darling-gdb/bfd/vms-alpha.c
Tristan Gingold cf6b876738 2011-03-25 Tristan Gingold <gingold@adacore.com>
* vms-alpha.c (evax_section_flags): Make $CODE$ section read-only.
	Minor reordering.
	(alpha_vms_create_eisd_for_section): Make code sections read-only.
2011-03-25 15:31:27 +00:00

9365 lines
277 KiB
C
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* vms.c -- BFD back-end for EVAX (openVMS/Alpha) files.
Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005,
2006, 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
Initial version written by Klaus Kaempf (kkaempf@rmi.de)
Major rewrite by Adacore.
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 3 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., 51 Franklin Street - Fifth Floor, Boston,
MA 02110-1301, USA. */
/* TODO:
o overlayed sections
o PIC
o Generation of shared image
o Relocation optimizations
o EISD for the stack
o Vectors isect
o 64 bits sections
o Entry point
o LIB$INITIALIZE
o protected sections (for messages)
...
*/
#include "sysdep.h"
#include "bfd.h"
#include "bfdlink.h"
#include "libbfd.h"
#include "bfdver.h"
#include "vms.h"
#include "vms/eihd.h"
#include "vms/eiha.h"
#include "vms/eihi.h"
#include "vms/eihs.h"
#include "vms/eisd.h"
#include "vms/dmt.h"
#include "vms/dst.h"
#include "vms/eihvn.h"
#include "vms/eobjrec.h"
#include "vms/egsd.h"
#include "vms/egps.h"
#include "vms/esgps.h"
#include "vms/eeom.h"
#include "vms/emh.h"
#include "vms/eiaf.h"
#include "vms/shl.h"
#include "vms/eicp.h"
#include "vms/etir.h"
#include "vms/egsy.h"
#include "vms/esdf.h"
#include "vms/esdfm.h"
#include "vms/esdfv.h"
#include "vms/esrf.h"
#include "vms/egst.h"
#include "vms/eidc.h"
#include "vms/dsc.h"
#include "vms/prt.h"
#include "vms/internal.h"
#define MIN(a,b) ((a) < (b) ? (a) : (b))
/* The r_type field in a reloc is one of the following values. */
#define ALPHA_R_IGNORE 0
#define ALPHA_R_REFQUAD 1
#define ALPHA_R_BRADDR 2
#define ALPHA_R_HINT 3
#define ALPHA_R_SREL16 4
#define ALPHA_R_SREL32 5
#define ALPHA_R_SREL64 6
#define ALPHA_R_OP_PUSH 7
#define ALPHA_R_OP_STORE 8
#define ALPHA_R_OP_PSUB 9
#define ALPHA_R_OP_PRSHIFT 10
#define ALPHA_R_LINKAGE 11
#define ALPHA_R_REFLONG 12
#define ALPHA_R_CODEADDR 13
#define ALPHA_R_NOP 14
#define ALPHA_R_BSR 15
#define ALPHA_R_LDA 16
#define ALPHA_R_BOH 17
/* These are used with DST_S_C_LINE_NUM. */
#define DST_S_C_LINE_NUM_HEADER_SIZE 4
/* These are used with DST_S_C_SOURCE */
#define DST_S_B_PCLINE_UNSBYTE 1
#define DST_S_W_PCLINE_UNSWORD 1
#define DST_S_L_PCLINE_UNSLONG 1
#define DST_S_B_MODBEG_NAME 14
#define DST_S_L_RTNBEG_ADDRESS 5
#define DST_S_B_RTNBEG_NAME 13
#define DST_S_L_RTNEND_SIZE 5
/* These are used with DST_S_C_SOURCE. */
#define DST_S_C_SOURCE_HEADER_SIZE 4
#define DST_S_B_SRC_DF_LENGTH 1
#define DST_S_W_SRC_DF_FILEID 3
#define DST_S_B_SRC_DF_FILENAME 20
#define DST_S_B_SRC_UNSBYTE 1
#define DST_S_W_SRC_UNSWORD 1
#define DST_S_L_SRC_UNSLONG 1
/* Debugger symbol definitions. */
#define DBG_S_L_DMT_MODBEG 0
#define DBG_S_L_DST_SIZE 4
#define DBG_S_W_DMT_PSECT_COUNT 8
#define DBG_S_C_DMT_HEADER_SIZE 12
#define DBG_S_L_DMT_PSECT_START 0
#define DBG_S_L_DMT_PSECT_LENGTH 4
#define DBG_S_C_DMT_PSECT_SIZE 8
/* VMS module header. */
struct hdr_struct
{
char hdr_b_strlvl;
int hdr_l_arch1;
int hdr_l_arch2;
int hdr_l_recsiz;
char *hdr_t_name;
char *hdr_t_version;
char *hdr_t_date;
char *hdr_c_lnm;
char *hdr_c_src;
char *hdr_c_ttl;
};
#define EMH_DATE_LENGTH 17
/* VMS End-Of-Module records (EOM/EEOM). */
struct eom_struct
{
unsigned int eom_l_total_lps;
unsigned short eom_w_comcod;
bfd_boolean eom_has_transfer;
unsigned char eom_b_tfrflg;
unsigned int eom_l_psindx;
unsigned int eom_l_tfradr;
};
struct vms_symbol_entry
{
bfd *owner;
/* Common fields. */
unsigned char typ;
unsigned char data_type;
unsigned short flags;
/* Section and offset/value of the symbol. */
unsigned int value;
asection *section;
/* Section and offset/value for the entry point (only for subprg). */
asection *code_section;
unsigned int code_value;
/* Symbol vector offset. */
unsigned int symbol_vector;
/* Length of the name. */
unsigned char namelen;
char name[1];
};
/* Stack value for push/pop commands. */
struct stack_struct
{
bfd_vma value;
unsigned int reloc;
};
#define STACKSIZE 128
/* A minimal decoding of DST compilation units. We only decode
what's needed to get to the line number information. */
struct fileinfo
{
char *name;
unsigned int srec;
};
struct srecinfo
{
struct srecinfo *next;
unsigned int line;
unsigned int sfile;
unsigned int srec;
};
struct lineinfo
{
struct lineinfo *next;
bfd_vma address;
unsigned int line;
};
struct funcinfo
{
struct funcinfo *next;
char *name;
bfd_vma low;
bfd_vma high;
};
struct module
{
/* Chain the previously read compilation unit. */
struct module *next;
/* The module name. */
char *name;
/* The start offset and size of debug info in the DST section. */
unsigned int modbeg;
unsigned int size;
/* The lowest and highest addresses contained in this compilation
unit as specified in the compilation unit header. */
bfd_vma low;
bfd_vma high;
/* The listing line table. */
struct lineinfo *line_table;
/* The source record table. */
struct srecinfo *srec_table;
/* A list of the functions found in this module. */
struct funcinfo *func_table;
/* Current allocation of file_table. */
unsigned int file_table_count;
/* An array of the files making up this module. */
struct fileinfo *file_table;
};
/* BFD private data for alpha-vms. */
struct vms_private_data_struct
{
/* If true, relocs have been read. */
bfd_boolean reloc_done;
/* Record input buffer. */
struct vms_rec_rd recrd;
struct vms_rec_wr recwr;
struct hdr_struct hdr_data; /* data from HDR/EMH record */
struct eom_struct eom_data; /* data from EOM/EEOM record */
/* Transfer addresses (entry points). */
bfd_vma transfer_address[4];
/* Array of GSD sections to get the correspond BFD one. */
unsigned int section_max; /* Size of the sections array. */
unsigned int section_count; /* Number of GSD sections. */
asection **sections;
/* Array of raw symbols. */
struct vms_symbol_entry **syms;
/* Canonicalized symbols. */
asymbol **csymbols;
/* Number of symbols. */
unsigned int gsd_sym_count;
/* Size of the syms array. */
unsigned int max_sym_count;
/* Number of procedure symbols. */
unsigned int norm_sym_count;
/* Stack used to evaluate TIR/ETIR commands. */
struct stack_struct *stack;
int stackptr;
/* Content reading. */
asection *image_section; /* section for image_ptr */
file_ptr image_offset; /* Offset for image_ptr. */
struct module *modules; /* list of all compilation units */
asection *dst_section;
unsigned int dst_ptr_offsets_count; /* # of offsets in following array */
unsigned int *dst_ptr_offsets; /* array of saved image_ptr offsets */
/* Shared library support */
bfd_vma symvva; /* relative virtual address of symbol vector */
unsigned int ident;
unsigned char matchctl;
/* Shared library index. This is used for input bfd while linking. */
unsigned int shr_index;
/* Used to place structures in the file. */
file_ptr file_pos;
/* Simply linked list of eisd. */
struct vms_internal_eisd_map *eisd_head;
struct vms_internal_eisd_map *eisd_tail;
/* Simply linked list of eisd for shared libraries. */
struct vms_internal_eisd_map *gbl_eisd_head;
struct vms_internal_eisd_map *gbl_eisd_tail;
/* linkage index counter used by conditional store commands */
int vms_linkage_index;
/* see tc-alpha.c of gas for a description. */
int flag_hash_long_names; /* -+, hash instead of truncate */
int flag_show_after_trunc; /* -H, show hashing/truncation */
};
#define PRIV2(abfd, name) \
(((struct vms_private_data_struct *)(abfd)->tdata.any)->name)
#define PRIV(name) PRIV2(abfd,name)
/* Used to keep extra VMS specific information for a given section.
reloc_size holds the size of the relocation stream, note this
is very different from the number of relocations as VMS relocations
are variable length.
reloc_stream is the actual stream of relocation entries. */
struct vms_section_data_struct
{
/* Maximnum number of entries in sec->relocation. */
unsigned reloc_max;
/* Corresponding eisd. Used only while generating executables. */
struct vms_internal_eisd_map *eisd;
/* PSC flags to be clear. */
flagword no_flags;
/* PSC flags to be set. */
flagword flags;
};
#define vms_section_data(sec) \
((struct vms_section_data_struct *)sec->used_by_bfd)
/* To be called from the debugger. */
struct vms_private_data_struct *bfd_vms_get_data (bfd *abfd);
static int vms_get_remaining_object_record (bfd *abfd, int read_so_far);
static bfd_boolean _bfd_vms_slurp_object_records (bfd * abfd);
static void alpha_vms_add_fixup_lp (struct bfd_link_info *, bfd *, bfd *);
static void alpha_vms_add_fixup_ca (struct bfd_link_info *, bfd *, bfd *);
static void alpha_vms_add_fixup_qr (struct bfd_link_info *, bfd *, bfd *,
bfd_vma);
static void alpha_vms_add_fixup_lr (struct bfd_link_info *, unsigned int,
bfd_vma);
static void alpha_vms_add_lw_reloc (struct bfd_link_info *info);
static void alpha_vms_add_qw_reloc (struct bfd_link_info *info);
struct vector_type
{
unsigned int max_el;
unsigned int nbr_el;
void *els;
};
/* Number of elements in VEC. */
#define VEC_COUNT(VEC) ((VEC).nbr_el)
/* Get the address of the Nth element. */
#define VEC_EL(VEC, TYPE, N) (((TYPE *)((VEC).els))[N])
#define VEC_INIT(VEC) \
do { \
(VEC).max_el = 0; \
(VEC).nbr_el = 0; \
(VEC).els = NULL; \
} while (0)
/* Be sure there is room for a new element. */
static void vector_grow1 (struct vector_type *vec, size_t elsz);
/* Allocate room for a new element and return its address. */
#define VEC_APPEND(VEC, TYPE) \
(vector_grow1 (&VEC, sizeof (TYPE)), &VEC_EL(VEC, TYPE, (VEC).nbr_el++))
/* Append an element. */
#define VEC_APPEND_EL(VEC, TYPE, EL) \
(*(VEC_APPEND (VEC, TYPE)) = EL)
struct alpha_vms_vma_ref
{
bfd_vma vma; /* Vma in the output. */
bfd_vma ref; /* Reference in the input. */
};
struct alpha_vms_shlib_el
{
bfd *abfd;
bfd_boolean has_fixups;
struct vector_type lp; /* Vector of bfd_vma. */
struct vector_type ca; /* Vector of bfd_vma. */
struct vector_type qr; /* Vector of struct alpha_vms_vma_ref. */
};
/* Alpha VMS linker hash table. */
struct alpha_vms_link_hash_table
{
struct bfd_link_hash_table root;
/* Vector of shared libaries. */
struct vector_type shrlibs;
/* Fixup section. */
asection *fixup;
/* Base address. Used by fixups. */
bfd_vma base_addr;
};
#define alpha_vms_link_hash(INFO) \
((struct alpha_vms_link_hash_table *)(INFO->hash))
/* Alpha VMS linker hash table entry. */
struct alpha_vms_link_hash_entry
{
struct bfd_link_hash_entry root;
/* Pointer to the original vms symbol. */
struct vms_symbol_entry *sym;
};
/* Image reading. */
/* Read & process EIHD record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_eihd (bfd *abfd, unsigned int *eisd_offset,
unsigned int *eihs_offset)
{
unsigned int imgtype, size;
bfd_vma symvva;
struct vms_eihd *eihd = (struct vms_eihd *)PRIV (recrd.rec);
vms_debug2 ((8, "_bfd_vms_slurp_eihd\n"));
size = bfd_getl32 (eihd->size);
imgtype = bfd_getl32 (eihd->imgtype);
if (imgtype == EIHD__K_EXE || imgtype == EIHD__K_LIM)
abfd->flags |= EXEC_P;
symvva = bfd_getl64 (eihd->symvva);
if (symvva != 0)
{
PRIV (symvva) = symvva;
abfd->flags |= DYNAMIC;
}
PRIV (ident) = bfd_getl32 (eihd->ident);
PRIV (matchctl) = eihd->matchctl;
*eisd_offset = bfd_getl32 (eihd->isdoff);
*eihs_offset = bfd_getl32 (eihd->symdbgoff);
vms_debug2 ((4, "EIHD size %d imgtype %d symvva 0x%lx eisd %d eihs %d\n",
size, imgtype, (unsigned long)symvva,
*eisd_offset, *eihs_offset));
return TRUE;
}
/* Read & process EISD record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_eisd (bfd *abfd, unsigned int offset)
{
int section_count = 0;
vms_debug2 ((8, "_bfd_vms_slurp_eisd\n"));
while (1)
{
struct vms_eisd *eisd;
unsigned int rec_size;
unsigned int size;
unsigned long long vaddr;
unsigned int flags;
unsigned int vbn;
char *name = NULL;
asection *section;
flagword bfd_flags;
eisd = (struct vms_eisd *)(PRIV (recrd.rec) + offset);
rec_size = bfd_getl32 (eisd->eisdsize);
if (rec_size == 0)
break;
/* Skip to next block if pad. */
if (rec_size == 0xffffffff)
{
offset = (offset + VMS_BLOCK_SIZE) & ~(VMS_BLOCK_SIZE - 1);
continue;
}
else
offset += rec_size;
size = bfd_getl32 (eisd->secsize);
vaddr = bfd_getl64 (eisd->virt_addr);
flags = bfd_getl32 (eisd->flags);
vbn = bfd_getl32 (eisd->vbn);
vms_debug2 ((4, "EISD at 0x%x size 0x%x addr 0x%lx flags 0x%x blk %d\n",
offset, size, (unsigned long)vaddr, flags, vbn));
/* VMS combines psects from .obj files into isects in the .exe. This
process doesn't preserve enough information to reliably determine
what's in each section without examining the data. This is
especially true of DWARF debug sections. */
bfd_flags = SEC_ALLOC;
if (vbn != 0)
bfd_flags |= SEC_HAS_CONTENTS | SEC_LOAD;
if (flags & EISD__M_EXE)
bfd_flags |= SEC_CODE;
if (flags & EISD__M_NONSHRADR)
bfd_flags |= SEC_DATA;
if (!(flags & EISD__M_WRT))
bfd_flags |= SEC_READONLY;
if (flags & EISD__M_DZRO)
bfd_flags |= SEC_DATA;
if (flags & EISD__M_FIXUPVEC)
bfd_flags |= SEC_DATA;
if (flags & EISD__M_CRF)
bfd_flags |= SEC_DATA;
if (flags & EISD__M_GBL)
{
name = _bfd_vms_save_counted_string (eisd->gblnam);
bfd_flags |= SEC_COFF_SHARED_LIBRARY;
bfd_flags &= ~(SEC_ALLOC | SEC_LOAD);
}
else if (flags & EISD__M_FIXUPVEC)
name = "$FIXUPVEC$";
else if (eisd->type == EISD__K_USRSTACK)
name = "$STACK$";
else
{
const char *pfx;
name = (char*) bfd_alloc (abfd, 32);
if (flags & EISD__M_DZRO)
pfx = "BSS";
else if (flags & EISD__M_EXE)
pfx = "CODE";
else if (!(flags & EISD__M_WRT))
pfx = "RO";
else
pfx = "LOCAL";
BFD_ASSERT (section_count < 999);
sprintf (name, "$%s_%03d$", pfx, section_count++);
}
section = bfd_make_section (abfd, name);
if (!section)
return FALSE;
section->filepos = vbn ? VMS_BLOCK_SIZE * (vbn - 1) : 0;
section->size = size;
section->vma = vaddr;
if (!bfd_set_section_flags (abfd, section, bfd_flags))
return FALSE;
}
return TRUE;
}
/* Read & process EIHS record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_eihs (bfd *abfd, unsigned int offset)
{
unsigned char *p = PRIV (recrd.rec) + offset;
unsigned int gstvbn = bfd_getl32 (p + EIHS__L_GSTVBN);
unsigned int gstsize ATTRIBUTE_UNUSED = bfd_getl32 (p + EIHS__L_GSTSIZE);
unsigned int dstvbn = bfd_getl32 (p + EIHS__L_DSTVBN);
unsigned int dstsize = bfd_getl32 (p + EIHS__L_DSTSIZE);
unsigned int dmtvbn = bfd_getl32 (p + EIHS__L_DMTVBN);
unsigned int dmtbytes = bfd_getl32 (p + EIHS__L_DMTBYTES);
asection *section;
#if VMS_DEBUG
vms_debug (8, "_bfd_vms_slurp_ihs\n");
vms_debug (4, "EIHS record gstvbn %d gstsize %d dstvbn %d dstsize %d dmtvbn %d dmtbytes %d\n",
gstvbn, gstsize, dstvbn, dstsize, dmtvbn, dmtbytes);
#endif
if (dstvbn)
{
flagword bfd_flags = SEC_HAS_CONTENTS | SEC_DEBUGGING;
section = bfd_make_section (abfd, "$DST$");
if (!section)
return FALSE;
section->size = dstsize;
section->filepos = VMS_BLOCK_SIZE * (dstvbn - 1);
if (!bfd_set_section_flags (abfd, section, bfd_flags))
return FALSE;
PRIV (dst_section) = section;
abfd->flags |= (HAS_DEBUG | HAS_LINENO);
}
if (dmtvbn)
{
flagword bfd_flags = SEC_HAS_CONTENTS | SEC_DEBUGGING;
section = bfd_make_section (abfd, "$DMT$");
if (!section)
return FALSE;
section->size = dmtbytes;
section->filepos = VMS_BLOCK_SIZE * (dmtvbn - 1);
if (!bfd_set_section_flags (abfd, section, bfd_flags))
return FALSE;
}
if (gstvbn)
{
if (bfd_seek (abfd, VMS_BLOCK_SIZE * (gstvbn - 1), SEEK_SET))
{
bfd_set_error (bfd_error_file_truncated);
return FALSE;
}
if (_bfd_vms_slurp_object_records (abfd) != TRUE)
return FALSE;
abfd->flags |= HAS_SYMS;
}
return TRUE;
}
/* Object file reading. */
/* Object file input functions. */
/* Get next record from object file to vms_buf.
Set PRIV(buf_size) and return it
This is a little tricky since it should be portable.
The openVMS object file has 'variable length' which means that
read() returns data in chunks of (hopefully) correct and expected
size. The linker (and other tools on VMS) depend on that. Unix
doesn't know about 'formatted' files, so reading and writing such
an object file in a Unix environment is not trivial.
With the tool 'file' (available on all VMS FTP sites), one
can view and change the attributes of a file. Changing from
'variable length' to 'fixed length, 512 bytes' reveals the
record size at the first 2 bytes of every record. The same
may happen during the transfer of object files from VMS to Unix,
at least with UCX, the DEC implementation of TCP/IP.
The VMS format repeats the size at bytes 2 & 3 of every record.
On the first call (file_format == FF_UNKNOWN) we check if
the first and the third byte pair (!) of the record match.
If they do it's an object file in an Unix environment or with
wrong attributes (FF_FOREIGN), else we should be in a VMS
environment where read() returns the record size (FF_NATIVE).
Reading is always done in 2 steps:
1. first just the record header is read and the size extracted,
2. then the read buffer is adjusted and the remaining bytes are
read in.
All file I/O is done on even file positions. */
#define VMS_OBJECT_ADJUSTMENT 2
static void
maybe_adjust_record_pointer_for_object (bfd *abfd)
{
/* Set the file format once for all on the first invocation. */
if (PRIV (recrd.file_format) == FF_UNKNOWN)
{
if (PRIV (recrd.rec)[0] == PRIV (recrd.rec)[4]
&& PRIV (recrd.rec)[1] == PRIV (recrd.rec)[5])
PRIV (recrd.file_format) = FF_FOREIGN;
else
PRIV (recrd.file_format) = FF_NATIVE;
}
/* The adjustment is needed only in an Unix environment. */
if (PRIV (recrd.file_format) == FF_FOREIGN)
PRIV (recrd.rec) += VMS_OBJECT_ADJUSTMENT;
}
/* Implement step #1 of the object record reading procedure.
Return the record type or -1 on failure. */
static int
_bfd_vms_get_object_record (bfd *abfd)
{
unsigned int test_len = 6;
int type;
vms_debug2 ((8, "_bfd_vms_get_obj_record\n"));
/* Skip alignment byte if the current position is odd. */
if (PRIV (recrd.file_format) == FF_FOREIGN && (bfd_tell (abfd) & 1))
{
if (bfd_bread (PRIV (recrd.buf), 1, abfd) != 1)
{
bfd_set_error (bfd_error_file_truncated);
return -1;
}
}
/* Read the record header */
if (bfd_bread (PRIV (recrd.buf), test_len, abfd) != test_len)
{
bfd_set_error (bfd_error_file_truncated);
return -1;
}
/* Reset the record pointer. */
PRIV (recrd.rec) = PRIV (recrd.buf);
maybe_adjust_record_pointer_for_object (abfd);
if (vms_get_remaining_object_record (abfd, test_len) <= 0)
return -1;
type = bfd_getl16 (PRIV (recrd.rec));
vms_debug2 ((8, "_bfd_vms_get_obj_record: rec %p, size %d, type %d\n",
PRIV (recrd.rec), PRIV (recrd.rec_size), type));
return type;
}
/* Implement step #2 of the object record reading procedure.
Return the size of the record or 0 on failure. */
static int
vms_get_remaining_object_record (bfd *abfd, int read_so_far)
{
unsigned int to_read;
vms_debug2 ((8, "vms_get_remaining_obj_record\n"));
/* Extract record size. */
PRIV (recrd.rec_size) = bfd_getl16 (PRIV (recrd.rec) + 2);
if (PRIV (recrd.rec_size) <= 0)
{
bfd_set_error (bfd_error_file_truncated);
return 0;
}
/* That's what the linker manual says. */
if (PRIV (recrd.rec_size) > EOBJ__C_MAXRECSIZ)
{
bfd_set_error (bfd_error_file_truncated);
return 0;
}
/* Take into account object adjustment. */
to_read = PRIV (recrd.rec_size);
if (PRIV (recrd.file_format) == FF_FOREIGN)
to_read += VMS_OBJECT_ADJUSTMENT;
/* Adjust the buffer. */
if (to_read > PRIV (recrd.buf_size))
{
PRIV (recrd.buf)
= (unsigned char *) bfd_realloc (PRIV (recrd.buf), to_read);
if (PRIV (recrd.buf) == NULL)
return 0;
PRIV (recrd.buf_size) = to_read;
}
/* Read the remaining record. */
to_read -= read_so_far;
vms_debug2 ((8, "vms_get_remaining_obj_record: to_read %d\n", to_read));
if (bfd_bread (PRIV (recrd.buf) + read_so_far, to_read, abfd) != to_read)
{
bfd_set_error (bfd_error_file_truncated);
return 0;
}
/* Reset the record pointer. */
PRIV (recrd.rec) = PRIV (recrd.buf);
maybe_adjust_record_pointer_for_object (abfd);
vms_debug2 ((8, "vms_get_remaining_obj_record: size %d\n",
PRIV (recrd.rec_size)));
return PRIV (recrd.rec_size);
}
/* Read and process emh record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_ehdr (bfd *abfd)
{
unsigned char *ptr;
unsigned char *vms_rec;
int subtype;
vms_rec = PRIV (recrd.rec);
vms_debug2 ((2, "HDR/EMH\n"));
subtype = bfd_getl16 (vms_rec + 4);
vms_debug2 ((3, "subtype %d\n", subtype));
switch (subtype)
{
case EMH__C_MHD:
/* Module header. */
PRIV (hdr_data).hdr_b_strlvl = vms_rec[6];
PRIV (hdr_data).hdr_l_arch1 = bfd_getl32 (vms_rec + 8);
PRIV (hdr_data).hdr_l_arch2 = bfd_getl32 (vms_rec + 12);
PRIV (hdr_data).hdr_l_recsiz = bfd_getl32 (vms_rec + 16);
PRIV (hdr_data).hdr_t_name = _bfd_vms_save_counted_string (vms_rec + 20);
ptr = vms_rec + 20 + vms_rec[20] + 1;
PRIV (hdr_data).hdr_t_version =_bfd_vms_save_counted_string (ptr);
ptr += *ptr + 1;
PRIV (hdr_data).hdr_t_date = _bfd_vms_save_sized_string (ptr, 17);
break;
case EMH__C_LNM:
PRIV (hdr_data).hdr_c_lnm =
_bfd_vms_save_sized_string (vms_rec, PRIV (recrd.rec_size - 6));
break;
case EMH__C_SRC:
PRIV (hdr_data).hdr_c_src =
_bfd_vms_save_sized_string (vms_rec, PRIV (recrd.rec_size - 6));
break;
case EMH__C_TTL:
PRIV (hdr_data).hdr_c_ttl =
_bfd_vms_save_sized_string (vms_rec, PRIV (recrd.rec_size - 6));
break;
case EMH__C_CPR:
case EMH__C_MTC:
case EMH__C_GTX:
break;
default:
bfd_set_error (bfd_error_wrong_format);
return FALSE;
}
return TRUE;
}
/* Typical sections for evax object files. */
#define EVAX_ABS_NAME "$ABS$"
#define EVAX_CODE_NAME "$CODE$"
#define EVAX_LINK_NAME "$LINK$"
#define EVAX_DATA_NAME "$DATA$"
#define EVAX_BSS_NAME "$BSS$"
#define EVAX_READONLYADDR_NAME "$READONLY_ADDR$"
#define EVAX_READONLY_NAME "$READONLY$"
#define EVAX_LITERAL_NAME "$LITERAL$"
#define EVAX_LITERALS_NAME "$LITERALS"
#define EVAX_COMMON_NAME "$COMMON$"
#define EVAX_LOCAL_NAME "$LOCAL$"
struct sec_flags_struct
{
const char *name; /* Name of section. */
int vflags_always;
flagword flags_always; /* Flags we set always. */
int vflags_hassize;
flagword flags_hassize; /* Flags we set if the section has a size > 0. */
};
/* These flags are deccrtl/vaxcrtl (openVMS 6.2 Alpha) compatible. */
static const struct sec_flags_struct evax_section_flags[] =
{
{ EVAX_ABS_NAME,
EGPS__V_SHR,
0,
EGPS__V_SHR,
0 },
{ EVAX_CODE_NAME,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_EXE,
SEC_CODE | SEC_READONLY,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_EXE,
SEC_CODE | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_LITERAL_NAME,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_RD | EGPS__V_NOMOD,
SEC_DATA | SEC_READONLY,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_RD,
SEC_DATA | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_LINK_NAME,
EGPS__V_REL | EGPS__V_RD,
SEC_DATA | SEC_READONLY,
EGPS__V_REL | EGPS__V_RD,
SEC_DATA | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_DATA_NAME,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT | EGPS__V_NOMOD,
SEC_DATA,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT,
SEC_DATA | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_BSS_NAME,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT | EGPS__V_NOMOD,
SEC_NO_FLAGS,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT | EGPS__V_NOMOD,
SEC_ALLOC },
{ EVAX_READONLYADDR_NAME,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_RD,
SEC_DATA | SEC_READONLY,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_RD,
SEC_DATA | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_READONLY_NAME,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_RD | EGPS__V_NOMOD,
SEC_DATA | SEC_READONLY,
EGPS__V_PIC | EGPS__V_REL | EGPS__V_SHR | EGPS__V_RD,
SEC_DATA | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_LOCAL_NAME,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT,
SEC_DATA,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT,
SEC_DATA | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ EVAX_LITERALS_NAME,
EGPS__V_PIC | EGPS__V_OVR,
SEC_DATA | SEC_READONLY,
EGPS__V_PIC | EGPS__V_OVR,
SEC_DATA | SEC_READONLY | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD },
{ NULL,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT,
SEC_DATA,
EGPS__V_REL | EGPS__V_RD | EGPS__V_WRT,
SEC_IN_MEMORY | SEC_DATA | SEC_HAS_CONTENTS | SEC_ALLOC | SEC_LOAD }
};
/* Retrieve BFD section flags by name and size. */
static flagword
vms_secflag_by_name (const struct sec_flags_struct *section_flags,
const char *name,
int hassize)
{
int i = 0;
while (section_flags[i].name != NULL)
{
if (strcmp (name, section_flags[i].name) == 0)
{
if (hassize)
return section_flags[i].flags_hassize;
else
return section_flags[i].flags_always;
}
i++;
}
if (hassize)
return section_flags[i].flags_hassize;
return section_flags[i].flags_always;
}
/* Retrieve VMS section flags by name and size. */
static flagword
vms_esecflag_by_name (const struct sec_flags_struct *section_flags,
const char *name,
int hassize)
{
int i = 0;
while (section_flags[i].name != NULL)
{
if (strcmp (name, section_flags[i].name) == 0)
{
if (hassize)
return section_flags[i].vflags_hassize;
else
return section_flags[i].vflags_always;
}
i++;
}
if (hassize)
return section_flags[i].vflags_hassize;
return section_flags[i].vflags_always;
}
/* Add SYM to the symbol table of ABFD.
Return FALSE in case of error. */
static bfd_boolean
add_symbol_entry (bfd *abfd, struct vms_symbol_entry *sym)
{
if (PRIV (gsd_sym_count) >= PRIV (max_sym_count))
{
if (PRIV (max_sym_count) == 0)
{
PRIV (max_sym_count) = 128;
PRIV (syms) = bfd_malloc
(PRIV (max_sym_count) * sizeof (struct vms_symbol_entry *));
}
else
{
PRIV (max_sym_count) *= 2;
PRIV (syms) = bfd_realloc
(PRIV (syms),
(PRIV (max_sym_count) * sizeof (struct vms_symbol_entry *)));
}
if (PRIV (syms) == NULL)
return FALSE;
}
PRIV (syms)[PRIV (gsd_sym_count)++] = sym;
return TRUE;
}
/* Create a symbol whose name is ASCIC and add it to ABFD.
Return NULL in case of error. */
static struct vms_symbol_entry *
add_symbol (bfd *abfd, const unsigned char *ascic)
{
struct vms_symbol_entry *entry;
int len;
len = *ascic++;
entry = (struct vms_symbol_entry *)bfd_zalloc (abfd, sizeof (*entry) + len);
if (entry == NULL)
return NULL;
entry->namelen = len;
memcpy (entry->name, ascic, len);
entry->name[len] = 0;
entry->owner = abfd;
if (!add_symbol_entry (abfd, entry))
return NULL;
return entry;
}
/* Read and process EGSD. Return FALSE on failure. */
static bfd_boolean
_bfd_vms_slurp_egsd (bfd *abfd)
{
int gsd_type, gsd_size;
unsigned char *vms_rec;
unsigned long base_addr;
vms_debug2 ((2, "EGSD\n"));
PRIV (recrd.rec) += 8; /* Skip type, size, align pad. */
PRIV (recrd.rec_size) -= 8;
/* Calculate base address for each section. */
base_addr = 0L;
while (PRIV (recrd.rec_size) > 0)
{
vms_rec = PRIV (recrd.rec);
gsd_type = bfd_getl16 (vms_rec);
gsd_size = bfd_getl16 (vms_rec + 2);
vms_debug2 ((3, "egsd_type %d\n", gsd_type));
switch (gsd_type)
{
case EGSD__C_PSC:
/* Program section definition. */
{
struct vms_egps *egps = (struct vms_egps *)vms_rec;
flagword new_flags, old_flags;
asection *section;
old_flags = bfd_getl16 (egps->flags);
if ((old_flags & EGPS__V_REL) == 0)
{
/* Use the global absolute section for all absolute sections. */
section = bfd_abs_section_ptr;
}
else
{
char *name;
unsigned long align_addr;
name = _bfd_vms_save_counted_string (&egps->namlng);
section = bfd_make_section (abfd, name);
if (!section)
return FALSE;
section->filepos = 0;
section->size = bfd_getl32 (egps->alloc);
section->alignment_power = egps->align;
vms_section_data (section)->flags = old_flags;
vms_section_data (section)->no_flags = 0;
new_flags = vms_secflag_by_name (evax_section_flags, name,
section->size > 0);
if (!(old_flags & EGPS__V_NOMOD) && section->size > 0)
{
new_flags |= SEC_HAS_CONTENTS;
if (old_flags & EGPS__V_REL)
new_flags |= SEC_RELOC;
}
if (!bfd_set_section_flags (abfd, section, new_flags))
return FALSE;
/* Give a non-overlapping vma to non absolute sections. */
align_addr = (1 << section->alignment_power);
if ((base_addr % align_addr) != 0)
base_addr += (align_addr - (base_addr % align_addr));
section->vma = (bfd_vma)base_addr;
base_addr += section->size;
}
/* Append it to the section array. */
if (PRIV (section_count) >= PRIV (section_max))
{
if (PRIV (section_max) == 0)
PRIV (section_max) = 16;
else
PRIV (section_max) *= 2;
PRIV (sections) = bfd_realloc_or_free
(PRIV (sections), PRIV (section_max) * sizeof (asection *));
if (PRIV (sections) == NULL)
return FALSE;
}
PRIV (sections)[PRIV (section_count)] = section;
PRIV (section_count)++;
}
break;
case EGSD__C_SYM:
{
int nameoff;
struct vms_symbol_entry *entry;
struct vms_egsy *egsy = (struct vms_egsy *) vms_rec;
flagword old_flags;
old_flags = bfd_getl16 (egsy->flags);
if (old_flags & EGSY__V_DEF)
nameoff = ESDF__B_NAMLNG;
else
nameoff = ESRF__B_NAMLNG;
entry = add_symbol (abfd, vms_rec + nameoff);
if (entry == NULL)
return FALSE;
/* Allow only duplicate reference. */
if ((entry->flags & EGSY__V_DEF) && (old_flags & EGSY__V_DEF))
abort ();
if (entry->typ == 0)
{
entry->typ = gsd_type;
entry->data_type = egsy->datyp;
entry->flags = old_flags;
}
if (old_flags & EGSY__V_DEF)
{
struct vms_esdf *esdf = (struct vms_esdf *)vms_rec;
entry->value = bfd_getl64 (esdf->value);
entry->section = PRIV (sections)[bfd_getl32 (esdf->psindx)];
if (old_flags & EGSY__V_NORM)
{
PRIV (norm_sym_count)++;
entry->code_value = bfd_getl64 (esdf->code_address);
entry->code_section =
PRIV (sections)[bfd_getl32 (esdf->ca_psindx)];
}
}
}
break;
case EGSD__C_SYMG:
{
struct vms_symbol_entry *entry;
struct vms_egst *egst = (struct vms_egst *)vms_rec;
flagword old_flags;
old_flags = bfd_getl16 (egst->header.flags);
entry = add_symbol (abfd, &egst->namlng);
if (entry == NULL)
return FALSE;
entry->typ = gsd_type;
entry->data_type = egst->header.datyp;
entry->flags = old_flags;
entry->symbol_vector = bfd_getl32 (egst->value);
if (old_flags & EGSY__V_REL)
entry->section = PRIV (sections)[bfd_getl32 (egst->psindx)];
else
entry->section = bfd_abs_section_ptr;
entry->value = bfd_getl64 (egst->lp_2);
if (old_flags & EGSY__V_NORM)
{
PRIV (norm_sym_count)++;
entry->code_value = bfd_getl64 (egst->lp_1);
entry->code_section = bfd_abs_section_ptr;
}
}
break;
case EGSD__C_SPSC:
case EGSD__C_IDC:
/* Currently ignored. */
break;
case EGSD__C_SYMM:
case EGSD__C_SYMV:
default:
(*_bfd_error_handler) (_("Unknown EGSD subtype %d"), gsd_type);
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
PRIV (recrd.rec_size) -= gsd_size;
PRIV (recrd.rec) += gsd_size;
}
if (PRIV (gsd_sym_count) > 0)
abfd->flags |= HAS_SYMS;
return TRUE;
}
/* Stack routines for vms ETIR commands. */
/* Push value and section index. */
static void
_bfd_vms_push (bfd *abfd, bfd_vma val, unsigned int reloc)
{
vms_debug2 ((4, "<push %08lx (0x%08x) at %d>\n",
(unsigned long)val, reloc, PRIV (stackptr)));
PRIV (stack[PRIV (stackptr)]).value = val;
PRIV (stack[PRIV (stackptr)]).reloc = reloc;
PRIV (stackptr)++;
if (PRIV (stackptr) >= STACKSIZE)
{
bfd_set_error (bfd_error_bad_value);
(*_bfd_error_handler) (_("Stack overflow (%d) in _bfd_vms_push"), PRIV (stackptr));
exit (1);
}
}
/* Pop value and section index. */
static void
_bfd_vms_pop (bfd *abfd, bfd_vma *val, unsigned int *rel)
{
if (PRIV (stackptr) == 0)
{
bfd_set_error (bfd_error_bad_value);
(*_bfd_error_handler) (_("Stack underflow in _bfd_vms_pop"));
exit (1);
}
PRIV (stackptr)--;
*val = PRIV (stack[PRIV (stackptr)]).value;
*rel = PRIV (stack[PRIV (stackptr)]).reloc;
vms_debug2 ((4, "<pop %08lx (0x%08x)>\n", (unsigned long)*val, *rel));
}
/* Routines to fill sections contents during tir/etir read. */
/* Initialize image buffer pointer to be filled. */
static void
image_set_ptr (bfd *abfd, bfd_vma vma, int sect, struct bfd_link_info *info)
{
asection *sec;
vms_debug2 ((4, "image_set_ptr (0x%08x, sect=%d)\n", (unsigned)vma, sect));
sec = PRIV (sections)[sect];
if (info)
{
/* Reading contents to an output bfd. */
if (sec->output_section == NULL)
{
/* Section discarded. */
vms_debug2 ((5, " section %s discarded\n", sec->name));
/* This is not used. */
PRIV (image_section) = NULL;
PRIV (image_offset) = 0;
return;
}
PRIV (image_offset) = sec->output_offset + vma;
PRIV (image_section) = sec->output_section;
}
else
{
PRIV (image_offset) = vma;
PRIV (image_section) = sec;
}
}
/* Increment image buffer pointer by offset. */
static void
image_inc_ptr (bfd *abfd, bfd_vma offset)
{
vms_debug2 ((4, "image_inc_ptr (%u)\n", (unsigned)offset));
PRIV (image_offset) += offset;
}
/* Save current DST location counter under specified index. */
static void
dst_define_location (bfd *abfd, unsigned int loc)
{
vms_debug2 ((4, "dst_define_location (%d)\n", (int)loc));
/* Grow the ptr offset table if necessary. */
if (loc + 1 > PRIV (dst_ptr_offsets_count))
{
PRIV (dst_ptr_offsets) = bfd_realloc (PRIV (dst_ptr_offsets),
(loc + 1) * sizeof (unsigned int));
PRIV (dst_ptr_offsets_count) = loc + 1;
}
PRIV (dst_ptr_offsets)[loc] = PRIV (image_offset);
}
/* Restore saved DST location counter from specified index. */
static void
dst_restore_location (bfd *abfd, unsigned int loc)
{
vms_debug2 ((4, "dst_restore_location (%d)\n", (int)loc));
PRIV (image_offset) = PRIV (dst_ptr_offsets)[loc];
}
/* Retrieve saved DST location counter from specified index. */
static unsigned int
dst_retrieve_location (bfd *abfd, unsigned int loc)
{
vms_debug2 ((4, "dst_retrieve_location (%d)\n", (int)loc));
return PRIV (dst_ptr_offsets)[loc];
}
/* Write multiple bytes to section image. */
static bfd_boolean
image_write (bfd *abfd, unsigned char *ptr, int size)
{
#if VMS_DEBUG
_bfd_vms_debug (8, "image_write from (%p, %d) to (%ld)\n", ptr, size,
(long)PRIV (image_offset));
_bfd_hexdump (9, ptr, size, 0);
#endif
if (PRIV (image_section)->contents != NULL)
{
asection *sec = PRIV (image_section);
file_ptr off = PRIV (image_offset);
/* Check bounds. */
if (off > (file_ptr)sec->size
|| size > (file_ptr)sec->size
|| off + size > (file_ptr)sec->size)
{
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
memcpy (sec->contents + off, ptr, size);
}
PRIV (image_offset) += size;
return TRUE;
}
/* Write byte to section image. */
static bfd_boolean
image_write_b (bfd * abfd, unsigned int value)
{
unsigned char data[1];
vms_debug2 ((6, "image_write_b (%02x)\n", (int) value));
*data = value;
return image_write (abfd, data, sizeof (data));
}
/* Write 2-byte word to image. */
static bfd_boolean
image_write_w (bfd * abfd, unsigned int value)
{
unsigned char data[2];
vms_debug2 ((6, "image_write_w (%04x)\n", (int) value));
bfd_putl16 (value, data);
return image_write (abfd, data, sizeof (data));
}
/* Write 4-byte long to image. */
static bfd_boolean
image_write_l (bfd * abfd, unsigned long value)
{
unsigned char data[4];
vms_debug2 ((6, "image_write_l (%08lx)\n", value));
bfd_putl32 (value, data);
return image_write (abfd, data, sizeof (data));
}
/* Write 8-byte quad to image. */
static bfd_boolean
image_write_q (bfd * abfd, bfd_vma value)
{
unsigned char data[8];
vms_debug2 ((6, "image_write_q (%08lx)\n", (unsigned long)value));
bfd_putl64 (value, data);
return image_write (abfd, data, sizeof (data));
}
static const char *
_bfd_vms_etir_name (int cmd)
{
switch (cmd)
{
case ETIR__C_STA_GBL: return "ETIR__C_STA_GBL";
case ETIR__C_STA_LW: return "ETIR__C_STA_LW";
case ETIR__C_STA_QW: return "ETIR__C_STA_QW";
case ETIR__C_STA_PQ: return "ETIR__C_STA_PQ";
case ETIR__C_STA_LI: return "ETIR__C_STA_LI";
case ETIR__C_STA_MOD: return "ETIR__C_STA_MOD";
case ETIR__C_STA_CKARG: return "ETIR__C_STA_CKARG";
case ETIR__C_STO_B: return "ETIR__C_STO_B";
case ETIR__C_STO_W: return "ETIR__C_STO_W";
case ETIR__C_STO_GBL: return "ETIR__C_STO_GBL";
case ETIR__C_STO_CA: return "ETIR__C_STO_CA";
case ETIR__C_STO_RB: return "ETIR__C_STO_RB";
case ETIR__C_STO_AB: return "ETIR__C_STO_AB";
case ETIR__C_STO_OFF: return "ETIR__C_STO_OFF";
case ETIR__C_STO_IMM: return "ETIR__C_STO_IMM";
case ETIR__C_STO_IMMR: return "ETIR__C_STO_IMMR";
case ETIR__C_STO_LW: return "ETIR__C_STO_LW";
case ETIR__C_STO_QW: return "ETIR__C_STO_QW";
case ETIR__C_STO_GBL_LW: return "ETIR__C_STO_GBL_LW";
case ETIR__C_STO_LP_PSB: return "ETIR__C_STO_LP_PSB";
case ETIR__C_STO_HINT_GBL: return "ETIR__C_STO_HINT_GBL";
case ETIR__C_STO_HINT_PS: return "ETIR__C_STO_HINT_PS";
case ETIR__C_OPR_ADD: return "ETIR__C_OPR_ADD";
case ETIR__C_OPR_SUB: return "ETIR__C_OPR_SUB";
case ETIR__C_OPR_INSV: return "ETIR__C_OPR_INSV";
case ETIR__C_OPR_USH: return "ETIR__C_OPR_USH";
case ETIR__C_OPR_ROT: return "ETIR__C_OPR_ROT";
case ETIR__C_OPR_REDEF: return "ETIR__C_OPR_REDEF";
case ETIR__C_OPR_DFLIT: return "ETIR__C_OPR_DFLIT";
case ETIR__C_STC_LP: return "ETIR__C_STC_LP";
case ETIR__C_STC_GBL: return "ETIR__C_STC_GBL";
case ETIR__C_STC_GCA: return "ETIR__C_STC_GCA";
case ETIR__C_STC_PS: return "ETIR__C_STC_PS";
case ETIR__C_STC_NBH_PS: return "ETIR__C_STC_NBH_PS";
case ETIR__C_STC_NOP_GBL: return "ETIR__C_STC_NOP_GBL";
case ETIR__C_STC_NOP_PS: return "ETIR__C_STC_NOP_PS";
case ETIR__C_STC_BSR_GBL: return "ETIR__C_STC_BSR_GBL";
case ETIR__C_STC_BSR_PS: return "ETIR__C_STC_BSR_PS";
case ETIR__C_STC_LDA_GBL: return "ETIR__C_STC_LDA_GBL";
case ETIR__C_STC_LDA_PS: return "ETIR__C_STC_LDA_PS";
case ETIR__C_STC_BOH_GBL: return "ETIR__C_STC_BOH_GBL";
case ETIR__C_STC_BOH_PS: return "ETIR__C_STC_BOH_PS";
case ETIR__C_STC_NBH_GBL: return "ETIR__C_STC_NBH_GBL";
case ETIR__C_STC_LP_PSB: return "ETIR__C_STC_LP_PSB";
case ETIR__C_CTL_SETRB: return "ETIR__C_CTL_SETRB";
case ETIR__C_CTL_AUGRB: return "ETIR__C_CTL_AUGRB";
case ETIR__C_CTL_DFLOC: return "ETIR__C_CTL_DFLOC";
case ETIR__C_CTL_STLOC: return "ETIR__C_CTL_STLOC";
case ETIR__C_CTL_STKDL: return "ETIR__C_CTL_STKDL";
default:
/* These names have not yet been added to this switch statement. */
(*_bfd_error_handler) (_("unknown ETIR command %d"), cmd);
}
return NULL;
}
#define HIGHBIT(op) ((op & 0x80000000L) == 0x80000000L)
static void
_bfd_vms_get_value (bfd *abfd, const unsigned char *ascic,
struct bfd_link_info *info,
bfd_vma *vma,
struct alpha_vms_link_hash_entry **hp)
{
char name[257];
int len;
int i;
struct alpha_vms_link_hash_entry *h;
/* Not linking. Do not try to resolve the symbol. */
if (info == NULL)
{
*vma = 0;
*hp = NULL;
return;
}
len = *ascic;
for (i = 0; i < len; i++)
name[i] = ascic[i + 1];
name[i] = 0;
h = (struct alpha_vms_link_hash_entry *)
bfd_link_hash_lookup (info->hash, name, FALSE, FALSE, TRUE);
*hp = h;
if (h != NULL
&& (h->root.type == bfd_link_hash_defined
|| h->root.type == bfd_link_hash_defweak))
*vma = h->root.u.def.value
+ h->root.u.def.section->output_offset
+ h->root.u.def.section->output_section->vma;
else if (h && h->root.type == bfd_link_hash_undefweak)
*vma = 0;
else
{
if (!(*info->callbacks->undefined_symbol)
(info, name, abfd, PRIV (image_section), PRIV (image_offset), TRUE))
abort ();
*vma = 0;
}
}
#define RELC_NONE 0
#define RELC_REL 1
#define RELC_SHR_BASE 0x10000
#define RELC_SEC_BASE 0x20000
#define RELC_MASK 0x0ffff
static unsigned int
alpha_vms_sym_to_ctxt (struct alpha_vms_link_hash_entry *h)
{
/* Handle undefined symbols. */
if (h == NULL || h->sym == NULL)
return RELC_NONE;
if (h->sym->typ == EGSD__C_SYMG)
{
if (h->sym->flags & EGSY__V_REL)
return RELC_SHR_BASE + PRIV2 (h->sym->owner, shr_index);
else
{
/* Can this happen (non-relocatable symg) ? I'd like to see
an example. */
abort ();
}
}
if (h->sym->typ == EGSD__C_SYM)
{
if (h->sym->flags & EGSY__V_REL)
return RELC_REL;
else
return RELC_NONE;
}
abort ();
}
static bfd_vma
alpha_vms_get_sym_value (asection *sect, bfd_vma addr)
{
return sect->output_section->vma + sect->output_offset + addr;
}
static bfd_vma
alpha_vms_fix_sec_rel (bfd *abfd, struct bfd_link_info *info,
unsigned int rel, bfd_vma vma)
{
asection *sec = PRIV (sections)[rel & RELC_MASK];
if (info)
{
if (sec->output_section == NULL)
abort ();
return vma + sec->output_section->vma + sec->output_offset;
}
else
return vma + sec->vma;
}
/* Read an ETIR record from ABFD. If INFO is not null, put the content into
the output section (used during linking).
Return FALSE in case of error. */
static bfd_boolean
_bfd_vms_slurp_etir (bfd *abfd, struct bfd_link_info *info)
{
unsigned char *ptr;
unsigned int length;
unsigned char *maxptr;
bfd_vma op1;
bfd_vma op2;
unsigned int rel1;
unsigned int rel2;
struct alpha_vms_link_hash_entry *h;
PRIV (recrd.rec) += ETIR__C_HEADER_SIZE;
PRIV (recrd.rec_size) -= ETIR__C_HEADER_SIZE;
ptr = PRIV (recrd.rec);
length = PRIV (recrd.rec_size);
maxptr = ptr + length;
vms_debug2 ((2, "ETIR: %d bytes\n", length));
while (ptr < maxptr)
{
int cmd = bfd_getl16 (ptr);
int cmd_length = bfd_getl16 (ptr + 2);
ptr += 4;
#if VMS_DEBUG
_bfd_vms_debug (4, "etir: %s(%d)\n",
_bfd_vms_etir_name (cmd), cmd);
_bfd_hexdump (8, ptr, cmd_length - 4, (intptr_t) ptr);
#endif
switch (cmd)
{
/* Stack global
arg: cs symbol name
stack 32 bit value of symbol (high bits set to 0). */
case ETIR__C_STA_GBL:
_bfd_vms_get_value (abfd, ptr, info, &op1, &h);
_bfd_vms_push (abfd, op1, alpha_vms_sym_to_ctxt (h));
break;
/* Stack longword
arg: lw value
stack 32 bit value, sign extend to 64 bit. */
case ETIR__C_STA_LW:
_bfd_vms_push (abfd, bfd_getl32 (ptr), RELC_NONE);
break;
/* Stack quadword
arg: qw value
stack 64 bit value of symbol. */
case ETIR__C_STA_QW:
_bfd_vms_push (abfd, bfd_getl64 (ptr), RELC_NONE);
break;
/* Stack psect base plus quadword offset
arg: lw section index
qw signed quadword offset (low 32 bits)
Stack qw argument and section index
(see ETIR__C_STO_OFF, ETIR__C_CTL_SETRB). */
case ETIR__C_STA_PQ:
{
int psect;
psect = bfd_getl32 (ptr);
if ((unsigned int) psect >= PRIV (section_count))
{
(*_bfd_error_handler) (_("bad section index in %s"),
_bfd_vms_etir_name (cmd));
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
op1 = bfd_getl64 (ptr + 4);
_bfd_vms_push (abfd, op1, psect | RELC_SEC_BASE);
}
break;
case ETIR__C_STA_LI:
case ETIR__C_STA_MOD:
case ETIR__C_STA_CKARG:
(*_bfd_error_handler) (_("unsupported STA cmd %s"),
_bfd_vms_etir_name (cmd));
return FALSE;
break;
/* Store byte: pop stack, write byte
arg: -. */
case ETIR__C_STO_B:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
image_write_b (abfd, (unsigned int) op1 & 0xff);
break;
/* Store word: pop stack, write word
arg: -. */
case ETIR__C_STO_W:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
image_write_w (abfd, (unsigned int) op1 & 0xffff);
break;
/* Store longword: pop stack, write longword
arg: -. */
case ETIR__C_STO_LW:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 & RELC_SEC_BASE)
{
op1 = alpha_vms_fix_sec_rel (abfd, info, rel1, op1);
rel1 = RELC_REL;
}
else if (rel1 & RELC_SHR_BASE)
{
alpha_vms_add_fixup_lr (info, rel1 & RELC_MASK, op1);
rel1 = RELC_NONE;
}
if (rel1 != RELC_NONE)
{
if (rel1 != RELC_REL)
abort ();
alpha_vms_add_lw_reloc (info);
}
image_write_l (abfd, op1);
break;
/* Store quadword: pop stack, write quadword
arg: -. */
case ETIR__C_STO_QW:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 & RELC_SEC_BASE)
{
op1 = alpha_vms_fix_sec_rel (abfd, info, rel1, op1);
rel1 = RELC_REL;
}
else if (rel1 & RELC_SHR_BASE)
abort ();
if (rel1 != RELC_NONE)
{
if (rel1 != RELC_REL)
abort ();
alpha_vms_add_qw_reloc (info);
}
image_write_q (abfd, op1);
break;
/* Store immediate repeated: pop stack for repeat count
arg: lw byte count
da data. */
case ETIR__C_STO_IMMR:
{
int size;
size = bfd_getl32 (ptr);
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
while (op1-- > 0)
image_write (abfd, ptr + 4, size);
}
break;
/* Store global: write symbol value
arg: cs global symbol name. */
case ETIR__C_STO_GBL:
_bfd_vms_get_value (abfd, ptr, info, &op1, &h);
if (h && h->sym)
{
if (h->sym->typ == EGSD__C_SYMG)
{
alpha_vms_add_fixup_qr
(info, abfd, h->sym->owner, h->sym->symbol_vector);
op1 = 0;
}
else
{
op1 = alpha_vms_get_sym_value (h->sym->section,
h->sym->value);
alpha_vms_add_qw_reloc (info);
}
}
image_write_q (abfd, op1);
break;
/* Store code address: write address of entry point
arg: cs global symbol name (procedure). */
case ETIR__C_STO_CA:
_bfd_vms_get_value (abfd, ptr, info, &op1, &h);
if (h && h->sym)
{
if (h->sym->flags & EGSY__V_NORM)
{
/* That's really a procedure. */
if (h->sym->typ == EGSD__C_SYMG)
{
alpha_vms_add_fixup_ca (info, abfd, h->sym->owner);
op1 = h->sym->symbol_vector;
}
else
{
op1 = alpha_vms_get_sym_value (h->sym->code_section,
h->sym->code_value);
alpha_vms_add_qw_reloc (info);
}
}
else
{
/* Symbol is not a procedure. */
abort ();
}
}
image_write_q (abfd, op1);
break;
/* Store offset to psect: pop stack, add low 32 bits to base of psect
arg: none. */
case ETIR__C_STO_OFF:
_bfd_vms_pop (abfd, &op1, &rel1);
if (!(rel1 & RELC_SEC_BASE))
abort ();
op1 = alpha_vms_fix_sec_rel (abfd, info, rel1, op1);
rel1 = RELC_REL;
image_write_q (abfd, op1);
break;
/* Store immediate
arg: lw count of bytes
da data. */
case ETIR__C_STO_IMM:
{
int size;
size = bfd_getl32 (ptr);
image_write (abfd, ptr + 4, size);
}
break;
/* This code is 'reserved to digital' according to the openVMS
linker manual, however it is generated by the DEC C compiler
and defined in the include file.
FIXME, since the following is just a guess
store global longword: store 32bit value of symbol
arg: cs symbol name. */
case ETIR__C_STO_GBL_LW:
_bfd_vms_get_value (abfd, ptr, info, &op1, &h);
#if 0
abort ();
#endif
image_write_l (abfd, op1);
break;
case ETIR__C_STO_RB:
case ETIR__C_STO_AB:
case ETIR__C_STO_LP_PSB:
(*_bfd_error_handler) (_("%s: not supported"),
_bfd_vms_etir_name (cmd));
return FALSE;
break;
case ETIR__C_STO_HINT_GBL:
case ETIR__C_STO_HINT_PS:
(*_bfd_error_handler) (_("%s: not implemented"),
_bfd_vms_etir_name (cmd));
return FALSE;
break;
/* 200 Store-conditional Linkage Pair
arg: none. */
case ETIR__C_STC_LP:
/* 202 Store-conditional Address at global address
lw linkage index
cs global name. */
case ETIR__C_STC_GBL:
/* 203 Store-conditional Code Address at global address
lw linkage index
cs procedure name. */
case ETIR__C_STC_GCA:
/* 204 Store-conditional Address at psect + offset
lw linkage index
lw psect index
qw offset. */
case ETIR__C_STC_PS:
(*_bfd_error_handler) (_("%s: not supported"),
_bfd_vms_etir_name (cmd));
return FALSE;
break;
/* 201 Store-conditional Linkage Pair with Procedure Signature
lw linkage index
cs procedure name
by signature length
da signature. */
case ETIR__C_STC_LP_PSB:
_bfd_vms_get_value (abfd, ptr + 4, info, &op1, &h);
if (h && h->sym)
{
if (h->sym->typ == EGSD__C_SYMG)
{
alpha_vms_add_fixup_lp (info, abfd, h->sym->owner);
op1 = h->sym->symbol_vector;
op2 = 0;
}
else
{
op1 = alpha_vms_get_sym_value (h->sym->code_section,
h->sym->code_value);
op2 = alpha_vms_get_sym_value (h->sym->section,
h->sym->value);
}
}
else
{
/* Undefined symbol. */
op1 = 0;
op2 = 0;
}
image_write_q (abfd, op1);
image_write_q (abfd, op2);
break;
/* 205 Store-conditional NOP at address of global
arg: none. */
case ETIR__C_STC_NOP_GBL:
/* ALPHA_R_NOP */
/* 207 Store-conditional BSR at global address
arg: none. */
case ETIR__C_STC_BSR_GBL:
/* ALPHA_R_BSR */
/* 209 Store-conditional LDA at global address
arg: none. */
case ETIR__C_STC_LDA_GBL:
/* ALPHA_R_LDA */
/* 211 Store-conditional BSR or Hint at global address
arg: none. */
case ETIR__C_STC_BOH_GBL:
/* Currentl ignored. */
break;
/* 213 Store-conditional NOP,BSR or HINT at global address
arg: none. */
case ETIR__C_STC_NBH_GBL:
/* 206 Store-conditional NOP at pect + offset
arg: none. */
case ETIR__C_STC_NOP_PS:
/* 208 Store-conditional BSR at pect + offset
arg: none. */
case ETIR__C_STC_BSR_PS:
/* 210 Store-conditional LDA at psect + offset
arg: none. */
case ETIR__C_STC_LDA_PS:
/* 212 Store-conditional BSR or Hint at pect + offset
arg: none. */
case ETIR__C_STC_BOH_PS:
/* 214 Store-conditional NOP, BSR or HINT at psect + offset
arg: none. */
case ETIR__C_STC_NBH_PS:
(*_bfd_error_handler) ("%s: not supported",
_bfd_vms_etir_name (cmd));
return FALSE;
break;
/* Det relocation base: pop stack, set image location counter
arg: none. */
case ETIR__C_CTL_SETRB:
_bfd_vms_pop (abfd, &op1, &rel1);
if (!(rel1 & RELC_SEC_BASE))
abort ();
image_set_ptr (abfd, op1, rel1 & RELC_MASK, info);
break;
/* Augment relocation base: increment image location counter by offset
arg: lw offset value. */
case ETIR__C_CTL_AUGRB:
op1 = bfd_getl32 (ptr);
image_inc_ptr (abfd, op1);
break;
/* Define location: pop index, save location counter under index
arg: none. */
case ETIR__C_CTL_DFLOC:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
dst_define_location (abfd, op1);
break;
/* Set location: pop index, restore location counter from index
arg: none. */
case ETIR__C_CTL_STLOC:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
dst_restore_location (abfd, op1);
break;
/* Stack defined location: pop index, push location counter from index
arg: none. */
case ETIR__C_CTL_STKDL:
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, dst_retrieve_location (abfd, op1), RELC_NONE);
break;
case ETIR__C_OPR_NOP: /* No-op. */
break;
case ETIR__C_OPR_ADD: /* Add. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 == RELC_NONE && rel2 != RELC_NONE)
rel1 = rel2;
else if (rel1 != RELC_NONE && rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op1 + op2, rel1);
break;
case ETIR__C_OPR_SUB: /* Subtract. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 == RELC_NONE && rel2 != RELC_NONE)
rel1 = rel2;
else if ((rel1 & RELC_SEC_BASE) && (rel2 & RELC_SEC_BASE))
{
op1 = alpha_vms_fix_sec_rel (abfd, info, rel1, op1);
op2 = alpha_vms_fix_sec_rel (abfd, info, rel2, op2);
rel1 = RELC_NONE;
}
else if (rel1 != RELC_NONE && rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op2 - op1, rel1);
break;
case ETIR__C_OPR_MUL: /* Multiply. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op1 * op2, RELC_NONE);
break;
case ETIR__C_OPR_DIV: /* Divide. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
goto bad_context;
if (op2 == 0)
_bfd_vms_push (abfd, 0, RELC_NONE);
else
_bfd_vms_push (abfd, op2 / op1, RELC_NONE);
break;
case ETIR__C_OPR_AND: /* Logical AND. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op1 & op2, RELC_NONE);
break;
case ETIR__C_OPR_IOR: /* Logical inclusive OR. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op1 | op2, RELC_NONE);
break;
case ETIR__C_OPR_EOR: /* Logical exclusive OR. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, op1 ^ op2, RELC_NONE);
break;
case ETIR__C_OPR_NEG: /* Negate. */
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, -op1, RELC_NONE);
break;
case ETIR__C_OPR_COM: /* Complement. */
_bfd_vms_pop (abfd, &op1, &rel1);
if (rel1 != RELC_NONE)
goto bad_context;
_bfd_vms_push (abfd, ~op1, RELC_NONE);
break;
case ETIR__C_OPR_ASH: /* Arithmetic shift. */
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
if (rel1 != RELC_NONE || rel2 != RELC_NONE)
{
bad_context:
(*_bfd_error_handler) (_("invalid use of %s with contexts"),
_bfd_vms_etir_name (cmd));
return FALSE;
}
if ((int)op2 < 0) /* Shift right. */
op1 >>= -(int)op2;
else /* Shift left. */
op1 <<= (int)op2;
_bfd_vms_push (abfd, op1, RELC_NONE); /* FIXME: sym. */
break;
case ETIR__C_OPR_INSV: /* Insert field. */
case ETIR__C_OPR_USH: /* Unsigned shift. */
case ETIR__C_OPR_ROT: /* Rotate. */
case ETIR__C_OPR_REDEF: /* Redefine symbol to current location. */
case ETIR__C_OPR_DFLIT: /* Define a literal. */
(*_bfd_error_handler) (_("%s: not supported"),
_bfd_vms_etir_name (cmd));
return FALSE;
break;
case ETIR__C_OPR_SEL: /* Select. */
_bfd_vms_pop (abfd, &op1, &rel1);
if (op1 & 0x01L)
_bfd_vms_pop (abfd, &op1, &rel1);
else
{
_bfd_vms_pop (abfd, &op1, &rel1);
_bfd_vms_pop (abfd, &op2, &rel2);
_bfd_vms_push (abfd, op1, rel1);
}
break;
default:
(*_bfd_error_handler) (_("reserved cmd %d"), cmd);
return FALSE;
break;
}
ptr += cmd_length - 4;
}
return TRUE;
}
/* Process EDBG/ETBT record.
Return TRUE on success, FALSE on error */
static bfd_boolean
vms_slurp_debug (bfd *abfd)
{
asection *section = PRIV (dst_section);
if (section == NULL)
{
/* We have no way to find out beforehand how much debug info there
is in an object file, so pick an initial amount and grow it as
needed later. */
flagword flags = SEC_HAS_CONTENTS | SEC_DEBUGGING | SEC_RELOC
| SEC_IN_MEMORY;
section = bfd_make_section (abfd, "$DST$");
if (!section)
return FALSE;
if (!bfd_set_section_flags (abfd, section, flags))
return FALSE;
PRIV (dst_section) = section;
}
PRIV (image_section) = section;
PRIV (image_offset) = section->size;
if (!_bfd_vms_slurp_etir (abfd, NULL))
return FALSE;
section->size = PRIV (image_offset);
return TRUE;
}
/* Process EDBG record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_edbg (bfd *abfd)
{
vms_debug2 ((2, "EDBG\n"));
abfd->flags |= HAS_DEBUG | HAS_LINENO;
return vms_slurp_debug (abfd);
}
/* Process ETBT record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_etbt (bfd *abfd)
{
vms_debug2 ((2, "ETBT\n"));
abfd->flags |= HAS_LINENO;
return vms_slurp_debug (abfd);
}
/* Process EEOM record.
Return TRUE on success, FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_eeom (bfd *abfd)
{
struct vms_eeom *eeom = (struct vms_eeom *) PRIV (recrd.rec);
vms_debug2 ((2, "EEOM\n"));
PRIV (eom_data).eom_l_total_lps = bfd_getl32 (eeom->total_lps);
PRIV (eom_data).eom_w_comcod = bfd_getl16 (eeom->comcod);
if (PRIV (eom_data).eom_w_comcod > 1)
{
(*_bfd_error_handler) (_("Object module NOT error-free !\n"));
bfd_set_error (bfd_error_bad_value);
return FALSE;
}
PRIV (eom_data).eom_has_transfer = FALSE;
if (PRIV (recrd.rec_size) > 10)
{
PRIV (eom_data).eom_has_transfer = TRUE;
PRIV (eom_data).eom_b_tfrflg = eeom->tfrflg;
PRIV (eom_data).eom_l_psindx = bfd_getl32 (eeom->psindx);
PRIV (eom_data).eom_l_tfradr = bfd_getl32 (eeom->tfradr);
abfd->start_address = PRIV (eom_data).eom_l_tfradr;
}
return TRUE;
}
/* Slurp an ordered set of VMS object records. Return FALSE on error. */
static bfd_boolean
_bfd_vms_slurp_object_records (bfd * abfd)
{
bfd_boolean err;
int type;
do
{
vms_debug2 ((7, "reading at %08lx\n", (unsigned long)bfd_tell (abfd)));
type = _bfd_vms_get_object_record (abfd);
if (type < 0)
{
vms_debug2 ((2, "next_record failed\n"));
return FALSE;
}
switch (type)
{
case EOBJ__C_EMH:
err = _bfd_vms_slurp_ehdr (abfd);
break;
case EOBJ__C_EEOM:
err = _bfd_vms_slurp_eeom (abfd);
break;
case EOBJ__C_EGSD:
err = _bfd_vms_slurp_egsd (abfd);
break;
case EOBJ__C_ETIR:
err = TRUE; /* _bfd_vms_slurp_etir (abfd); */
break;
case EOBJ__C_EDBG:
err = _bfd_vms_slurp_edbg (abfd);
break;
case EOBJ__C_ETBT:
err = _bfd_vms_slurp_etbt (abfd);
break;
default:
err = FALSE;
}
if (err != TRUE)
{
vms_debug2 ((2, "slurp type %d failed\n", type));
return FALSE;
}
}
while (type != EOBJ__C_EEOM);
return TRUE;
}
/* Initialize private data */
static bfd_boolean
vms_initialize (bfd * abfd)
{
bfd_size_type amt;
amt = sizeof (struct vms_private_data_struct);
abfd->tdata.any = bfd_zalloc (abfd, amt);
if (abfd->tdata.any == NULL)
return FALSE;
PRIV (recrd.file_format) = FF_UNKNOWN;
amt = sizeof (struct stack_struct) * STACKSIZE;
PRIV (stack) = bfd_alloc (abfd, amt);
if (PRIV (stack) == NULL)
goto error_ret1;
return TRUE;
error_ret1:
bfd_release (abfd, abfd->tdata.any);
abfd->tdata.any = NULL;
return FALSE;
}
/* Check the format for a file being read.
Return a (bfd_target *) if it's an object file or zero if not. */
static const struct bfd_target *
alpha_vms_object_p (bfd *abfd)
{
PTR tdata_save = abfd->tdata.any;
unsigned int test_len;
unsigned char *buf;
vms_debug2 ((1, "vms_object_p(%p)\n", abfd));
/* Allocate alpha-vms specific data. */
if (!vms_initialize (abfd))
goto error_ret;
if (bfd_seek (abfd, (file_ptr) 0, SEEK_SET))
goto err_wrong_format;
/* The first challenge with VMS is to discover the kind of the file.
Image files (executable or shared images) are stored as a raw
stream of bytes (like on UNIX), but there is no magic number.
Object files are written with RMS (record management service), ie
each records are preceeded by its length (on a word - 2 bytes), and
padded for word-alignment. That would be simple but when files
are transfered to a UNIX filesystem (using ftp), records are lost.
Only the raw content of the records are transfered. Fortunately,
the Alpha Object file format also store the length of the record
in the records. Is that clear ? */
/* Minimum is 6 bytes for objects (2 bytes size, 2 bytes record id,
2 bytes size repeated) and 12 bytes for images (4 bytes major id,
4 bytes minor id, 4 bytes length). */
test_len = 12;
/* Size the main buffer. */
buf = (unsigned char *) bfd_malloc (test_len);
if (buf == NULL)
goto error_ret;
PRIV (recrd.buf) = buf;
PRIV (recrd.buf_size) = test_len;
/* Initialize the record pointer. */
PRIV (recrd.rec) = buf;
if (bfd_bread (buf, test_len, abfd) != test_len)
{
bfd_set_error (bfd_error_file_truncated);
goto error_ret;
}
/* Is it an image? */
if ((bfd_getl32 (buf) == EIHD__K_MAJORID)
&& (bfd_getl32 (buf + 4) == EIHD__K_MINORID))
{
unsigned int to_read;
unsigned int read_so_far;
unsigned int remaining;
unsigned int eisd_offset, eihs_offset;
/* Extract the header size. */
PRIV (recrd.rec_size) = bfd_getl32 (buf + EIHD__L_SIZE);
/* The header size is 0 for DSF files. */
if (PRIV (recrd.rec_size) == 0)
PRIV (recrd.rec_size) = sizeof (struct vms_eihd);
if (PRIV (recrd.rec_size) > PRIV (recrd.buf_size))
{
buf = bfd_realloc_or_free (buf, PRIV (recrd.rec_size));
if (buf == NULL)
{
PRIV (recrd.buf) = NULL;
bfd_set_error (bfd_error_no_memory);
goto error_ret;
}
PRIV (recrd.buf) = buf;
PRIV (recrd.buf_size) = PRIV (recrd.rec_size);
}
/* Read the remaining record. */
remaining = PRIV (recrd.rec_size) - test_len;
to_read = MIN (VMS_BLOCK_SIZE - test_len, remaining);
read_so_far = test_len;
while (remaining > 0)
{
if (bfd_bread (buf + read_so_far, to_read, abfd) != to_read)
{
bfd_set_error (bfd_error_file_truncated);
goto err_wrong_format;
}
read_so_far += to_read;
remaining -= to_read;
to_read = MIN (VMS_BLOCK_SIZE, remaining);
}
/* Reset the record pointer. */
PRIV (recrd.rec) = buf;
vms_debug2 ((2, "file type is image\n"));
if (_bfd_vms_slurp_eihd (abfd, &eisd_offset, &eihs_offset) != TRUE)
goto err_wrong_format;
if (_bfd_vms_slurp_eisd (abfd, eisd_offset) != TRUE)
goto err_wrong_format;
/* EIHS is optional. */
if (eihs_offset != 0 && _bfd_vms_slurp_eihs (abfd, eihs_offset) != TRUE)
goto err_wrong_format;
}
else
{
int type;
/* Assume it's a module and adjust record pointer if necessary. */
maybe_adjust_record_pointer_for_object (abfd);
/* But is it really a module? */
if (bfd_getl16 (PRIV (recrd.rec)) <= EOBJ__C_MAXRECTYP
&& bfd_getl16 (PRIV (recrd.rec) + 2) <= EOBJ__C_MAXRECSIZ)
{
if (vms_get_remaining_object_record (abfd, test_len) <= 0)
goto err_wrong_format;
vms_debug2 ((2, "file type is module\n"));
type = bfd_getl16 (PRIV (recrd.rec));
if (type != EOBJ__C_EMH || _bfd_vms_slurp_ehdr (abfd) != TRUE)
goto err_wrong_format;
if (_bfd_vms_slurp_object_records (abfd) != TRUE)
goto err_wrong_format;
}
else
goto err_wrong_format;
}
/* Set arch_info to alpha. */
if (! bfd_default_set_arch_mach (abfd, bfd_arch_alpha, 0))
goto err_wrong_format;
return abfd->xvec;
err_wrong_format:
bfd_set_error (bfd_error_wrong_format);
error_ret:
if (PRIV (recrd.buf))
free (PRIV (recrd.buf));
if (abfd->tdata.any != tdata_save && abfd->tdata.any != NULL)
bfd_release (abfd, abfd->tdata.any);
abfd->tdata.any = tdata_save;
return NULL;
}
/* Image write. */
/* Write an EMH/MHD record. */
static void
_bfd_vms_write_emh (bfd *abfd)
{
struct vms_rec_wr *recwr = &PRIV (recwr);
_bfd_vms_output_alignment (recwr, 2);
/* EMH. */
_bfd_vms_output_begin (recwr, EOBJ__C_EMH);
_bfd_vms_output_short (recwr, EMH__C_MHD);
_bfd_vms_output_short (recwr, EOBJ__C_STRLVL);
_bfd_vms_output_long (recwr, 0);
_bfd_vms_output_long (recwr, 0);
_bfd_vms_output_long (recwr, MAX_OUTREC_SIZE);
/* Create module name from filename. */
if (bfd_get_filename (abfd) != 0)
{
char *module = vms_get_module_name (bfd_get_filename (abfd), TRUE);
_bfd_vms_output_counted (recwr, module);
free (module);
}
else
_bfd_vms_output_counted (recwr, "NONAME");
_bfd_vms_output_counted (recwr, BFD_VERSION_STRING);
_bfd_vms_output_dump (recwr, get_vms_time_string (), EMH_DATE_LENGTH);
_bfd_vms_output_fill (recwr, 0, EMH_DATE_LENGTH);
_bfd_vms_output_end (abfd, recwr);
}
/* Write an EMH/LMN record. */
static void
_bfd_vms_write_lmn (bfd *abfd, const char *name)
{
char version [64];
struct vms_rec_wr *recwr = &PRIV (recwr);
unsigned int ver = BFD_VERSION / 10000;
/* LMN. */
_bfd_vms_output_begin (recwr, EOBJ__C_EMH);
_bfd_vms_output_short (recwr, EMH__C_LNM);
snprintf (version, sizeof (version), "%s %d.%d.%d", name,
ver / 10000, (ver / 100) % 100, ver % 100);
_bfd_vms_output_dump (recwr, (unsigned char *)version, strlen (version));
_bfd_vms_output_end (abfd, recwr);
}
/* Write eom record for bfd abfd. Return FALSE on error. */
static bfd_boolean
_bfd_vms_write_eeom (bfd *abfd)
{
struct vms_rec_wr *recwr = &PRIV (recwr);
vms_debug2 ((2, "vms_write_eeom\n"));
_bfd_vms_output_alignment (recwr, 2);
_bfd_vms_output_begin (recwr, EOBJ__C_EEOM);
_bfd_vms_output_long (recwr, (unsigned long) (PRIV (vms_linkage_index) >> 1));
_bfd_vms_output_byte (recwr, 0); /* Completion code. */
_bfd_vms_output_byte (recwr, 0); /* Fill byte. */
if ((abfd->flags & EXEC_P) == 0
&& bfd_get_start_address (abfd) != (bfd_vma)-1)
{
asection *section;
section = bfd_get_section_by_name (abfd, ".link");
if (section == 0)
{
bfd_set_error (bfd_error_nonrepresentable_section);
return FALSE;
}
_bfd_vms_output_short (recwr, 0);
_bfd_vms_output_long (recwr, (unsigned long) section->target_index);
_bfd_vms_output_long (recwr,
(unsigned long) bfd_get_start_address (abfd));
_bfd_vms_output_long (recwr, 0);
}
_bfd_vms_output_end (abfd, recwr);
return TRUE;
}
/* This hash routine borrowed from GNU-EMACS, and strengthened
slightly. ERY. */
static int
hash_string (const char *ptr)
{
const unsigned char *p = (unsigned char *) ptr;
const unsigned char *end = p + strlen (ptr);
unsigned char c;
int hash = 0;
while (p != end)
{
c = *p++;
hash = ((hash << 3) + (hash << 15) + (hash >> 28) + c);
}
return hash;
}
/* Generate a length-hashed VMS symbol name (limited to maxlen chars). */
static char *
_bfd_vms_length_hash_symbol (bfd *abfd, const char *in, int maxlen)
{
unsigned long result;
int in_len;
char *new_name;
const char *old_name;
int i;
static char outbuf[EOBJ__C_SYMSIZ + 1];
char *out = outbuf;
#if VMS_DEBUG
vms_debug (4, "_bfd_vms_length_hash_symbol \"%s\"\n", in);
#endif
if (maxlen > EOBJ__C_SYMSIZ)
maxlen = EOBJ__C_SYMSIZ;
/* Save this for later. */
new_name = out;
/* We may need to truncate the symbol, save the hash for later. */
in_len = strlen (in);
result = (in_len > maxlen) ? hash_string (in) : 0;
old_name = in;
/* Do the length checking. */
if (in_len <= maxlen)
i = in_len;
else
{
if (PRIV (flag_hash_long_names))
i = maxlen - 9;
else
i = maxlen;
}
strncpy (out, in, (size_t) i);
in += i;
out += i;
if ((in_len > maxlen)
&& PRIV (flag_hash_long_names))
sprintf (out, "_%08lx", result);
else
*out = 0;
#if VMS_DEBUG
vms_debug (4, "--> [%d]\"%s\"\n", (int)strlen (outbuf), outbuf);
#endif
if (in_len > maxlen
&& PRIV (flag_hash_long_names)
&& PRIV (flag_show_after_trunc))
printf (_("Symbol %s replaced by %s\n"), old_name, new_name);
return outbuf;
}
static void
vector_grow1 (struct vector_type *vec, size_t elsz)
{
if (vec->nbr_el + 1 < vec->max_el)
return;
if (vec->max_el == 0)
{
vec->max_el = 16;
vec->els = bfd_malloc2 (vec->max_el, elsz);
}
else
{
vec->max_el *= 2;
vec->els = bfd_realloc2 (vec->els, vec->max_el, elsz);
}
}
/* Bump ABFD file position to next block. */
static void
alpha_vms_file_position_block (bfd *abfd)
{
/* Next block. */
PRIV (file_pos) += VMS_BLOCK_SIZE - 1;
PRIV (file_pos) -= (PRIV (file_pos) % VMS_BLOCK_SIZE);
}
/* Convert from internal structure SRC to external structure DST. */
static void
alpha_vms_swap_eisd_out (struct vms_internal_eisd_map *src,
struct vms_eisd *dst)
{
bfd_putl32 (src->u.eisd.majorid, dst->majorid);
bfd_putl32 (src->u.eisd.minorid, dst->minorid);
bfd_putl32 (src->u.eisd.eisdsize, dst->eisdsize);
if (src->u.eisd.eisdsize <= EISD__K_LENEND)
return;
bfd_putl32 (src->u.eisd.secsize, dst->secsize);
bfd_putl64 (src->u.eisd.virt_addr, dst->virt_addr);
bfd_putl32 (src->u.eisd.flags, dst->flags);
bfd_putl32 (src->u.eisd.vbn, dst->vbn);
dst->pfc = src->u.eisd.pfc;
dst->matchctl = src->u.eisd.matchctl;
dst->type = src->u.eisd.type;
dst->fill_1 = 0;
if (src->u.eisd.flags & EISD__M_GBL)
{
bfd_putl32 (src->u.gbl_eisd.ident, dst->ident);
memcpy (dst->gblnam, src->u.gbl_eisd.gblnam,
src->u.gbl_eisd.gblnam[0] + 1);
}
}
/* Append EISD to the list of extra eisd for ABFD. */
static void
alpha_vms_append_extra_eisd (bfd *abfd, struct vms_internal_eisd_map *eisd)
{
eisd->next = NULL;
if (PRIV (gbl_eisd_head) == NULL)
PRIV (gbl_eisd_head) = eisd;
else
PRIV (gbl_eisd_tail)->next = eisd;
PRIV (gbl_eisd_tail) = eisd;
}
/* Create an EISD for shared image SHRIMG.
Return FALSE in case of error. */
static bfd_boolean
alpha_vms_create_eisd_for_shared (bfd *abfd, bfd *shrimg)
{
struct vms_internal_eisd_map *eisd;
int namlen;
namlen = strlen (PRIV2 (shrimg, hdr_data.hdr_t_name));
if (namlen + 5 > EISD__K_GBLNAMLEN)
{
/* Won't fit. */
return FALSE;
}
eisd = bfd_alloc (abfd, sizeof (*eisd));
if (eisd == NULL)
return FALSE;
/* Fill the fields. */
eisd->u.gbl_eisd.common.majorid = EISD__K_MAJORID;
eisd->u.gbl_eisd.common.minorid = EISD__K_MINORID;
eisd->u.gbl_eisd.common.eisdsize = (EISD__K_LEN + 4 + namlen + 5 + 3) & ~3;
eisd->u.gbl_eisd.common.secsize = VMS_BLOCK_SIZE; /* Must not be 0. */
eisd->u.gbl_eisd.common.virt_addr = 0;
eisd->u.gbl_eisd.common.flags = EISD__M_GBL;
eisd->u.gbl_eisd.common.vbn = 0;
eisd->u.gbl_eisd.common.pfc = 0;
eisd->u.gbl_eisd.common.matchctl = PRIV2 (shrimg, matchctl);
eisd->u.gbl_eisd.common.type = EISD__K_SHRPIC;
eisd->u.gbl_eisd.ident = PRIV2 (shrimg, ident);
eisd->u.gbl_eisd.gblnam[0] = namlen + 4;
memcpy (eisd->u.gbl_eisd.gblnam + 1, PRIV2 (shrimg, hdr_data.hdr_t_name),
namlen);
memcpy (eisd->u.gbl_eisd.gblnam + 1 + namlen, "_001", 4);
/* Append it to the list. */
alpha_vms_append_extra_eisd (abfd, eisd);
return TRUE;
}
/* Create an EISD for section SEC.
Return FALSE in case of failure. */
static bfd_boolean
alpha_vms_create_eisd_for_section (bfd *abfd, asection *sec)
{
struct vms_internal_eisd_map *eisd;
/* Only for allocating section. */
if (!(sec->flags & SEC_ALLOC))
return TRUE;
BFD_ASSERT (vms_section_data (sec)->eisd == NULL);
eisd = bfd_alloc (abfd, sizeof (*eisd));
if (eisd == NULL)
return FALSE;
vms_section_data (sec)->eisd = eisd;
/* Fill the fields. */
eisd->u.eisd.majorid = EISD__K_MAJORID;
eisd->u.eisd.minorid = EISD__K_MINORID;
eisd->u.eisd.eisdsize = EISD__K_LEN;
eisd->u.eisd.secsize =
(sec->size + VMS_BLOCK_SIZE - 1) & ~(VMS_BLOCK_SIZE - 1);
eisd->u.eisd.virt_addr = sec->vma;
eisd->u.eisd.flags = 0;
eisd->u.eisd.vbn = 0; /* To be later defined. */
eisd->u.eisd.pfc = 0; /* Default. */
eisd->u.eisd.matchctl = EISD__K_MATALL;
eisd->u.eisd.type = EISD__K_NORMAL;
if (sec->flags & SEC_CODE)
eisd->u.eisd.flags |= EISD__M_EXE;
if (!(sec->flags & SEC_READONLY))
eisd->u.eisd.flags |= EISD__M_WRT | EISD__M_CRF;
/* If relocations or fixup will be applied, make this isect writeable. */
if (sec->flags & SEC_RELOC)
eisd->u.eisd.flags |= EISD__M_WRT | EISD__M_CRF;
if (!(sec->flags & SEC_LOAD))
{
eisd->u.eisd.flags |= EISD__M_DZRO;
eisd->u.eisd.flags &= ~EISD__M_CRF;
}
if (sec->flags & SEC_LINKER_CREATED)
{
if (strcmp (sec->name, "$FIXUP$") == 0)
eisd->u.eisd.flags |= EISD__M_FIXUPVEC;
}
/* Append it to the list. */
eisd->next = NULL;
if (PRIV (eisd_head) == NULL)
PRIV (eisd_head) = eisd;
else
PRIV (eisd_tail)->next = eisd;
PRIV (eisd_tail) = eisd;
return TRUE;
}
/* Layout executable ABFD and write it to the disk.
Return FALSE in case of failure. */
static bfd_boolean
alpha_vms_write_exec (bfd *abfd)
{
struct vms_eihd eihd;
struct vms_eiha *eiha;
struct vms_eihi *eihi;
struct vms_eihs *eihs = NULL;
asection *sec;
struct vms_internal_eisd_map *first_eisd;
struct vms_internal_eisd_map *eisd;
asection *dst;
asection *dmt;
file_ptr gst_filepos = 0;
unsigned int lnkflags = 0;
/* Build the EIHD. */
PRIV (file_pos) = EIHD__C_LENGTH;
memset (&eihd, 0, sizeof (eihd));
memset (eihd.fill_2, 0xff, sizeof (eihd.fill_2));
bfd_putl32 (EIHD__K_MAJORID, eihd.majorid);
bfd_putl32 (EIHD__K_MINORID, eihd.minorid);
bfd_putl32 (sizeof (eihd), eihd.size);
bfd_putl32 (0, eihd.isdoff);
bfd_putl32 (0, eihd.activoff);
bfd_putl32 (0, eihd.symdbgoff);
bfd_putl32 (0, eihd.imgidoff);
bfd_putl32 (0, eihd.patchoff);
bfd_putl64 (0, eihd.iafva);
bfd_putl32 (0, eihd.version_array_off);
bfd_putl32 (EIHD__K_EXE, eihd.imgtype);
bfd_putl32 (0, eihd.subtype);
bfd_putl32 (0, eihd.imgiocnt);
bfd_putl32 (-1, eihd.privreqs);
bfd_putl32 (-1, eihd.privreqs + 4);
bfd_putl32 ((sizeof (eihd) + VMS_BLOCK_SIZE - 1) / VMS_BLOCK_SIZE,
eihd.hdrblkcnt);
bfd_putl32 (0, eihd.ident);
bfd_putl32 (0, eihd.sysver);
eihd.matchctl = 0;
bfd_putl32 (0, eihd.symvect_size);
bfd_putl32 (16, eihd.virt_mem_block_size);
bfd_putl32 (0, eihd.ext_fixup_off);
bfd_putl32 (0, eihd.noopt_psect_off);
bfd_putl32 (-1, eihd.alias);
/* Alloc EIHA. */
eiha = (struct vms_eiha *)((char *) &eihd + PRIV (file_pos));
bfd_putl32 (PRIV (file_pos), eihd.activoff);
PRIV (file_pos) += sizeof (struct vms_eiha);
bfd_putl32 (sizeof (struct vms_eiha), eiha->size);
bfd_putl32 (0, eiha->spare);
bfd_putl64 (PRIV (transfer_address[0]), eiha->tfradr1);
bfd_putl64 (PRIV (transfer_address[1]), eiha->tfradr2);
bfd_putl64 (PRIV (transfer_address[2]), eiha->tfradr3);
bfd_putl64 (PRIV (transfer_address[3]), eiha->tfradr4);
bfd_putl64 (0, eiha->inishr);
/* Alloc EIHI. */
eihi = (struct vms_eihi *)((char *) &eihd + PRIV (file_pos));
bfd_putl32 (PRIV (file_pos), eihd.imgidoff);
PRIV (file_pos) += sizeof (struct vms_eihi);
bfd_putl32 (EIHI__K_MAJORID, eihi->majorid);
bfd_putl32 (EIHI__K_MINORID, eihi->minorid);
{
char *module;
unsigned int len;
/* Set module name. */
module = vms_get_module_name (bfd_get_filename (abfd), TRUE);
len = strlen (module);
if (len > sizeof (eihi->imgnam) - 1)
len = sizeof (eihi->imgnam) - 1;
eihi->imgnam[0] = len;
memcpy (eihi->imgnam + 1, module, len);
free (module);
}
{
unsigned int lo;
unsigned int hi;
/* Set time. */
vms_get_time (&hi, &lo);
bfd_putl32 (lo, eihi->linktime + 0);
bfd_putl32 (hi, eihi->linktime + 4);
}
eihi->imgid[0] = 0;
eihi->linkid[0] = 0;
eihi->imgbid[0] = 0;
/* Alloc EIHS. */
dst = PRIV (dst_section);
dmt = bfd_get_section_by_name (abfd, "$DMT$");
if (dst != NULL && dst->size != 0)
{
eihs = (struct vms_eihs *)((char *) &eihd + PRIV (file_pos));
bfd_putl32 (PRIV (file_pos), eihd.symdbgoff);
PRIV (file_pos) += sizeof (struct vms_eihs);
bfd_putl32 (EIHS__K_MAJORID, eihs->majorid);
bfd_putl32 (EIHS__K_MINORID, eihs->minorid);
bfd_putl32 (0, eihs->dstvbn);
bfd_putl32 (0, eihs->dstsize);
bfd_putl32 (0, eihs->gstvbn);
bfd_putl32 (0, eihs->gstsize);
bfd_putl32 (0, eihs->dmtvbn);
bfd_putl32 (0, eihs->dmtsize);
}
/* One EISD per section. */
for (sec = abfd->sections; sec; sec = sec->next)
{
if (!alpha_vms_create_eisd_for_section (abfd, sec))
return FALSE;
}
/* Merge section EIDS which extra ones. */
if (PRIV (eisd_tail))
PRIV (eisd_tail)->next = PRIV (gbl_eisd_head);
else
PRIV (eisd_head) = PRIV (gbl_eisd_head);
if (PRIV (gbl_eisd_tail))
PRIV (eisd_tail) = PRIV (gbl_eisd_tail);
first_eisd = PRIV (eisd_head);
/* Add end of eisd. */
if (first_eisd)
{
eisd = bfd_zalloc (abfd, sizeof (*eisd));
if (eisd == NULL)
return FALSE;
eisd->u.eisd.majorid = 0;
eisd->u.eisd.minorid = 0;
eisd->u.eisd.eisdsize = 0;
alpha_vms_append_extra_eisd (abfd, eisd);
}
/* Place EISD in the file. */
for (eisd = first_eisd; eisd; eisd = eisd->next)
{
file_ptr room = VMS_BLOCK_SIZE - (PRIV (file_pos) % VMS_BLOCK_SIZE);
/* First block is a little bit special: there is a word at the end. */
if (PRIV (file_pos) < VMS_BLOCK_SIZE && room > 2)
room -= 2;
if (room < eisd->u.eisd.eisdsize + EISD__K_LENEND)
alpha_vms_file_position_block (abfd);
eisd->file_pos = PRIV (file_pos);
PRIV (file_pos) += eisd->u.eisd.eisdsize;
if (eisd->u.eisd.flags & EISD__M_FIXUPVEC)
bfd_putl64 (eisd->u.eisd.virt_addr, eihd.iafva);
}
if (first_eisd != NULL)
{
bfd_putl32 (first_eisd->file_pos, eihd.isdoff);
/* Real size of end of eisd marker. */
PRIV (file_pos) += EISD__K_LENEND;
}
bfd_putl32 (PRIV (file_pos), eihd.size);
bfd_putl32 ((PRIV (file_pos) + VMS_BLOCK_SIZE - 1) / VMS_BLOCK_SIZE,
eihd.hdrblkcnt);
/* Place sections. */
for (sec = abfd->sections; sec; sec = sec->next)
{
if (!(sec->flags & SEC_HAS_CONTENTS))
continue;
eisd = vms_section_data (sec)->eisd;
/* Align on a block. */
alpha_vms_file_position_block (abfd);
sec->filepos = PRIV (file_pos);
if (eisd != NULL)
eisd->u.eisd.vbn = (sec->filepos / VMS_BLOCK_SIZE) + 1;
PRIV (file_pos) += sec->size;
}
/* Update EIHS. */
if (eihs != NULL && dst != NULL)
{
bfd_putl32 ((dst->filepos / VMS_BLOCK_SIZE) + 1, eihs->dstvbn);
bfd_putl32 (dst->size, eihs->dstsize);
if (dmt != NULL)
{
lnkflags |= EIHD__M_DBGDMT;
bfd_putl32 ((dmt->filepos / VMS_BLOCK_SIZE) + 1, eihs->dmtvbn);
bfd_putl32 (dmt->size, eihs->dmtsize);
}
if (PRIV (gsd_sym_count) != 0)
{
alpha_vms_file_position_block (abfd);
gst_filepos = PRIV (file_pos);
bfd_putl32 ((gst_filepos / VMS_BLOCK_SIZE) + 1, eihs->gstvbn);
bfd_putl32 ((PRIV (gsd_sym_count) + 4) / 5 + 4, eihs->gstsize);
}
}
/* Write EISD in hdr. */
for (eisd = first_eisd; eisd && eisd->file_pos < VMS_BLOCK_SIZE;
eisd = eisd->next)
alpha_vms_swap_eisd_out
(eisd, (struct vms_eisd *)((char *)&eihd + eisd->file_pos));
/* Write first block. */
bfd_putl32 (lnkflags, eihd.lnkflags);
if (bfd_bwrite (&eihd, sizeof (eihd), abfd) != sizeof (eihd))
return FALSE;
/* Write remaining eisd. */
if (eisd != NULL)
{
unsigned char blk[VMS_BLOCK_SIZE];
struct vms_internal_eisd_map *next_eisd;
memset (blk, 0xff, sizeof (blk));
while (eisd != NULL)
{
alpha_vms_swap_eisd_out
(eisd,
(struct vms_eisd *)(blk + (eisd->file_pos % VMS_BLOCK_SIZE)));
next_eisd = eisd->next;
if (next_eisd == NULL
|| (next_eisd->file_pos / VMS_BLOCK_SIZE
!= eisd->file_pos / VMS_BLOCK_SIZE))
{
if (bfd_bwrite (blk, sizeof (blk), abfd) != sizeof (blk))
return FALSE;
memset (blk, 0xff, sizeof (blk));
}
eisd = next_eisd;
}
}
/* Write sections. */
for (sec = abfd->sections; sec; sec = sec->next)
{
unsigned char blk[VMS_BLOCK_SIZE];
bfd_size_type len;
if (sec->size == 0 || !(sec->flags & SEC_HAS_CONTENTS))
continue;
if (bfd_bwrite (sec->contents, sec->size, abfd) != sec->size)
return FALSE;
/* Pad. */
len = VMS_BLOCK_SIZE - sec->size % VMS_BLOCK_SIZE;
if (len != VMS_BLOCK_SIZE)
{
memset (blk, 0, len);
if (bfd_bwrite (blk, len, abfd) != len)
return FALSE;
}
}
/* Write GST. */
if (gst_filepos != 0)
{
struct vms_rec_wr *recwr = &PRIV (recwr);
unsigned int i;
_bfd_vms_write_emh (abfd);
_bfd_vms_write_lmn (abfd, "GNU LD");
/* PSC for the absolute section. */
_bfd_vms_output_begin (recwr, EOBJ__C_EGSD);
_bfd_vms_output_long (recwr, 0);
_bfd_vms_output_begin_subrec (recwr, EGSD__C_PSC);
_bfd_vms_output_short (recwr, 0);
_bfd_vms_output_short (recwr, EGPS__V_PIC | EGPS__V_LIB | EGPS__V_RD);
_bfd_vms_output_long (recwr, 0);
_bfd_vms_output_counted (recwr, ".$$ABS$$.");
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_end (abfd, recwr);
for (i = 0; i < PRIV (gsd_sym_count); i++)
{
struct vms_symbol_entry *sym = PRIV (syms)[i];
char *hash;
bfd_vma val;
bfd_vma ep;
if ((i % 5) == 0)
{
_bfd_vms_output_alignment (recwr, 8);
_bfd_vms_output_begin (recwr, EOBJ__C_EGSD);
_bfd_vms_output_long (recwr, 0);
}
_bfd_vms_output_begin_subrec (recwr, EGSD__C_SYMG);
_bfd_vms_output_short (recwr, 0); /* Data type, alignment. */
_bfd_vms_output_short (recwr, sym->flags);
if (sym->code_section)
ep = alpha_vms_get_sym_value (sym->code_section, sym->code_value);
else
{
BFD_ASSERT (sym->code_value == 0);
ep = 0;
}
val = alpha_vms_get_sym_value (sym->section, sym->value);
_bfd_vms_output_quad
(recwr, sym->typ == EGSD__C_SYMG ? sym->symbol_vector : val);
_bfd_vms_output_quad (recwr, ep);
_bfd_vms_output_quad (recwr, val);
_bfd_vms_output_long (recwr, 0);
hash = _bfd_vms_length_hash_symbol (abfd, sym->name, EOBJ__C_SYMSIZ);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
if ((i % 5) == 4)
_bfd_vms_output_end (abfd, recwr);
}
if ((i % 5) != 0)
_bfd_vms_output_end (abfd, recwr);
if (!_bfd_vms_write_eeom (abfd))
return FALSE;
}
return TRUE;
}
/* Object write. */
/* Write section and symbol directory of bfd abfd. Return FALSE on error. */
static bfd_boolean
_bfd_vms_write_egsd (bfd *abfd)
{
asection *section;
asymbol *symbol;
unsigned int symnum;
const char *sname;
flagword new_flags, old_flags;
int abs_section_index = -1;
unsigned int target_index = 0;
struct vms_rec_wr *recwr = &PRIV (recwr);
vms_debug2 ((2, "vms_write_egsd\n"));
/* Egsd is quadword aligned. */
_bfd_vms_output_alignment (recwr, 8);
_bfd_vms_output_begin (recwr, EOBJ__C_EGSD);
_bfd_vms_output_long (recwr, 0);
/* Number sections. */
for (section = abfd->sections; section != NULL; section = section->next)
{
if (section->flags & SEC_DEBUGGING)
continue;
if (!strcmp (section->name, ".vmsdebug"))
{
section->flags |= SEC_DEBUGGING;
continue;
}
section->target_index = target_index++;
}
for (section = abfd->sections; section != NULL; section = section->next)
{
vms_debug2 ((3, "Section #%d %s, %d bytes\n",
section->target_index, section->name, (int)section->size));
/* Don't write out the VMS debug info section since it is in the
ETBT and EDBG sections in etir. */
if (section->flags & SEC_DEBUGGING)
continue;
/* 13 bytes egsd, max 31 chars name -> should be 44 bytes. */
if (_bfd_vms_output_check (recwr, 64) < 0)
{
_bfd_vms_output_end (abfd, recwr);
_bfd_vms_output_begin (recwr, EOBJ__C_EGSD);
_bfd_vms_output_long (recwr, 0);
}
/* Don't know if this is necessary for the linker but for now it keeps
vms_slurp_gsd happy. */
sname = section->name;
if (*sname == '.')
{
/* Remove leading dot. */
sname++;
if ((*sname == 't') && (strcmp (sname, "text") == 0))
sname = EVAX_CODE_NAME;
else if ((*sname == 'd') && (strcmp (sname, "data") == 0))
sname = EVAX_DATA_NAME;
else if ((*sname == 'b') && (strcmp (sname, "bss") == 0))
sname = EVAX_BSS_NAME;
else if ((*sname == 'l') && (strcmp (sname, "link") == 0))
sname = EVAX_LINK_NAME;
else if ((*sname == 'r') && (strcmp (sname, "rdata") == 0))
sname = EVAX_READONLY_NAME;
else if ((*sname == 'l') && (strcmp (sname, "literal") == 0))
sname = EVAX_LITERAL_NAME;
else if ((*sname == 'l') && (strcmp (sname, "literals") == 0))
sname = EVAX_LITERALS_NAME;
else if ((*sname == 'c') && (strcmp (sname, "comm") == 0))
sname = EVAX_COMMON_NAME;
else if ((*sname == 'l') && (strcmp (sname, "lcomm") == 0))
sname = EVAX_LOCAL_NAME;
}
else
sname = _bfd_vms_length_hash_symbol (abfd, sname, EOBJ__C_SECSIZ);
if (bfd_is_com_section (section))
new_flags = (EGPS__V_OVR | EGPS__V_REL | EGPS__V_GBL | EGPS__V_RD
| EGPS__V_WRT | EGPS__V_NOMOD | EGPS__V_COM);
else
new_flags = vms_esecflag_by_name (evax_section_flags, sname,
section->size > 0);
/* Modify them as directed. */
if (section->flags & SEC_READONLY)
new_flags &= ~EGPS__V_WRT;
new_flags &= ~vms_section_data (section)->no_flags;
new_flags |= vms_section_data (section)->flags;
vms_debug2 ((3, "sec flags %x\n", section->flags));
vms_debug2 ((3, "new_flags %x, _raw_size %lu\n",
new_flags, (unsigned long)section->size));
_bfd_vms_output_begin_subrec (recwr, EGSD__C_PSC);
_bfd_vms_output_short (recwr, section->alignment_power & 0xff);
_bfd_vms_output_short (recwr, new_flags);
_bfd_vms_output_long (recwr, (unsigned long) section->size);
_bfd_vms_output_counted (recwr, sname);
_bfd_vms_output_end_subrec (recwr);
/* If the section is an obsolute one, remind its index as it will be
used later for absolute symbols. */
if ((new_flags & EGPS__V_REL) == 0 && abs_section_index < 0)
abs_section_index = section->target_index;
}
/* Output symbols. */
vms_debug2 ((3, "%d symbols found\n", abfd->symcount));
bfd_set_start_address (abfd, (bfd_vma) -1);
for (symnum = 0; symnum < abfd->symcount; symnum++)
{
char *hash;
symbol = abfd->outsymbols[symnum];
old_flags = symbol->flags;
/* Work-around a missing feature: consider __main as the main entry
point. */
if (*(symbol->name) == '_')
{
if (strcmp (symbol->name, "__main") == 0)
bfd_set_start_address (abfd, (bfd_vma)symbol->value);
}
/* Only put in the GSD the global and the undefined symbols. */
if (old_flags & BSF_FILE)
continue;
if ((old_flags & BSF_GLOBAL) == 0 && !bfd_is_und_section (symbol->section))
{
/* If the LIB$INITIIALIZE section is present, add a reference to
LIB$INITIALIZE symbol. FIXME: this should be done explicitely
in the assembly file. */
if (!((old_flags & BSF_SECTION_SYM) != 0
&& strcmp (symbol->section->name, "LIB$INITIALIZE") == 0))
continue;
}
/* 13 bytes egsd, max 64 chars name -> should be 77 bytes. Add 16 more
bytes for a possible ABS section. */
if (_bfd_vms_output_check (recwr, 80 + 16) < 0)
{
_bfd_vms_output_end (abfd, recwr);
_bfd_vms_output_begin (recwr, EOBJ__C_EGSD);
_bfd_vms_output_long (recwr, 0);
}
if ((old_flags & BSF_GLOBAL) != 0
&& bfd_is_abs_section (symbol->section)
&& abs_section_index <= 0)
{
/* Create an absolute section if none was defined. It is highly
unlikely that the name $ABS$ clashes with a user defined
non-absolute section name. */
_bfd_vms_output_begin_subrec (recwr, EGSD__C_PSC);
_bfd_vms_output_short (recwr, 4);
_bfd_vms_output_short (recwr, EGPS__V_SHR);
_bfd_vms_output_long (recwr, 0);
_bfd_vms_output_counted (recwr, "$ABS$");
_bfd_vms_output_end_subrec (recwr);
abs_section_index = target_index++;
}
_bfd_vms_output_begin_subrec (recwr, EGSD__C_SYM);
/* Data type, alignment. */
_bfd_vms_output_short (recwr, 0);
new_flags = 0;
if (old_flags & BSF_WEAK)
new_flags |= EGSY__V_WEAK;
if (bfd_is_com_section (symbol->section)) /* .comm */
new_flags |= (EGSY__V_WEAK | EGSY__V_COMM);
if (old_flags & BSF_FUNCTION)
{
new_flags |= EGSY__V_NORM;
new_flags |= EGSY__V_REL;
}
if (old_flags & BSF_GLOBAL)
{
new_flags |= EGSY__V_DEF;
if (!bfd_is_abs_section (symbol->section))
new_flags |= EGSY__V_REL;
}
_bfd_vms_output_short (recwr, new_flags);
if (old_flags & BSF_GLOBAL)
{
/* Symbol definition. */
bfd_vma code_address = 0;
unsigned long ca_psindx = 0;
unsigned long psindx;
if ((old_flags & BSF_FUNCTION) && symbol->udata.p != NULL)
{
asymbol *sym;
sym =
((struct evax_private_udata_struct *)symbol->udata.p)->enbsym;
code_address = sym->value;
ca_psindx = sym->section->target_index;
}
if (bfd_is_abs_section (symbol->section))
psindx = abs_section_index;
else
psindx = symbol->section->target_index;
_bfd_vms_output_quad (recwr, symbol->value);
_bfd_vms_output_quad (recwr, code_address);
_bfd_vms_output_long (recwr, ca_psindx);
_bfd_vms_output_long (recwr, psindx);
}
hash = _bfd_vms_length_hash_symbol (abfd, symbol->name, EOBJ__C_SYMSIZ);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
}
_bfd_vms_output_alignment (recwr, 8);
_bfd_vms_output_end (abfd, recwr);
return TRUE;
}
/* Write object header for bfd abfd. Return FALSE on error. */
static bfd_boolean
_bfd_vms_write_ehdr (bfd *abfd)
{
asymbol *symbol;
unsigned int symnum;
int had_case = 0;
int had_file = 0;
struct vms_rec_wr *recwr = &PRIV (recwr);
vms_debug2 ((2, "vms_write_ehdr (%p)\n", abfd));
_bfd_vms_output_alignment (recwr, 2);
_bfd_vms_write_emh (abfd);
_bfd_vms_write_lmn (abfd, "GNU AS");
/* SRC. */
_bfd_vms_output_begin (recwr, EOBJ__C_EMH);
_bfd_vms_output_short (recwr, EMH__C_SRC);
for (symnum = 0; symnum < abfd->symcount; symnum++)
{
symbol = abfd->outsymbols[symnum];
if (symbol->flags & BSF_FILE)
{
if (CONST_STRNEQ ((char *)symbol->name, "<CASE:"))
{
PRIV (flag_hash_long_names) = symbol->name[6] - '0';
PRIV (flag_show_after_trunc) = symbol->name[7] - '0';
if (had_file)
break;
had_case = 1;
continue;
}
_bfd_vms_output_dump (recwr, (unsigned char *) symbol->name,
(int) strlen (symbol->name));
if (had_case)
break;
had_file = 1;
}
}
if (symnum == abfd->symcount)
_bfd_vms_output_dump (recwr, (unsigned char *) STRING_COMMA_LEN ("noname"));
_bfd_vms_output_end (abfd, recwr);
/* TTL. */
_bfd_vms_output_begin (recwr, EOBJ__C_EMH);
_bfd_vms_output_short (recwr, EMH__C_TTL);
_bfd_vms_output_dump (recwr, (unsigned char *) STRING_COMMA_LEN ("TTL"));
_bfd_vms_output_end (abfd, recwr);
/* CPR. */
_bfd_vms_output_begin (recwr, EOBJ__C_EMH);
_bfd_vms_output_short (recwr, EMH__C_CPR);
_bfd_vms_output_dump (recwr,
(unsigned char *)"GNU BFD ported by Klaus Kämpf 1994-1996",
39);
_bfd_vms_output_end (abfd, recwr);
return TRUE;
}
/* Part 4.6, relocations. */
/* WRITE ETIR SECTION
This is still under construction and therefore not documented. */
/* Close the etir/etbt record. */
static void
end_etir_record (bfd * abfd)
{
struct vms_rec_wr *recwr = &PRIV (recwr);
_bfd_vms_output_end (abfd, recwr);
}
static void
start_etir_or_etbt_record (bfd *abfd, asection *section, bfd_vma offset)
{
struct vms_rec_wr *recwr = &PRIV (recwr);
if (section->flags & SEC_DEBUGGING)
{
_bfd_vms_output_begin (recwr, EOBJ__C_ETBT);
if (offset == 0)
{
/* Push start offset. */
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_LW);
_bfd_vms_output_long (recwr, (unsigned long) 0);
_bfd_vms_output_end_subrec (recwr);
/* Set location. */
_bfd_vms_output_begin_subrec (recwr, ETIR__C_CTL_DFLOC);
_bfd_vms_output_end_subrec (recwr);
}
}
else
{
_bfd_vms_output_begin (recwr, EOBJ__C_ETIR);
if (offset == 0)
{
/* Push start offset. */
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_PQ);
_bfd_vms_output_long (recwr, (unsigned long) section->target_index);
_bfd_vms_output_quad (recwr, offset);
_bfd_vms_output_end_subrec (recwr);
/* Start = pop (). */
_bfd_vms_output_begin_subrec (recwr, ETIR__C_CTL_SETRB);
_bfd_vms_output_end_subrec (recwr);
}
}
}
/* Output a STO_IMM command for SSIZE bytes of data from CPR at virtual
address VADDR in section specified by SEC_INDEX and NAME. */
static void
sto_imm (bfd *abfd, asection *section,
bfd_size_type ssize, unsigned char *cptr, bfd_vma vaddr)
{
bfd_size_type size;
struct vms_rec_wr *recwr = &PRIV (recwr);
#if VMS_DEBUG
_bfd_vms_debug (8, "sto_imm %d bytes\n", (int) ssize);
_bfd_hexdump (9, cptr, (int) ssize, (int) vaddr);
#endif
while (ssize > 0)
{
/* Try all the rest. */
size = ssize;
if (_bfd_vms_output_check (recwr, size) < 0)
{
/* Doesn't fit, split ! */
end_etir_record (abfd);
start_etir_or_etbt_record (abfd, section, vaddr);
size = _bfd_vms_output_check (recwr, 0); /* get max size */
if (size > ssize) /* more than what's left ? */
size = ssize;
}
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_IMM);
_bfd_vms_output_long (recwr, (unsigned long) (size));
_bfd_vms_output_dump (recwr, cptr, size);
_bfd_vms_output_end_subrec (recwr);
#if VMS_DEBUG
_bfd_vms_debug (10, "dumped %d bytes\n", (int) size);
_bfd_hexdump (10, cptr, (int) size, (int) vaddr);
#endif
vaddr += size;
cptr += size;
ssize -= size;
}
}
static void
etir_output_check (bfd *abfd, asection *section, bfd_vma vaddr, int checklen)
{
if (_bfd_vms_output_check (&PRIV (recwr), checklen) < 0)
{
/* Not enough room in this record. Close it and open a new one. */
end_etir_record (abfd);
start_etir_or_etbt_record (abfd, section, vaddr);
}
}
/* Return whether RELOC must be deferred till the end. */
static bfd_boolean
defer_reloc_p (arelent *reloc)
{
switch (reloc->howto->type)
{
case ALPHA_R_NOP:
case ALPHA_R_LDA:
case ALPHA_R_BSR:
case ALPHA_R_BOH:
return TRUE;
default:
return FALSE;
}
}
/* Write section contents for bfd abfd. Return FALSE on error. */
static bfd_boolean
_bfd_vms_write_etir (bfd * abfd, int objtype ATTRIBUTE_UNUSED)
{
asection *section;
struct vms_rec_wr *recwr = &PRIV (recwr);
vms_debug2 ((2, "vms_write_tir (%p, %d)\n", abfd, objtype));
_bfd_vms_output_alignment (recwr, 4);
PRIV (vms_linkage_index) = 1;
for (section = abfd->sections; section; section = section->next)
{
vms_debug2 ((4, "writing %d. section '%s' (%d bytes)\n",
section->target_index, section->name, (int) (section->size)));
if (!(section->flags & SEC_HAS_CONTENTS)
|| bfd_is_com_section (section))
continue;
if (!section->contents)
{
bfd_set_error (bfd_error_no_contents);
return FALSE;
}
start_etir_or_etbt_record (abfd, section, 0);
if (section->flags & SEC_RELOC)
{
bfd_vma curr_addr = 0;
unsigned char *curr_data = section->contents;
bfd_size_type size;
int pass2_needed = 0;
int pass2_in_progress = 0;
unsigned int irel;
if (section->reloc_count <= 0)
(*_bfd_error_handler)
(_("SEC_RELOC with no relocs in section %s"), section->name);
#if VMS_DEBUG
else
{
int i = section->reloc_count;
arelent **rptr = section->orelocation;
_bfd_vms_debug (4, "%d relocations:\n", i);
while (i-- > 0)
{
_bfd_vms_debug (4, "sym %s in sec %s, value %08lx, "
"addr %08lx, off %08lx, len %d: %s\n",
(*(*rptr)->sym_ptr_ptr)->name,
(*(*rptr)->sym_ptr_ptr)->section->name,
(long) (*(*rptr)->sym_ptr_ptr)->value,
(unsigned long)(*rptr)->address,
(unsigned long)(*rptr)->addend,
bfd_get_reloc_size ((*rptr)->howto),
( *rptr)->howto->name);
rptr++;
}
}
#endif
new_pass:
for (irel = 0; irel < section->reloc_count; irel++)
{
struct evax_private_udata_struct *udata;
arelent *rptr = section->orelocation [irel];
bfd_vma addr = rptr->address;
asymbol *sym = *rptr->sym_ptr_ptr;
asection *sec = sym->section;
bfd_boolean defer = defer_reloc_p (rptr);
unsigned int slen;
char *hash;
if (pass2_in_progress)
{
/* Non-deferred relocs have already been output. */
if (!defer)
continue;
}
else
{
/* Deferred relocs must be output at the very end. */
if (defer)
{
pass2_needed = 1;
continue;
}
/* Regular relocs are intertwined with binary data. */
if (curr_addr > addr)
(*_bfd_error_handler) (_("Size error in section %s"),
section->name);
size = addr - curr_addr;
sto_imm (abfd, section, size, curr_data, curr_addr);
curr_data += size;
curr_addr += size;
}
size = bfd_get_reloc_size (rptr->howto);
switch (rptr->howto->type)
{
case ALPHA_R_IGNORE:
break;
case ALPHA_R_REFLONG:
if (bfd_is_und_section (sym->section))
{
bfd_vma addend = rptr->addend;
slen = strlen ((char *) sym->name);
hash = _bfd_vms_length_hash_symbol
(abfd, sym->name, EOBJ__C_SYMSIZ);
etir_output_check (abfd, section, curr_addr, slen);
if (addend)
{
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_GBL);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_LW);
_bfd_vms_output_long (recwr, (unsigned long) addend);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_OPR_ADD);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_LW);
_bfd_vms_output_end_subrec (recwr);
}
else
{
_bfd_vms_output_begin_subrec
(recwr, ETIR__C_STO_GBL_LW);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
}
}
else if (bfd_is_abs_section (sym->section))
{
etir_output_check (abfd, section, curr_addr, 16);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_LW);
_bfd_vms_output_long (recwr, (unsigned long) sym->value);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_LW);
_bfd_vms_output_end_subrec (recwr);
}
else
{
etir_output_check (abfd, section, curr_addr, 32);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_PQ);
_bfd_vms_output_long (recwr,
(unsigned long) sec->target_index);
_bfd_vms_output_quad (recwr, rptr->addend + sym->value);
_bfd_vms_output_end_subrec (recwr);
/* ??? Table B-8 of the OpenVMS Linker Utilily Manual
says that we should have a ETIR__C_STO_OFF here.
But the relocation would not be BFD_RELOC_32 then.
This case is very likely unreachable. */
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_LW);
_bfd_vms_output_end_subrec (recwr);
}
break;
case ALPHA_R_REFQUAD:
if (bfd_is_und_section (sym->section))
{
bfd_vma addend = rptr->addend;
slen = strlen ((char *) sym->name);
hash = _bfd_vms_length_hash_symbol
(abfd, sym->name, EOBJ__C_SYMSIZ);
etir_output_check (abfd, section, curr_addr, slen);
if (addend)
{
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_GBL);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_QW);
_bfd_vms_output_quad (recwr, addend);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_OPR_ADD);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_QW);
_bfd_vms_output_end_subrec (recwr);
}
else
{
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_GBL);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
}
}
else if (bfd_is_abs_section (sym->section))
{
etir_output_check (abfd, section, curr_addr, 16);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_QW);
_bfd_vms_output_quad (recwr, sym->value);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_QW);
_bfd_vms_output_end_subrec (recwr);
}
else
{
etir_output_check (abfd, section, curr_addr, 32);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STA_PQ);
_bfd_vms_output_long (recwr,
(unsigned long) sec->target_index);
_bfd_vms_output_quad (recwr, rptr->addend + sym->value);
_bfd_vms_output_end_subrec (recwr);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_OFF);
_bfd_vms_output_end_subrec (recwr);
}
break;
case ALPHA_R_HINT:
sto_imm (abfd, section, size, curr_data, curr_addr);
break;
case ALPHA_R_LINKAGE:
etir_output_check (abfd, section, curr_addr, 64);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STC_LP_PSB);
_bfd_vms_output_long
(recwr, (unsigned long) PRIV (vms_linkage_index));
PRIV (vms_linkage_index) += 2;
hash = _bfd_vms_length_hash_symbol
(abfd, sym->name, EOBJ__C_SYMSIZ);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_byte (recwr, 0);
_bfd_vms_output_end_subrec (recwr);
break;
case ALPHA_R_CODEADDR:
slen = strlen ((char *) sym->name);
hash = _bfd_vms_length_hash_symbol
(abfd, sym->name, EOBJ__C_SYMSIZ);
etir_output_check (abfd, section, curr_addr, slen);
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STO_CA);
_bfd_vms_output_counted (recwr, hash);
_bfd_vms_output_end_subrec (recwr);
break;
case ALPHA_R_NOP:
udata
= (struct evax_private_udata_struct *) rptr->sym_ptr_ptr;
etir_output_check (abfd, section, curr_addr,
32 + 1 + strlen (udata->origname));
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STC_NOP_GBL);
_bfd_vms_output_long (recwr, (unsigned long) udata->lkindex);
_bfd_vms_output_long
(recwr,
(unsigned long) udata->enbsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->address);
_bfd_vms_output_long (recwr, (unsigned long) 0x47ff041f);
_bfd_vms_output_long
(recwr,
(unsigned long) udata->enbsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->addend);
_bfd_vms_output_counted
(recwr, _bfd_vms_length_hash_symbol
(abfd, udata->origname, EOBJ__C_SYMSIZ));
_bfd_vms_output_end_subrec (recwr);
break;
case ALPHA_R_BSR:
(*_bfd_error_handler) (_("Spurious ALPHA_R_BSR reloc"));
break;
case ALPHA_R_LDA:
udata
= (struct evax_private_udata_struct *) rptr->sym_ptr_ptr;
etir_output_check (abfd, section, curr_addr,
32 + 1 + strlen (udata->origname));
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STC_LDA_GBL);
_bfd_vms_output_long
(recwr, (unsigned long) udata->lkindex + 1);
_bfd_vms_output_long
(recwr,
(unsigned long) udata->enbsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->address);
_bfd_vms_output_long (recwr, (unsigned long) 0x237B0000);
_bfd_vms_output_long
(recwr, (unsigned long) udata->bsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->addend);
_bfd_vms_output_counted
(recwr, _bfd_vms_length_hash_symbol
(abfd, udata->origname, EOBJ__C_SYMSIZ));
_bfd_vms_output_end_subrec (recwr);
break;
case ALPHA_R_BOH:
udata
= (struct evax_private_udata_struct *) rptr->sym_ptr_ptr;
etir_output_check (abfd, section, curr_addr,
32 + 1 + strlen (udata->origname));
_bfd_vms_output_begin_subrec (recwr, ETIR__C_STC_BOH_GBL);
_bfd_vms_output_long (recwr, (unsigned long) udata->lkindex);
_bfd_vms_output_long
(recwr,
(unsigned long) udata->enbsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->address);
_bfd_vms_output_long (recwr, (unsigned long) 0xD3400000);
_bfd_vms_output_long
(recwr,
(unsigned long) udata->enbsym->section->target_index);
_bfd_vms_output_quad (recwr, rptr->addend);
_bfd_vms_output_counted
(recwr, _bfd_vms_length_hash_symbol
(abfd, udata->origname, EOBJ__C_SYMSIZ));
_bfd_vms_output_end_subrec (recwr);
break;
default:
(*_bfd_error_handler) (_("Unhandled relocation %s"),
rptr->howto->name);
break;
}
curr_data += size;
curr_addr += size;
} /* End of relocs loop. */
if (!pass2_in_progress)
{
/* Output rest of section. */
if (curr_addr > section->size)
(*_bfd_error_handler) (_("Size error in section %s"),
section->name);
size = section->size - curr_addr;
sto_imm (abfd, section, size, curr_data, curr_addr);
curr_data += size;
curr_addr += size;
if (pass2_needed)
{
pass2_in_progress = 1;
goto new_pass;
}
}
}
else /* (section->flags & SEC_RELOC) */
sto_imm (abfd, section, section->size, section->contents, 0);
end_etir_record (abfd);
}
_bfd_vms_output_alignment (recwr, 2);
return TRUE;
}
/* Write cached information into a file being written, at bfd_close. */
static bfd_boolean
alpha_vms_write_object_contents (bfd *abfd)
{
vms_debug2 ((1, "vms_write_object_contents (%p)\n", abfd));
if (abfd->flags & (EXEC_P | DYNAMIC))
{
return alpha_vms_write_exec (abfd);
}
else
{
if (abfd->section_count > 0) /* we have sections */
{
if (_bfd_vms_write_ehdr (abfd) != TRUE)
return FALSE;
if (_bfd_vms_write_egsd (abfd) != TRUE)
return FALSE;
if (_bfd_vms_write_etir (abfd, EOBJ__C_ETIR) != TRUE)
return FALSE;
if (_bfd_vms_write_eeom (abfd) != TRUE)
return FALSE;
}
}
return TRUE;
}
/* Debug stuff: nearest line. */
#define SET_MODULE_PARSED(m) \
do { if ((m)->name == NULL) (m)->name = ""; } while (0)
#define IS_MODULE_PARSED(m) ((m)->name != NULL)
/* Build a new module for the specified BFD. */
static struct module *
new_module (bfd *abfd)
{
struct module *module
= (struct module *) bfd_zalloc (abfd, sizeof (struct module));
module->file_table_count = 16; /* Arbitrary. */
module->file_table
= bfd_malloc (module->file_table_count * sizeof (struct fileinfo));
return module;
}
/* Parse debug info for a module and internalize it. */
static void
parse_module (bfd *abfd, struct module *module, unsigned char *ptr,
int length)
{
unsigned char *maxptr = ptr + length;
unsigned char *src_ptr, *pcl_ptr;
unsigned int prev_linum = 0, curr_linenum = 0;
bfd_vma prev_pc = 0, curr_pc = 0;
struct srecinfo *curr_srec, *srec;
struct lineinfo *curr_line, *line;
struct funcinfo *funcinfo;
/* Initialize tables with zero element. */
curr_srec = (struct srecinfo *) bfd_zalloc (abfd, sizeof (struct srecinfo));
module->srec_table = curr_srec;
curr_line = (struct lineinfo *) bfd_zalloc (abfd, sizeof (struct lineinfo));
module->line_table = curr_line;
while (length == -1 || ptr < maxptr)
{
/* The first byte is not counted in the recorded length. */
int rec_length = bfd_getl16 (ptr) + 1;
int rec_type = bfd_getl16 (ptr + 2);
vms_debug2 ((2, "DST record: leng %d, type %d\n", rec_length, rec_type));
if (length == -1 && rec_type == DST__K_MODEND)
break;
switch (rec_type)
{
case DST__K_MODBEG:
module->name
= _bfd_vms_save_counted_string (ptr + DST_S_B_MODBEG_NAME);
curr_pc = 0;
prev_pc = 0;
curr_linenum = 0;
prev_linum = 0;
vms_debug2 ((3, "module: %s\n", module->name));
break;
case DST__K_MODEND:
break;
case DST__K_RTNBEG:
funcinfo = (struct funcinfo *)
bfd_zalloc (abfd, sizeof (struct funcinfo));
funcinfo->name
= _bfd_vms_save_counted_string (ptr + DST_S_B_RTNBEG_NAME);
funcinfo->low = bfd_getl32 (ptr + DST_S_L_RTNBEG_ADDRESS);
funcinfo->next = module->func_table;
module->func_table = funcinfo;
vms_debug2 ((3, "routine: %s at 0x%lx\n",
funcinfo->name, (unsigned long) funcinfo->low));
break;
case DST__K_RTNEND:
module->func_table->high = module->func_table->low
+ bfd_getl32 (ptr + DST_S_L_RTNEND_SIZE) - 1;
if (module->func_table->high > module->high)
module->high = module->func_table->high;
vms_debug2 ((3, "end routine\n"));
break;
case DST__K_PROLOG:
vms_debug2 ((3, "prologue\n"));
break;
case DST__K_EPILOG:
vms_debug2 ((3, "epilog\n"));
break;
case DST__K_BLKBEG:
vms_debug2 ((3, "block\n"));
break;
case DST__K_BLKEND:
vms_debug2 ((3, "end block\n"));
break;
case DST__K_SOURCE:
src_ptr = ptr + DST_S_C_SOURCE_HEADER_SIZE;
vms_debug2 ((3, "source info\n"));
while (src_ptr < ptr + rec_length)
{
int cmd = src_ptr[0], cmd_length, data;
switch (cmd)
{
case DST__K_SRC_DECLFILE:
{
unsigned int fileid
= bfd_getl16 (src_ptr + DST_S_W_SRC_DF_FILEID);
char *filename
= _bfd_vms_save_counted_string (src_ptr
+ DST_S_B_SRC_DF_FILENAME);
while (fileid >= module->file_table_count)
{
module->file_table_count *= 2;
module->file_table
= bfd_realloc (module->file_table,
module->file_table_count
* sizeof (struct fileinfo));
}
module->file_table [fileid].name = filename;
module->file_table [fileid].srec = 1;
cmd_length = src_ptr[DST_S_B_SRC_DF_LENGTH] + 2;
vms_debug2 ((4, "DST_S_C_SRC_DECLFILE: %d, %s\n",
fileid, module->file_table [fileid].name));
}
break;
case DST__K_SRC_DEFLINES_B:
/* Perform the association and set the next higher index
to the limit. */
data = src_ptr[DST_S_B_SRC_UNSBYTE];
srec = (struct srecinfo *)
bfd_zalloc (abfd, sizeof (struct srecinfo));
srec->line = curr_srec->line + data;
srec->srec = curr_srec->srec + data;
srec->sfile = curr_srec->sfile;
curr_srec->next = srec;
curr_srec = srec;
cmd_length = 2;
vms_debug2 ((4, "DST_S_C_SRC_DEFLINES_B: %d\n", data));
break;
case DST__K_SRC_DEFLINES_W:
/* Perform the association and set the next higher index
to the limit. */
data = bfd_getl16 (src_ptr + DST_S_W_SRC_UNSWORD);
srec = (struct srecinfo *)
bfd_zalloc (abfd, sizeof (struct srecinfo));
srec->line = curr_srec->line + data;
srec->srec = curr_srec->srec + data,
srec->sfile = curr_srec->sfile;
curr_srec->next = srec;
curr_srec = srec;
cmd_length = 3;
vms_debug2 ((4, "DST_S_C_SRC_DEFLINES_W: %d\n", data));
break;
case DST__K_SRC_INCRLNUM_B:
data = src_ptr[DST_S_B_SRC_UNSBYTE];
curr_srec->line += data;
cmd_length = 2;
vms_debug2 ((4, "DST_S_C_SRC_INCRLNUM_B: %d\n", data));
break;
case DST__K_SRC_SETFILE:
data = bfd_getl16 (src_ptr + DST_S_W_SRC_UNSWORD);
curr_srec->sfile = data;
curr_srec->srec = module->file_table[data].srec;
cmd_length = 3;
vms_debug2 ((4, "DST_S_C_SRC_SETFILE: %d\n", data));
break;
case DST__K_SRC_SETLNUM_L:
data = bfd_getl32 (src_ptr + DST_S_L_SRC_UNSLONG);
curr_srec->line = data;
cmd_length = 5;
vms_debug2 ((4, "DST_S_C_SRC_SETLNUM_L: %d\n", data));
break;
case DST__K_SRC_SETLNUM_W:
data = bfd_getl16 (src_ptr + DST_S_W_SRC_UNSWORD);
curr_srec->line = data;
cmd_length = 3;
vms_debug2 ((4, "DST_S_C_SRC_SETLNUM_W: %d\n", data));
break;
case DST__K_SRC_SETREC_L:
data = bfd_getl32 (src_ptr + DST_S_L_SRC_UNSLONG);
curr_srec->srec = data;
module->file_table[curr_srec->sfile].srec = data;
cmd_length = 5;
vms_debug2 ((4, "DST_S_C_SRC_SETREC_L: %d\n", data));
break;
case DST__K_SRC_SETREC_W:
data = bfd_getl16 (src_ptr + DST_S_W_SRC_UNSWORD);
curr_srec->srec = data;
module->file_table[curr_srec->sfile].srec = data;
cmd_length = 3;
vms_debug2 ((4, "DST_S_C_SRC_SETREC_W: %d\n", data));
break;
case DST__K_SRC_FORMFEED:
cmd_length = 1;
vms_debug2 ((4, "DST_S_C_SRC_FORMFEED\n"));
break;
default:
(*_bfd_error_handler) (_("unknown source command %d"),
cmd);
cmd_length = 2;
break;
}
src_ptr += cmd_length;
}
break;
case DST__K_LINE_NUM:
pcl_ptr = ptr + DST_S_C_LINE_NUM_HEADER_SIZE;
vms_debug2 ((3, "line info\n"));
while (pcl_ptr < ptr + rec_length)
{
/* The command byte is signed so we must sign-extend it. */
int cmd = ((signed char *)pcl_ptr)[0], cmd_length, data;
switch (cmd)
{
case DST__K_DELTA_PC_W:
data = bfd_getl16 (pcl_ptr + DST_S_W_PCLINE_UNSWORD);
curr_pc += data;
curr_linenum += 1;
cmd_length = 3;
vms_debug2 ((4, "DST__K_DELTA_PC_W: %d\n", data));
break;
case DST__K_DELTA_PC_L:
data = bfd_getl32 (pcl_ptr + DST_S_L_PCLINE_UNSLONG);
curr_pc += data;
curr_linenum += 1;
cmd_length = 5;
vms_debug2 ((4, "DST__K_DELTA_PC_L: %d\n", data));
break;
case DST__K_INCR_LINUM:
data = pcl_ptr[DST_S_B_PCLINE_UNSBYTE];
curr_linenum += data;
cmd_length = 2;
vms_debug2 ((4, "DST__K_INCR_LINUM: %d\n", data));
break;
case DST__K_INCR_LINUM_W:
data = bfd_getl16 (pcl_ptr + DST_S_W_PCLINE_UNSWORD);
curr_linenum += data;
cmd_length = 3;
vms_debug2 ((4, "DST__K_INCR_LINUM_W: %d\n", data));
break;
case DST__K_INCR_LINUM_L:
data = bfd_getl32 (pcl_ptr + DST_S_L_PCLINE_UNSLONG);
curr_linenum += data;
cmd_length = 5;
vms_debug2 ((4, "DST__K_INCR_LINUM_L: %d\n", data));
break;
case DST__K_SET_LINUM_INCR:
(*_bfd_error_handler)
(_("DST__K_SET_LINUM_INCR not implemented"));
cmd_length = 2;
break;
case DST__K_SET_LINUM_INCR_W:
(*_bfd_error_handler)
(_("DST__K_SET_LINUM_INCR_W not implemented"));
cmd_length = 3;
break;
case DST__K_RESET_LINUM_INCR:
(*_bfd_error_handler)
(_("DST__K_RESET_LINUM_INCR not implemented"));
cmd_length = 1;
break;
case DST__K_BEG_STMT_MODE:
(*_bfd_error_handler)
(_("DST__K_BEG_STMT_MODE not implemented"));
cmd_length = 1;
break;
case DST__K_END_STMT_MODE:
(*_bfd_error_handler)
(_("DST__K_END_STMT_MODE not implemented"));
cmd_length = 1;
break;
case DST__K_SET_LINUM_B:
data = pcl_ptr[DST_S_B_PCLINE_UNSBYTE];
curr_linenum = data;
cmd_length = 2;
vms_debug2 ((4, "DST__K_SET_LINUM_B: %d\n", data));
break;
case DST__K_SET_LINUM:
data = bfd_getl16 (pcl_ptr + DST_S_W_PCLINE_UNSWORD);
curr_linenum = data;
cmd_length = 3;
vms_debug2 ((4, "DST__K_SET_LINE_NUM: %d\n", data));
break;
case DST__K_SET_LINUM_L:
data = bfd_getl32 (pcl_ptr + DST_S_L_PCLINE_UNSLONG);
curr_linenum = data;
cmd_length = 5;
vms_debug2 ((4, "DST__K_SET_LINUM_L: %d\n", data));
break;
case DST__K_SET_PC:
(*_bfd_error_handler)
(_("DST__K_SET_PC not implemented"));
cmd_length = 2;
break;
case DST__K_SET_PC_W:
(*_bfd_error_handler)
(_("DST__K_SET_PC_W not implemented"));
cmd_length = 3;
break;
case DST__K_SET_PC_L:
(*_bfd_error_handler)
(_("DST__K_SET_PC_L not implemented"));
cmd_length = 5;
break;
case DST__K_SET_STMTNUM:
(*_bfd_error_handler)
(_("DST__K_SET_STMTNUM not implemented"));
cmd_length = 2;
break;
case DST__K_TERM:
data = pcl_ptr[DST_S_B_PCLINE_UNSBYTE];
curr_pc += data;
cmd_length = 2;
vms_debug2 ((4, "DST__K_TERM: %d\n", data));
break;
case DST__K_TERM_W:
data = bfd_getl16 (pcl_ptr + DST_S_W_PCLINE_UNSWORD);
curr_pc += data;
cmd_length = 3;
vms_debug2 ((4, "DST__K_TERM_W: %d\n", data));
break;
case DST__K_TERM_L:
data = bfd_getl32 (pcl_ptr + DST_S_L_PCLINE_UNSLONG);
curr_pc += data;
cmd_length = 5;
vms_debug2 ((4, "DST__K_TERM_L: %d\n", data));
break;
case DST__K_SET_ABS_PC:
data = bfd_getl32 (pcl_ptr + DST_S_L_PCLINE_UNSLONG);
curr_pc = data;
cmd_length = 5;
vms_debug2 ((4, "DST__K_SET_ABS_PC: 0x%x\n", data));
break;
default:
if (cmd <= 0)
{
curr_pc -= cmd;
curr_linenum += 1;
cmd_length = 1;
vms_debug2 ((4, "bump pc to 0x%lx and line to %d\n",
(unsigned long)curr_pc, curr_linenum));
}
else
{
(*_bfd_error_handler) (_("unknown line command %d"),
cmd);
cmd_length = 2;
}
break;
}
if ((curr_linenum != prev_linum && curr_pc != prev_pc)
|| cmd <= 0
|| cmd == DST__K_DELTA_PC_L
|| cmd == DST__K_DELTA_PC_W)
{
line = (struct lineinfo *)
bfd_zalloc (abfd, sizeof (struct lineinfo));
line->address = curr_pc;
line->line = curr_linenum;
curr_line->next = line;
curr_line = line;
prev_linum = curr_linenum;
prev_pc = curr_pc;
vms_debug2 ((4, "-> correlate pc 0x%lx with line %d\n",
(unsigned long)curr_pc, curr_linenum));
}
pcl_ptr += cmd_length;
}
break;
case 0x17: /* Undocumented type used by DEC C to declare equates. */
vms_debug2 ((3, "undocumented type 0x17\n"));
break;
default:
vms_debug2 ((3, "ignoring record\n"));
break;
}
ptr += rec_length;
}
/* Finalize tables with EOL marker. */
srec = (struct srecinfo *) bfd_zalloc (abfd, sizeof (struct srecinfo));
srec->line = (unsigned int) -1;
srec->srec = (unsigned int) -1;
curr_srec->next = srec;
line = (struct lineinfo *) bfd_zalloc (abfd, sizeof (struct lineinfo));
line->line = (unsigned int) -1;
line->address = (bfd_vma) -1;
curr_line->next = line;
/* Advertise that this module has been parsed. This is needed
because parsing can be either performed at module creation
or deferred until debug info is consumed. */
SET_MODULE_PARSED (module);
}
/* Build the list of modules for the specified BFD. */
static struct module *
build_module_list (bfd *abfd)
{
struct module *module, *list = NULL;
asection *dmt;
if ((dmt = bfd_get_section_by_name (abfd, "$DMT$")))
{
/* We have a DMT section so this must be an image. Parse the
section and build the list of modules. This is sufficient
since we can compute the start address and the end address
of every module from the section contents. */
bfd_size_type size = bfd_get_section_size (dmt);
unsigned char *ptr, *end;
ptr = (unsigned char *) bfd_alloc (abfd, size);
if (! ptr)
return NULL;
if (! bfd_get_section_contents (abfd, dmt, ptr, 0, size))
return NULL;
vms_debug2 ((2, "DMT\n"));
end = ptr + size;
while (ptr < end)
{
/* Each header declares a module with its start offset and size
of debug info in the DST section, as well as the count of
program sections (i.e. address spans) it contains. */
int modbeg = bfd_getl32 (ptr + DBG_S_L_DMT_MODBEG);
int msize = bfd_getl32 (ptr + DBG_S_L_DST_SIZE);
int count = bfd_getl16 (ptr + DBG_S_W_DMT_PSECT_COUNT);
ptr += DBG_S_C_DMT_HEADER_SIZE;
vms_debug2 ((3, "module: modbeg = %d, size = %d, count = %d\n",
modbeg, msize, count));
/* We create a 'module' structure for each program section since
we only support contiguous addresses in a 'module' structure.
As a consequence, the actual debug info in the DST section is
shared and can be parsed multiple times; that doesn't seem to
cause problems in practice. */
while (count-- > 0)
{
int start = bfd_getl32 (ptr + DBG_S_L_DMT_PSECT_START);
int length = bfd_getl32 (ptr + DBG_S_L_DMT_PSECT_LENGTH);
module = new_module (abfd);
module->modbeg = modbeg;
module->size = msize;
module->low = start;
module->high = start + length;
module->next = list;
list = module;
ptr += DBG_S_C_DMT_PSECT_SIZE;
vms_debug2 ((4, "section: start = 0x%x, length = %d\n",
start, length));
}
}
}
else
{
/* We don't have a DMT section so this must be an object. Parse
the module right now in order to compute its start address and
end address. */
module = new_module (abfd);
parse_module (abfd, module, PRIV (dst_section)->contents, -1);
list = module;
}
return list;
}
/* Calculate and return the name of the source file and the line nearest
to the wanted location in the specified module. */
static bfd_boolean
module_find_nearest_line (bfd *abfd, struct module *module, bfd_vma addr,
const char **file, const char **func,
unsigned int *line)
{
struct funcinfo *funcinfo;
struct lineinfo *lineinfo;
struct srecinfo *srecinfo;
bfd_boolean ret = FALSE;
/* Parse this module if that was not done at module creation. */
if (! IS_MODULE_PARSED (module))
{
unsigned int size = module->size;
unsigned int modbeg = PRIV (dst_section)->filepos + module->modbeg;
unsigned char *buffer = (unsigned char *) bfd_malloc (module->size);
if (bfd_seek (abfd, modbeg, SEEK_SET) != 0
|| bfd_bread (buffer, size, abfd) != size)
{
bfd_set_error (bfd_error_no_debug_section);
return FALSE;
}
parse_module (abfd, module, buffer, size);
free (buffer);
}
/* Find out the function (if any) that contains the address. */
for (funcinfo = module->func_table; funcinfo; funcinfo = funcinfo->next)
if (addr >= funcinfo->low && addr <= funcinfo->high)
{
*func = funcinfo->name;
ret = TRUE;
break;
}
/* Find out the source file and the line nearest to the address. */
for (lineinfo = module->line_table; lineinfo; lineinfo = lineinfo->next)
if (lineinfo->next && addr < lineinfo->next->address)
{
for (srecinfo = module->srec_table; srecinfo; srecinfo = srecinfo->next)
if (srecinfo->next && lineinfo->line < srecinfo->next->line)
{
if (srecinfo->sfile > 0)
{
*file = module->file_table[srecinfo->sfile].name;
*line = srecinfo->srec + lineinfo->line - srecinfo->line;
}
else
{
*file = module->name;
*line = lineinfo->line;
}
return TRUE;
}
break;
}
return ret;
}
/* Provided a BFD, a section and an offset into the section, calculate and
return the name of the source file and the line nearest to the wanted
location. */
static bfd_boolean
_bfd_vms_find_nearest_dst_line (bfd *abfd, asection *section,
asymbol **symbols ATTRIBUTE_UNUSED,
bfd_vma offset, const char **file,
const char **func, unsigned int *line)
{
struct module *module;
/* What address are we looking for? */
bfd_vma addr = section->vma + offset;
*file = NULL;
*func = NULL;
*line = 0;
if (PRIV (dst_section) == NULL || !(abfd->flags & (EXEC_P | DYNAMIC)))
return FALSE;
if (PRIV (modules) == NULL)
{
PRIV (modules) = build_module_list (abfd);
if (PRIV (modules) == NULL)
return FALSE;
}
for (module = PRIV (modules); module; module = module->next)
if (addr >= module->low && addr <= module->high)
return module_find_nearest_line (abfd, module, addr, file, func, line);
return FALSE;
}
/* Canonicalizations. */
/* Set name, value, section and flags of SYM from E. */
static bfd_boolean
alpha_vms_convert_symbol (bfd *abfd, struct vms_symbol_entry *e, asymbol *sym)
{
flagword flags;
symvalue value;
asection *sec;
const char *name;
name = e->name;
value = 0;
flags = BSF_NO_FLAGS;
sec = NULL;
switch (e->typ)
{
case EGSD__C_SYM:
if (e->flags & EGSY__V_WEAK)
flags |= BSF_WEAK;
if (e->flags & EGSY__V_DEF)
{
/* Symbol definition. */
flags |= BSF_GLOBAL;
if (e->flags & EGSY__V_NORM)
flags |= BSF_FUNCTION;
value = e->value;
sec = e->section;
}
else
{
/* Symbol reference. */
sec = bfd_und_section_ptr;
}
break;
case EGSD__C_SYMG:
/* A universal symbol is by definition global... */
flags |= BSF_GLOBAL;
/* ...and dynamic in shared libraries. */
if (abfd->flags & DYNAMIC)
flags |= BSF_DYNAMIC;
if (e->flags & EGSY__V_WEAK)
flags |= BSF_WEAK;
if (!(e->flags & EGSY__V_DEF))
abort ();
if (e->flags & EGSY__V_NORM)
flags |= BSF_FUNCTION;
value = e->value;
/* sec = e->section; */
sec = bfd_abs_section_ptr;
break;
default:
return FALSE;
}
sym->name = name;
sym->section = sec;
sym->flags = flags;
sym->value = value;
return TRUE;
}
/* Return the number of bytes required to store a vector of pointers
to asymbols for all the symbols in the BFD abfd, including a
terminal NULL pointer. If there are no symbols in the BFD,
then return 0. If an error occurs, return -1. */
static long
alpha_vms_get_symtab_upper_bound (bfd *abfd)
{
vms_debug2 ((1, "alpha_vms_get_symtab_upper_bound (%p), %d symbols\n",
abfd, PRIV (gsd_sym_count)));
return (PRIV (gsd_sym_count) + 1) * sizeof (asymbol *);
}
/* Read the symbols from the BFD abfd, and fills in the vector
location with pointers to the symbols and a trailing NULL.
Return number of symbols read. */
static long
alpha_vms_canonicalize_symtab (bfd *abfd, asymbol **symbols)
{
unsigned int i;
vms_debug2 ((1, "alpha_vms_canonicalize_symtab (%p, <ret>)\n", abfd));
if (PRIV (csymbols) == NULL)
{
PRIV (csymbols) = (asymbol **) bfd_alloc
(abfd, PRIV (gsd_sym_count) * sizeof (asymbol *));
/* Traverse table and fill symbols vector. */
for (i = 0; i < PRIV (gsd_sym_count); i++)
{
struct vms_symbol_entry *e = PRIV (syms)[i];
asymbol *sym;
sym = bfd_make_empty_symbol (abfd);
if (sym == NULL || !alpha_vms_convert_symbol (abfd, e, sym))
{
bfd_release (abfd, PRIV (csymbols));
PRIV (csymbols) = NULL;
return -1;
}
PRIV (csymbols)[i] = sym;
}
}
if (symbols != NULL)
{
for (i = 0; i < PRIV (gsd_sym_count); i++)
symbols[i] = PRIV (csymbols)[i];
symbols[i] = NULL;
}
return PRIV (gsd_sym_count);
}
/* Read and convert relocations from ETIR. We do it once for all sections. */
static bfd_boolean
alpha_vms_slurp_relocs (bfd *abfd)
{
int cur_psect = -1;
vms_debug2 ((3, "alpha_vms_slurp_relocs\n"));
/* We slurp relocs only once, for all sections. */
if (PRIV (reloc_done))
return TRUE;
PRIV (reloc_done) = TRUE;
if (alpha_vms_canonicalize_symtab (abfd, NULL) < 0)
return FALSE;
if (bfd_seek (abfd, 0, SEEK_SET) != 0)
return FALSE;
while (1)
{
unsigned char *begin;
unsigned char *end;
unsigned char *ptr;
bfd_reloc_code_real_type reloc_code;
int type;
bfd_vma vaddr = 0;
int length;
bfd_vma cur_address;
int cur_psidx = -1;
unsigned char *cur_sym = NULL;
int prev_cmd = -1;
bfd_vma cur_addend = 0;
/* Skip non-ETIR records. */
type = _bfd_vms_get_object_record (abfd);
if (type == EOBJ__C_EEOM)
break;
if (type != EOBJ__C_ETIR)
continue;
begin = PRIV (recrd.rec) + 4;
end = PRIV (recrd.rec) + PRIV (recrd.rec_size);
for (ptr = begin; ptr < end; ptr += length)
{
int cmd;
cmd = bfd_getl16 (ptr);
length = bfd_getl16 (ptr + 2);
cur_address = vaddr;
vms_debug2 ((4, "alpha_vms_slurp_relocs: etir %s\n",
_bfd_vms_etir_name (cmd)));
switch (cmd)
{
case ETIR__C_STA_GBL: /* ALPHA_R_REFLONG und_section, step 1 */
/* ALPHA_R_REFQUAD und_section, step 1 */
cur_sym = ptr + 4;
prev_cmd = cmd;
continue;
case ETIR__C_STA_PQ: /* ALPHA_R_REF{LONG|QUAD}, others part 1 */
cur_psidx = bfd_getl32 (ptr + 4);
cur_addend = bfd_getl64 (ptr + 8);
prev_cmd = cmd;
continue;
case ETIR__C_CTL_SETRB:
if (prev_cmd != ETIR__C_STA_PQ)
{
(*_bfd_error_handler)
(_("Unknown reloc %s + %s"), _bfd_vms_etir_name (prev_cmd),
_bfd_vms_etir_name (cmd));
return FALSE;
}
cur_psect = cur_psidx;
vaddr = cur_addend;
cur_psidx = -1;
cur_addend = 0;
continue;
case ETIR__C_STA_LW: /* ALPHA_R_REFLONG abs_section, step 1 */
/* ALPHA_R_REFLONG und_section, step 2 */
if (prev_cmd != -1)
{
if (prev_cmd != ETIR__C_STA_GBL)
{
(*_bfd_error_handler)
(_("Unknown reloc %s + %s"), _bfd_vms_etir_name (cmd),
_bfd_vms_etir_name (ETIR__C_STA_LW));
return FALSE;
}
}
cur_addend = bfd_getl32 (ptr + 4);
prev_cmd = cmd;
continue;
case ETIR__C_STA_QW: /* ALPHA_R_REFQUAD abs_section, step 1 */
/* ALPHA_R_REFQUAD und_section, step 2 */
if (prev_cmd != -1 && prev_cmd != ETIR__C_STA_GBL)
{
(*_bfd_error_handler)
(_("Unknown reloc %s + %s"), _bfd_vms_etir_name (cmd),
_bfd_vms_etir_name (ETIR__C_STA_QW));
return FALSE;
}
cur_addend = bfd_getl64 (ptr + 4);
prev_cmd = cmd;
continue;
case ETIR__C_STO_LW: /* ALPHA_R_REFLONG und_section, step 4 */
/* ALPHA_R_REFLONG abs_section, step 2 */
/* ALPHA_R_REFLONG others, step 2 */
if (prev_cmd != ETIR__C_OPR_ADD
&& prev_cmd != ETIR__C_STA_LW
&& prev_cmd != ETIR__C_STA_PQ)
{
(*_bfd_error_handler) (_("Unknown reloc %s + %s"),
_bfd_vms_etir_name (prev_cmd),
_bfd_vms_etir_name (ETIR__C_STO_LW));
return FALSE;
}
reloc_code = BFD_RELOC_32;
break;
case ETIR__C_STO_QW: /* ALPHA_R_REFQUAD und_section, step 4 */
/* ALPHA_R_REFQUAD abs_section, step 2 */
if (prev_cmd != ETIR__C_OPR_ADD && prev_cmd != ETIR__C_STA_QW)
{
(*_bfd_error_handler) (_("Unknown reloc %s + %s"),
_bfd_vms_etir_name (prev_cmd),
_bfd_vms_etir_name (ETIR__C_STO_QW));
return FALSE;
}
reloc_code = BFD_RELOC_64;
break;
case ETIR__C_STO_OFF: /* ALPHA_R_REFQUAD others, step 2 */
if (prev_cmd != ETIR__C_STA_PQ)
{
(*_bfd_error_handler) (_("Unknown reloc %s + %s"),
_bfd_vms_etir_name (prev_cmd),
_bfd_vms_etir_name (ETIR__C_STO_OFF));
return FALSE;
}
reloc_code = BFD_RELOC_64;
break;
case ETIR__C_OPR_ADD: /* ALPHA_R_REFLONG und_section, step 3 */
/* ALPHA_R_REFQUAD und_section, step 3 */
if (prev_cmd != ETIR__C_STA_LW && prev_cmd != ETIR__C_STA_QW)
{
(*_bfd_error_handler) (_("Unknown reloc %s + %s"),
_bfd_vms_etir_name (prev_cmd),
_bfd_vms_etir_name (ETIR__C_OPR_ADD));
return FALSE;
}
prev_cmd = ETIR__C_OPR_ADD;
continue;
case ETIR__C_STO_CA: /* ALPHA_R_CODEADDR */
reloc_code = BFD_RELOC_ALPHA_CODEADDR;
cur_sym = ptr + 4;
break;
case ETIR__C_STO_GBL: /* ALPHA_R_REFQUAD und_section */
reloc_code = BFD_RELOC_64;
cur_sym = ptr + 4;
break;
case ETIR__C_STO_GBL_LW: /* ALPHA_R_REFLONG und_section */
reloc_code = BFD_RELOC_32;
cur_sym = ptr + 4;
break;
case ETIR__C_STC_LP_PSB: /* ALPHA_R_LINKAGE */
reloc_code = BFD_RELOC_ALPHA_LINKAGE;
cur_sym = ptr + 8;
break;
case ETIR__C_STC_NOP_GBL: /* ALPHA_R_NOP */
reloc_code = BFD_RELOC_ALPHA_NOP;
goto call_reloc;
case ETIR__C_STC_BSR_GBL: /* ALPHA_R_BSR */
reloc_code = BFD_RELOC_ALPHA_BSR;
goto call_reloc;
case ETIR__C_STC_LDA_GBL: /* ALPHA_R_LDA */
reloc_code = BFD_RELOC_ALPHA_LDA;
goto call_reloc;
case ETIR__C_STC_BOH_GBL: /* ALPHA_R_BOH */
reloc_code = BFD_RELOC_ALPHA_BOH;
goto call_reloc;
call_reloc:
cur_sym = ptr + 4 + 32;
cur_address = bfd_getl64 (ptr + 4 + 8);
cur_addend = bfd_getl64 (ptr + 4 + 24);
break;
case ETIR__C_STO_IMM:
vaddr += bfd_getl32 (ptr + 4);
continue;
default:
(*_bfd_error_handler) (_("Unknown reloc %s"),
_bfd_vms_etir_name (cmd));
return FALSE;
}
{
asection *sec;
struct vms_section_data_struct *vms_sec;
arelent *reloc;
/* Get section to which the relocation applies. */
if (cur_psect < 0 || cur_psect > (int)PRIV (section_count))
{
(*_bfd_error_handler) (_("Invalid section index in ETIR"));
return FALSE;
}
sec = PRIV (sections)[cur_psect];
vms_sec = vms_section_data (sec);
/* Allocate a reloc entry. */
if (sec->reloc_count >= vms_sec->reloc_max)
{
if (vms_sec->reloc_max == 0)
{
vms_sec->reloc_max = 64;
sec->relocation = bfd_zmalloc
(vms_sec->reloc_max * sizeof (arelent));
}
else
{
vms_sec->reloc_max *= 2;
sec->relocation = bfd_realloc
(sec->relocation, vms_sec->reloc_max * sizeof (arelent));
}
}
reloc = &sec->relocation[sec->reloc_count];
sec->reloc_count++;
reloc->howto = bfd_reloc_type_lookup (abfd, reloc_code);
if (cur_sym != NULL)
{
unsigned int j;
unsigned int symlen = *cur_sym;
asymbol **sym;
/* Linear search. */
symlen = *cur_sym;
cur_sym++;
sym = NULL;
for (j = 0; j < PRIV (gsd_sym_count); j++)
if (PRIV (syms)[j]->namelen == symlen
&& memcmp (PRIV (syms)[j]->name, cur_sym, symlen) == 0)
{
sym = &PRIV (csymbols)[j];
break;
}
if (sym == NULL)
{
(*_bfd_error_handler) (_("Unknown symbol in command %s"),
_bfd_vms_etir_name (cmd));
reloc->sym_ptr_ptr = NULL;
}
else
reloc->sym_ptr_ptr = sym;
}
else if (cur_psidx >= 0)
reloc->sym_ptr_ptr =
PRIV (sections)[cur_psidx]->symbol_ptr_ptr;
else
reloc->sym_ptr_ptr = NULL;
reloc->address = cur_address;
reloc->addend = cur_addend;
vaddr += bfd_get_reloc_size (reloc->howto);
}
cur_addend = 0;
prev_cmd = -1;
cur_sym = NULL;
cur_psidx = -1;
}
}
vms_debug2 ((3, "alpha_vms_slurp_relocs: result = TRUE\n"));
return TRUE;
}
/* Return the number of bytes required to store the relocation
information associated with the given section. */
static long
alpha_vms_get_reloc_upper_bound (bfd *abfd ATTRIBUTE_UNUSED, asection *section)
{
alpha_vms_slurp_relocs (abfd);
return (section->reloc_count + 1) * sizeof (arelent *);
}
/* Convert relocations from VMS (external) form into BFD internal
form. Return the number of relocations. */
static long
alpha_vms_canonicalize_reloc (bfd *abfd, asection *section, arelent **relptr,
asymbol **symbols ATTRIBUTE_UNUSED)
{
arelent *tblptr;
int count;
if (!alpha_vms_slurp_relocs (abfd))
return -1;
count = section->reloc_count;
tblptr = section->relocation;
while (count--)
*relptr++ = tblptr++;
*relptr = (arelent *) NULL;
return section->reloc_count;
}
/* This is just copied from ecoff-alpha, needs to be fixed probably. */
/* How to process the various reloc types. */
static bfd_reloc_status_type
reloc_nil (bfd * abfd ATTRIBUTE_UNUSED,
arelent *reloc ATTRIBUTE_UNUSED,
asymbol *sym ATTRIBUTE_UNUSED,
void * data ATTRIBUTE_UNUSED,
asection *sec ATTRIBUTE_UNUSED,
bfd *output_bfd ATTRIBUTE_UNUSED,
char **error_message ATTRIBUTE_UNUSED)
{
#if VMS_DEBUG
vms_debug (1, "reloc_nil (abfd %p, output_bfd %p)\n", abfd, output_bfd);
vms_debug (2, "In section %s, symbol %s\n",
sec->name, sym->name);
vms_debug (2, "reloc sym %s, addr %08lx, addend %08lx, reloc is a %s\n",
reloc->sym_ptr_ptr[0]->name,
(unsigned long)reloc->address,
(unsigned long)reloc->addend, reloc->howto->name);
vms_debug (2, "data at %p\n", data);
/* _bfd_hexdump (2, data, bfd_get_reloc_size (reloc->howto), 0); */
#endif
return bfd_reloc_ok;
}
/* 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)
static reloc_howto_type alpha_howto_table[] =
{
HOWTO (ALPHA_R_IGNORE, /* Type. */
0, /* Rightshift. */
0, /* Size (0 = byte, 1 = short, 2 = long). */
8, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"IGNORE", /* Name. */
TRUE, /* Partial_inplace. */
0, /* Source mask */
0, /* Dest mask. */
TRUE), /* PC rel offset. */
/* A 64 bit reference to a symbol. */
HOWTO (ALPHA_R_REFQUAD, /* Type. */
0, /* Rightshift. */
4, /* Size (0 = byte, 1 = short, 2 = long). */
64, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_bitfield, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"REFQUAD", /* Name. */
TRUE, /* Partial_inplace. */
MINUS_ONE, /* Source mask. */
MINUS_ONE, /* Dest mask. */
FALSE), /* PC rel offset. */
/* A 21 bit branch. The native assembler generates these for
branches within the text segment, and also fills in the PC
relative offset in the instruction. */
HOWTO (ALPHA_R_BRADDR, /* Type. */
2, /* Rightshift. */
2, /* Size (0 = byte, 1 = short, 2 = long). */
21, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_signed, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"BRADDR", /* Name. */
TRUE, /* Partial_inplace. */
0x1fffff, /* Source mask. */
0x1fffff, /* Dest mask. */
FALSE), /* PC rel offset. */
/* A hint for a jump to a register. */
HOWTO (ALPHA_R_HINT, /* Type. */
2, /* Rightshift. */
1, /* Size (0 = byte, 1 = short, 2 = long). */
14, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"HINT", /* Name. */
TRUE, /* Partial_inplace. */
0x3fff, /* Source mask. */
0x3fff, /* Dest mask. */
FALSE), /* PC rel offset. */
/* 16 bit PC relative offset. */
HOWTO (ALPHA_R_SREL16, /* Type. */
0, /* Rightshift. */
1, /* Size (0 = byte, 1 = short, 2 = long). */
16, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_signed, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"SREL16", /* Name. */
TRUE, /* Partial_inplace. */
0xffff, /* Source mask. */
0xffff, /* Dest mask. */
FALSE), /* PC rel offset. */
/* 32 bit PC relative offset. */
HOWTO (ALPHA_R_SREL32, /* Type. */
0, /* Rightshift. */
2, /* Size (0 = byte, 1 = short, 2 = long). */
32, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_signed, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"SREL32", /* Name. */
TRUE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
/* A 64 bit PC relative offset. */
HOWTO (ALPHA_R_SREL64, /* Type. */
0, /* Rightshift. */
4, /* Size (0 = byte, 1 = short, 2 = long). */
64, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_signed, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"SREL64", /* Name. */
TRUE, /* Partial_inplace. */
MINUS_ONE, /* Source mask. */
MINUS_ONE, /* Dest mask. */
FALSE), /* PC rel offset. */
/* Push a value on the reloc evaluation stack. */
HOWTO (ALPHA_R_OP_PUSH, /* Type. */
0, /* Rightshift. */
0, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"OP_PUSH", /* Name. */
FALSE, /* Partial_inplace. */
0, /* Source mask. */
0, /* Dest mask. */
FALSE), /* PC rel offset. */
/* Store the value from the stack at the given address. Store it in
a bitfield of size r_size starting at bit position r_offset. */
HOWTO (ALPHA_R_OP_STORE, /* Type. */
0, /* Rightshift. */
4, /* Size (0 = byte, 1 = short, 2 = long). */
64, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"OP_STORE", /* Name. */
FALSE, /* Partial_inplace. */
0, /* Source mask. */
MINUS_ONE, /* Dest mask. */
FALSE), /* PC rel offset. */
/* Subtract the reloc address from the value on the top of the
relocation stack. */
HOWTO (ALPHA_R_OP_PSUB, /* Type. */
0, /* Rightshift. */
0, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"OP_PSUB", /* Name. */
FALSE, /* Partial_inplace. */
0, /* Source mask. */
0, /* Dest mask. */
FALSE), /* PC rel offset. */
/* Shift the value on the top of the relocation stack right by the
given value. */
HOWTO (ALPHA_R_OP_PRSHIFT, /* Type. */
0, /* Rightshift. */
0, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"OP_PRSHIFT", /* Name. */
FALSE, /* Partial_inplace. */
0, /* Source mask. */
0, /* Dest mask. */
FALSE), /* PC rel offset. */
/* Hack. Linkage is done by linker. */
HOWTO (ALPHA_R_LINKAGE, /* Type. */
0, /* Rightshift. */
8, /* Size (0 = byte, 1 = short, 2 = long). */
256, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"LINKAGE", /* Name. */
FALSE, /* Partial_inplace. */
0, /* Source mask. */
0, /* Dest mask. */
FALSE), /* PC rel offset. */
/* A 32 bit reference to a symbol. */
HOWTO (ALPHA_R_REFLONG, /* Type. */
0, /* Rightshift. */
2, /* Size (0 = byte, 1 = short, 2 = long). */
32, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_bitfield, /* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"REFLONG", /* Name. */
TRUE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
/* A 64 bit reference to a procedure, written as 32 bit value. */
HOWTO (ALPHA_R_CODEADDR, /* Type. */
0, /* Rightshift. */
4, /* Size (0 = byte, 1 = short, 2 = long). */
64, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_signed,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"CODEADDR", /* Name. */
FALSE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
HOWTO (ALPHA_R_NOP, /* Type. */
0, /* Rightshift. */
3, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
/* The following value must match that of ALPHA_R_BSR/ALPHA_R_BOH
because the calculations for the 3 relocations are the same.
See B.4.5.2 of the OpenVMS Linker Utility Manual. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"NOP", /* Name. */
FALSE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
HOWTO (ALPHA_R_BSR, /* Type. */
0, /* Rightshift. */
3, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"BSR", /* Name. */
FALSE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
HOWTO (ALPHA_R_LDA, /* Type. */
0, /* Rightshift. */
3, /* Size (0 = byte, 1 = short, 2 = long). */
0, /* Bitsize. */
FALSE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"LDA", /* Name. */
FALSE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
HOWTO (ALPHA_R_BOH, /* Type. */
0, /* Rightshift. */
3, /* Size (0 = byte, 1 = short, 2 = long, 3 = nil). */
0, /* Bitsize. */
TRUE, /* PC relative. */
0, /* Bitpos. */
complain_overflow_dont,/* Complain_on_overflow. */
reloc_nil, /* Special_function. */
"BOH", /* Name. */
FALSE, /* Partial_inplace. */
0xffffffff, /* Source mask. */
0xffffffff, /* Dest mask. */
FALSE), /* PC rel offset. */
};
/* Return a pointer to a howto structure which, when invoked, will perform
the relocation code on data from the architecture noted. */
static const struct reloc_howto_struct *
alpha_vms_bfd_reloc_type_lookup (bfd * abfd ATTRIBUTE_UNUSED,
bfd_reloc_code_real_type code)
{
int alpha_type;
vms_debug2 ((1, "vms_bfd_reloc_type_lookup (%p, %d)\t", abfd, code));
switch (code)
{
case BFD_RELOC_16: alpha_type = ALPHA_R_SREL16; break;
case BFD_RELOC_32: alpha_type = ALPHA_R_REFLONG; break;
case BFD_RELOC_64: alpha_type = ALPHA_R_REFQUAD; break;
case BFD_RELOC_CTOR: alpha_type = ALPHA_R_REFQUAD; break;
case BFD_RELOC_23_PCREL_S2: alpha_type = ALPHA_R_BRADDR; break;
case BFD_RELOC_ALPHA_HINT: alpha_type = ALPHA_R_HINT; break;
case BFD_RELOC_16_PCREL: alpha_type = ALPHA_R_SREL16; break;
case BFD_RELOC_32_PCREL: alpha_type = ALPHA_R_SREL32; break;
case BFD_RELOC_64_PCREL: alpha_type = ALPHA_R_SREL64; break;
case BFD_RELOC_ALPHA_LINKAGE: alpha_type = ALPHA_R_LINKAGE; break;
case BFD_RELOC_ALPHA_CODEADDR: alpha_type = ALPHA_R_CODEADDR; break;
case BFD_RELOC_ALPHA_NOP: alpha_type = ALPHA_R_NOP; break;
case BFD_RELOC_ALPHA_BSR: alpha_type = ALPHA_R_BSR; break;
case BFD_RELOC_ALPHA_LDA: alpha_type = ALPHA_R_LDA; break;
case BFD_RELOC_ALPHA_BOH: alpha_type = ALPHA_R_BOH; break;
default:
(*_bfd_error_handler) ("reloc (%d) is *UNKNOWN*", code);
return NULL;
}
vms_debug2 ((2, "reloc is %s\n", alpha_howto_table[alpha_type].name));
return & alpha_howto_table[alpha_type];
}
static reloc_howto_type *
alpha_vms_bfd_reloc_name_lookup (bfd *abfd ATTRIBUTE_UNUSED,
const char *r_name)
{
unsigned int i;
for (i = 0;
i < sizeof (alpha_howto_table) / sizeof (alpha_howto_table[0]);
i++)
if (alpha_howto_table[i].name != NULL
&& strcasecmp (alpha_howto_table[i].name, r_name) == 0)
return &alpha_howto_table[i];
return NULL;
}
static long
alpha_vms_get_synthetic_symtab (bfd *abfd,
long symcount ATTRIBUTE_UNUSED,
asymbol **usyms ATTRIBUTE_UNUSED,
long dynsymcount ATTRIBUTE_UNUSED,
asymbol **dynsyms ATTRIBUTE_UNUSED,
asymbol **ret)
{
asymbol *syms;
unsigned int i;
unsigned int n = 0;
syms = (asymbol *) bfd_malloc (PRIV (norm_sym_count) * sizeof (asymbol));
*ret = syms;
if (syms == NULL)
return -1;
for (i = 0; i < PRIV (gsd_sym_count); i++)
{
struct vms_symbol_entry *e = PRIV (syms)[i];
asymbol *sym;
flagword flags;
symvalue value;
asection *sec;
const char *name;
char *sname;
int l;
name = e->name;
value = 0;
flags = BSF_LOCAL | BSF_SYNTHETIC;
sec = NULL;
switch (e->typ)
{
case EGSD__C_SYM:
case EGSD__C_SYMG:
if ((e->flags & EGSY__V_DEF) && (e->flags & EGSY__V_NORM))
{
value = e->code_value;
sec = e->code_section;
}
else
continue;
break;
default:
continue;
}
l = strlen (name);
sname = bfd_alloc (abfd, l + 5);
if (sname == NULL)
return FALSE;
memcpy (sname, name, l);
memcpy (sname + l, "..en", 5);
sym = &syms[n++];
sym->name = sname;
sym->section = sec;
sym->flags = flags;
sym->value = value;
sym->udata.p = NULL;
}
return n;
}
/* Private dump. */
static const char *
vms_time_to_str (unsigned char *buf)
{
time_t t = vms_rawtime_to_time_t (buf);
char *res = ctime (&t);
if (!res)
res = "*invalid time*";
else
res[24] = 0;
return res;
}
static void
evax_bfd_print_emh (FILE *file, unsigned char *rec, unsigned int rec_len)
{
struct vms_emh_common *emh = (struct vms_emh_common *)rec;
unsigned int subtype;
subtype = (unsigned)bfd_getl16 (emh->subtyp);
fprintf (file, _(" EMH %u (len=%u): "), subtype, rec_len);
switch (subtype)
{
case EMH__C_MHD:
{
struct vms_emh_mhd *mhd = (struct vms_emh_mhd *)rec;
const char *name;
fprintf (file, _("Module header\n"));
fprintf (file, _(" structure level: %u\n"), mhd->strlvl);
fprintf (file, _(" max record size: %u\n"),
(unsigned)bfd_getl32 (mhd->recsiz));
name = (char *)(mhd + 1);
fprintf (file, _(" module name : %.*s\n"), name[0], name + 1);
name += name[0] + 1;
fprintf (file, _(" module version : %.*s\n"), name[0], name + 1);
name += name[0] + 1;
fprintf (file, _(" compile date : %.17s\n"), name);
}
break;
case EMH__C_LNM:
{
fprintf (file, _("Language Processor Name\n"));
fprintf (file, _(" language name: %.*s\n"),
(int)(rec_len - sizeof (struct vms_emh_common)),
(char *)rec + sizeof (struct vms_emh_common));
}
break;
case EMH__C_SRC:
{
fprintf (file, _("Source Files Header\n"));
fprintf (file, _(" file: %.*s\n"),
(int)(rec_len - sizeof (struct vms_emh_common)),
(char *)rec + sizeof (struct vms_emh_common));
}
break;
case EMH__C_TTL:
{
fprintf (file, _("Title Text Header\n"));
fprintf (file, _(" title: %.*s\n"),
(int)(rec_len - sizeof (struct vms_emh_common)),
(char *)rec + sizeof (struct vms_emh_common));
}
break;
case EMH__C_CPR:
{
fprintf (file, _("Copyright Header\n"));
fprintf (file, _(" copyright: %.*s\n"),
(int)(rec_len - sizeof (struct vms_emh_common)),
(char *)rec + sizeof (struct vms_emh_common));
}
break;
default:
fprintf (file, _("unhandled emh subtype %u\n"), subtype);
break;
}
}
static void
evax_bfd_print_eeom (FILE *file, unsigned char *rec, unsigned int rec_len)
{
struct vms_eeom *eeom = (struct vms_eeom *)rec;
fprintf (file, _(" EEOM (len=%u):\n"), rec_len);
fprintf (file, _(" number of cond linkage pairs: %u\n"),
(unsigned)bfd_getl32 (eeom->total_lps));
fprintf (file, _(" completion code: %u\n"),
(unsigned)bfd_getl16 (eeom->comcod));
if (rec_len > 10)
{
fprintf (file, _(" transfer addr flags: 0x%02x\n"), eeom->tfrflg);
fprintf (file, _(" transfer addr psect: %u\n"),
(unsigned)bfd_getl32 (eeom->psindx));
fprintf (file, _(" transfer address : 0x%08x\n"),
(unsigned)bfd_getl32 (eeom->tfradr));
}
}
static void
exav_bfd_print_egsy_flags (unsigned int flags, FILE *file)
{
if (flags & EGSY__V_WEAK)
fputs (_(" WEAK"), file);
if (flags & EGSY__V_DEF)
fputs (_(" DEF"), file);
if (flags & EGSY__V_UNI)
fputs (_(" UNI"), file);
if (flags & EGSY__V_REL)
fputs (_(" REL"), file);
if (flags & EGSY__V_COMM)
fputs (_(" COMM"), file);
if (flags & EGSY__V_VECEP)
fputs (_(" VECEP"), file);
if (flags & EGSY__V_NORM)
fputs (_(" NORM"), file);
if (flags & EGSY__V_QUAD_VAL)
fputs (_(" QVAL"), file);
}
static void
evax_bfd_print_egsd_flags (FILE *file, unsigned int flags)
{
if (flags & EGPS__V_PIC)
fputs (_(" PIC"), file);
if (flags & EGPS__V_LIB)
fputs (_(" LIB"), file);
if (flags & EGPS__V_OVR)
fputs (_(" OVR"), file);
if (flags & EGPS__V_REL)
fputs (_(" REL"), file);
if (flags & EGPS__V_GBL)
fputs (_(" GBL"), file);
if (flags & EGPS__V_SHR)
fputs (_(" SHR"), file);
if (flags & EGPS__V_EXE)
fputs (_(" EXE"), file);
if (flags & EGPS__V_RD)
fputs (_(" RD"), file);
if (flags & EGPS__V_WRT)
fputs (_(" WRT"), file);
if (flags & EGPS__V_VEC)
fputs (_(" VEC"), file);
if (flags & EGPS__V_NOMOD)
fputs (_(" NOMOD"), file);
if (flags & EGPS__V_COM)
fputs (_(" COM"), file);
if (flags & EGPS__V_ALLOC_64BIT)
fputs (_(" 64B"), file);
}
static void
evax_bfd_print_egsd (FILE *file, unsigned char *rec, unsigned int rec_len)
{
unsigned int off = sizeof (struct vms_egsd);
unsigned int n;
fprintf (file, _(" EGSD (len=%u):\n"), rec_len);
n = 0;
for (off = sizeof (struct vms_egsd); off < rec_len; )
{
struct vms_egsd_entry *e = (struct vms_egsd_entry *)(rec + off);
unsigned int type;
unsigned int len;
type = (unsigned)bfd_getl16 (e->gsdtyp);
len = (unsigned)bfd_getl16 (e->gsdsiz);
fprintf (file, _(" EGSD entry %2u (type: %u, len: %u): "),
n, type, len);
n++;
switch (type)
{
case EGSD__C_PSC:
{
struct vms_egps *egps = (struct vms_egps *)e;
unsigned int flags = bfd_getl16 (egps->flags);
unsigned int l;
fprintf (file, _("PSC - Program section definition\n"));
fprintf (file, _(" alignment : 2**%u\n"), egps->align);
fprintf (file, _(" flags : 0x%04x"), flags);
evax_bfd_print_egsd_flags (file, flags);
fputc ('\n', file);
l = bfd_getl32 (egps->alloc);
fprintf (file, _(" alloc (len): %u (0x%08x)\n"), l, l);
fprintf (file, _(" name : %.*s\n"),
egps->namlng, egps->name);
}
break;
case EGSD__C_SPSC:
{
struct vms_esgps *esgps = (struct vms_esgps *)e;
unsigned int flags = bfd_getl16 (esgps->flags);
unsigned int l;
fprintf (file, _("SPSC - Shared Image Program section def\n"));
fprintf (file, _(" alignment : 2**%u\n"), esgps->align);
fprintf (file, _(" flags : 0x%04x"), flags);
evax_bfd_print_egsd_flags (file, flags);
fputc ('\n', file);
l = bfd_getl32 (esgps->alloc);
fprintf (file, _(" alloc (len) : %u (0x%08x)\n"), l, l);
fprintf (file, _(" image offset : 0x%08x\n"),
(unsigned int)bfd_getl32 (esgps->base));
fprintf (file, _(" symvec offset : 0x%08x\n"),
(unsigned int)bfd_getl32 (esgps->value));
fprintf (file, _(" name : %.*s\n"),
esgps->namlng, esgps->name);
}
break;
case EGSD__C_SYM:
{
struct vms_egsy *egsy = (struct vms_egsy *)e;
unsigned int flags = bfd_getl16 (egsy->flags);
if (flags & EGSY__V_DEF)
{
struct vms_esdf *esdf = (struct vms_esdf *)e;
fprintf (file, _("SYM - Global symbol definition\n"));
fprintf (file, _(" flags: 0x%04x"), flags);
exav_bfd_print_egsy_flags (flags, file);
fputc ('\n', file);
fprintf (file, _(" psect offset: 0x%08x\n"),
(unsigned)bfd_getl32 (esdf->value));
if (flags & EGSY__V_NORM)
{
fprintf (file, _(" code address: 0x%08x\n"),
(unsigned)bfd_getl32 (esdf->code_address));
fprintf (file, _(" psect index for entry point : %u\n"),
(unsigned)bfd_getl32 (esdf->ca_psindx));
}
fprintf (file, _(" psect index : %u\n"),
(unsigned)bfd_getl32 (esdf->psindx));
fprintf (file, _(" name : %.*s\n"),
esdf->namlng, esdf->name);
}
else
{
struct vms_esrf *esrf = (struct vms_esrf *)e;
fprintf (file, _("SYM - Global symbol reference\n"));
fprintf (file, _(" name : %.*s\n"),
esrf->namlng, esrf->name);
}
}
break;
case EGSD__C_IDC:
{
struct vms_eidc *eidc = (struct vms_eidc *)e;
unsigned int flags = bfd_getl32 (eidc->flags);
unsigned char *p;
fprintf (file, _("IDC - Ident Consistency check\n"));
fprintf (file, _(" flags : 0x%08x"), flags);
if (flags & EIDC__V_BINIDENT)
fputs (" BINDENT", file);
fputc ('\n', file);
fprintf (file, _(" id match : %x\n"),
(flags >> EIDC__V_IDMATCH_SH) & EIDC__V_IDMATCH_MASK);
fprintf (file, _(" error severity: %x\n"),
(flags >> EIDC__V_ERRSEV_SH) & EIDC__V_ERRSEV_MASK);
p = eidc->name;
fprintf (file, _(" entity name : %.*s\n"), p[0], p + 1);
p += 1 + p[0];
fprintf (file, _(" object name : %.*s\n"), p[0], p + 1);
p += 1 + p[0];
if (flags & EIDC__V_BINIDENT)
fprintf (file, _(" binary ident : 0x%08x\n"),
(unsigned)bfd_getl32 (p + 1));
else
fprintf (file, _(" ascii ident : %.*s\n"), p[0], p + 1);
}
break;
case EGSD__C_SYMG:
{
struct vms_egst *egst = (struct vms_egst *)e;
unsigned int flags = bfd_getl16 (egst->header.flags);
fprintf (file, _("SYMG - Universal symbol definition\n"));
fprintf (file, _(" flags: 0x%04x"), flags);
exav_bfd_print_egsy_flags (flags, file);
fputc ('\n', file);
fprintf (file, _(" symbol vector offset: 0x%08x\n"),
(unsigned)bfd_getl32 (egst->value));
fprintf (file, _(" entry point: 0x%08x\n"),
(unsigned)bfd_getl32 (egst->lp_1));
fprintf (file, _(" proc descr : 0x%08x\n"),
(unsigned)bfd_getl32 (egst->lp_2));
fprintf (file, _(" psect index: %u\n"),
(unsigned)bfd_getl32 (egst->psindx));
fprintf (file, _(" name : %.*s\n"),
egst->namlng, egst->name);
}
break;
case EGSD__C_SYMV:
{
struct vms_esdfv *esdfv = (struct vms_esdfv *)e;
unsigned int flags = bfd_getl16 (esdfv->flags);
fprintf (file, _("SYMV - Vectored symbol definition\n"));
fprintf (file, _(" flags: 0x%04x"), flags);
exav_bfd_print_egsy_flags (flags, file);
fputc ('\n', file);
fprintf (file, _(" vector : 0x%08x\n"),
(unsigned)bfd_getl32 (esdfv->vector));
fprintf (file, _(" psect offset: %u\n"),
(unsigned)bfd_getl32 (esdfv->value));
fprintf (file, _(" psect index : %u\n"),
(unsigned)bfd_getl32 (esdfv->psindx));
fprintf (file, _(" name : %.*s\n"),
esdfv->namlng, esdfv->name);
}
break;
case EGSD__C_SYMM:
{
struct vms_esdfm *esdfm = (struct vms_esdfm *)e;
unsigned int flags = bfd_getl16 (esdfm->flags);
fprintf (file, _("SYMM - Global symbol definition with version\n"));
fprintf (file, _(" flags: 0x%04x"), flags);
exav_bfd_print_egsy_flags (flags, file);
fputc ('\n', file);
fprintf (file, _(" version mask: 0x%08x\n"),
(unsigned)bfd_getl32 (esdfm->version_mask));
fprintf (file, _(" psect offset: %u\n"),
(unsigned)bfd_getl32 (esdfm->value));
fprintf (file, _(" psect index : %u\n"),
(unsigned)bfd_getl32 (esdfm->psindx));
fprintf (file, _(" name : %.*s\n"),
esdfm->namlng, esdfm->name);
}
break;
default:
fprintf (file, _("unhandled egsd entry type %u\n"), type);
break;
}
off += len;
}
}
static void
evax_bfd_print_hex (FILE *file, const char *pfx,
const unsigned char *buf, unsigned int len)
{
unsigned int i;
unsigned int n;
n = 0;
for (i = 0; i < len; i++)
{
if (n == 0)
fputs (pfx, file);
fprintf (file, " %02x", buf[i]);
n++;
if (n == 16)
{
n = 0;
fputc ('\n', file);
}
}
if (n != 0)
fputc ('\n', file);
}
static void
evax_bfd_print_etir_stc_ir (FILE *file, const unsigned char *buf, int is_ps)
{
fprintf (file, _(" linkage index: %u, replacement insn: 0x%08x\n"),
(unsigned)bfd_getl32 (buf),
(unsigned)bfd_getl32 (buf + 16));
fprintf (file, _(" psect idx 1: %u, offset 1: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf + 4),
(unsigned)bfd_getl32 (buf + 12),
(unsigned)bfd_getl32 (buf + 8));
fprintf (file, _(" psect idx 2: %u, offset 2: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf + 20),
(unsigned)bfd_getl32 (buf + 28),
(unsigned)bfd_getl32 (buf + 24));
if (is_ps)
fprintf (file, _(" psect idx 3: %u, offset 3: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf + 32),
(unsigned)bfd_getl32 (buf + 40),
(unsigned)bfd_getl32 (buf + 36));
else
fprintf (file, _(" global name: %.*s\n"), buf[32], buf + 33);
}
static void
evax_bfd_print_etir (FILE *file, const char *name,
unsigned char *rec, unsigned int rec_len)
{
unsigned int off = sizeof (struct vms_egsd);
unsigned int sec_len;
fprintf (file, _(" %s (len=%u+%u):\n"), name,
(unsigned)(rec_len - sizeof (struct vms_eobjrec)),
(unsigned)sizeof (struct vms_eobjrec));
for (off = sizeof (struct vms_eobjrec); off < rec_len; )
{
struct vms_etir *etir = (struct vms_etir *)(rec + off);
unsigned char *buf;
unsigned int type;
unsigned int size;
type = bfd_getl16 (etir->rectyp);
size = bfd_getl16 (etir->size);
buf = rec + off + sizeof (struct vms_etir);
fprintf (file, _(" (type: %3u, size: 4+%3u): "), type, size - 4);
switch (type)
{
case ETIR__C_STA_GBL:
fprintf (file, _("STA_GBL (stack global) %.*s\n"),
buf[0], buf + 1);
break;
case ETIR__C_STA_LW:
fprintf (file, _("STA_LW (stack longword) 0x%08x\n"),
(unsigned)bfd_getl32 (buf));
break;
case ETIR__C_STA_QW:
fprintf (file, _("STA_QW (stack quadword) 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf + 4),
(unsigned)bfd_getl32 (buf + 0));
break;
case ETIR__C_STA_PQ:
fprintf (file, _("STA_PQ (stack psect base + offset)\n"));
fprintf (file, _(" psect: %u, offset: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf + 0),
(unsigned)bfd_getl32 (buf + 8),
(unsigned)bfd_getl32 (buf + 4));
break;
case ETIR__C_STA_LI:
fprintf (file, _("STA_LI (stack literal)\n"));
break;
case ETIR__C_STA_MOD:
fprintf (file, _("STA_MOD (stack module)\n"));
break;
case ETIR__C_STA_CKARG:
fprintf (file, _("STA_CKARG (compare procedure argument)\n"));
break;
case ETIR__C_STO_B:
fprintf (file, _("STO_B (store byte)\n"));
break;
case ETIR__C_STO_W:
fprintf (file, _("STO_W (store word)\n"));
break;
case ETIR__C_STO_LW:
fprintf (file, _("STO_LW (store longword)\n"));
break;
case ETIR__C_STO_QW:
fprintf (file, _("STO_QW (store quadword)\n"));
break;
case ETIR__C_STO_IMMR:
{
unsigned int len = bfd_getl32 (buf);
fprintf (file,
_("STO_IMMR (store immediate repeat) %u bytes\n"),
len);
evax_bfd_print_hex (file, " ", buf + 4, len);
sec_len += len;
}
break;
case ETIR__C_STO_GBL:
fprintf (file, _("STO_GBL (store global) %.*s\n"),
buf[0], buf + 1);
break;
case ETIR__C_STO_CA:
fprintf (file, _("STO_CA (store code address) %.*s\n"),
buf[0], buf + 1);
break;
case ETIR__C_STO_RB:
fprintf (file, _("STO_RB (store relative branch)\n"));
break;
case ETIR__C_STO_AB:
fprintf (file, _("STO_AB (store absolute branch)\n"));
break;
case ETIR__C_STO_OFF:
fprintf (file, _("STO_OFF (store offset to psect)\n"));
break;
case ETIR__C_STO_IMM:
{
unsigned int len = bfd_getl32 (buf);
fprintf (file,
_("STO_IMM (store immediate) %u bytes\n"),
len);
evax_bfd_print_hex (file, " ", buf + 4, len);
sec_len += len;
}
break;
case ETIR__C_STO_GBL_LW:
fprintf (file, _("STO_GBL_LW (store global longword) %.*s\n"),
buf[0], buf + 1);
break;
case ETIR__C_STO_LP_PSB:
fprintf (file, _("STO_OFF (store LP with procedure signature)\n"));
break;
case ETIR__C_STO_HINT_GBL:
fprintf (file, _("STO_BR_GBL (store branch global) *todo*\n"));
break;
case ETIR__C_STO_HINT_PS:
fprintf (file, _("STO_BR_PS (store branch psect + offset) *todo*\n"));
break;
case ETIR__C_OPR_NOP:
fprintf (file, _("OPR_NOP (no-operation)\n"));
break;
case ETIR__C_OPR_ADD:
fprintf (file, _("OPR_ADD (add)\n"));
break;
case ETIR__C_OPR_SUB:
fprintf (file, _("OPR_SUB (substract)\n"));
break;
case ETIR__C_OPR_MUL:
fprintf (file, _("OPR_MUL (multiply)\n"));
break;
case ETIR__C_OPR_DIV:
fprintf (file, _("OPR_DIV (divide)\n"));
break;
case ETIR__C_OPR_AND:
fprintf (file, _("OPR_AND (logical and)\n"));
break;
case ETIR__C_OPR_IOR:
fprintf (file, _("OPR_IOR (logical inclusive or)\n"));
break;
case ETIR__C_OPR_EOR:
fprintf (file, _("OPR_EOR (logical exclusive or)\n"));
break;
case ETIR__C_OPR_NEG:
fprintf (file, _("OPR_NEG (negate)\n"));
break;
case ETIR__C_OPR_COM:
fprintf (file, _("OPR_COM (complement)\n"));
break;
case ETIR__C_OPR_INSV:
fprintf (file, _("OPR_INSV (insert field)\n"));
break;
case ETIR__C_OPR_ASH:
fprintf (file, _("OPR_ASH (arithmetic shift)\n"));
break;
case ETIR__C_OPR_USH:
fprintf (file, _("OPR_USH (unsigned shift)\n"));
break;
case ETIR__C_OPR_ROT:
fprintf (file, _("OPR_ROT (rotate)\n"));
break;
case ETIR__C_OPR_SEL:
fprintf (file, _("OPR_SEL (select)\n"));
break;
case ETIR__C_OPR_REDEF:
fprintf (file, _("OPR_REDEF (redefine symbol to curr location)\n"));
break;
case ETIR__C_OPR_DFLIT:
fprintf (file, _("OPR_REDEF (define a literal)\n"));
break;
case ETIR__C_STC_LP:
fprintf (file, _("STC_LP (store cond linkage pair)\n"));
break;
case ETIR__C_STC_LP_PSB:
fprintf (file,
_("STC_LP_PSB (store cond linkage pair + signature)\n"));
fprintf (file, _(" linkage index: %u, procedure: %.*s\n"),
(unsigned)bfd_getl32 (buf), buf[4], buf + 5);
buf += 4 + 1 + buf[4];
fprintf (file, _(" signature: %.*s\n"), buf[0], buf + 1);
break;
case ETIR__C_STC_GBL:
fprintf (file, _("STC_GBL (store cond global)\n"));
fprintf (file, _(" linkage index: %u, global: %.*s\n"),
(unsigned)bfd_getl32 (buf), buf[4], buf + 5);
break;
case ETIR__C_STC_GCA:
fprintf (file, _("STC_GCA (store cond code address)\n"));
fprintf (file, _(" linkage index: %u, procedure name: %.*s\n"),
(unsigned)bfd_getl32 (buf), buf[4], buf + 5);
break;
case ETIR__C_STC_PS:
fprintf (file, _("STC_PS (store cond psect + offset)\n"));
fprintf (file,
_(" linkage index: %u, psect: %u, offset: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (buf),
(unsigned)bfd_getl32 (buf + 4),
(unsigned)bfd_getl32 (buf + 12),
(unsigned)bfd_getl32 (buf + 8));
break;
case ETIR__C_STC_NOP_GBL:
fprintf (file, _("STC_NOP_GBL (store cond NOP at global addr)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 0);
break;
case ETIR__C_STC_NOP_PS:
fprintf (file, _("STC_NOP_PS (store cond NOP at psect + offset)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 1);
break;
case ETIR__C_STC_BSR_GBL:
fprintf (file, _("STC_BSR_GBL (store cond BSR at global addr)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 0);
break;
case ETIR__C_STC_BSR_PS:
fprintf (file, _("STC_BSR_PS (store cond BSR at psect + offset)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 1);
break;
case ETIR__C_STC_LDA_GBL:
fprintf (file, _("STC_LDA_GBL (store cond LDA at global addr)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 0);
break;
case ETIR__C_STC_LDA_PS:
fprintf (file, _("STC_LDA_PS (store cond LDA at psect + offset)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 1);
break;
case ETIR__C_STC_BOH_GBL:
fprintf (file, _("STC_BOH_GBL (store cond BOH at global addr)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 0);
break;
case ETIR__C_STC_BOH_PS:
fprintf (file, _("STC_BOH_PS (store cond BOH at psect + offset)\n"));
evax_bfd_print_etir_stc_ir (file, buf, 1);
break;
case ETIR__C_STC_NBH_GBL:
fprintf (file,
_("STC_NBH_GBL (store cond or hint at global addr)\n"));
break;
case ETIR__C_STC_NBH_PS:
fprintf (file,
_("STC_NBH_PS (store cond or hint at psect + offset)\n"));
break;
case ETIR__C_CTL_SETRB:
fprintf (file, _("CTL_SETRB (set relocation base)\n"));
sec_len += 4;
break;
case ETIR__C_CTL_AUGRB:
{
unsigned int val = bfd_getl32 (buf);
fprintf (file, _("CTL_AUGRB (augment relocation base) %u\n"), val);
}
break;
case ETIR__C_CTL_DFLOC:
fprintf (file, _("CTL_DFLOC (define location)\n"));
break;
case ETIR__C_CTL_STLOC:
fprintf (file, _("CTL_STLOC (set location)\n"));
break;
case ETIR__C_CTL_STKDL:
fprintf (file, _("CTL_STKDL (stack defined location)\n"));
break;
default:
fprintf (file, _("*unhandled*\n"));
break;
}
off += size;
}
}
static void
evax_bfd_print_eobj (struct bfd *abfd, FILE *file)
{
bfd_boolean is_first = TRUE;
bfd_boolean has_records = FALSE;
while (1)
{
unsigned int rec_len;
unsigned int pad_len;
unsigned char *rec;
unsigned int hdr_size;
unsigned int type;
if (is_first)
{
unsigned char buf[6];
is_first = FALSE;
/* Read 6 bytes. */
if (bfd_bread (buf, sizeof (buf), abfd) != sizeof (buf))
{
fprintf (file, _("cannot read GST record length\n"));
return;
}
rec_len = bfd_getl16 (buf + 0);
if (rec_len == bfd_getl16 (buf + 4)
&& bfd_getl16 (buf + 2) == EOBJ__C_EMH)
{
/* The format is raw: record-size, type, record-size. */
has_records = TRUE;
pad_len = (rec_len + 1) & ~1U;
hdr_size = 4;
}
else if (rec_len == EOBJ__C_EMH)
{
has_records = FALSE;
pad_len = bfd_getl16 (buf + 2);
hdr_size = 6;
}
else
{
/* Ill-formed. */
fprintf (file, _("cannot find EMH in first GST record\n"));
return;
}
rec = bfd_malloc (pad_len);
memcpy (rec, buf + sizeof (buf) - hdr_size, hdr_size);
}
else
{
unsigned int rec_len2 = 0;
unsigned char hdr[4];
if (has_records)
{
unsigned char buf_len[2];
if (bfd_bread (buf_len, sizeof (buf_len), abfd)
!= sizeof (buf_len))
{
fprintf (file, _("cannot read GST record length\n"));
return;
}
rec_len2 = (unsigned)bfd_getl16 (buf_len);
}
if (bfd_bread (hdr, sizeof (hdr), abfd) != sizeof (hdr))
{
fprintf (file, _("cannot read GST record header\n"));
return;
}
rec_len = (unsigned)bfd_getl16 (hdr + 2);
if (has_records)
pad_len = (rec_len + 1) & ~1U;
else
pad_len = rec_len;
rec = bfd_malloc (pad_len);
memcpy (rec, hdr, sizeof (hdr));
hdr_size = sizeof (hdr);
if (has_records && rec_len2 != rec_len)
{
fprintf (file, _(" corrupted GST\n"));
break;
}
}
if (bfd_bread (rec + hdr_size, pad_len - hdr_size, abfd)
!= pad_len - hdr_size)
{
fprintf (file, _("cannot read GST record\n"));
return;
}
type = (unsigned)bfd_getl16 (rec);
switch (type)
{
case EOBJ__C_EMH:
evax_bfd_print_emh (file, rec, rec_len);
break;
case EOBJ__C_EGSD:
evax_bfd_print_egsd (file, rec, rec_len);
break;
case EOBJ__C_EEOM:
evax_bfd_print_eeom (file, rec, rec_len);
free (rec);
return;
break;
case EOBJ__C_ETIR:
evax_bfd_print_etir (file, "ETIR", rec, rec_len);
break;
case EOBJ__C_EDBG:
evax_bfd_print_etir (file, "EDBG", rec, rec_len);
break;
case EOBJ__C_ETBT:
evax_bfd_print_etir (file, "ETBT", rec, rec_len);
break;
default:
fprintf (file, _(" unhandled EOBJ record type %u\n"), type);
break;
}
free (rec);
}
}
static void
evax_bfd_print_relocation_records (FILE *file, const unsigned char *rel,
unsigned int stride)
{
while (1)
{
unsigned int base;
unsigned int count;
unsigned int j;
count = bfd_getl32 (rel + 0);
if (count == 0)
break;
base = bfd_getl32 (rel + 4);
fprintf (file, _(" bitcount: %u, base addr: 0x%08x\n"),
count, base);
rel += 8;
for (j = 0; count > 0; j += 4, count -= 32)
{
unsigned int k;
unsigned int n = 0;
unsigned int val;
val = bfd_getl32 (rel);
rel += 4;
fprintf (file, _(" bitmap: 0x%08x (count: %u):\n"), val, count);
for (k = 0; k < 32; k++)
if (val & (1 << k))
{
if (n == 0)
fputs (" ", file);
fprintf (file, _(" %08x"), base + (j * 8 + k) * stride);
n++;
if (n == 8)
{
fputs ("\n", file);
n = 0;
}
}
if (n)
fputs ("\n", file);
}
}
}
static void
evax_bfd_print_address_fixups (FILE *file, const unsigned char *rel)
{
while (1)
{
unsigned int j;
unsigned int count;
count = bfd_getl32 (rel + 0);
if (count == 0)
return;
fprintf (file, _(" image %u (%u entries)\n"),
(unsigned)bfd_getl32 (rel + 4), count);
rel += 8;
for (j = 0; j < count; j++)
{
fprintf (file, _(" offset: 0x%08x, val: 0x%08x\n"),
(unsigned)bfd_getl32 (rel + 0),
(unsigned)bfd_getl32 (rel + 4));
rel += 8;
}
}
}
static void
evax_bfd_print_reference_fixups (FILE *file, const unsigned char *rel)
{
unsigned int count;
while (1)
{
unsigned int j;
unsigned int n = 0;
count = bfd_getl32 (rel + 0);
if (count == 0)
break;
fprintf (file, _(" image %u (%u entries), offsets:\n"),
(unsigned)bfd_getl32 (rel + 4), count);
rel += 8;
for (j = 0; j < count; j++)
{
if (n == 0)
fputs (" ", file);
fprintf (file, _(" 0x%08x"), (unsigned)bfd_getl32 (rel));
n++;
if (n == 7)
{
fputs ("\n", file);
n = 0;
}
rel += 4;
}
if (n)
fputs ("\n", file);
}
}
static void
evax_bfd_print_indent (int indent, FILE *file)
{
for (; indent; indent--)
fputc (' ', file);
}
static const char *
evax_bfd_get_dsc_name (unsigned int v)
{
switch (v)
{
case DSC__K_DTYPE_Z:
return "Z (Unspecified)";
case DSC__K_DTYPE_V:
return "V (Bit)";
case DSC__K_DTYPE_BU:
return "BU (Byte logical)";
case DSC__K_DTYPE_WU:
return "WU (Word logical)";
case DSC__K_DTYPE_LU:
return "LU (Longword logical)";
case DSC__K_DTYPE_QU:
return "QU (Quadword logical)";
case DSC__K_DTYPE_B:
return "B (Byte integer)";
case DSC__K_DTYPE_W:
return "W (Word integer)";
case DSC__K_DTYPE_L:
return "L (Longword integer)";
case DSC__K_DTYPE_Q:
return "Q (Quadword integer)";
case DSC__K_DTYPE_F:
return "F (Single-precision floating)";
case DSC__K_DTYPE_D:
return "D (Double-precision floating)";
case DSC__K_DTYPE_FC:
return "FC (Complex)";
case DSC__K_DTYPE_DC:
return "DC (Double-precision Complex)";
case DSC__K_DTYPE_T:
return "T (ASCII text string)";
case DSC__K_DTYPE_NU:
return "NU (Numeric string, unsigned)";
case DSC__K_DTYPE_NL:
return "NL (Numeric string, left separate sign)";
case DSC__K_DTYPE_NLO:
return "NLO (Numeric string, left overpunched sign)";
case DSC__K_DTYPE_NR:
return "NR (Numeric string, right separate sign)";
case DSC__K_DTYPE_NRO:
return "NRO (Numeric string, right overpunched sig)";
case DSC__K_DTYPE_NZ:
return "NZ (Numeric string, zoned sign)";
case DSC__K_DTYPE_P:
return "P (Packed decimal string)";
case DSC__K_DTYPE_ZI:
return "ZI (Sequence of instructions)";
case DSC__K_DTYPE_ZEM:
return "ZEM (Procedure entry mask)";
case DSC__K_DTYPE_DSC:
return "DSC (Descriptor, used for arrays of dyn strings)";
case DSC__K_DTYPE_OU:
return "OU (Octaword logical)";
case DSC__K_DTYPE_O:
return "O (Octaword integer)";
case DSC__K_DTYPE_G:
return "G (Double precision G floating, 64 bit)";
case DSC__K_DTYPE_H:
return "H (Quadruple precision floating, 128 bit)";
case DSC__K_DTYPE_GC:
return "GC (Double precision complex, G floating)";
case DSC__K_DTYPE_HC:
return "HC (Quadruple precision complex, H floating)";
case DSC__K_DTYPE_CIT:
return "CIT (COBOL intermediate temporary)";
case DSC__K_DTYPE_BPV:
return "BPV (Bound Procedure Value)";
case DSC__K_DTYPE_BLV:
return "BLV (Bound Label Value)";
case DSC__K_DTYPE_VU:
return "VU (Bit Unaligned)";
case DSC__K_DTYPE_ADT:
return "ADT (Absolute Date-Time)";
case DSC__K_DTYPE_VT:
return "VT (Varying Text)";
case DSC__K_DTYPE_T2:
return "T2 (16-bit char)";
case DSC__K_DTYPE_VT2:
return "VT2 (16-bit varying char)";
default:
return "?? (unknown)";
}
}
static void
evax_bfd_print_desc (const unsigned char *buf, int indent, FILE *file)
{
unsigned char bclass = buf[3];
unsigned char dtype = buf[2];
unsigned int len = (unsigned)bfd_getl16 (buf);
unsigned int pointer = (unsigned)bfd_getl32 (buf + 4);
evax_bfd_print_indent (indent, file);
if (len == 1 && pointer == 0xffffffffUL)
{
/* 64 bits. */
fprintf (file, _("64 bits *unhandled*\n"));
}
else
{
fprintf (file, _("class: %u, dtype: %u, length: %u, pointer: 0x%08x\n"),
bclass, dtype, len, pointer);
switch (bclass)
{
case DSC__K_CLASS_NCA:
{
const struct vms_dsc_nca *dsc = (const void *)buf;
unsigned int i;
const unsigned char *b;
evax_bfd_print_indent (indent, file);
fprintf (file, _("non-contiguous array of %s\n"),
evax_bfd_get_dsc_name (dsc->dtype));
evax_bfd_print_indent (indent + 1, file);
fprintf (file,
_("dimct: %u, aflags: 0x%02x, digits: %u, scale: %u\n"),
dsc->dimct, dsc->aflags, dsc->digits, dsc->scale);
evax_bfd_print_indent (indent + 1, file);
fprintf (file,
_("arsize: %u, a0: 0x%08x\n"),
(unsigned)bfd_getl32 (dsc->arsize),
(unsigned)bfd_getl32 (dsc->a0));
evax_bfd_print_indent (indent + 1, file);
fprintf (file, _("Strides:\n"));
b = buf + sizeof (*dsc);
for (i = 0; i < dsc->dimct; i++)
{
evax_bfd_print_indent (indent + 2, file);
fprintf (file, _("[%u]: %u\n"), i + 1,
(unsigned)bfd_getl32 (b));
b += 4;
}
evax_bfd_print_indent (indent + 1, file);
fprintf (file, _("Bounds:\n"));
b = buf + sizeof (*dsc);
for (i = 0; i < dsc->dimct; i++)
{
evax_bfd_print_indent (indent + 2, file);
fprintf (file, _("[%u]: Lower: %u, upper: %u\n"), i + 1,
(unsigned)bfd_getl32 (b + 0),
(unsigned)bfd_getl32 (b + 4));
b += 8;
}
}
break;
case DSC__K_CLASS_UBS:
{
const struct vms_dsc_ubs *ubs = (const void *)buf;
evax_bfd_print_indent (indent, file);
fprintf (file, _("unaligned bit-string of %s\n"),
evax_bfd_get_dsc_name (ubs->dtype));
evax_bfd_print_indent (indent + 1, file);
fprintf (file,
_("base: %u, pos: %u\n"),
(unsigned)bfd_getl32 (ubs->base),
(unsigned)bfd_getl32 (ubs->pos));
}
break;
default:
fprintf (file, _("*unhandled*\n"));
break;
}
}
}
static unsigned int
evax_bfd_print_valspec (const unsigned char *buf, int indent, FILE *file)
{
unsigned int vflags = buf[0];
unsigned int value = (unsigned)bfd_getl32 (buf + 1);
unsigned int len = 5;
evax_bfd_print_indent (indent, file);
fprintf (file, _("vflags: 0x%02x, value: 0x%08x "), vflags, value);
buf += 5;
switch (vflags)
{
case DST__K_VFLAGS_NOVAL:
fprintf (file, _("(no value)\n"));
break;
case DST__K_VFLAGS_NOTACTIVE:
fprintf (file, _("(not active)\n"));
break;
case DST__K_VFLAGS_UNALLOC:
fprintf (file, _("(not allocated)\n"));
break;
case DST__K_VFLAGS_DSC:
fprintf (file, _("(descriptor)\n"));
evax_bfd_print_desc (buf + value, indent + 1, file);
break;
case DST__K_VFLAGS_TVS:
fprintf (file, _("(trailing value)\n"));
break;
case DST__K_VS_FOLLOWS:
fprintf (file, _("(value spec follows)\n"));
break;
case DST__K_VFLAGS_BITOFFS:
fprintf (file, _("(at bit offset %u)\n"), value);
break;
default:
fprintf (file, _("(reg: %u, disp: %u, indir: %u, kind: "),
(vflags & DST__K_REGNUM_MASK) >> DST__K_REGNUM_SHIFT,
vflags & DST__K_DISP ? 1 : 0,
vflags & DST__K_INDIR ? 1 : 0);
switch (vflags & DST__K_VALKIND_MASK)
{
case DST__K_VALKIND_LITERAL:
fputs (_("literal"), file);
break;
case DST__K_VALKIND_ADDR:
fputs (_("address"), file);
break;
case DST__K_VALKIND_DESC:
fputs (_("desc"), file);
break;
case DST__K_VALKIND_REG:
fputs (_("reg"), file);
break;
}
fputs (")\n", file);
break;
}
return len;
}
static void
evax_bfd_print_typspec (const unsigned char *buf, int indent, FILE *file)
{
unsigned char kind = buf[2];
unsigned int len = (unsigned)bfd_getl16 (buf);
evax_bfd_print_indent (indent, file);
fprintf (file, ("len: %2u, kind: %2u "), len, kind);
buf += 3;
switch (kind)
{
case DST__K_TS_ATOM:
fprintf (file, ("atomic, type=0x%02x %s\n"),
buf[0], evax_bfd_get_dsc_name (buf[0]));
break;
case DST__K_TS_IND:
fprintf (file, ("indirect, defined at 0x%08x\n"),
(unsigned)bfd_getl32 (buf));
break;
case DST__K_TS_TPTR:
fprintf (file, ("typed pointer\n"));
evax_bfd_print_typspec (buf, indent + 1, file);
break;
case DST__K_TS_PTR:
fprintf (file, ("pointer\n"));
break;
case DST__K_TS_ARRAY:
{
const unsigned char *vs;
unsigned int vec_len;
unsigned int i;
fprintf (file, ("array, dim: %u, bitmap: "), buf[0]);
vec_len = (buf[0] + 1 + 7) / 8;
for (i = 0; i < vec_len; i++)
fprintf (file, " %02x", buf[i + 1]);
fputc ('\n', file);
vs = buf + 1 + vec_len;
evax_bfd_print_indent (indent, file);
fprintf (file, ("array descriptor:\n"));
vs += evax_bfd_print_valspec (vs, indent + 1, file);
for (i = 0; i < buf[0] + 1U; i++)
if (buf[1 + i / 8] & (1 << (i % 8)))
{
evax_bfd_print_indent (indent, file);
if (i == 0)
fprintf (file, ("type spec for element:\n"));
else
fprintf (file, ("type spec for subscript %u:\n"), i);
evax_bfd_print_typspec (vs, indent + 1, file);
vs += bfd_getl16 (vs);
}
}
break;
default:
fprintf (file, ("*unhandled*\n"));
}
}
static void
evax_bfd_print_dst (struct bfd *abfd, unsigned int dst_size, FILE *file)
{
unsigned int off = 0;
unsigned int pc = 0;
unsigned int line = 0;
fprintf (file, _("Debug symbol table:\n"));
while (dst_size > 0)
{
struct vms_dst_header dsth;
unsigned int len;
unsigned int type;
unsigned char *buf;
if (bfd_bread (&dsth, sizeof (dsth), abfd) != sizeof (dsth))
{
fprintf (file, _("cannot read DST header\n"));
return;
}
len = bfd_getl16 (dsth.length);
type = bfd_getl16 (dsth.type);
fprintf (file, _(" type: %3u, len: %3u (at 0x%08x): "),
type, len, off);
if (len == 0)
{
fputc ('\n', file);
break;
}
len++;
dst_size -= len;
off += len;
len -= sizeof (dsth);
buf = bfd_malloc (len);
if (bfd_bread (buf, len, abfd) != len)
{
fprintf (file, _("cannot read DST symbol\n"));
return;
}
switch (type)
{
case DSC__K_DTYPE_V:
case DSC__K_DTYPE_BU:
case DSC__K_DTYPE_WU:
case DSC__K_DTYPE_LU:
case DSC__K_DTYPE_QU:
case DSC__K_DTYPE_B:
case DSC__K_DTYPE_W:
case DSC__K_DTYPE_L:
case DSC__K_DTYPE_Q:
case DSC__K_DTYPE_F:
case DSC__K_DTYPE_D:
case DSC__K_DTYPE_FC:
case DSC__K_DTYPE_DC:
case DSC__K_DTYPE_T:
case DSC__K_DTYPE_NU:
case DSC__K_DTYPE_NL:
case DSC__K_DTYPE_NLO:
case DSC__K_DTYPE_NR:
case DSC__K_DTYPE_NRO:
case DSC__K_DTYPE_NZ:
case DSC__K_DTYPE_P:
case DSC__K_DTYPE_ZI:
case DSC__K_DTYPE_ZEM:
case DSC__K_DTYPE_DSC:
case DSC__K_DTYPE_OU:
case DSC__K_DTYPE_O:
case DSC__K_DTYPE_G:
case DSC__K_DTYPE_H:
case DSC__K_DTYPE_GC:
case DSC__K_DTYPE_HC:
case DSC__K_DTYPE_CIT:
case DSC__K_DTYPE_BPV:
case DSC__K_DTYPE_BLV:
case DSC__K_DTYPE_VU:
case DSC__K_DTYPE_ADT:
case DSC__K_DTYPE_VT:
case DSC__K_DTYPE_T2:
case DSC__K_DTYPE_VT2:
fprintf (file, _("standard data: %s\n"),
evax_bfd_get_dsc_name (type));
evax_bfd_print_valspec (buf, 4, file);
fprintf (file, _(" name: %.*s\n"), buf[5], buf + 6);
break;
case DST__K_MODBEG:
{
struct vms_dst_modbeg *dst = (void *)buf;
const char *name = (const char *)buf + sizeof (*dst);
fprintf (file, _("modbeg\n"));
fprintf (file, _(" flags: %d, language: %u, "
"major: %u, minor: %u\n"),
dst->flags,
(unsigned)bfd_getl32 (dst->language),
(unsigned)bfd_getl16 (dst->major),
(unsigned)bfd_getl16 (dst->minor));
fprintf (file, _(" module name: %.*s\n"),
name[0], name + 1);
name += name[0] + 1;
fprintf (file, _(" compiler : %.*s\n"),
name[0], name + 1);
}
break;
case DST__K_MODEND:
fprintf (file, _("modend\n"));
break;
case DST__K_RTNBEG:
{
struct vms_dst_rtnbeg *dst = (void *)buf;
const char *name = (const char *)buf + sizeof (*dst);
fputs (_("rtnbeg\n"), file);
fprintf (file, _(" flags: %u, address: 0x%08x, "
"pd-address: 0x%08x\n"),
dst->flags,
(unsigned)bfd_getl32 (dst->address),
(unsigned)bfd_getl32 (dst->pd_address));
fprintf (file, _(" routine name: %.*s\n"),
name[0], name + 1);
}
break;
case DST__K_RTNEND:
{
struct vms_dst_rtnend *dst = (void *)buf;
fprintf (file, _("rtnend: size 0x%08x\n"),
(unsigned)bfd_getl32 (dst->size));
}
break;
case DST__K_PROLOG:
{
struct vms_dst_prolog *dst = (void *)buf;
fprintf (file, _("prolog: bkpt address 0x%08x\n"),
(unsigned)bfd_getl32 (dst->bkpt_addr));
}
break;
case DST__K_EPILOG:
{
struct vms_dst_epilog *dst = (void *)buf;
fprintf (file, _("epilog: flags: %u, count: %u\n"),
dst->flags, (unsigned)bfd_getl32 (dst->count));
}
break;
case DST__K_BLKBEG:
{
struct vms_dst_blkbeg *dst = (void *)buf;
const char *name = (const char *)buf + sizeof (*dst);
fprintf (file, _("blkbeg: address: 0x%08x, name: %.*s\n"),
(unsigned)bfd_getl32 (dst->address),
name[0], name + 1);
}
break;
case DST__K_BLKEND:
{
struct vms_dst_blkend *dst = (void *)buf;
fprintf (file, _("blkend: size: 0x%08x\n"),
(unsigned)bfd_getl32 (dst->size));
}
break;
case DST__K_TYPSPEC:
{
fprintf (file, _("typspec (len: %u)\n"), len);
fprintf (file, _(" name: %.*s\n"), buf[0], buf + 1);
evax_bfd_print_typspec (buf + 1 + buf[0], 5, file);
}
break;
case DST__K_SEPTYP:
{
fprintf (file, _("septyp, name: %.*s\n"), buf[5], buf + 6);
evax_bfd_print_valspec (buf, 4, file);
}
break;
case DST__K_RECBEG:
{
struct vms_dst_recbeg *recbeg = (void *)buf;
const char *name = (const char *)buf + sizeof (*recbeg);
fprintf (file, _("recbeg: name: %.*s\n"), name[0], name + 1);
evax_bfd_print_valspec (buf, 4, file);
fprintf (file, (" len: %u bits\n"),
(unsigned)bfd_getl32 (name + 1 + name[0]));
}
break;
case DST__K_RECEND:
fprintf (file, _("recend\n"));
break;
case DST__K_ENUMBEG:
fprintf (file, _("enumbeg, len: %u, name: %.*s\n"),
buf[0], buf[1], buf + 2);
break;
case DST__K_ENUMELT:
fprintf (file, _("enumelt, name: %.*s\n"), buf[5], buf + 6);
evax_bfd_print_valspec (buf, 4, file);
break;
case DST__K_ENUMEND:
fprintf (file, _("enumend\n"));
break;
case DST__K_LABEL:
{
struct vms_dst_label *lab = (void *)buf;
fprintf (file, ("label, name: %.*s\n"),
lab->name[0], lab->name + 1);
fprintf (file, (" address: 0x%08x\n"),
(unsigned)bfd_getl32 (lab->value));
}
break;
case DST__K_DIS_RANGE:
{
unsigned int cnt = bfd_getl32 (buf);
unsigned char *rng = buf + 4;
unsigned int i;
fprintf (file, _("discontiguous range (nbr: %u)\n"), cnt);
for (i = 0; i < cnt; i++, rng += 8)
fprintf (file, _(" address: 0x%08x, size: %u\n"),
(unsigned)bfd_getl32 (rng),
(unsigned)bfd_getl32 (rng + 4));
}
break;
case DST__K_LINE_NUM:
{
unsigned char *buf_orig = buf;
fprintf (file, _("line num (len: %u)\n"), len);
while (len > 0)
{
signed char cmd;
unsigned char cmdlen;
unsigned int val;
cmd = buf[0];
cmdlen = 0;
fputs (" ", file);
switch (cmd)
{
case DST__K_DELTA_PC_W:
val = bfd_getl16 (buf + 1);
fprintf (file, _("delta_pc_w %u\n"), val);
pc += val;
line++;
cmdlen = 3;
break;
case DST__K_INCR_LINUM:
val = buf[1];
fprintf (file, _("incr_linum(b): +%u\n"), val);
line += val;
cmdlen = 2;
break;
case DST__K_INCR_LINUM_W:
val = bfd_getl16 (buf + 1);
fprintf (file, _("incr_linum_w: +%u\n"), val);
line += val;
cmdlen = 3;
break;
case DST__K_INCR_LINUM_L:
val = bfd_getl32 (buf + 1);
fprintf (file, _("incr_linum_l: +%u\n"), val);
line += val;
cmdlen = 5;
break;
case DST__K_SET_LINUM:
line = bfd_getl16 (buf + 1);
fprintf (file, _("set_line_num(w) %u\n"), line);
cmdlen = 3;
break;
case DST__K_SET_LINUM_B:
line = buf[1];
fprintf (file, _("set_line_num_b %u\n"), line);
cmdlen = 2;
break;
case DST__K_SET_LINUM_L:
line = bfd_getl32 (buf + 1);
fprintf (file, _("set_line_num_l %u\n"), line);
cmdlen = 5;
break;
case DST__K_SET_ABS_PC:
pc = bfd_getl32 (buf + 1);
fprintf (file, _("set_abs_pc: 0x%08x\n"), pc);
cmdlen = 5;
break;
case DST__K_DELTA_PC_L:
fprintf (file, _("delta_pc_l: +0x%08x\n"),
(unsigned)bfd_getl32 (buf + 1));
cmdlen = 5;
break;
case DST__K_TERM:
fprintf (file, _("term(b): 0x%02x"), buf[1]);
pc += buf[1];
fprintf (file, _(" pc: 0x%08x\n"), pc);
cmdlen = 2;
break;
case DST__K_TERM_W:
val = bfd_getl16 (buf + 1);
fprintf (file, _("term_w: 0x%04x"), val);
pc += val;
fprintf (file, _(" pc: 0x%08x\n"), pc);
cmdlen = 3;
break;
default:
if (cmd <= 0)
{
fprintf (file, _("delta pc +%-4d"), -cmd);
line++; /* FIXME: curr increment. */
pc += -cmd;
fprintf (file, _(" pc: 0x%08x line: %5u\n"),
pc, line);
cmdlen = 1;
}
else
fprintf (file, _(" *unhandled* cmd %u\n"), cmd);
break;
}
if (cmdlen == 0)
break;
len -= cmdlen;
buf += cmdlen;
}
buf = buf_orig;
}
break;
case DST__K_SOURCE:
{
unsigned char *buf_orig = buf;
fprintf (file, _("source (len: %u)\n"), len);
while (len > 0)
{
signed char cmd = buf[0];
unsigned char cmdlen = 0;
switch (cmd)
{
case DST__K_SRC_DECLFILE:
{
struct vms_dst_src_decl_src *src = (void *)(buf + 1);
const char *name;
fprintf (file, _(" declfile: len: %u, flags: %u, "
"fileid: %u\n"),
src->length, src->flags,
(unsigned)bfd_getl16 (src->fileid));
fprintf (file, _(" rms: cdt: 0x%08x %08x, "
"ebk: 0x%08x, ffb: 0x%04x, "
"rfo: %u\n"),
(unsigned)bfd_getl32 (src->rms_cdt + 4),
(unsigned)bfd_getl32 (src->rms_cdt + 0),
(unsigned)bfd_getl32 (src->rms_ebk),
(unsigned)bfd_getl16 (src->rms_ffb),
src->rms_rfo);
name = (const char *)buf + 1 + sizeof (*src);
fprintf (file, _(" filename : %.*s\n"),
name[0], name + 1);
name += name[0] + 1;
fprintf (file, _(" module name: %.*s\n"),
name[0], name + 1);
cmdlen = 2 + src->length;
}
break;
case DST__K_SRC_SETFILE:
fprintf (file, _(" setfile %u\n"),
(unsigned)bfd_getl16 (buf + 1));
cmdlen = 3;
break;
case DST__K_SRC_SETREC_W:
fprintf (file, _(" setrec %u\n"),
(unsigned)bfd_getl16 (buf + 1));
cmdlen = 3;
break;
case DST__K_SRC_SETREC_L:
fprintf (file, _(" setrec %u\n"),
(unsigned)bfd_getl32 (buf + 1));
cmdlen = 5;
break;
case DST__K_SRC_SETLNUM_W:
fprintf (file, _(" setlnum %u\n"),
(unsigned)bfd_getl16 (buf + 1));
cmdlen = 3;
break;
case DST__K_SRC_SETLNUM_L:
fprintf (file, _(" setlnum %u\n"),
(unsigned)bfd_getl32 (buf + 1));
cmdlen = 5;
break;
case DST__K_SRC_DEFLINES_W:
fprintf (file, _(" deflines %u\n"),
(unsigned)bfd_getl16 (buf + 1));
cmdlen = 3;
break;
case DST__K_SRC_DEFLINES_B:
fprintf (file, _(" deflines %u\n"), buf[1]);
cmdlen = 2;
break;
case DST__K_SRC_FORMFEED:
fprintf (file, _(" formfeed\n"));
cmdlen = 1;
break;
default:
fprintf (file, _(" *unhandled* cmd %u\n"), cmd);
break;
}
if (cmdlen == 0)
break;
len -= cmdlen;
buf += cmdlen;
}
buf = buf_orig;
}
break;
default:
fprintf (file, _("*unhandled* dst type %u\n"), type);
break;
}
free (buf);
}
}
static void
evax_bfd_print_image (bfd *abfd, FILE *file)
{
struct vms_eihd eihd;
const char *name;
unsigned int val;
unsigned int eiha_off;
unsigned int eihi_off;
unsigned int eihs_off;
unsigned int eisd_off;
unsigned int eihef_off = 0;
unsigned int eihnp_off = 0;
unsigned int dmt_vbn = 0;
unsigned int dmt_size = 0;
unsigned int dst_vbn = 0;
unsigned int dst_size = 0;
unsigned int gst_vbn = 0;
unsigned int gst_size = 0;
unsigned int eiaf_vbn = 0;
unsigned int eiaf_size = 0;
unsigned int eihvn_off;
if (bfd_seek (abfd, (file_ptr) 0, SEEK_SET)
|| bfd_bread (&eihd, sizeof (eihd), abfd) != sizeof (eihd))
{
fprintf (file, _("cannot read EIHD\n"));
return;
}
fprintf (file, _("EIHD: (size: %u, nbr blocks: %u)\n"),
(unsigned)bfd_getl32 (eihd.size),
(unsigned)bfd_getl32 (eihd.hdrblkcnt));
fprintf (file, _(" majorid: %u, minorid: %u\n"),
(unsigned)bfd_getl32 (eihd.majorid),
(unsigned)bfd_getl32 (eihd.minorid));
val = (unsigned)bfd_getl32 (eihd.imgtype);
switch (val)
{
case EIHD__K_EXE:
name = _("executable");
break;
case EIHD__K_LIM:
name = _("linkable image");
break;
default:
name = _("unknown");
break;
}
fprintf (file, _(" image type: %u (%s)"), val, name);
val = (unsigned)bfd_getl32 (eihd.subtype);
switch (val)
{
case EIHD__C_NATIVE:
name = _("native");
break;
case EIHD__C_CLI:
name = _("CLI");
break;
default:
name = _("unknown");
break;
}
fprintf (file, _(", subtype: %u (%s)\n"), val, name);
eisd_off = bfd_getl32 (eihd.isdoff);
eiha_off = bfd_getl32 (eihd.activoff);
eihi_off = bfd_getl32 (eihd.imgidoff);
eihs_off = bfd_getl32 (eihd.symdbgoff);
fprintf (file, _(" offsets: isd: %u, activ: %u, symdbg: %u, "
"imgid: %u, patch: %u\n"),
eisd_off, eiha_off, eihs_off, eihi_off,
(unsigned)bfd_getl32 (eihd.patchoff));
fprintf (file, _(" fixup info rva: "));
bfd_fprintf_vma (abfd, file, bfd_getl64 (eihd.iafva));
fprintf (file, _(", symbol vector rva: "));
bfd_fprintf_vma (abfd, file, bfd_getl64 (eihd.symvva));
eihvn_off = bfd_getl32 (eihd.version_array_off);
fprintf (file, _("\n"
" version array off: %u\n"),
eihvn_off);
fprintf (file,
_(" img I/O count: %u, nbr channels: %u, req pri: %08x%08x\n"),
(unsigned)bfd_getl32 (eihd.imgiocnt),
(unsigned)bfd_getl32 (eihd.iochancnt),
(unsigned)bfd_getl32 (eihd.privreqs + 4),
(unsigned)bfd_getl32 (eihd.privreqs + 0));
val = (unsigned)bfd_getl32 (eihd.lnkflags);
fprintf (file, _(" linker flags: %08x:"), val);
if (val & EIHD__M_LNKDEBUG)
fprintf (file, " LNKDEBUG");
if (val & EIHD__M_LNKNOTFR)
fprintf (file, " LNKNOTFR");
if (val & EIHD__M_NOP0BUFS)
fprintf (file, " NOP0BUFS");
if (val & EIHD__M_PICIMG)
fprintf (file, " PICIMG");
if (val & EIHD__M_P0IMAGE)
fprintf (file, " P0IMAGE");
if (val & EIHD__M_DBGDMT)
fprintf (file, " DBGDMT");
if (val & EIHD__M_INISHR)
fprintf (file, " INISHR");
if (val & EIHD__M_XLATED)
fprintf (file, " XLATED");
if (val & EIHD__M_BIND_CODE_SEC)
fprintf (file, " BIND_CODE_SEC");
if (val & EIHD__M_BIND_DATA_SEC)
fprintf (file, " BIND_DATA_SEC");
if (val & EIHD__M_MKTHREADS)
fprintf (file, " MKTHREADS");
if (val & EIHD__M_UPCALLS)
fprintf (file, " UPCALLS");
if (val & EIHD__M_OMV_READY)
fprintf (file, " OMV_READY");
if (val & EIHD__M_EXT_BIND_SECT)
fprintf (file, " EXT_BIND_SECT");
fprintf (file, "\n");
fprintf (file, _(" ident: 0x%08x, sysver: 0x%08x, "
"match ctrl: %u, symvect_size: %u\n"),
(unsigned)bfd_getl32 (eihd.ident),
(unsigned)bfd_getl32 (eihd.sysver),
eihd.matchctl,
(unsigned)bfd_getl32 (eihd.symvect_size));
fprintf (file, _(" BPAGE: %u"),
(unsigned)bfd_getl32 (eihd.virt_mem_block_size));
if (val & (EIHD__M_OMV_READY | EIHD__M_EXT_BIND_SECT))
{
eihef_off = bfd_getl32 (eihd.ext_fixup_off);
eihnp_off = bfd_getl32 (eihd.noopt_psect_off);
fprintf (file, _(", ext fixup offset: %u, no_opt psect off: %u"),
eihef_off, eihnp_off);
}
fprintf (file, _(", alias: %u\n"), (unsigned)bfd_getl16 (eihd.alias));
if (eihvn_off != 0)
{
struct vms_eihvn eihvn;
unsigned int mask;
unsigned int j;
fprintf (file, _("system version array information:\n"));
if (bfd_seek (abfd, (file_ptr) eihvn_off, SEEK_SET)
|| bfd_bread (&eihvn, sizeof (eihvn), abfd) != sizeof (eihvn))
{
fprintf (file, _("cannot read EIHVN header\n"));
return;
}
mask = bfd_getl32 (eihvn.subsystem_mask);
for (j = 0; j < 32; j++)
if (mask & (1 << j))
{
struct vms_eihvn_subversion ver;
if (bfd_bread (&ver, sizeof (ver), abfd) != sizeof (ver))
{
fprintf (file, _("cannot read EIHVN version\n"));
return;
}
fprintf (file, _(" %02u "), j);
switch (j)
{
case EIHVN__BASE_IMAGE_BIT:
fputs (_("BASE_IMAGE "), file);
break;
case EIHVN__MEMORY_MANAGEMENT_BIT:
fputs (_("MEMORY_MANAGEMENT"), file);
break;
case EIHVN__IO_BIT:
fputs (_("IO "), file);
break;
case EIHVN__FILES_VOLUMES_BIT:
fputs (_("FILES_VOLUMES "), file);
break;
case EIHVN__PROCESS_SCHED_BIT:
fputs (_("PROCESS_SCHED "), file);
break;
case EIHVN__SYSGEN_BIT:
fputs (_("SYSGEN "), file);
break;
case EIHVN__CLUSTERS_LOCKMGR_BIT:
fputs (_("CLUSTERS_LOCKMGR "), file);
break;
case EIHVN__LOGICAL_NAMES_BIT:
fputs (_("LOGICAL_NAMES "), file);
break;
case EIHVN__SECURITY_BIT:
fputs (_("SECURITY "), file);
break;
case EIHVN__IMAGE_ACTIVATOR_BIT:
fputs (_("IMAGE_ACTIVATOR "), file);
break;
case EIHVN__NETWORKS_BIT:
fputs (_("NETWORKS "), file);
break;
case EIHVN__COUNTERS_BIT:
fputs (_("COUNTERS "), file);
break;
case EIHVN__STABLE_BIT:
fputs (_("STABLE "), file);
break;
case EIHVN__MISC_BIT:
fputs (_("MISC "), file);
break;
case EIHVN__CPU_BIT:
fputs (_("CPU "), file);
break;
case EIHVN__VOLATILE_BIT:
fputs (_("VOLATILE "), file);
break;
case EIHVN__SHELL_BIT:
fputs (_("SHELL "), file);
break;
case EIHVN__POSIX_BIT:
fputs (_("POSIX "), file);
break;
case EIHVN__MULTI_PROCESSING_BIT:
fputs (_("MULTI_PROCESSING "), file);
break;
case EIHVN__GALAXY_BIT:
fputs (_("GALAXY "), file);
break;
default:
fputs (_("*unknown* "), file);
break;
}
fprintf (file, _(": %u.%u\n"),
(unsigned)bfd_getl16 (ver.major),
(unsigned)bfd_getl16 (ver.minor));
}
}
if (eiha_off != 0)
{
struct vms_eiha eiha;
if (bfd_seek (abfd, (file_ptr) eiha_off, SEEK_SET)
|| bfd_bread (&eiha, sizeof (eiha), abfd) != sizeof (eiha))
{
fprintf (file, _("cannot read EIHA\n"));
return;
}
fprintf (file, _("Image activation: (size=%u)\n"),
(unsigned)bfd_getl32 (eiha.size));
fprintf (file, _(" First address : 0x%08x 0x%08x\n"),
(unsigned)bfd_getl32 (eiha.tfradr1_h),
(unsigned)bfd_getl32 (eiha.tfradr1));
fprintf (file, _(" Second address: 0x%08x 0x%08x\n"),
(unsigned)bfd_getl32 (eiha.tfradr2_h),
(unsigned)bfd_getl32 (eiha.tfradr2));
fprintf (file, _(" Third address : 0x%08x 0x%08x\n"),
(unsigned)bfd_getl32 (eiha.tfradr3_h),
(unsigned)bfd_getl32 (eiha.tfradr3));
fprintf (file, _(" Fourth address: 0x%08x 0x%08x\n"),
(unsigned)bfd_getl32 (eiha.tfradr4_h),
(unsigned)bfd_getl32 (eiha.tfradr4));
fprintf (file, _(" Shared image : 0x%08x 0x%08x\n"),
(unsigned)bfd_getl32 (eiha.inishr_h),
(unsigned)bfd_getl32 (eiha.inishr));
}
if (eihi_off != 0)
{
struct vms_eihi eihi;
if (bfd_seek (abfd, (file_ptr) eihi_off, SEEK_SET)
|| bfd_bread (&eihi, sizeof (eihi), abfd) != sizeof (eihi))
{
fprintf (file, _("cannot read EIHI\n"));
return;
}
fprintf (file, _("Image identification: (major: %u, minor: %u)\n"),
(unsigned)bfd_getl32 (eihi.majorid),
(unsigned)bfd_getl32 (eihi.minorid));
fprintf (file, _(" image name : %.*s\n"),
eihi.imgnam[0], eihi.imgnam + 1);
fprintf (file, _(" link time : %s\n"),
vms_time_to_str (eihi.linktime));
fprintf (file, _(" image ident : %.*s\n"),
eihi.imgid[0], eihi.imgid + 1);
fprintf (file, _(" linker ident : %.*s\n"),
eihi.linkid[0], eihi.linkid + 1);
fprintf (file, _(" image build ident: %.*s\n"),
eihi.imgbid[0], eihi.imgbid + 1);
}
if (eihs_off != 0)
{
struct vms_eihs eihs;
if (bfd_seek (abfd, (file_ptr) eihs_off, SEEK_SET)
|| bfd_bread (&eihs, sizeof (eihs), abfd) != sizeof (eihs))
{
fprintf (file, _("cannot read EIHS\n"));
return;
}
fprintf (file, _("Image symbol & debug table: (major: %u, minor: %u)\n"),
(unsigned)bfd_getl32 (eihs.majorid),
(unsigned)bfd_getl32 (eihs.minorid));
dst_vbn = bfd_getl32 (eihs.dstvbn);
dst_size = bfd_getl32 (eihs.dstsize);
fprintf (file, _(" debug symbol table : vbn: %u, size: %u (0x%x)\n"),
dst_vbn, dst_size, dst_size);
gst_vbn = bfd_getl32 (eihs.gstvbn);
gst_size = bfd_getl32 (eihs.gstsize);
fprintf (file, _(" global symbol table: vbn: %u, records: %u\n"),
gst_vbn, gst_size);
dmt_vbn = bfd_getl32 (eihs.dmtvbn);
dmt_size = bfd_getl32 (eihs.dmtsize);
fprintf (file, _(" debug module table : vbn: %u, size: %u\n"),
dmt_vbn, dmt_size);
}
while (eisd_off != 0)
{
struct vms_eisd eisd;
unsigned int len;
while (1)
{
if (bfd_seek (abfd, (file_ptr) eisd_off, SEEK_SET)
|| bfd_bread (&eisd, sizeof (eisd), abfd) != sizeof (eisd))
{
fprintf (file, _("cannot read EISD\n"));
return;
}
len = (unsigned)bfd_getl32 (eisd.eisdsize);
if (len != (unsigned)-1)
break;
/* Next block. */
eisd_off = (eisd_off + VMS_BLOCK_SIZE) & ~(VMS_BLOCK_SIZE - 1);
}
fprintf (file, _("Image section descriptor: (major: %u, minor: %u, "
"size: %u, offset: %u)\n"),
(unsigned)bfd_getl32 (eisd.majorid),
(unsigned)bfd_getl32 (eisd.minorid),
len, eisd_off);
if (len == 0)
break;
fprintf (file, _(" section: base: 0x%08x%08x size: 0x%08x\n"),
(unsigned)bfd_getl32 (eisd.virt_addr + 4),
(unsigned)bfd_getl32 (eisd.virt_addr + 0),
(unsigned)bfd_getl32 (eisd.secsize));
val = (unsigned)bfd_getl32 (eisd.flags);
fprintf (file, _(" flags: 0x%04x"), val);
if (val & EISD__M_GBL)
fprintf (file, " GBL");
if (val & EISD__M_CRF)
fprintf (file, " CRF");
if (val & EISD__M_DZRO)
fprintf (file, " DZRO");
if (val & EISD__M_WRT)
fprintf (file, " WRT");
if (val & EISD__M_INITALCODE)
fprintf (file, " INITALCODE");
if (val & EISD__M_BASED)
fprintf (file, " BASED");
if (val & EISD__M_FIXUPVEC)
fprintf (file, " FIXUPVEC");
if (val & EISD__M_RESIDENT)
fprintf (file, " RESIDENT");
if (val & EISD__M_VECTOR)
fprintf (file, " VECTOR");
if (val & EISD__M_PROTECT)
fprintf (file, " PROTECT");
if (val & EISD__M_LASTCLU)
fprintf (file, " LASTCLU");
if (val & EISD__M_EXE)
fprintf (file, " EXE");
if (val & EISD__M_NONSHRADR)
fprintf (file, " NONSHRADR");
if (val & EISD__M_QUAD_LENGTH)
fprintf (file, " QUAD_LENGTH");
if (val & EISD__M_ALLOC_64BIT)
fprintf (file, " ALLOC_64BIT");
fprintf (file, "\n");
if (val & EISD__M_FIXUPVEC)
{
eiaf_vbn = bfd_getl32 (eisd.vbn);
eiaf_size = bfd_getl32 (eisd.secsize);
}
fprintf (file, _(" vbn: %u, pfc: %u, matchctl: %u type: %u ("),
(unsigned)bfd_getl32 (eisd.vbn),
eisd.pfc, eisd.matchctl, eisd.type);
switch (eisd.type)
{
case EISD__K_NORMAL:
fputs (_("NORMAL"), file);
break;
case EISD__K_SHRFXD:
fputs (_("SHRFXD"), file);
break;
case EISD__K_PRVFXD:
fputs (_("PRVFXD"), file);
break;
case EISD__K_SHRPIC:
fputs (_("SHRPIC"), file);
break;
case EISD__K_PRVPIC:
fputs (_("PRVPIC"), file);
break;
case EISD__K_USRSTACK:
fputs (_("USRSTACK"), file);
break;
default:
fputs (_("*unknown*"), file);
break;
}
fputs (_(")\n"), file);
if (val & EISD__M_GBL)
fprintf (file, _(" ident: 0x%08x, name: %.*s\n"),
(unsigned)bfd_getl32 (eisd.ident),
eisd.gblnam[0], eisd.gblnam + 1);
eisd_off += len;
}
if (dmt_vbn != 0)
{
if (bfd_seek (abfd, (file_ptr) (dmt_vbn - 1) * VMS_BLOCK_SIZE, SEEK_SET))
{
fprintf (file, _("cannot read DMT\n"));
return;
}
fprintf (file, _("Debug module table:\n"));
while (dmt_size > 0)
{
struct vms_dmt_header dmth;
unsigned int count;
if (bfd_bread (&dmth, sizeof (dmth), abfd) != sizeof (dmth))
{
fprintf (file, _("cannot read DMT header\n"));
return;
}
count = bfd_getl16 (dmth.psect_count);
fprintf (file,
_(" module offset: 0x%08x, size: 0x%08x, (%u psects)\n"),
(unsigned)bfd_getl32 (dmth.modbeg),
(unsigned)bfd_getl32 (dmth.size), count);
dmt_size -= sizeof (dmth);
while (count > 0)
{
struct vms_dmt_psect dmtp;
if (bfd_bread (&dmtp, sizeof (dmtp), abfd) != sizeof (dmtp))
{
fprintf (file, _("cannot read DMT psect\n"));
return;
}
fprintf (file, _(" psect start: 0x%08x, length: %u\n"),
(unsigned)bfd_getl32 (dmtp.start),
(unsigned)bfd_getl32 (dmtp.length));
count--;
dmt_size -= sizeof (dmtp);
}
}
}
if (dst_vbn != 0)
{
if (bfd_seek (abfd, (file_ptr) (dst_vbn - 1) * VMS_BLOCK_SIZE, SEEK_SET))
{
fprintf (file, _("cannot read DST\n"));
return;
}
evax_bfd_print_dst (abfd, dst_size, file);
}
if (gst_vbn != 0)
{
if (bfd_seek (abfd, (file_ptr) (gst_vbn - 1) * VMS_BLOCK_SIZE, SEEK_SET))
{
fprintf (file, _("cannot read GST\n"));
return;
}
fprintf (file, _("Global symbol table:\n"));
evax_bfd_print_eobj (abfd, file);
}
if (eiaf_vbn != 0)
{
unsigned char *buf;
struct vms_eiaf *eiaf;
unsigned int qrelfixoff;
unsigned int lrelfixoff;
unsigned int qdotadroff;
unsigned int ldotadroff;
unsigned int shrimgcnt;
unsigned int shlstoff;
unsigned int codeadroff;
unsigned int lpfixoff;
unsigned int chgprtoff;
buf = bfd_malloc (eiaf_size);
if (bfd_seek (abfd, (file_ptr) (eiaf_vbn - 1) * VMS_BLOCK_SIZE, SEEK_SET)
|| bfd_bread (buf, eiaf_size, abfd) != eiaf_size)
{
fprintf (file, _("cannot read EIHA\n"));
free (buf);
return;
}
eiaf = (struct vms_eiaf *)buf;
fprintf (file,
_("Image activator fixup: (major: %u, minor: %u)\n"),
(unsigned)bfd_getl32 (eiaf->majorid),
(unsigned)bfd_getl32 (eiaf->minorid));
fprintf (file, _(" iaflink : 0x%08x %08x\n"),
(unsigned)bfd_getl32 (eiaf->iaflink + 0),
(unsigned)bfd_getl32 (eiaf->iaflink + 4));
fprintf (file, _(" fixuplnk: 0x%08x %08x\n"),
(unsigned)bfd_getl32 (eiaf->fixuplnk + 0),
(unsigned)bfd_getl32 (eiaf->fixuplnk + 4));
fprintf (file, _(" size : %u\n"),
(unsigned)bfd_getl32 (eiaf->size));
fprintf (file, _(" flags: 0x%08x\n"),
(unsigned)bfd_getl32 (eiaf->flags));
qrelfixoff = bfd_getl32 (eiaf->qrelfixoff);
lrelfixoff = bfd_getl32 (eiaf->lrelfixoff);
fprintf (file, _(" qrelfixoff: %5u, lrelfixoff: %5u\n"),
qrelfixoff, lrelfixoff);
qdotadroff = bfd_getl32 (eiaf->qdotadroff);
ldotadroff = bfd_getl32 (eiaf->ldotadroff);
fprintf (file, _(" qdotadroff: %5u, ldotadroff: %5u\n"),
qdotadroff, ldotadroff);
codeadroff = bfd_getl32 (eiaf->codeadroff);
lpfixoff = bfd_getl32 (eiaf->lpfixoff);
fprintf (file, _(" codeadroff: %5u, lpfixoff : %5u\n"),
codeadroff, lpfixoff);
chgprtoff = bfd_getl32 (eiaf->chgprtoff);
fprintf (file, _(" chgprtoff : %5u\n"), chgprtoff);
shrimgcnt = bfd_getl32 (eiaf->shrimgcnt);
shlstoff = bfd_getl32 (eiaf->shlstoff);
fprintf (file, _(" shlstoff : %5u, shrimgcnt : %5u\n"),
shlstoff, shrimgcnt);
fprintf (file, _(" shlextra : %5u, permctx : %5u\n"),
(unsigned)bfd_getl32 (eiaf->shlextra),
(unsigned)bfd_getl32 (eiaf->permctx));
fprintf (file, _(" base_va : 0x%08x\n"),
(unsigned)bfd_getl32 (eiaf->base_va));
fprintf (file, _(" lppsbfixoff: %5u\n"),
(unsigned)bfd_getl32 (eiaf->lppsbfixoff));
if (shlstoff)
{
struct vms_shl *shl = (struct vms_shl *)(buf + shlstoff);
unsigned int j;
fprintf (file, _(" Shareable images:\n"));
for (j = 0; j < shrimgcnt; j++, shl++)
{
fprintf (file,
_(" %u: size: %u, flags: 0x%02x, name: %.*s\n"),
j, shl->size, shl->flags,
shl->imgnam[0], shl->imgnam + 1);
}
}
if (qrelfixoff != 0)
{
fprintf (file, _(" quad-word relocation fixups:\n"));
evax_bfd_print_relocation_records (file, buf + qrelfixoff, 8);
}
if (lrelfixoff != 0)
{
fprintf (file, _(" long-word relocation fixups:\n"));
evax_bfd_print_relocation_records (file, buf + lrelfixoff, 4);
}
if (qdotadroff != 0)
{
fprintf (file, _(" quad-word .address reference fixups:\n"));
evax_bfd_print_address_fixups (file, buf + qdotadroff);
}
if (ldotadroff != 0)
{
fprintf (file, _(" long-word .address reference fixups:\n"));
evax_bfd_print_address_fixups (file, buf + ldotadroff);
}
if (codeadroff != 0)
{
fprintf (file, _(" Code Address Reference Fixups:\n"));
evax_bfd_print_reference_fixups (file, buf + codeadroff);
}
if (lpfixoff != 0)
{
fprintf (file, _(" Linkage Pairs Referece Fixups:\n"));
evax_bfd_print_reference_fixups (file, buf + lpfixoff);
}
if (chgprtoff)
{
unsigned int count = (unsigned)bfd_getl32 (buf + chgprtoff);
struct vms_eicp *eicp = (struct vms_eicp *)(buf + chgprtoff + 4);
unsigned int j;
fprintf (file, _(" Change Protection (%u entries):\n"), count);
for (j = 0; j < count; j++, eicp++)
{
unsigned int prot = bfd_getl32 (eicp->newprt);
fprintf (file,
_(" base: 0x%08x %08x, size: 0x%08x, prot: 0x%08x "),
(unsigned)bfd_getl32 (eicp->baseva + 4),
(unsigned)bfd_getl32 (eicp->baseva + 0),
(unsigned)bfd_getl32 (eicp->size),
(unsigned)bfd_getl32 (eicp->newprt));
switch (prot)
{
case PRT__C_NA:
fprintf (file, "NA");
break;
case PRT__C_RESERVED:
fprintf (file, "RES");
break;
case PRT__C_KW:
fprintf (file, "KW");
break;
case PRT__C_KR:
fprintf (file, "KR");
break;
case PRT__C_UW:
fprintf (file, "UW");
break;
case PRT__C_EW:
fprintf (file, "EW");
break;
case PRT__C_ERKW:
fprintf (file, "ERKW");
break;
case PRT__C_ER:
fprintf (file, "ER");
break;
case PRT__C_SW:
fprintf (file, "SW");
break;
case PRT__C_SREW:
fprintf (file, "SREW");
break;
case PRT__C_SRKW:
fprintf (file, "SRKW");
break;
case PRT__C_SR:
fprintf (file, "SR");
break;
case PRT__C_URSW:
fprintf (file, "URSW");
break;
case PRT__C_UREW:
fprintf (file, "UREW");
break;
case PRT__C_URKW:
fprintf (file, "URKW");
break;
case PRT__C_UR:
fprintf (file, "UR");
break;
default:
fputs ("??", file);
break;
}
fputc ('\n', file);
}
}
free (buf);
}
}
static bfd_boolean
vms_bfd_print_private_bfd_data (bfd *abfd, void *ptr)
{
FILE *file = (FILE *)ptr;
if (bfd_get_file_flags (abfd) & (EXEC_P | DYNAMIC))
evax_bfd_print_image (abfd, file);
else
{
if (bfd_seek (abfd, 0, SEEK_SET))
return FALSE;
evax_bfd_print_eobj (abfd, file);
}
return TRUE;
}
/* Linking. */
/* Slurp ETIR/EDBG/ETBT VMS object records. */
static bfd_boolean
alpha_vms_read_sections_content (bfd *abfd, struct bfd_link_info *info)
{
asection *cur_section;
file_ptr cur_offset;
asection *dst_section;
file_ptr dst_offset;
if (bfd_seek (abfd, 0, SEEK_SET) != 0)
return FALSE;
cur_section = NULL;
cur_offset = 0;
dst_section = PRIV (dst_section);
dst_offset = 0;
if (info)
{
if (info->strip == strip_all || info->strip == strip_debugger)
{
/* Discard the DST section. */
dst_offset = 0;
dst_section = NULL;
}
else if (dst_section)
{
dst_offset = dst_section->output_offset;
dst_section = dst_section->output_section;
}
}
while (1)
{
int type;
bfd_boolean res;
type = _bfd_vms_get_object_record (abfd);
if (type < 0)
{
vms_debug2 ((2, "next_record failed\n"));
return FALSE;
}
switch (type)
{
case EOBJ__C_ETIR:
PRIV (image_section) = cur_section;
PRIV (image_offset) = cur_offset;
res = _bfd_vms_slurp_etir (abfd, info);
cur_section = PRIV (image_section);
cur_offset = PRIV (image_offset);
break;
case EOBJ__C_EDBG:
case EOBJ__C_ETBT:
if (dst_section == NULL)
continue;
PRIV (image_section) = dst_section;
PRIV (image_offset) = dst_offset;
res = _bfd_vms_slurp_etir (abfd, info);
dst_offset = PRIV (image_offset);
break;
case EOBJ__C_EEOM:
return TRUE;
default:
continue;
}
if (!res)
{
vms_debug2 ((2, "slurp eobj type %d failed\n", type));
return FALSE;
}
}
}
static int
alpha_vms_sizeof_headers (bfd *abfd ATTRIBUTE_UNUSED,
struct bfd_link_info *info ATTRIBUTE_UNUSED)
{
return 0;
}
/* Add a linkage pair fixup at address SECT + OFFSET to SHLIB. */
static void
alpha_vms_add_fixup_lp (struct bfd_link_info *info, bfd *src, bfd *shlib)
{
struct alpha_vms_shlib_el *sl;
asection *sect = PRIV2 (src, image_section);
file_ptr offset = PRIV2 (src, image_offset);
sl = &VEC_EL (alpha_vms_link_hash (info)->shrlibs,
struct alpha_vms_shlib_el, PRIV2 (shlib, shr_index));
sl->has_fixups = TRUE;
VEC_APPEND_EL (sl->lp, bfd_vma,
sect->output_section->vma + sect->output_offset + offset);
sect->output_section->flags |= SEC_RELOC;
}
/* Add a code address fixup at address SECT + OFFSET to SHLIB. */
static void
alpha_vms_add_fixup_ca (struct bfd_link_info *info, bfd *src, bfd *shlib)
{
struct alpha_vms_shlib_el *sl;
asection *sect = PRIV2 (src, image_section);
file_ptr offset = PRIV2 (src, image_offset);
sl = &VEC_EL (alpha_vms_link_hash (info)->shrlibs,
struct alpha_vms_shlib_el, PRIV2 (shlib, shr_index));
sl->has_fixups = TRUE;
VEC_APPEND_EL (sl->ca, bfd_vma,
sect->output_section->vma + sect->output_offset + offset);
sect->output_section->flags |= SEC_RELOC;
}
/* Add a quad word relocation fixup at address SECT + OFFSET to SHLIB. */
static void
alpha_vms_add_fixup_qr (struct bfd_link_info *info, bfd *src,
bfd *shlib, bfd_vma vec)
{
struct alpha_vms_shlib_el *sl;
struct alpha_vms_vma_ref *r;
asection *sect = PRIV2 (src, image_section);
file_ptr offset = PRIV2 (src, image_offset);
sl = &VEC_EL (alpha_vms_link_hash (info)->shrlibs,
struct alpha_vms_shlib_el, PRIV2 (shlib, shr_index));
sl->has_fixups = TRUE;
r = VEC_APPEND (sl->qr, struct alpha_vms_vma_ref);
r->vma = sect->output_section->vma + sect->output_offset + offset;
r->ref = vec;
sect->output_section->flags |= SEC_RELOC;
}
static void
alpha_vms_add_fixup_lr (struct bfd_link_info *info ATTRIBUTE_UNUSED,
unsigned int shr ATTRIBUTE_UNUSED,
bfd_vma vec ATTRIBUTE_UNUSED)
{
/* Not yet supported. */
abort ();
}
/* Add relocation. FIXME: Not yet emitted. */
static void
alpha_vms_add_lw_reloc (struct bfd_link_info *info ATTRIBUTE_UNUSED)
{
}
static void
alpha_vms_add_qw_reloc (struct bfd_link_info *info ATTRIBUTE_UNUSED)
{
}
static struct bfd_hash_entry *
alpha_vms_link_hash_newfunc (struct bfd_hash_entry *entry,
struct bfd_hash_table *table,
const char *string)
{
struct alpha_vms_link_hash_entry *ret =
(struct alpha_vms_link_hash_entry *) entry;
/* Allocate the structure if it has not already been allocated by a
subclass. */
if (ret == NULL)
ret = ((struct alpha_vms_link_hash_entry *)
bfd_hash_allocate (table,
sizeof (struct alpha_vms_link_hash_entry)));
if (ret == NULL)
return NULL;
/* Call the allocation method of the superclass. */
ret = ((struct alpha_vms_link_hash_entry *)
_bfd_link_hash_newfunc ((struct bfd_hash_entry *) ret,
table, string));
ret->sym = NULL;
return (struct bfd_hash_entry *) ret;
}
/* Create an Alpha/VMS link hash table. */
static struct bfd_link_hash_table *
alpha_vms_bfd_link_hash_table_create (bfd *abfd)
{
struct alpha_vms_link_hash_table *ret;
bfd_size_type amt = sizeof (struct alpha_vms_link_hash_table);
ret = (struct alpha_vms_link_hash_table *) bfd_malloc (amt);
if (ret == NULL)
return NULL;
if (!_bfd_link_hash_table_init (&ret->root, abfd,
alpha_vms_link_hash_newfunc,
sizeof (struct alpha_vms_link_hash_entry)))
{
free (ret);
return NULL;
}
VEC_INIT (ret->shrlibs);
ret->fixup = NULL;
return &ret->root;
}
static bfd_boolean
alpha_vms_link_add_object_symbols (bfd *abfd, struct bfd_link_info *info)
{
unsigned int i;
for (i = 0; i < PRIV (gsd_sym_count); i++)
{
struct vms_symbol_entry *e = PRIV (syms)[i];
struct alpha_vms_link_hash_entry *h;
struct bfd_link_hash_entry *h_root;
asymbol sym;
if (!alpha_vms_convert_symbol (abfd, e, &sym))
return FALSE;
if ((e->flags & EGSY__V_DEF) && abfd->selective_search)
{
/* In selective_search mode, only add definition that are
required. */
h = (struct alpha_vms_link_hash_entry *)bfd_link_hash_lookup
(info->hash, sym.name, FALSE, FALSE, FALSE);
if (h == NULL || h->root.type != bfd_link_hash_undefined)
continue;
}
else
h = NULL;
h_root = (struct bfd_link_hash_entry *) h;
if (_bfd_generic_link_add_one_symbol
(info, abfd, sym.name, sym.flags, sym.section, sym.value,
NULL, FALSE, FALSE, &h_root) == FALSE)
return FALSE;
h = (struct alpha_vms_link_hash_entry *) h_root;
if ((e->flags & EGSY__V_DEF)
&& h->sym == NULL
&& abfd->xvec == info->output_bfd->xvec)
h->sym = e;
}
if (abfd->flags & DYNAMIC)
{
struct alpha_vms_shlib_el *shlib;
/* We do not want to include any of the sections in a dynamic
object in the output file. See comment in elflink.c. */
bfd_section_list_clear (abfd);
shlib = VEC_APPEND (alpha_vms_link_hash (info)->shrlibs,
struct alpha_vms_shlib_el);
shlib->abfd = abfd;
VEC_INIT (shlib->ca);
VEC_INIT (shlib->lp);
VEC_INIT (shlib->qr);
PRIV (shr_index) = VEC_COUNT (alpha_vms_link_hash (info)->shrlibs) - 1;
}
return TRUE;
}
static bfd_boolean
alpha_vms_link_add_archive_symbols (bfd *abfd, struct bfd_link_info *info)
{
int pass;
struct bfd_link_hash_entry **pundef;
struct bfd_link_hash_entry **next_pundef;
/* We only accept VMS libraries. */
if (info->output_bfd->xvec != abfd->xvec)
{
bfd_set_error (bfd_error_wrong_format);
return FALSE;
}
/* The archive_pass field in the archive itself is used to
initialize PASS, since we may search the same archive multiple
times. */
pass = ++abfd->archive_pass;
/* Look through the list of undefined symbols. */
for (pundef = &info->hash->undefs; *pundef != NULL; pundef = next_pundef)
{
struct bfd_link_hash_entry *h;
symindex symidx;
bfd *element;
bfd *orig_element;
h = *pundef;
next_pundef = &(*pundef)->u.undef.next;
/* When a symbol is defined, it is not necessarily removed from
the list. */
if (h->type != bfd_link_hash_undefined
&& h->type != bfd_link_hash_common)
{
/* Remove this entry from the list, for general cleanliness
and because we are going to look through the list again
if we search any more libraries. We can't remove the
entry if it is the tail, because that would lose any
entries we add to the list later on. */
if (*pundef != info->hash->undefs_tail)
{
*pundef = *next_pundef;
next_pundef = pundef;
}
continue;
}
/* Look for this symbol in the archive hash table. */
symidx = _bfd_vms_lib_find_symbol (abfd, h->root.string);
if (symidx == BFD_NO_MORE_SYMBOLS)
{
/* Nothing in this slot. */
continue;
}
element = bfd_get_elt_at_index (abfd, symidx);
if (element == NULL)
return FALSE;
if (element->archive_pass == -1 || element->archive_pass == pass)
{
/* Next symbol if this archive is wrong or already handled. */
continue;
}
if (! bfd_check_format (element, bfd_object))
{
element->archive_pass = -1;
return FALSE;
}
orig_element = element;
if (bfd_is_thin_archive (abfd))
{
element = _bfd_vms_lib_get_imagelib_file (element);
if (element == NULL || !bfd_check_format (element, bfd_object))
{
orig_element->archive_pass = -1;
return FALSE;
}
}
/* Unlike the generic linker, we know that this element provides
a definition for an undefined symbol and we know that we want
to include it. We don't need to check anything. */
if (!(*info->callbacks
->add_archive_element) (info, element, h->root.string, &element))
return FALSE;
if (!alpha_vms_link_add_object_symbols (element, info))
return FALSE;
orig_element->archive_pass = pass;
}
return TRUE;
}
static bfd_boolean
alpha_vms_bfd_link_add_symbols (bfd *abfd, struct bfd_link_info *info)
{
switch (bfd_get_format (abfd))
{
case bfd_object:
vms_debug2 ((2, "vms_link_add_symbols for object %s\n",
abfd->filename));
return alpha_vms_link_add_object_symbols (abfd, info);
break;
case bfd_archive:
vms_debug2 ((2, "vms_link_add_symbols for archive %s\n",
abfd->filename));
return alpha_vms_link_add_archive_symbols (abfd, info);
break;
default:
bfd_set_error (bfd_error_wrong_format);
return FALSE;
}
}
static bfd_boolean
alpha_vms_build_fixups (struct bfd_link_info *info)
{
struct alpha_vms_link_hash_table *t = alpha_vms_link_hash (info);
unsigned char *content;
unsigned int i;
unsigned int sz = 0;
unsigned int lp_sz = 0;
unsigned int ca_sz = 0;
unsigned int qr_sz = 0;
unsigned int shrimg_cnt = 0;
unsigned int chgprt_num = 0;
unsigned int chgprt_sz = 0;
struct vms_eiaf *eiaf;
unsigned int off;
asection *sec;
/* Shared libraries. */
for (i = 0; i < VEC_COUNT (t->shrlibs); i++)
{
struct alpha_vms_shlib_el *shlib;
shlib = &VEC_EL (t->shrlibs, struct alpha_vms_shlib_el, i);
if (!shlib->has_fixups)
continue;
shrimg_cnt++;
if (VEC_COUNT (shlib->ca) > 0)
{
/* Header + entries. */
ca_sz += 8;
ca_sz += VEC_COUNT (shlib->ca) * 4;
}
if (VEC_COUNT (shlib->lp) > 0)
{
/* Header + entries. */
lp_sz += 8;
lp_sz += VEC_COUNT (shlib->lp) * 4;
}
if (VEC_COUNT (shlib->qr) > 0)
{
/* Header + entries. */
qr_sz += 8;
qr_sz += VEC_COUNT (shlib->qr) * 8;
}
}
/* Add markers. */
if (ca_sz > 0)
ca_sz += 8;
if (lp_sz > 0)
lp_sz += 8;
if (qr_sz > 0)
qr_sz += 8;
/* Finish now if there is no content. */
if (ca_sz + lp_sz + qr_sz == 0)
return TRUE;
/* Add an eicp entry for the fixup itself. */
chgprt_num = 1;
for (sec = info->output_bfd->sections; sec != NULL; sec = sec->next)
{
/* This isect could be made RO or EXE after relocations are applied. */
if ((sec->flags & SEC_RELOC) != 0
&& (sec->flags & (SEC_CODE | SEC_READONLY)) != 0)
chgprt_num++;
}
chgprt_sz = 4 + chgprt_num * sizeof (struct vms_eicp);
/* Allocate section content (round-up size) */
sz = sizeof (struct vms_eiaf) + shrimg_cnt * sizeof (struct vms_shl)
+ ca_sz + lp_sz + qr_sz + chgprt_sz;
sz = (sz + VMS_BLOCK_SIZE - 1) & ~(VMS_BLOCK_SIZE - 1);
content = bfd_zalloc (info->output_bfd, sz);
if (content == NULL)
return FALSE;
sec = alpha_vms_link_hash (info)->fixup;
sec->contents = content;
sec->size = sz;
eiaf = (struct vms_eiaf *)content;
off = sizeof (struct vms_eiaf);
bfd_putl32 (0, eiaf->majorid);
bfd_putl32 (0, eiaf->minorid);
bfd_putl32 (0, eiaf->iaflink);
bfd_putl32 (0, eiaf->fixuplnk);
bfd_putl32 (sizeof (struct vms_eiaf), eiaf->size);
bfd_putl32 (0, eiaf->flags);
bfd_putl32 (0, eiaf->qrelfixoff);
bfd_putl32 (0, eiaf->lrelfixoff);
bfd_putl32 (0, eiaf->qdotadroff);
bfd_putl32 (0, eiaf->ldotadroff);
bfd_putl32 (0, eiaf->codeadroff);
bfd_putl32 (0, eiaf->lpfixoff);
bfd_putl32 (0, eiaf->chgprtoff);
bfd_putl32 (shrimg_cnt ? off : 0, eiaf->shlstoff);
bfd_putl32 (shrimg_cnt, eiaf->shrimgcnt);
bfd_putl32 (0, eiaf->shlextra);
bfd_putl32 (0, eiaf->permctx);
bfd_putl32 (0, eiaf->base_va);
bfd_putl32 (0, eiaf->lppsbfixoff);
if (shrimg_cnt)
{
shrimg_cnt = 0;
/* Write shl. */
for (i = 0; i < VEC_COUNT (t->shrlibs); i++)
{
struct alpha_vms_shlib_el *shlib;
struct vms_shl *shl;
shlib = &VEC_EL (t->shrlibs, struct alpha_vms_shlib_el, i);
if (!shlib->has_fixups)
continue;
/* Renumber shared images. */
PRIV2 (shlib->abfd, shr_index) = shrimg_cnt++;
shl = (struct vms_shl *)(content + off);
bfd_putl32 (0, shl->baseva);
bfd_putl32 (0, shl->shlptr);
bfd_putl32 (0, shl->ident);
bfd_putl32 (0, shl->permctx);
shl->size = sizeof (struct vms_shl);
bfd_putl16 (0, shl->fill_1);
shl->flags = 0;
bfd_putl32 (0, shl->icb);
shl->imgnam[0] = strlen (PRIV2 (shlib->abfd, hdr_data.hdr_t_name));
memcpy (shl->imgnam + 1, PRIV2 (shlib->abfd, hdr_data.hdr_t_name),
shl->imgnam[0]);
off += sizeof (struct vms_shl);
}
/* CA fixups. */
if (ca_sz != 0)
{
bfd_putl32 (off, eiaf->codeadroff);
for (i = 0; i < VEC_COUNT (t->shrlibs); i++)
{
struct alpha_vms_shlib_el *shlib;
unsigned int j;
shlib = &VEC_EL (t->shrlibs, struct alpha_vms_shlib_el, i);
if (VEC_COUNT (shlib->ca) == 0)
continue;
bfd_putl32 (VEC_COUNT (shlib->ca), content + off);
bfd_putl32 (PRIV2 (shlib->abfd, shr_index), content + off + 4);
off += 8;
for (j = 0; j < VEC_COUNT (shlib->ca); j++)
{
bfd_putl32 (VEC_EL (shlib->ca, bfd_vma, j) - t->base_addr,
content + off);
off += 4;
}
}
bfd_putl32 (0, content + off);
bfd_putl32 (0, content + off + 4);
off += 8;
}
/* LP fixups. */
if (lp_sz != 0)
{
bfd_putl32 (off, eiaf->lpfixoff);
for (i = 0; i < VEC_COUNT (t->shrlibs); i++)
{
struct alpha_vms_shlib_el *shlib;
unsigned int j;
shlib = &VEC_EL (t->shrlibs, struct alpha_vms_shlib_el, i);
if (VEC_COUNT (shlib->lp) == 0)
continue;
bfd_putl32 (VEC_COUNT (shlib->lp), content + off);
bfd_putl32 (PRIV2 (shlib->abfd, shr_index), content + off + 4);
off += 8;
for (j = 0; j < VEC_COUNT (shlib->lp); j++)
{
bfd_putl32 (VEC_EL (shlib->lp, bfd_vma, j) - t->base_addr,
content + off);
off += 4;
}
}
bfd_putl32 (0, content + off);
bfd_putl32 (0, content + off + 4);
off += 8;
}
/* QR fixups. */
if (qr_sz != 0)
{
bfd_putl32 (off, eiaf->qdotadroff);
for (i = 0; i < VEC_COUNT (t->shrlibs); i++)
{
struct alpha_vms_shlib_el *shlib;
unsigned int j;
shlib = &VEC_EL (t->shrlibs, struct alpha_vms_shlib_el, i);
if (VEC_COUNT (shlib->qr) == 0)
continue;
bfd_putl32 (VEC_COUNT (shlib->qr), content + off);
bfd_putl32 (PRIV2 (shlib->abfd, shr_index), content + off + 4);
off += 8;
for (j = 0; j < VEC_COUNT (shlib->qr); j++)
{
struct alpha_vms_vma_ref *r;
r = &VEC_EL (shlib->qr, struct alpha_vms_vma_ref, j);
bfd_putl32 (r->vma - t->base_addr, content + off);
bfd_putl32 (r->ref, content + off + 4);
off += 8;
}
}
bfd_putl32 (0, content + off);
bfd_putl32 (0, content + off + 4);
off += 8;
}
}
/* Write the change protection table. */
bfd_putl32 (off, eiaf->chgprtoff);
bfd_putl32 (chgprt_num, content + off);
off += 4;
for (sec = info->output_bfd->sections; sec != NULL; sec = sec->next)
{
struct vms_eicp *eicp;
unsigned int prot;
if ((sec->flags & SEC_LINKER_CREATED) != 0 &&
strcmp (sec->name, "$FIXUP$") == 0)
prot = PRT__C_UREW;
else if ((sec->flags & SEC_RELOC) != 0
&& (sec->flags & (SEC_CODE | SEC_READONLY)) != 0)
prot = PRT__C_UR;
else
continue;
eicp = (struct vms_eicp *)(content + off);
bfd_putl64 (sec->vma - t->base_addr, eicp->baseva);
bfd_putl32 ((sec->size + VMS_BLOCK_SIZE - 1) & ~(VMS_BLOCK_SIZE - 1),
eicp->size);
bfd_putl32 (prot, eicp->newprt);
off += sizeof (struct vms_eicp);
}
return TRUE;
}
/* Called by bfd_link_hash_traverse to fill the symbol table.
Return FALSE in case of failure. */
static bfd_boolean
alpha_vms_link_output_symbol (struct bfd_link_hash_entry *hc, void *infov)
{
struct bfd_link_info *info = (struct bfd_link_info *)infov;
struct alpha_vms_link_hash_entry *h = (struct alpha_vms_link_hash_entry *)hc;
struct vms_symbol_entry *sym;
switch (h->root.type)
{
case bfd_link_hash_new:
case bfd_link_hash_undefined:
abort ();
case bfd_link_hash_undefweak:
return TRUE;
case bfd_link_hash_defined:
case bfd_link_hash_defweak:
{
asection *sec = h->root.u.def.section;
/* FIXME: this is certainly a symbol from a dynamic library. */
if (bfd_is_abs_section (sec))
return TRUE;
if (sec->owner->flags & DYNAMIC)
return TRUE;
}
break;
case bfd_link_hash_common:
break;
case bfd_link_hash_indirect:
case bfd_link_hash_warning:
return TRUE;
}
/* Do not write not kept symbols. */
if (info->strip == strip_some
&& bfd_hash_lookup (info->keep_hash, h->root.root.string,
FALSE, FALSE) != NULL)
return TRUE;
if (h->sym == NULL)
{
/* This symbol doesn't come from a VMS object. So we suppose it is
a data. */
int len = strlen (h->root.root.string);
sym = (struct vms_symbol_entry *)bfd_zalloc (info->output_bfd,
sizeof (*sym) + len);
if (sym == NULL)
abort ();
sym->namelen = len;
memcpy (sym->name, h->root.root.string, len);
sym->name[len] = 0;
sym->owner = info->output_bfd;
sym->typ = EGSD__C_SYMG;
sym->data_type = 0;
sym->flags = EGSY__V_DEF | EGSY__V_REL;
sym->symbol_vector = h->root.u.def.value;
sym->section = h->root.u.def.section;
sym->value = h->root.u.def.value;
}
else
sym = h->sym;
if (!add_symbol_entry (info->output_bfd, sym))
return FALSE;
return TRUE;
}
static bfd_boolean
alpha_vms_bfd_final_link (bfd *abfd, struct bfd_link_info *info)
{
asection *o;
struct bfd_link_order *p;
bfd *sub;
asection *fixupsec;
bfd_vma base_addr;
bfd_vma last_addr;
asection *dst;
asection *dmt;
if (info->relocatable)
{
/* FIXME: we do not yet support relocatable link. It is not obvious
how to do it for debug infos. */
(*info->callbacks->einfo)(_("%P: relocatable link is not supported\n"));
return FALSE;
}
bfd_get_outsymbols (abfd) = NULL;
bfd_get_symcount (abfd) = 0;
/* Mark all sections which will be included in the output file. */
for (o = abfd->sections; o != NULL; o = o->next)
for (p = o->map_head.link_order; p != NULL; p = p->next)
if (p->type == bfd_indirect_link_order)
p->u.indirect.section->linker_mark = TRUE;
#if 0
/* Handle all the link order information for the sections. */
for (o = abfd->sections; o != NULL; o = o->next)
{
printf ("For section %s (at 0x%08x, flags=0x%08x):\n",
o->name, (unsigned)o->vma, (unsigned)o->flags);
for (p = o->map_head.link_order; p != NULL; p = p->next)
{
printf (" at 0x%08x - 0x%08x: ",
(unsigned)p->offset, (unsigned)(p->offset + p->size - 1));
switch (p->type)
{
case bfd_section_reloc_link_order:
case bfd_symbol_reloc_link_order:
printf (" section/symbol reloc\n");
break;
case bfd_indirect_link_order:
printf (" section %s of %s\n",
p->u.indirect.section->name,
p->u.indirect.section->owner->filename);
break;
case bfd_data_link_order:
printf (" explicit data\n");
break;
default:
printf (" *unknown* type %u\n", p->type);
break;
}
}
}
#endif
/* Generate the symbol table. */
BFD_ASSERT (PRIV (syms) == NULL);
if (info->strip != strip_all)
bfd_link_hash_traverse (info->hash, alpha_vms_link_output_symbol, info);
/* Find the entry point. */
if (bfd_get_start_address (abfd) == 0)
{
bfd *startbfd = NULL;
for (sub = info->input_bfds; sub != NULL; sub = sub->link_next)
{
/* Consider only VMS object files. */
if (sub->xvec != abfd->xvec)
continue;
if (!PRIV2 (sub, eom_data).eom_has_transfer)
continue;
if ((PRIV2 (sub, eom_data).eom_b_tfrflg & EEOM__M_WKTFR) && startbfd)
continue;
if (startbfd != NULL
&& !(PRIV2 (sub, eom_data).eom_b_tfrflg & EEOM__M_WKTFR))
{
(*info->callbacks->einfo)
(_("%P: multiple entry points: in modules %B and %B\n"),
startbfd, sub);
continue;
}
startbfd = sub;
}
if (startbfd)
{
unsigned int ps_idx = PRIV2 (startbfd, eom_data).eom_l_psindx;
bfd_vma tfradr = PRIV2 (startbfd, eom_data).eom_l_tfradr;
asection *sec;
sec = PRIV2 (startbfd, sections)[ps_idx];
bfd_set_start_address
(abfd, sec->output_section->vma + sec->output_offset + tfradr);
}
}
/* Set transfer addresses. */
{
int i;
struct bfd_link_hash_entry *h;
i = 0;
PRIV (transfer_address[i++]) = 0xffffffff00000340ULL; /* SYS$IMGACT */
h = bfd_link_hash_lookup (info->hash, "LIB$INITIALIZE", FALSE, FALSE, TRUE);
if (h != NULL && h->type == bfd_link_hash_defined)
PRIV (transfer_address[i++]) =
alpha_vms_get_sym_value (h->u.def.section, h->u.def.value);
PRIV (transfer_address[i++]) = bfd_get_start_address (abfd);
while (i < 4)
PRIV (transfer_address[i++]) = 0;
}
/* Allocate contents.
Also compute the virtual base address. */
base_addr = (bfd_vma)-1;
last_addr = 0;
for (o = abfd->sections; o != NULL; o = o->next)
{
if (o->flags & SEC_HAS_CONTENTS)
{
o->contents = bfd_alloc (abfd, o->size);
if (o->contents == NULL)
return FALSE;
}
if (o->flags & SEC_LOAD)
{
if (o->vma < base_addr)
base_addr = o->vma;
if (o->vma + o->size > last_addr)
last_addr = o->vma + o->size;
}
/* Clear the RELOC flags. Currently we don't support incremental
linking. We use the RELOC flag for computing the eicp entries. */
o->flags &= ~SEC_RELOC;
}
/* Create the fixup section. */
fixupsec = bfd_make_section_anyway_with_flags
(info->output_bfd, "$FIXUP$",
SEC_ALLOC | SEC_LOAD | SEC_HAS_CONTENTS | SEC_LINKER_CREATED);
if (fixupsec == NULL)
return FALSE;
last_addr = (last_addr + 0xffff) & ~0xffff;
fixupsec->vma = last_addr;
alpha_vms_link_hash (info)->fixup = fixupsec;
alpha_vms_link_hash (info)->base_addr = base_addr;
/* Create the DMT section, if necessary. */
BFD_ASSERT (PRIV (dst_section) == NULL);
dst = bfd_get_section_by_name (abfd, "$DST$");
if (dst != NULL && dst->size == 0)
dst = NULL;
if (dst != NULL)
{
PRIV (dst_section) = dst;
dmt = bfd_make_section_anyway_with_flags
(info->output_bfd, "$DMT$",
SEC_DEBUGGING | SEC_HAS_CONTENTS | SEC_LINKER_CREATED);
if (dmt == NULL)
return FALSE;
}
else
dmt = NULL;
/* Read all sections from the inputs. */
for (sub = info->input_bfds; sub != NULL; sub = sub->link_next)
{
if (sub->flags & DYNAMIC)
{
alpha_vms_create_eisd_for_shared (abfd, sub);
continue;
}
if (!alpha_vms_read_sections_content (sub, info))
return FALSE;
}
/* Handle all the link order information for the sections.
Note: past this point, it is not possible to create new sections. */
for (o = abfd->sections; o != NULL; o = o->next)
{
for (p = o->map_head.link_order; p != NULL; p = p->next)
{
switch (p->type)
{
case bfd_section_reloc_link_order:
case bfd_symbol_reloc_link_order:
abort ();
return FALSE;
case bfd_indirect_link_order:
/* Already done. */
break;
default:
if (! _bfd_default_link_order (abfd, info, o, p))
return FALSE;
break;
}
}
}
/* Compute fixups. */
if (!alpha_vms_build_fixups (info))
return FALSE;
/* Compute the DMT. */
if (dmt != NULL)
{
int pass;
unsigned char *contents = NULL;
/* In pass 1, compute the size. In pass 2, write the DMT contents. */
for (pass = 0; pass < 2; pass++)
{
unsigned int off = 0;
/* For each object file (ie for each module). */
for (sub = info->input_bfds; sub != NULL; sub = sub->link_next)
{
asection *sub_dst;
struct vms_dmt_header *dmth = NULL;
unsigned int psect_count;
/* Skip this module if it has no DST. */
sub_dst = PRIV2 (sub, dst_section);
if (sub_dst == NULL || sub_dst->size == 0)
continue;
if (pass == 1)
{
/* Write the header. */
dmth = (struct vms_dmt_header *)(contents + off);
bfd_putl32 (sub_dst->output_offset, dmth->modbeg);
bfd_putl32 (sub_dst->size, dmth->size);
}
off += sizeof (struct vms_dmt_header);
psect_count = 0;
/* For each section (ie for each psect). */
for (o = sub->sections; o != NULL; o = o->next)
{
/* Only consider interesting sections. */
if (!(o->flags & SEC_ALLOC))
continue;
if (o->flags & SEC_LINKER_CREATED)
continue;
if (pass == 1)
{
/* Write an entry. */
struct vms_dmt_psect *dmtp;
dmtp = (struct vms_dmt_psect *)(contents + off);
bfd_putl32 (o->output_offset + o->output_section->vma,
dmtp->start);
bfd_putl32 (o->size, dmtp->length);
psect_count++;
}
off += sizeof (struct vms_dmt_psect);
}
if (pass == 1)
bfd_putl32 (psect_count, dmth->psect_count);
}
if (pass == 0)
{
contents = bfd_zalloc (info->output_bfd, off);
if (contents == NULL)
return FALSE;
dmt->contents = contents;
dmt->size = off;
}
else
{
BFD_ASSERT (off == dmt->size);
}
}
}
return TRUE;
}
/* Read the contents of a section.
buf points to a buffer of buf_size bytes to be filled with
section data (starting at offset into section) */
static bfd_boolean
alpha_vms_get_section_contents (bfd *abfd, asection *section,
void *buf, file_ptr offset,
bfd_size_type count)
{
asection *sec;
/* Image are easy. */
if (bfd_get_file_flags (abfd) & (EXEC_P | DYNAMIC))
return _bfd_generic_get_section_contents (abfd, section,
buf, offset, count);
/* Safety check. */
if (offset + count < count
|| offset + count > section->size)
{
bfd_set_error (bfd_error_invalid_operation);
return FALSE;
}
/* Alloc in memory and read ETIRs. */
BFD_ASSERT (section->contents == NULL);
for (sec = abfd->sections; sec; sec = sec->next)
{
BFD_ASSERT (sec->contents == NULL);
if (sec->size != 0 && (sec->flags & SEC_HAS_CONTENTS))
{
sec->contents = bfd_alloc (abfd, sec->size);
if (sec->contents == NULL)
return FALSE;
}
}
if (!alpha_vms_read_sections_content (abfd, NULL))
return FALSE;
for (sec = abfd->sections; sec; sec = sec->next)
if (section->contents)
section->flags |= SEC_IN_MEMORY;
memcpy (buf, section->contents + offset, count);
return TRUE;
}
/* Set the format of a file being written. */
static bfd_boolean
alpha_vms_mkobject (bfd * abfd)
{
const bfd_arch_info_type *arch;
vms_debug2 ((1, "alpha_vms_mkobject (%p)\n", abfd));
if (!vms_initialize (abfd))
return FALSE;
PRIV (recwr.buf) = bfd_alloc (abfd, MAX_OUTREC_SIZE);
if (PRIV (recwr.buf) == NULL)
return FALSE;
arch = bfd_scan_arch ("alpha");
if (arch == 0)
{
bfd_set_error (bfd_error_wrong_format);
return FALSE;
}
abfd->arch_info = arch;
return TRUE;
}
/* 4.1, generic. */
/* Called when the BFD is being closed to do any necessary cleanup. */
static bfd_boolean
vms_close_and_cleanup (bfd * abfd)
{
vms_debug2 ((1, "vms_close_and_cleanup (%p)\n", abfd));
if (abfd == NULL || abfd->tdata.any == NULL)
return TRUE;
if (abfd->format == bfd_archive)
{
bfd_release (abfd, abfd->tdata.any);
abfd->tdata.any = NULL;
return TRUE;
}
if (PRIV (recrd.buf) != NULL)
free (PRIV (recrd.buf));
if (PRIV (sections) != NULL)
free (PRIV (sections));
bfd_release (abfd, abfd->tdata.any);
abfd->tdata.any = NULL;
#ifdef VMS
if (abfd->direction == write_direction)
{
/* Last step on VMS is to convert the file to variable record length
format. */
if (bfd_cache_close (abfd) != TRUE)
return FALSE;
if (_bfd_vms_convert_to_var_unix_filename (abfd->filename) != TRUE)
return FALSE;
}
#endif
return TRUE;
}
/* Called when a new section is created. */
static bfd_boolean
vms_new_section_hook (bfd * abfd, asection *section)
{
bfd_size_type amt;
vms_debug2 ((1, "vms_new_section_hook (%p, [%d]%s)\n",
abfd, section->index, section->name));
bfd_set_section_alignment (abfd, section, 0);
vms_debug2 ((7, "%d: %s\n", section->index, section->name));
amt = sizeof (struct vms_section_data_struct);
section->used_by_bfd = (PTR) bfd_zalloc (abfd, amt);
if (section->used_by_bfd == NULL)
return FALSE;
/* Create the section symbol. */
return _bfd_generic_new_section_hook (abfd, section);
}
/* Part 4.5, symbols. */
/* Print symbol to file according to how. how is one of
bfd_print_symbol_name just print the name
bfd_print_symbol_more print more (???)
bfd_print_symbol_all print all we know, which is not much right now :-). */
static void
vms_print_symbol (bfd * abfd,
void * file,
asymbol *symbol,
bfd_print_symbol_type how)
{
vms_debug2 ((1, "vms_print_symbol (%p, %p, %p, %d)\n",
abfd, file, symbol, how));
switch (how)
{
case bfd_print_symbol_name:
case bfd_print_symbol_more:
fprintf ((FILE *)file," %s", symbol->name);
break;
case bfd_print_symbol_all:
{
const char *section_name = symbol->section->name;
bfd_print_symbol_vandf (abfd, file, symbol);
fprintf ((FILE *) file," %-8s %s", section_name, symbol->name);
}
break;
}
}
/* Return information about symbol in ret.
fill type, value and name
type:
A absolute
B bss segment symbol
C common symbol
D data segment symbol
f filename
t a static function symbol
T text segment symbol
U undefined
- debug. */
static void
vms_get_symbol_info (bfd * abfd ATTRIBUTE_UNUSED,
asymbol *symbol,
symbol_info *ret)
{
asection *sec;
vms_debug2 ((1, "vms_get_symbol_info (%p, %p, %p)\n", abfd, symbol, ret));
sec = symbol->section;
if (ret == NULL)
return;
if (sec == NULL)
ret->type = 'U';
else if (bfd_is_com_section (sec))
ret->type = 'C';
else if (bfd_is_abs_section (sec))
ret->type = 'A';
else if (bfd_is_und_section (sec))
ret->type = 'U';
else if (bfd_is_ind_section (sec))
ret->type = 'I';
else if ((symbol->flags & BSF_FUNCTION)
|| (bfd_get_section_flags (abfd, sec) & SEC_CODE))
ret->type = 'T';
else if (bfd_get_section_flags (abfd, sec) & SEC_DATA)
ret->type = 'D';
else if (bfd_get_section_flags (abfd, sec) & SEC_ALLOC)
ret->type = 'B';
else
ret->type = '?';
if (ret->type != 'U')
ret->value = symbol->value + symbol->section->vma;
else
ret->value = 0;
ret->name = symbol->name;
}
/* Return TRUE if the given symbol sym in the BFD abfd is
a compiler generated local label, else return FALSE. */
static bfd_boolean
vms_bfd_is_local_label_name (bfd * abfd ATTRIBUTE_UNUSED,
const char *name)
{
vms_debug2 ((1, "vms_bfd_is_local_label_name (%p, %s)\n", abfd, name));
return name[0] == '$';
}
/* Part 4.7, writing an object file. */
/* Sets the contents of the section section in BFD abfd to the data starting
in memory at LOCATION. The data is written to the output section starting
at offset offset for count bytes.
Normally TRUE is returned, else FALSE. Possible error returns are:
o bfd_error_no_contents - The output section does not have the
SEC_HAS_CONTENTS attribute, so nothing can be written to it.
o and some more too */
static bfd_boolean
_bfd_vms_set_section_contents (bfd * abfd,
asection *section,
const void * location,
file_ptr offset,
bfd_size_type count)
{
if (section->contents == NULL)
{
section->contents = bfd_alloc (abfd, section->size);
if (section->contents == NULL)
return FALSE;
memcpy (section->contents + offset, location, (size_t) count);
}
return TRUE;
}
/* Set the architecture and machine type in BFD abfd to arch and mach.
Find the correct pointer to a structure and insert it into the arch_info
pointer. */
static bfd_boolean
alpha_vms_set_arch_mach (bfd *abfd,
enum bfd_architecture arch, unsigned long mach)
{
if (arch != bfd_arch_alpha
&& arch != bfd_arch_unknown)
return FALSE;
return bfd_default_set_arch_mach (abfd, arch, mach);
}
/* Set section VMS flags. Clear NO_FLAGS and set FLAGS. */
void
bfd_vms_set_section_flags (bfd *abfd ATTRIBUTE_UNUSED,
asection *sec, flagword no_flags, flagword flags)
{
vms_section_data (sec)->no_flags = no_flags;
vms_section_data (sec)->flags = flags;
}
struct vms_private_data_struct *
bfd_vms_get_data (bfd *abfd)
{
return (struct vms_private_data_struct *)abfd->tdata.any;
}
#define vms_bfd_is_target_special_symbol ((bfd_boolean (*) (bfd *, asymbol *)) bfd_false)
#define vms_bfd_link_just_syms _bfd_generic_link_just_syms
#define vms_bfd_copy_link_hash_symbol_type \
_bfd_generic_copy_link_hash_symbol_type
#define vms_bfd_is_group_section bfd_generic_is_group_section
#define vms_bfd_discard_group bfd_generic_discard_group
#define vms_section_already_linked _bfd_generic_section_already_linked
#define vms_bfd_define_common_symbol bfd_generic_define_common_symbol
#define vms_bfd_copy_private_header_data _bfd_generic_bfd_copy_private_header_data
#define vms_bfd_copy_private_bfd_data _bfd_generic_bfd_copy_private_bfd_data
#define vms_bfd_free_cached_info _bfd_generic_bfd_free_cached_info
#define vms_bfd_copy_private_section_data _bfd_generic_bfd_copy_private_section_data
#define vms_bfd_copy_private_symbol_data _bfd_generic_bfd_copy_private_symbol_data
#define vms_bfd_set_private_flags _bfd_generic_bfd_set_private_flags
#define vms_bfd_merge_private_bfd_data _bfd_generic_bfd_merge_private_bfd_data
/* Symbols table. */
#define alpha_vms_make_empty_symbol _bfd_generic_make_empty_symbol
#define alpha_vms_bfd_is_target_special_symbol \
((bfd_boolean (*) (bfd *, asymbol *)) bfd_false)
#define alpha_vms_print_symbol vms_print_symbol
#define alpha_vms_get_symbol_info vms_get_symbol_info
#define alpha_vms_read_minisymbols _bfd_generic_read_minisymbols
#define alpha_vms_minisymbol_to_symbol _bfd_generic_minisymbol_to_symbol
#define alpha_vms_get_lineno _bfd_nosymbols_get_lineno
#define alpha_vms_find_inliner_info _bfd_nosymbols_find_inliner_info
#define alpha_vms_bfd_make_debug_symbol _bfd_nosymbols_bfd_make_debug_symbol
#define alpha_vms_find_nearest_line _bfd_vms_find_nearest_dst_line
#define alpha_vms_bfd_is_local_label_name vms_bfd_is_local_label_name
/* Generic table. */
#define alpha_vms_close_and_cleanup vms_close_and_cleanup
#define alpha_vms_bfd_free_cached_info vms_bfd_free_cached_info
#define alpha_vms_new_section_hook vms_new_section_hook
#define alpha_vms_set_section_contents _bfd_vms_set_section_contents
#define alpha_vms_get_section_contents_in_window _bfd_generic_get_section_contents_in_window
#define alpha_vms_bfd_get_relocated_section_contents \
bfd_generic_get_relocated_section_contents
#define alpha_vms_bfd_relax_section bfd_generic_relax_section
#define alpha_vms_bfd_gc_sections bfd_generic_gc_sections
#define alpha_vms_bfd_merge_sections bfd_generic_merge_sections
#define alpha_vms_bfd_is_group_section bfd_generic_is_group_section
#define alpha_vms_bfd_discard_group bfd_generic_discard_group
#define alpha_vms_section_already_linked \
_bfd_generic_section_already_linked
#define alpha_vms_bfd_define_common_symbol bfd_generic_define_common_symbol
#define alpha_vms_bfd_link_hash_table_free _bfd_generic_link_hash_table_free
#define alpha_vms_bfd_link_just_syms _bfd_generic_link_just_syms
#define alpha_vms_bfd_copy_link_hash_symbol_type \
_bfd_generic_copy_link_hash_symbol_type
#define alpha_vms_bfd_link_split_section _bfd_generic_link_split_section
#define alpha_vms_get_dynamic_symtab_upper_bound \
_bfd_nodynamic_get_dynamic_symtab_upper_bound
#define alpha_vms_canonicalize_dynamic_symtab \
_bfd_nodynamic_canonicalize_dynamic_symtab
#define alpha_vms_get_dynamic_reloc_upper_bound \
_bfd_nodynamic_get_dynamic_reloc_upper_bound
#define alpha_vms_canonicalize_dynamic_reloc \
_bfd_nodynamic_canonicalize_dynamic_reloc
const bfd_target vms_alpha_vec =
{
"vms-alpha", /* Name. */
bfd_target_evax_flavour,
BFD_ENDIAN_LITTLE, /* Data byte order is little. */
BFD_ENDIAN_LITTLE, /* Header byte order is little. */
(HAS_RELOC | EXEC_P | HAS_LINENO | HAS_DEBUG | HAS_SYMS | HAS_LOCALS
| WP_TEXT | D_PAGED), /* Object flags. */
(SEC_ALLOC | SEC_LOAD | SEC_RELOC
| SEC_READONLY | SEC_CODE | SEC_DATA
| SEC_HAS_CONTENTS | SEC_IN_MEMORY), /* Sect flags. */
0, /* symbol_leading_char. */
' ', /* ar_pad_char. */
15, /* ar_max_namelen. */
bfd_getl64, bfd_getl_signed_64, bfd_putl64,
bfd_getl32, bfd_getl_signed_32, bfd_putl32,
bfd_getl16, bfd_getl_signed_16, bfd_putl16,
bfd_getl64, bfd_getl_signed_64, bfd_putl64,
bfd_getl32, bfd_getl_signed_32, bfd_putl32,
bfd_getl16, bfd_getl_signed_16, bfd_putl16,
{_bfd_dummy_target, alpha_vms_object_p, /* bfd_check_format. */
_bfd_vms_lib_alpha_archive_p, _bfd_dummy_target},
{bfd_false, alpha_vms_mkobject, /* bfd_set_format. */
_bfd_vms_lib_alpha_mkarchive, bfd_false},
{bfd_false, alpha_vms_write_object_contents, /* bfd_write_contents. */
_bfd_vms_lib_write_archive_contents, bfd_false},
BFD_JUMP_TABLE_GENERIC (alpha_vms),
BFD_JUMP_TABLE_COPY (vms),
BFD_JUMP_TABLE_CORE (_bfd_nocore),
BFD_JUMP_TABLE_ARCHIVE (_bfd_vms_lib),
BFD_JUMP_TABLE_SYMBOLS (alpha_vms),
BFD_JUMP_TABLE_RELOCS (alpha_vms),
BFD_JUMP_TABLE_WRITE (alpha_vms),
BFD_JUMP_TABLE_LINK (alpha_vms),
BFD_JUMP_TABLE_DYNAMIC (alpha_vms),
NULL,
(PTR) 0
};