


#define	aout_64_openr_next_archived_file	bfd_generic_openr_next_archived_file
#define	aout_64_generic_stat_arch_elt		bfd_generic_stat_arch_elt
#define	aout_64_slurp_armap			bfd_slurp_bsd_armap
#define	aout_64_slurp_extended_name_table	bfd_true
#define	aout_64_write_armap			bsd_write_armap
#define	aout_64_truncate_arname			bfd_bsd_truncate_arname
#define aout_64_machine_type 			sunos_machine_type

#define	aout_64_core_file_failing_command 	sunos4_core_file_failing_command
#define	aout_64_core_file_failing_signal	sunos4_core_file_failing_signal
#define	aout_64_core_file_matches_executable_p	sunos4_core_file_matches_executable_p

#define aout_64_bfd_debug_info_start		bfd_void
#define aout_64_bfd_debug_info_end		bfd_void
#define aout_64_bfd_debug_info_accumulate	bfd_void

#define aout_32_bfd_debug_info_start		bfd_void
#define aout_32_bfd_debug_info_end		bfd_void
#define aout_32_bfd_debug_info_accumulate	bfd_void



/* We implement these routines ourselves, rather than using the generic
a.out versions.  */
#define	aout_write_object_contents	sunos4_write_object_contents

bfd_target VECNAME =
  {
    TARGETNAME,
    bfd_target_aout_flavour_enum,
    true,			/* target byte order */
    true,			/* target headers byte order */
    (HAS_RELOC | EXEC_P |	/* object flags */
     HAS_LINENO | HAS_DEBUG |
     HAS_SYMS | HAS_LOCALS | DYNAMIC | WP_TEXT | D_PAGED),
    (SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD | SEC_RELOC), /* section flags */
    ' ',						   /* ar_pad_char */
    16,							   /* ar_max_namelen */
    3,							   /* minimum alignment power */
    _do_getb64, _do_putb64, _do_getb32, _do_putb32, _do_getb16, _do_putb16, /* data */
    _do_getb64, _do_putb64, _do_getb32, _do_putb32, _do_getb16, _do_putb16, /* hdrs */
    
      {_bfd_dummy_target, NAME(sunos,object_p),
       bfd_generic_archive_p, sunos4_core_file_p},
      {bfd_false, NAME(aout,mkobject),
       _bfd_generic_mkarchive, bfd_false},
      {bfd_false, NAME(aout,sunos4_write_object_contents), /* bfd_write_contents */
       _bfd_write_archive_contents, bfd_false},
    
    JUMP_TABLE(JNAME(aout))
    };