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[/] [or1k_old/] [trunk/] [gdb-5.3/] [include/] [aout/] [aout64.h] - Blame information for rev 1782

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1 1181 sfurman
/* `a.out' object-file definitions, including extensions to 64-bit fields
2
 
3
   Copyright 2001 Free Software Foundation, Inc.
4
 
5
   This program is free software; you can redistribute it and/or modify
6
   it under the terms of the GNU General Public License as published by
7
   the Free Software Foundation; either version 2 of the License, or
8
   (at your option) any later version.
9
 
10
   This program is distributed in the hope that it will be useful,
11
   but WITHOUT ANY WARRANTY; without even the implied warranty of
12
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
13
   GNU General Public License for more details.
14
 
15
   You should have received a copy of the GNU General Public License
16
   along with this program; if not, write to the Free Software
17
   Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.  */
18
 
19
#ifndef __A_OUT_64_H__
20
#define __A_OUT_64_H__
21
 
22
/* This is the layout on disk of the 32-bit or 64-bit exec header. */
23
 
24
#ifndef external_exec
25
struct external_exec
26
{
27
  bfd_byte e_info[4];           /* magic number and stuff               */
28
  bfd_byte e_text[BYTES_IN_WORD]; /* length of text section in bytes    */
29
  bfd_byte e_data[BYTES_IN_WORD]; /* length of data section in bytes    */
30
  bfd_byte e_bss[BYTES_IN_WORD]; /* length of bss area in bytes                 */
31
  bfd_byte e_syms[BYTES_IN_WORD]; /* length of symbol table in bytes    */
32
  bfd_byte e_entry[BYTES_IN_WORD]; /* start address                     */
33
  bfd_byte e_trsize[BYTES_IN_WORD]; /* length of text relocation info   */
34
  bfd_byte e_drsize[BYTES_IN_WORD]; /* length of data relocation info   */
35
};
36
 
37
#define EXEC_BYTES_SIZE (4 + BYTES_IN_WORD * 7)
38
 
39
/* Magic numbers for a.out files */
40
 
41
#if ARCH_SIZE==64
42
#define OMAGIC 0x1001           /* Code indicating object file  */
43
#define ZMAGIC 0x1002           /* Code indicating demand-paged executable.  */
44
#define NMAGIC 0x1003           /* Code indicating pure executable.  */
45
 
46
/* There is no 64-bit QMAGIC as far as I know.  */
47
 
48
#define N_BADMAG(x)       (N_MAGIC(x) != OMAGIC         \
49
                        && N_MAGIC(x) != NMAGIC         \
50
                        && N_MAGIC(x) != ZMAGIC)
51
#else
52
#define OMAGIC 0407             /* ...object file or impure executable.  */
53
#define NMAGIC 0410             /* Code indicating pure executable.  */
54
#define ZMAGIC 0413             /* Code indicating demand-paged executable.  */
55
#define BMAGIC 0415             /* Used by a b.out object.  */
56
 
57
/* This indicates a demand-paged executable with the header in the text.
58
   It is used by 386BSD (and variants) and Linux, at least.  */
59
#ifndef QMAGIC
60
#define QMAGIC 0314
61
#endif
62
# ifndef N_BADMAG
63
#  define N_BADMAG(x)     (N_MAGIC(x) != OMAGIC         \
64
                        && N_MAGIC(x) != NMAGIC         \
65
                        && N_MAGIC(x) != ZMAGIC \
66
                        && N_MAGIC(x) != QMAGIC)
67
# endif /* N_BADMAG */
68
#endif
69
 
70
#endif
71
 
72
#ifdef QMAGIC
73
#define N_IS_QMAGIC(x) (N_MAGIC (x) == QMAGIC)
74
#else
75
#define N_IS_QMAGIC(x) (0)
76
#endif
77
 
78
/* The difference between TARGET_PAGE_SIZE and N_SEGSIZE is that TARGET_PAGE_SIZE is
79
   the finest granularity at which you can page something, thus it
80
   controls the padding (if any) before the text segment of a ZMAGIC
81
   file.  N_SEGSIZE is the resolution at which things can be marked as
82
   read-only versus read/write, so it controls the padding between the
83
   text segment and the data segment (in memory; on disk the padding
84
   between them is TARGET_PAGE_SIZE).  TARGET_PAGE_SIZE and N_SEGSIZE are the same
85
   for most machines, but different for sun3.  */
86
 
87
/* By default, segment size is constant.  But some machines override this
88
   to be a function of the a.out header (e.g. machine type).  */
89
 
90
#ifndef N_SEGSIZE
91
#define N_SEGSIZE(x)    SEGMENT_SIZE
92
#endif
93
 
94
/* Virtual memory address of the text section.
95
   This is getting very complicated.  A good reason to discard a.out format
96
   for something that specifies these fields explicitly.  But til then...
97
 
98
   * OMAGIC and NMAGIC files:
99
       (object files: text for "relocatable addr 0" right after the header)
100
       start at 0, offset is EXEC_BYTES_SIZE, size as stated.
101
   * The text address, offset, and size of ZMAGIC files depend
102
     on the entry point of the file:
103
     * entry point below TEXT_START_ADDR:
104
       (hack for SunOS shared libraries)
105
       start at 0, offset is 0, size as stated.
106
     * If N_HEADER_IN_TEXT(x) is true (which defaults to being the
107
       case when the entry point is EXEC_BYTES_SIZE or further into a page):
108
       no padding is needed; text can start after exec header.  Sun
109
       considers the text segment of such files to include the exec header;
110
       for BFD's purposes, we don't, which makes more work for us.
111
       start at TEXT_START_ADDR + EXEC_BYTES_SIZE, offset is EXEC_BYTES_SIZE,
112
       size as stated minus EXEC_BYTES_SIZE.
113
     * If N_HEADER_IN_TEXT(x) is false (which defaults to being the case when
114
       the entry point is less than EXEC_BYTES_SIZE into a page (e.g. page
115
       aligned)): (padding is needed so that text can start at a page boundary)
116
       start at TEXT_START_ADDR, offset TARGET_PAGE_SIZE, size as stated.
117
 
118
    Specific configurations may want to hardwire N_HEADER_IN_TEXT,
119
    for efficiency or to allow people to play games with the entry point.
120
    In that case, you would #define N_HEADER_IN_TEXT(x) as 1 for sunos,
121
    and as 0 for most other hosts (Sony News, Vax Ultrix, etc).
122
    (Do this in the appropriate bfd target file.)
123
    (The default is a heuristic that will break if people try changing
124
    the entry point, perhaps with the ld -e flag.)
125
 
126
    * QMAGIC is always like a ZMAGIC for which N_HEADER_IN_TEXT is true,
127
    and for which the starting address is TARGET_PAGE_SIZE (or should this be
128
    SEGMENT_SIZE?) (TEXT_START_ADDR only applies to ZMAGIC, not to QMAGIC).
129
    */
130
 
131
/* This macro is only relevant for ZMAGIC files; QMAGIC always has the header
132
   in the text.  */
133
#ifndef N_HEADER_IN_TEXT
134
#define N_HEADER_IN_TEXT(x) \
135
  (((x).a_entry & (TARGET_PAGE_SIZE-1)) >= EXEC_BYTES_SIZE)
136
#endif
137
 
138
/* Sun shared libraries, not linux.  This macro is only relevant for ZMAGIC
139
   files.  */
140
#ifndef N_SHARED_LIB
141
#if defined (TEXT_START_ADDR) && TEXT_START_ADDR == 0
142
#define N_SHARED_LIB(x) (0)
143
#else
144
#define N_SHARED_LIB(x) ((x).a_entry < TEXT_START_ADDR)
145
#endif
146
#endif
147
 
148
/* Returning 0 not TEXT_START_ADDR for OMAGIC and NMAGIC is based on
149
   the assumption that we are dealing with a .o file, not an
150
   executable.  This is necessary for OMAGIC (but means we don't work
151
   right on the output from ld -N); more questionable for NMAGIC.  */
152
 
153
#ifndef N_TXTADDR
154
#define N_TXTADDR(x) \
155
    (/* The address of a QMAGIC file is always one page in, */          \
156
     /* with the header in the text.  */                                \
157
     N_IS_QMAGIC (x)                                                    \
158
     ? (bfd_vma) TARGET_PAGE_SIZE + EXEC_BYTES_SIZE                     \
159
     : (N_MAGIC (x) != ZMAGIC                                           \
160
        ? (bfd_vma) 0    /* object file or NMAGIC */                     \
161
        : (N_SHARED_LIB (x)                                             \
162
           ? (bfd_vma) 0                                         \
163
           : (N_HEADER_IN_TEXT (x)                                      \
164
              ? (bfd_vma) TEXT_START_ADDR + EXEC_BYTES_SIZE             \
165
              : (bfd_vma) TEXT_START_ADDR))))
166
#endif
167
 
168
/* If N_HEADER_IN_TEXT is not true for ZMAGIC, there is some padding
169
   to make the text segment start at a certain boundary.  For most
170
   systems, this boundary is TARGET_PAGE_SIZE.  But for Linux, in the
171
   time-honored tradition of crazy ZMAGIC hacks, it is 1024 which is
172
   not what TARGET_PAGE_SIZE needs to be for QMAGIC.  */
173
 
174
#ifndef ZMAGIC_DISK_BLOCK_SIZE
175
#define ZMAGIC_DISK_BLOCK_SIZE TARGET_PAGE_SIZE
176
#endif
177
 
178
#define N_DISK_BLOCK_SIZE(x) \
179
  (N_MAGIC(x) == ZMAGIC ? ZMAGIC_DISK_BLOCK_SIZE : TARGET_PAGE_SIZE)
180
 
181
/* Offset in an a.out of the start of the text section. */
182
#ifndef N_TXTOFF
183
#define N_TXTOFF(x)                                                     \
184
    (/* For {O,N,Q}MAGIC, no padding.  */                               \
185
     N_MAGIC (x) != ZMAGIC                                              \
186
     ? EXEC_BYTES_SIZE                                                  \
187
     : (N_SHARED_LIB (x)                                                \
188
        ? 0                                                              \
189
        : (N_HEADER_IN_TEXT (x)                                         \
190
           ? EXEC_BYTES_SIZE            /* no padding */                \
191
           : ZMAGIC_DISK_BLOCK_SIZE     /* a page of padding */)))
192
#endif
193
/* Size of the text section.  It's always as stated, except that we
194
   offset it to `undo' the adjustment to N_TXTADDR and N_TXTOFF
195
   for ZMAGIC files that nominally include the exec header
196
   as part of the first page of text.  (BFD doesn't consider the
197
   exec header to be part of the text segment.)  */
198
#ifndef N_TXTSIZE
199
#define N_TXTSIZE(x) \
200
  (/* For QMAGIC, we don't consider the header part of the text section.  */\
201
   N_IS_QMAGIC (x)                                                      \
202
   ? (x).a_text - EXEC_BYTES_SIZE                                       \
203
   : ((N_MAGIC (x) != ZMAGIC || N_SHARED_LIB (x))                       \
204
      ? (x).a_text                                                      \
205
      : (N_HEADER_IN_TEXT (x)                                           \
206
         ? (x).a_text - EXEC_BYTES_SIZE /* no padding */                \
207
         : (x).a_text                   /* a page of padding */ )))
208
#endif
209
/* The address of the data segment in virtual memory.
210
   It is the text segment address, plus text segment size, rounded
211
   up to a N_SEGSIZE boundary for pure or pageable files. */
212
#ifndef N_DATADDR
213
#define N_DATADDR(x) \
214
  (N_MAGIC (x) == OMAGIC                                                \
215
   ? (N_TXTADDR (x) + N_TXTSIZE (x))                                    \
216
   : (N_SEGSIZE (x) + ((N_TXTADDR (x) + N_TXTSIZE (x) - 1)              \
217
                       & ~ (bfd_vma) (N_SEGSIZE (x) - 1))))
218
#endif
219
/* The address of the BSS segment -- immediately after the data segment.  */
220
 
221
#define N_BSSADDR(x)    (N_DATADDR (x) + (x).a_data)
222
 
223
/* Offsets of the various portions of the file after the text segment.  */
224
 
225
/* For {Q,Z}MAGIC, there is padding to make the data segment start on
226
   a page boundary.  Most of the time the a_text field (and thus
227
   N_TXTSIZE) already contains this padding.  It is possible that for
228
   BSDI and/or 386BSD it sometimes doesn't contain the padding, and
229
   perhaps we should be adding it here.  But this seems kind of
230
   questionable and probably should be BSDI/386BSD-specific if we do
231
   do it.
232
 
233
   For NMAGIC (at least for hp300 BSD, probably others), there is
234
   padding in memory only, not on disk, so we must *not* ever pad here
235
   for NMAGIC.  */
236
 
237
#ifndef N_DATOFF
238
#define N_DATOFF(x)     ( N_TXTOFF (x) + N_TXTSIZE (x) )
239
#endif
240
#ifndef N_TRELOFF
241
#define N_TRELOFF(x)    ( N_DATOFF (x) + (x).a_data )
242
#endif
243
#ifndef N_DRELOFF
244
#define N_DRELOFF(x)    ( N_TRELOFF (x) + (x).a_trsize )
245
#endif
246
#ifndef N_SYMOFF
247
#define N_SYMOFF(x)     ( N_DRELOFF (x) + (x).a_drsize )
248
#endif
249
#ifndef N_STROFF
250
#define N_STROFF(x)     ( N_SYMOFF (x) + (x).a_syms )
251
#endif
252
 
253
/* Symbols */
254
#ifndef external_nlist
255
struct external_nlist {
256
  bfd_byte e_strx[BYTES_IN_WORD];       /* index into string table of name */
257
  bfd_byte e_type[1];                   /* type of symbol */
258
  bfd_byte e_other[1];                  /* misc info (usually empty) */
259
  bfd_byte e_desc[2];                   /* description field */
260
  bfd_byte e_value[BYTES_IN_WORD];      /* value of symbol */
261
};
262
#define EXTERNAL_NLIST_SIZE (BYTES_IN_WORD+4+BYTES_IN_WORD)
263
#endif
264
 
265
struct internal_nlist {
266
  unsigned long n_strx;                 /* index into string table of name */
267
  unsigned char n_type;                 /* type of symbol */
268
  unsigned char n_other;                /* misc info (usually empty) */
269
  unsigned short n_desc;                /* description field */
270
  bfd_vma n_value;                      /* value of symbol */
271
};
272
 
273
/* The n_type field is the symbol type, containing:  */
274
 
275
#define N_UNDF  0        /* Undefined symbol */
276
#define N_ABS   2       /* Absolute symbol -- defined at particular addr */
277
#define N_TEXT  4       /* Text sym -- defined at offset in text seg */
278
#define N_DATA  6       /* Data sym -- defined at offset in data seg */
279
#define N_BSS   8       /* BSS  sym -- defined at offset in zero'd seg */
280
#define N_COMM  0x12    /* Common symbol (visible after shared lib dynlink) */
281
#define N_FN    0x1f    /* File name of .o file */
282
#define N_FN_SEQ 0x0C   /* N_FN from Sequent compilers (sigh) */
283
/* Note: N_EXT can only be usefully OR-ed with N_UNDF, N_ABS, N_TEXT,
284
   N_DATA, or N_BSS.  When the low-order bit of other types is set,
285
   (e.g. N_WARNING versus N_FN), they are two different types.  */
286
#define N_EXT   1       /* External symbol (as opposed to local-to-this-file) */
287
#define N_TYPE  0x1e
288
#define N_STAB  0xe0    /* If any of these bits are on, it's a debug symbol */
289
 
290
#define N_INDR 0x0a
291
 
292
/* The following symbols refer to set elements.
293
   All the N_SET[ATDB] symbols with the same name form one set.
294
   Space is allocated for the set in the text section, and each set
295
   elements value is stored into one word of the space.
296
   The first word of the space is the length of the set (number of elements).
297
 
298
   The address of the set is made into an N_SETV symbol
299
   whose name is the same as the name of the set.
300
   This symbol acts like a N_DATA global symbol
301
   in that it can satisfy undefined external references.  */
302
 
303
/* These appear as input to LD, in a .o file.  */
304
#define N_SETA  0x14            /* Absolute set element symbol */
305
#define N_SETT  0x16            /* Text set element symbol */
306
#define N_SETD  0x18            /* Data set element symbol */
307
#define N_SETB  0x1A            /* Bss set element symbol */
308
 
309
/* This is output from LD.  */
310
#define N_SETV  0x1C            /* Pointer to set vector in data area.  */
311
 
312
/* Warning symbol. The text gives a warning message, the next symbol
313
   in the table will be undefined. When the symbol is referenced, the
314
   message is printed.  */
315
 
316
#define N_WARNING 0x1e
317
 
318
/* Weak symbols.  These are a GNU extension to the a.out format.  The
319
   semantics are those of ELF weak symbols.  Weak symbols are always
320
   externally visible.  The N_WEAK? values are squeezed into the
321
   available slots.  The value of a N_WEAKU symbol is 0.  The values
322
   of the other types are the definitions.  */
323
#define N_WEAKU 0x0d            /* Weak undefined symbol.  */
324
#define N_WEAKA 0x0e            /* Weak absolute symbol.  */
325
#define N_WEAKT 0x0f            /* Weak text symbol.  */
326
#define N_WEAKD 0x10            /* Weak data symbol.  */
327
#define N_WEAKB 0x11            /* Weak bss symbol.  */
328
 
329
/* Relocations
330
 
331
  There are two types of relocation flavours for a.out systems,
332
  standard and extended. The standard form is used on systems where the
333
  instruction has room for all the bits of an offset to the operand, whilst
334
  the extended form is used when an address operand has to be split over n
335
  instructions. Eg, on the 68k, each move instruction can reference
336
  the target with a displacement of 16 or 32 bits. On the sparc, move
337
  instructions use an offset of 14 bits, so the offset is stored in
338
  the reloc field, and the data in the section is ignored.
339
*/
340
 
341
/* This structure describes a single relocation to be performed.
342
   The text-relocation section of the file is a vector of these structures,
343
   all of which apply to the text section.
344
   Likewise, the data-relocation section applies to the data section.  */
345
 
346
struct reloc_std_external {
347
  bfd_byte      r_address[BYTES_IN_WORD];       /* offset of of data to relocate        */
348
  bfd_byte r_index[3];  /* symbol table index of symbol         */
349
  bfd_byte r_type[1];   /* relocation type                      */
350
};
351
 
352
#define RELOC_STD_BITS_PCREL_BIG        ((unsigned int) 0x80)
353
#define RELOC_STD_BITS_PCREL_LITTLE     ((unsigned int) 0x01)
354
 
355
#define RELOC_STD_BITS_LENGTH_BIG       ((unsigned int) 0x60)
356
#define RELOC_STD_BITS_LENGTH_SH_BIG    5
357
#define RELOC_STD_BITS_LENGTH_LITTLE    ((unsigned int) 0x06)
358
#define RELOC_STD_BITS_LENGTH_SH_LITTLE 1
359
 
360
#define RELOC_STD_BITS_EXTERN_BIG       ((unsigned int) 0x10)
361
#define RELOC_STD_BITS_EXTERN_LITTLE    ((unsigned int) 0x08)
362
 
363
#define RELOC_STD_BITS_BASEREL_BIG      ((unsigned int) 0x08)
364
#define RELOC_STD_BITS_BASEREL_LITTLE   ((unsigned int) 0x10)
365
 
366
#define RELOC_STD_BITS_JMPTABLE_BIG     ((unsigned int) 0x04)
367
#define RELOC_STD_BITS_JMPTABLE_LITTLE  ((unsigned int) 0x20)
368
 
369
#define RELOC_STD_BITS_RELATIVE_BIG     ((unsigned int) 0x02)
370
#define RELOC_STD_BITS_RELATIVE_LITTLE  ((unsigned int) 0x40)
371
 
372
#define RELOC_STD_SIZE  (BYTES_IN_WORD + 3 + 1)         /* Bytes per relocation entry */
373
 
374
struct reloc_std_internal
375
{
376
  bfd_vma r_address;            /* Address (within segment) to be relocated.  */
377
  /* The meaning of r_symbolnum depends on r_extern.  */
378
  unsigned int r_symbolnum:24;
379
  /* Nonzero means value is a pc-relative offset
380
     and it should be relocated for changes in its own address
381
     as well as for changes in the symbol or section specified.  */
382
  unsigned int r_pcrel:1;
383
  /* Length (as exponent of 2) of the field to be relocated.
384
     Thus, a value of 2 indicates 1<<2 bytes.  */
385
  unsigned int r_length:2;
386
  /* 1 => relocate with value of symbol.
387
     r_symbolnum is the index of the symbol
388
     in files the symbol table.
389
 
390
     r_symbolnum is N_TEXT, N_DATA, N_BSS or N_ABS
391
     (the N_EXT bit may be set also, but signifies nothing).  */
392
  unsigned int r_extern:1;
393
  /* The next three bits are for SunOS shared libraries, and seem to
394
     be undocumented.  */
395
  unsigned int r_baserel:1;     /* Linkage table relative */
396
  unsigned int r_jmptable:1;    /* pc-relative to jump table */
397
  unsigned int r_relative:1;    /* "relative relocation" */
398
  /* unused */
399
  unsigned int r_pad:1;         /* Padding -- set to zero */
400
};
401
 
402
 
403
/* EXTENDED RELOCS  */
404
 
405
struct reloc_ext_external {
406
  bfd_byte r_address[BYTES_IN_WORD];    /* offset of of data to relocate        */
407
  bfd_byte r_index[3];  /* symbol table index of symbol         */
408
  bfd_byte r_type[1];   /* relocation type                      */
409
  bfd_byte r_addend[BYTES_IN_WORD];     /* datum addend                         */
410
};
411
 
412
#ifndef RELOC_EXT_BITS_EXTERN_BIG
413
#define RELOC_EXT_BITS_EXTERN_BIG       ((unsigned int) 0x80)
414
#endif
415
 
416
#ifndef RELOC_EXT_BITS_EXTERN_LITTLE
417
#define RELOC_EXT_BITS_EXTERN_LITTLE    ((unsigned int) 0x01)
418
#endif
419
 
420
#ifndef RELOC_EXT_BITS_TYPE_BIG
421
#define RELOC_EXT_BITS_TYPE_BIG         ((unsigned int) 0x1F)
422
#endif
423
 
424
#ifndef RELOC_EXT_BITS_TYPE_SH_BIG
425
#define RELOC_EXT_BITS_TYPE_SH_BIG      0
426
#endif
427
 
428
#ifndef RELOC_EXT_BITS_TYPE_LITTLE
429
#define RELOC_EXT_BITS_TYPE_LITTLE      ((unsigned int) 0xF8)
430
#endif
431
 
432
#ifndef RELOC_EXT_BITS_TYPE_SH_LITTLE
433
#define RELOC_EXT_BITS_TYPE_SH_LITTLE   3
434
#endif
435
 
436
/* Bytes per relocation entry */
437
#define RELOC_EXT_SIZE  (BYTES_IN_WORD + 3 + 1 + BYTES_IN_WORD)
438
 
439
enum reloc_type
440
{
441
  /* simple relocations */
442
  RELOC_8,                      /* data[0:7] = addend + sv              */
443
  RELOC_16,                     /* data[0:15] = addend + sv             */
444
  RELOC_32,                     /* data[0:31] = addend + sv             */
445
  /* pc-rel displacement */
446
  RELOC_DISP8,                  /* data[0:7] = addend - pc + sv         */
447
  RELOC_DISP16,                 /* data[0:15] = addend - pc + sv        */
448
  RELOC_DISP32,                 /* data[0:31] = addend - pc + sv        */
449
  /* Special */
450
  RELOC_WDISP30,                /* data[0:29] = (addend + sv - pc)>>2   */
451
  RELOC_WDISP22,                /* data[0:21] = (addend + sv - pc)>>2   */
452
  RELOC_HI22,                   /* data[0:21] = (addend + sv)>>10       */
453
  RELOC_22,                     /* data[0:21] = (addend + sv)           */
454
  RELOC_13,                     /* data[0:12] = (addend + sv)           */
455
  RELOC_LO10,                   /* data[0:9] = (addend + sv)            */
456
  RELOC_SFA_BASE,
457
  RELOC_SFA_OFF13,
458
  /* P.I.C. (base-relative) */
459
  RELOC_BASE10,                 /* Not sure - maybe we can do this the */
460
  RELOC_BASE13,                 /* right way now */
461
  RELOC_BASE22,
462
  /* for some sort of pc-rel P.I.C. (?) */
463
  RELOC_PC10,
464
  RELOC_PC22,
465
  /* P.I.C. jump table */
466
  RELOC_JMP_TBL,
467
  /* reputedly for shared libraries somehow */
468
  RELOC_SEGOFF16,
469
  RELOC_GLOB_DAT,
470
  RELOC_JMP_SLOT,
471
  RELOC_RELATIVE,
472
 
473
  RELOC_11,
474
  RELOC_WDISP2_14,
475
  RELOC_WDISP19,
476
  RELOC_HHI22,                  /* data[0:21] = (addend + sv) >> 42     */
477
  RELOC_HLO10,                  /* data[0:9] = (addend + sv) >> 32      */
478
 
479
  /* 29K relocation types */
480
  RELOC_JUMPTARG,
481
  RELOC_CONST,
482
  RELOC_CONSTH,
483
 
484
  /* All the new ones I can think of, for sparc v9 */
485
 
486
  RELOC_64,                     /* data[0:63] = addend + sv             */
487
  RELOC_DISP64,                 /* data[0:63] = addend - pc + sv        */
488
  RELOC_WDISP21,                /* data[0:20] = (addend + sv - pc)>>2   */
489
  RELOC_DISP21,                 /* data[0:20] = addend - pc + sv        */
490
  RELOC_DISP14,                 /* data[0:13] = addend - pc + sv        */
491
  /* Q .
492
     What are the other ones,
493
     Since this is a clean slate, can we throw away the ones we dont
494
     understand ? Should we sort the values ? What about using a
495
     microcode format like the 68k ?
496
     */
497
  NO_RELOC
498
  };
499
 
500
 
501
struct reloc_internal {
502
  bfd_vma r_address;            /* offset of of data to relocate        */
503
  long  r_index;                /* symbol table index of symbol         */
504
  enum reloc_type r_type;       /* relocation type                      */
505
  bfd_vma r_addend;             /* datum addend                         */
506
};
507
 
508
/* Q.
509
   Should the length of the string table be 4 bytes or 8 bytes ?
510
 
511
   Q.
512
   What about archive indexes ?
513
 
514
 */
515
 
516
#endif                          /* __A_OUT_64_H__ */

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