OpenCores
URL https://opencores.org/ocsvn/or1k/or1k/trunk

Subversion Repositories or1k

[/] [or1k/] [trunk/] [gdb-5.3/] [gdb/] [dwarf2cfi.c] - Blame information for rev 1181

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 1181 sfurman 
/* Stack unwinding code based on dwarf2 frame info for GDB, the GNU debugger.
2 
   Copyright 2001, 2002 Free Software Foundation, Inc.
3 
   Contributed by Jiri Smid, SuSE Labs.
4 
   Based on code written by Daniel Berlin (dan@dberlin.org).
5 
 
6 
   This file is part of GDB.
7 
 
8 
   This program is free software; you can redistribute it and/or modify
9 
   it under the terms of the GNU General Public License as published by
10 
   the Free Software Foundation; either version 2 of the License, or
11 
   (at your option) any later version.
12 
 
13 
   This program is distributed in the hope that it will be useful,
14 
   but WITHOUT ANY WARRANTY; without even the implied warranty of
15 
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
16 
   GNU General Public License for more details.
17 
 
18 
   You should have received a copy of the GNU General Public License
19 
   along with this program; if not, write to the Free Software
20 
   Foundation, Inc., 59 Temple Place - Suite 330,
21 
   Boston, MA 02111-1307, USA.  */
22 
 
23 
#include "defs.h"
24 
#include "gdbcore.h"
25 
#include "symtab.h"
26 
#include "symfile.h"
27 
#include "objfiles.h"
28 
#include "target.h"
29 
#include "elf/dwarf2.h"
30 
#include "inferior.h"
31 
#include "regcache.h"
32 
#include "dwarf2cfi.h"
33 
#include "gdb_assert.h"
34 
 
35 
/* Common Information Entry - holds information that is shared among many
36 
   Frame Descriptors.  */
37 
struct cie_unit
38 
{
39 
  /* Offset of this unit in .debug_frame or .eh_frame.  */
40 
  ULONGEST offset;
41 
 
42 
  /* A null-terminated string that identifies the augmentation to this CIE or
43 
     to the FDEs that use it.  */
44 
  char *augmentation;
45 
 
46 
  /* A constant that is factored out of all advance location instructions.  */
47 
  unsigned int code_align;
48 
 
49 
  /* A constant that is factored out of all offset instructions.  */
50 
  int data_align;
51 
 
52 
  /* A constant that indicates which regiter represents the return address
53 
     of a function.  */
54 
  unsigned char ra;
55 
 
56 
  /* Indicates how addresses are encoded.  */
57 
  unsigned char addr_encoding;
58 
 
59 
  /* Pointer and length of the cie program.  */
60 
  char *data;
61 
  unsigned int data_length;
62 
 
63 
  struct objfile *objfile;
64 
 
65 
  /* Next in chain.  */
66 
  struct cie_unit *next;
67 
};
68 
 
69 
/* Frame Description Entry.  */
70 
struct fde_unit
71 
{
72 
  /* Address of the first location associated with this entry.  */
73 
  CORE_ADDR initial_location;
74 
 
75 
  /* Length of program section described by this entry.  */
76 
  CORE_ADDR address_range;
77 
 
78 
  /* Pointer to asociated CIE.  */
79 
  struct cie_unit *cie_ptr;
80 
 
81 
  /* Pointer and length of the cie program.  */
82 
  char *data;
83 
  unsigned int data_length;
84 
};
85 
 
86 
struct fde_array
87 
{
88 
  struct fde_unit **array;
89 
  int elems;
90 
  int array_size;
91 
};
92 
 
93 
struct context_reg
94 
{
95 
  union
96 
  {
97 
    unsigned int reg;
98 
    long offset;
99 
    CORE_ADDR addr;
100 
  }
101 
  loc;
102 
  enum
103 
  {
104 
    REG_CTX_UNSAVED,
105 
    REG_CTX_SAVED_OFFSET,
106 
    REG_CTX_SAVED_REG,
107 
    REG_CTX_SAVED_ADDR,
108 
    REG_CTX_VALUE,
109 
  }
110 
  how;
111 
};
112 
 
113 
/* This is the register and unwind state for a particular frame.  */
114 
struct context
115 
{
116 
  struct context_reg *reg;
117 
 
118 
  CORE_ADDR cfa;
119 
  CORE_ADDR ra;
120 
  void *lsda;
121 
  int args_size;
122 
};
123 
 
124 
struct frame_state_reg
125 
{
126 
  union
127 
  {
128 
    unsigned int reg;
129 
    long offset;
130 
    unsigned char *exp;
131 
  }
132 
  loc;
133 
  enum
134 
  {
135 
    REG_UNSAVED,
136 
    REG_SAVED_OFFSET,
137 
    REG_SAVED_REG,
138 
    REG_SAVED_EXP,
139 
  }
140 
  how;
141 
};
142 
 
143 
struct frame_state
144 
{
145 
  /* Each register save state can be described in terms of a CFA slot,
146 
     another register, or a location expression.  */
147 
  struct frame_state_regs
148 
  {
149 
    struct frame_state_reg *reg;
150 
 
151 
    /* Used to implement DW_CFA_remember_state.  */
152 
    struct frame_state_regs *prev;
153 
  }
154 
  regs;
155 
 
156 
  /* The CFA can be described in terms of a reg+offset or a
157 
     location expression.  */
158 
  long cfa_offset;
159 
  int cfa_reg;
160 
  unsigned char *cfa_exp;
161 
  enum
162 
  {
163 
    CFA_UNSET,
164 
    CFA_REG_OFFSET,
165 
    CFA_EXP,
166 
  }
167 
  cfa_how;
168 
 
169 
  /* The PC described by the current frame state.  */
170 
  CORE_ADDR pc;
171 
 
172 
  /* The information we care about from the CIE/FDE.  */
173 
  int data_align;
174 
  unsigned int code_align;
175 
  unsigned char retaddr_column;
176 
  unsigned char addr_encoding;
177 
 
178 
  struct objfile *objfile;
179 
};
180 
 
181 
enum ptr_encoding
182 
{
183 
  PE_absptr = DW_EH_PE_absptr,
184 
  PE_pcrel = DW_EH_PE_pcrel,
185 
  PE_textrel = DW_EH_PE_textrel,
186 
  PE_datarel = DW_EH_PE_datarel,
187 
  PE_funcrel = DW_EH_PE_funcrel
188 
};
189 
 
190 
#define UNWIND_CONTEXT(fi) ((struct context *) (fi->context))
191 
 
192 
 
193 
static struct cie_unit *cie_chunks;
194 
static struct fde_array fde_chunks;
195 
/* Obstack for allocating temporary storage used during unwind operations.  */
196 
static struct obstack unwind_tmp_obstack;
197 
 
198 
extern file_ptr dwarf_frame_offset;
199 
extern unsigned int dwarf_frame_size;
200 
extern file_ptr dwarf_eh_frame_offset;
201 
extern unsigned int dwarf_eh_frame_size;
202 
 
203 
 
204 
extern char *dwarf2_read_section (struct objfile *objfile, file_ptr offset,
205 
                                  unsigned int size);
206 
 
207 
static struct fde_unit *fde_unit_alloc (void);
208 
static struct cie_unit *cie_unit_alloc (void);
209 
static void fde_chunks_need_space ();
210 
 
211 
static struct context *context_alloc ();
212 
static struct frame_state *frame_state_alloc ();
213 
static void unwind_tmp_obstack_init ();
214 
static void unwind_tmp_obstack_free ();
215 
static void context_cpy (struct context *dst, struct context *src);
216 
 
217 
static unsigned int read_1u (bfd * abfd, char **p);
218 
static int read_1s (bfd * abfd, char **p);
219 
static unsigned int read_2u (bfd * abfd, char **p);
220 
static int read_2s (bfd * abfd, char **p);
221 
static unsigned int read_4u (bfd * abfd, char **p);
222 
static int read_4s (bfd * abfd, char **p);
223 
static ULONGEST read_8u (bfd * abfd, char **p);
224 
static LONGEST read_8s (bfd * abfd, char **p);
225 
 
226 
static ULONGEST read_uleb128 (bfd * abfd, char **p);
227 
static LONGEST read_sleb128 (bfd * abfd, char **p);
228 
static CORE_ADDR read_pointer (bfd * abfd, char **p);
229 
static CORE_ADDR read_encoded_pointer (bfd * abfd, char **p,
230 
                                       unsigned char encoding);
231 
static enum ptr_encoding pointer_encoding (unsigned char encoding);
232 
 
233 
static LONGEST read_initial_length (bfd * abfd, char *buf, int *bytes_read);
234 
static ULONGEST read_length (bfd * abfd, char *buf, int *bytes_read,
235 
                             int dwarf64);
236 
 
237 
static int is_cie (ULONGEST cie_id, int dwarf64);
238 
static int compare_fde_unit (const void *a, const void *b);
239 
void dwarf2_build_frame_info (struct objfile *objfile);
240 
 
241 
static void execute_cfa_program (struct objfile *objfile, char *insn_ptr,
242 
                                 char *insn_end, struct context *context,
243 
                                 struct frame_state *fs);
244 
static struct fde_unit *get_fde_for_addr (CORE_ADDR pc);
245 
static void frame_state_for (struct context *context, struct frame_state *fs);
246 
static void get_reg (char *reg, struct context *context, int regnum);
247 
static CORE_ADDR execute_stack_op (struct objfile *objfile,
248 
                                   char *op_ptr, char *op_end,
249 
                                   struct context *context,
250 
                                   CORE_ADDR initial);
251 
static void update_context (struct context *context, struct frame_state *fs,
252 
                            int chain);
253 
 
254 
 
255 
/* Memory allocation functions.  */
256 
static struct fde_unit *
257 
fde_unit_alloc (void)
258 
{
259 
  struct fde_unit *fde;
260 
 
261 
  fde = (struct fde_unit *) xmalloc (sizeof (struct fde_unit));
262 
  memset (fde, 0, sizeof (struct fde_unit));
263 
  return fde;
264 
}
265 
 
266 
static struct cie_unit *
267 
cie_unit_alloc (void)
268 
{
269 
  struct cie_unit *cie;
270 
 
271 
  cie = (struct cie_unit *) xmalloc (sizeof (struct cie_unit));
272 
  memset (cie, 0, sizeof (struct cie_unit));
273 
  return cie;
274 
}
275 
 
276 
static void
277 
fde_chunks_need_space (void)
278 
{
279 
  if (fde_chunks.elems < fde_chunks.array_size)
280 
    return;
281 
  fde_chunks.array_size =
282 
    fde_chunks.array_size ? 2 * fde_chunks.array_size : 1024;
283 
  fde_chunks.array =
284 
    xrealloc (fde_chunks.array,
285 
              sizeof (struct fde_unit) * fde_chunks.array_size);
286 
}
287 
 
288 
/* Alocate a new `struct context' on temporary obstack.  */
289 
static struct context *
290 
context_alloc (void)
291 
{
292 
  struct context *context;
293 
 
294 
  int regs_size = sizeof (struct context_reg) * NUM_REGS;
295 
 
296 
  context = (struct context *) obstack_alloc (&unwind_tmp_obstack,
297 
                                              sizeof (struct context));
298 
  memset (context, 0, sizeof (struct context));
299 
  context->reg = (struct context_reg *) obstack_alloc (&unwind_tmp_obstack,
300 
                                                       regs_size);
301 
  memset (context->reg, 0, regs_size);
302 
  return context;
303 
}
304 
 
305 
/* Alocate a new `struct frame_state' on temporary obstack.  */
306 
static struct frame_state *
307 
frame_state_alloc (void)
308 
{
309 
  struct frame_state *fs;
310 
 
311 
  int regs_size = sizeof (struct frame_state_reg) * NUM_REGS;
312 
 
313 
  fs = (struct frame_state *) obstack_alloc (&unwind_tmp_obstack,
314 
                                             sizeof (struct frame_state));
315 
  memset (fs, 0, sizeof (struct frame_state));
316 
  fs->regs.reg =
317 
    (struct frame_state_reg *) obstack_alloc (&unwind_tmp_obstack, regs_size);
318 
  memset (fs->regs.reg, 0, regs_size);
319 
  return fs;
320 
}
321 
 
322 
static void
323 
unwind_tmp_obstack_init (void)
324 
{
325 
  obstack_init (&unwind_tmp_obstack);
326 
}
327 
 
328 
static void
329 
unwind_tmp_obstack_free (void)
330 
{
331 
  obstack_free (&unwind_tmp_obstack, NULL);
332 
  unwind_tmp_obstack_init ();
333 
}
334 
 
335 
static void
336 
context_cpy (struct context *dst, struct context *src)
337 
{
338 
  int regs_size = sizeof (struct context_reg) * NUM_REGS;
339 
  struct context_reg *dreg;
340 
 
341 
  /* Structure dst contains a pointer to an array of
342 
   * registers of a given frame as well as src does. This
343 
   * array was already allocated before dst was passed to
344 
   * context_cpy but the pointer to it was overriden by
345 
   * '*dst = *src' and the array was lost. This led to the
346 
   * situation, that we've had a copy of src placed in dst,
347 
   * but both of them pointed to the same regs array and
348 
   * thus we've sometimes blindly rewritten it.  Now we save
349 
   * the pointer before copying src to dst, return it back
350 
   * after that and copy the registers into their new place
351 
   * finally.   ---   mludvig@suse.cz  */
352 
  dreg = dst->reg;
353 
  *dst = *src;
354 
  dst->reg = dreg;
355 
 
356 
  memcpy (dst->reg, src->reg, regs_size);
357 
}
358 
 
359 
static unsigned int
360 
read_1u (bfd * abfd, char **p)
361 
{
362 
  unsigned ret;
363 
 
364 
  ret = bfd_get_8 (abfd, (bfd_byte *) * p);
365 
  (*p)++;
366 
  return ret;
367 
}
368 
 
369 
static int
370 
read_1s (bfd * abfd, char **p)
371 
{
372 
  int ret;
373 
 
374 
  ret = bfd_get_signed_8 (abfd, (bfd_byte *) * p);
375 
  (*p)++;
376 
  return ret;
377 
}
378 
 
379 
static unsigned int
380 
read_2u (bfd * abfd, char **p)
381 
{
382 
  unsigned ret;
383 
 
384 
  ret = bfd_get_16 (abfd, (bfd_byte *) * p);
385 
  (*p)++;
386 
  return ret;
387 
}
388 
 
389 
static int
390 
read_2s (bfd * abfd, char **p)
391 
{
392 
  int ret;
393 
 
394 
  ret = bfd_get_signed_16 (abfd, (bfd_byte *) * p);
395 
  (*p) += 2;
396 
  return ret;
397 
}
398 
 
399 
static unsigned int
400 
read_4u (bfd * abfd, char **p)
401 
{
402 
  unsigned int ret;
403 
 
404 
  ret = bfd_get_32 (abfd, (bfd_byte *) * p);
405 
  (*p) += 4;
406 
  return ret;
407 
}
408 
 
409 
static int
410 
read_4s (bfd * abfd, char **p)
411 
{
412 
  int ret;
413 
 
414 
  ret = bfd_get_signed_32 (abfd, (bfd_byte *) * p);
415 
  (*p) += 4;
416 
  return ret;
417 
}
418 
 
419 
static ULONGEST
420 
read_8u (bfd * abfd, char **p)
421 
{
422 
  ULONGEST ret;
423 
 
424 
  ret = bfd_get_64 (abfd, (bfd_byte *) * p);
425 
  (*p) += 8;
426 
  return ret;
427 
}
428 
 
429 
static LONGEST
430 
read_8s (bfd * abfd, char **p)
431 
{
432 
  LONGEST ret;
433 
 
434 
  ret = bfd_get_signed_64 (abfd, (bfd_byte *) * p);
435 
  (*p) += 8;
436 
  return ret;
437 
}
438 
 
439 
static ULONGEST
440 
read_uleb128 (bfd * abfd, char **p)
441 
{
442 
  ULONGEST ret;
443 
  int i, shift;
444 
  unsigned char byte;
445 
 
446 
  ret = 0;
447 
  shift = 0;
448 
  i = 0;
449 
  while (1)
450 
    {
451 
      byte = bfd_get_8 (abfd, (bfd_byte *) * p);
452 
      (*p)++;
453 
      ret |= ((unsigned long) (byte & 127) << shift);
454 
      if ((byte & 128) == 0)
455 
        {
456 
          break;
457 
        }
458 
      shift += 7;
459 
    }
460 
  return ret;
461 
}
462 
 
463 
static LONGEST
464 
read_sleb128 (bfd * abfd, char **p)
465 
{
466 
  LONGEST ret;
467 
  int i, shift, size, num_read;
468 
  unsigned char byte;
469 
 
470 
  ret = 0;
471 
  shift = 0;
472 
  size = 32;
473 
  num_read = 0;
474 
  i = 0;
475 
  while (1)
476 
    {
477 
      byte = bfd_get_8 (abfd, (bfd_byte *) * p);
478 
      (*p)++;
479 
      ret |= ((long) (byte & 127) << shift);
480 
      shift += 7;
481 
      if ((byte & 128) == 0)
482 
        {
483 
          break;
484 
        }
485 
    }
486 
  if ((shift < size) && (byte & 0x40))
487 
    {
488 
      ret |= -(1 << shift);
489 
    }
490 
  return ret;
491 
}
492 
 
493 
static CORE_ADDR
494 
read_pointer (bfd * abfd, char **p)
495 
{
496 
  switch (TARGET_ADDR_BIT / TARGET_CHAR_BIT)
497 
    {
498 
    case 4:
499 
      return read_4u (abfd, p);
500 
    case 8:
501 
      return read_8u (abfd, p);
502 
    default:
503 
      error ("dwarf cfi error: unsupported target address length.");
504 
    }
505 
}
506 
 
507 
/* This functions only reads appropriate amount of data from *p
508 
 * and returns the resulting value. Calling function must handle
509 
 * different encoding possibilities itself!  */
510 
static CORE_ADDR
511 
read_encoded_pointer (bfd * abfd, char **p, unsigned char encoding)
512 
{
513 
  CORE_ADDR ret;
514 
 
515 
  switch (encoding & 0x0f)
516 
    {
517 
    case DW_EH_PE_absptr:
518 
      ret = read_pointer (abfd, p);
519 
      break;
520 
 
521 
    case DW_EH_PE_uleb128:
522 
      ret = read_uleb128 (abfd, p);
523 
      break;
524 
    case DW_EH_PE_sleb128:
525 
      ret = read_sleb128 (abfd, p);
526 
      break;
527 
 
528 
    case DW_EH_PE_udata2:
529 
      ret = read_2u (abfd, p);
530 
      break;
531 
    case DW_EH_PE_udata4:
532 
      ret = read_4u (abfd, p);
533 
      break;
534 
    case DW_EH_PE_udata8:
535 
      ret = read_8u (abfd, p);
536 
      break;
537 
 
538 
    case DW_EH_PE_sdata2:
539 
      ret = read_2s (abfd, p);
540 
      break;
541 
    case DW_EH_PE_sdata4:
542 
      ret = read_4s (abfd, p);
543 
      break;
544 
    case DW_EH_PE_sdata8:
545 
      ret = read_8s (abfd, p);
546 
      break;
547 
 
548 
    default:
549 
      internal_error (__FILE__, __LINE__,
550 
                      "read_encoded_pointer: unknown pointer encoding");
551 
    }
552 
 
553 
  return ret;
554 
}
555 
 
556 
/* Variable 'encoding' carries 3 different flags:
557 
 * - encoding & 0x0f : size of the address (handled in read_encoded_pointer())
558 
 * - encoding & 0x70 : type (absolute, relative, ...)
559 
 * - encoding & 0x80 : indirect flag (DW_EH_PE_indirect == 0x80).  */
560 
enum ptr_encoding
561 
pointer_encoding (unsigned char encoding)
562 
{
563 
  int ret;
564 
 
565 
  if (encoding & DW_EH_PE_indirect)
566 
    warning ("CFI: Unsupported pointer encoding: DW_EH_PE_indirect");
567 
 
568 
  switch (encoding & 0x70)
569 
    {
570 
    case DW_EH_PE_absptr:
571 
    case DW_EH_PE_pcrel:
572 
    case DW_EH_PE_textrel:
573 
    case DW_EH_PE_datarel:
574 
    case DW_EH_PE_funcrel:
575 
      ret = encoding & 0x70;
576 
      break;
577 
    default:
578 
      internal_error (__FILE__, __LINE__, "CFI: unknown pointer encoding");
579 
    }
580 
  return ret;
581 
}
582 
 
583 
static LONGEST
584 
read_initial_length (bfd * abfd, char *buf, int *bytes_read)
585 
{
586 
  LONGEST ret = 0;
587 
 
588 
  ret = bfd_get_32 (abfd, (bfd_byte *) buf);
589 
 
590 
  if (ret == 0xffffffff)
591 
    {
592 
      ret = bfd_get_64 (abfd, (bfd_byte *) buf + 4);
593 
      *bytes_read = 12;
594 
    }
595 
  else
596 
    {
597 
      *bytes_read = 4;
598 
    }
599 
 
600 
  return ret;
601 
}
602 
 
603 
static ULONGEST
604 
read_length (bfd * abfd, char *buf, int *bytes_read, int dwarf64)
605 
{
606 
  if (dwarf64)
607 
    {
608 
      *bytes_read = 8;
609 
      return read_8u (abfd, &buf);
610 
    }
611 
  else
612 
    {
613 
      *bytes_read = 4;
614 
      return read_4u (abfd, &buf);
615 
    }
616 
}
617 
 
618 
static void
619 
execute_cfa_program (struct objfile *objfile, char *insn_ptr, char *insn_end,
620 
                     struct context *context, struct frame_state *fs)
621 
{
622 
  struct frame_state_regs *unused_rs = NULL;
623 
 
624 
  /* Don't allow remember/restore between CIE and FDE programs.  */
625 
  fs->regs.prev = NULL;
626 
 
627 
  while (insn_ptr < insn_end && fs->pc < context->ra)
628 
    {
629 
      unsigned char insn = *insn_ptr++;
630 
      ULONGEST reg, uoffset;
631 
      LONGEST offset;
632 
 
633 
      if (insn & DW_CFA_advance_loc)
634 
        fs->pc += (insn & 0x3f) * fs->code_align;
635 
      else if (insn & DW_CFA_offset)
636 
        {
637 
          reg = insn & 0x3f;
638 
          uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
639 
          offset = (long) uoffset *fs->data_align;
640 
          fs->regs.reg[reg].how = REG_SAVED_OFFSET;
641 
          fs->regs.reg[reg].loc.offset = offset;
642 
        }
643 
      else if (insn & DW_CFA_restore)
644 
        {
645 
          reg = insn & 0x3f;
646 
          fs->regs.reg[reg].how = REG_UNSAVED;
647 
        }
648 
      else
649 
        switch (insn)
650 
          {
651 
          case DW_CFA_set_loc:
652 
            fs->pc = read_encoded_pointer (objfile->obfd, &insn_ptr,
653 
                                           fs->addr_encoding);
654 
 
655 
            if (pointer_encoding (fs->addr_encoding) != PE_absptr)
656 
              warning ("CFI: DW_CFA_set_loc uses relative addressing");
657 
 
658 
            break;
659 
 
660 
          case DW_CFA_advance_loc1:
661 
            fs->pc += read_1u (objfile->obfd, &insn_ptr);
662 
            break;
663 
          case DW_CFA_advance_loc2:
664 
            fs->pc += read_2u (objfile->obfd, &insn_ptr);
665 
            break;
666 
          case DW_CFA_advance_loc4:
667 
            fs->pc += read_4u (objfile->obfd, &insn_ptr);
668 
            break;
669 
 
670 
          case DW_CFA_offset_extended:
671 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
672 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
673 
            offset = (long) uoffset *fs->data_align;
674 
            fs->regs.reg[reg].how = REG_SAVED_OFFSET;
675 
            fs->regs.reg[reg].loc.offset = offset;
676 
            break;
677 
 
678 
          case DW_CFA_restore_extended:
679 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
680 
            fs->regs.reg[reg].how = REG_UNSAVED;
681 
            break;
682 
 
683 
          case DW_CFA_undefined:
684 
          case DW_CFA_same_value:
685 
          case DW_CFA_nop:
686 
            break;
687 
 
688 
          case DW_CFA_register:
689 
            {
690 
              ULONGEST reg2;
691 
              reg = read_uleb128 (objfile->obfd, &insn_ptr);
692 
              reg2 = read_uleb128 (objfile->obfd, &insn_ptr);
693 
              fs->regs.reg[reg].how = REG_SAVED_REG;
694 
              fs->regs.reg[reg].loc.reg = reg2;
695 
            }
696 
            break;
697 
 
698 
          case DW_CFA_remember_state:
699 
            {
700 
              struct frame_state_regs *new_rs;
701 
              if (unused_rs)
702 
                {
703 
                  new_rs = unused_rs;
704 
                  unused_rs = unused_rs->prev;
705 
                }
706 
              else
707 
                new_rs = xmalloc (sizeof (struct frame_state_regs));
708 
 
709 
              *new_rs = fs->regs;
710 
              fs->regs.prev = new_rs;
711 
            }
712 
            break;
713 
 
714 
          case DW_CFA_restore_state:
715 
            {
716 
              struct frame_state_regs *old_rs = fs->regs.prev;
717 
              fs->regs = *old_rs;
718 
              old_rs->prev = unused_rs;
719 
              unused_rs = old_rs;
720 
            }
721 
            break;
722 
 
723 
          case DW_CFA_def_cfa:
724 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
725 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
726 
            fs->cfa_reg = reg;
727 
            fs->cfa_offset = uoffset;
728 
            fs->cfa_how = CFA_REG_OFFSET;
729 
            break;
730 
 
731 
          case DW_CFA_def_cfa_register:
732 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
733 
            fs->cfa_reg = reg;
734 
            fs->cfa_how = CFA_REG_OFFSET;
735 
            break;
736 
 
737 
          case DW_CFA_def_cfa_offset:
738 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
739 
            fs->cfa_offset = uoffset;
740 
            break;
741 
 
742 
          case DW_CFA_def_cfa_expression:
743 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
744 
            fs->cfa_exp = insn_ptr;
745 
            fs->cfa_how = CFA_EXP;
746 
            insn_ptr += uoffset;
747 
            break;
748 
 
749 
          case DW_CFA_expression:
750 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
751 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
752 
            fs->regs.reg[reg].how = REG_SAVED_EXP;
753 
            fs->regs.reg[reg].loc.exp = insn_ptr;
754 
            insn_ptr += uoffset;
755 
            break;
756 
 
757 
            /* From the 2.1 draft.  */
758 
          case DW_CFA_offset_extended_sf:
759 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
760 
            offset = read_sleb128 (objfile->obfd, &insn_ptr);
761 
            offset *= fs->data_align;
762 
            fs->regs.reg[reg].how = REG_SAVED_OFFSET;
763 
            fs->regs.reg[reg].loc.offset = offset;
764 
            break;
765 
 
766 
          case DW_CFA_def_cfa_sf:
767 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
768 
            offset = read_sleb128 (objfile->obfd, &insn_ptr);
769 
            fs->cfa_offset = offset;
770 
            fs->cfa_reg = reg;
771 
            fs->cfa_how = CFA_REG_OFFSET;
772 
            break;
773 
 
774 
          case DW_CFA_def_cfa_offset_sf:
775 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
776 
            fs->cfa_offset = uoffset;
777 
            /* cfa_how deliberately not set.  */
778 
            break;
779 
 
780 
          case DW_CFA_GNU_window_save:
781 
            /* ??? Hardcoded for SPARC register window configuration.  */
782 
            for (reg = 16; reg < 32; ++reg)
783 
              {
784 
                fs->regs.reg[reg].how = REG_SAVED_OFFSET;
785 
                fs->regs.reg[reg].loc.offset = (reg - 16) * sizeof (void *);
786 
              }
787 
            break;
788 
 
789 
          case DW_CFA_GNU_args_size:
790 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
791 
            context->args_size = uoffset;
792 
            break;
793 
 
794 
          case DW_CFA_GNU_negative_offset_extended:
795 
            /* Obsoleted by DW_CFA_offset_extended_sf, but used by
796 
               older PowerPC code.  */
797 
            reg = read_uleb128 (objfile->obfd, &insn_ptr);
798 
            uoffset = read_uleb128 (objfile->obfd, &insn_ptr);
799 
            offset = (long) uoffset *fs->data_align;
800 
            fs->regs.reg[reg].how = REG_SAVED_OFFSET;
801 
            fs->regs.reg[reg].loc.offset = -offset;
802 
            break;
803 
 
804 
          default:
805 
            error ("dwarf cfi error: unknown cfa instruction %d.", insn);
806 
          }
807 
    }
808 
}
809 
 
810 
static struct fde_unit *
811 
get_fde_for_addr (CORE_ADDR pc)
812 
{
813 
  size_t lo, hi;
814 
  struct fde_unit *fde = NULL;
815 
  lo = 0;
816 
  hi = fde_chunks.elems;
817 
 
818 
  while (lo < hi)
819 
    {
820 
      size_t i = (lo + hi) / 2;
821 
      fde = fde_chunks.array[i];
822 
      if (pc < fde->initial_location)
823 
        hi = i;
824 
      else if (pc >= fde->initial_location + fde->address_range)
825 
        lo = i + 1;
826 
      else
827 
        return fde;
828 
    }
829 
  return 0;
830 
}
831 
 
832 
static void
833 
frame_state_for (struct context *context, struct frame_state *fs)
834 
{
835 
  struct fde_unit *fde;
836 
  struct cie_unit *cie;
837 
 
838 
  context->args_size = 0;
839 
  context->lsda = 0;
840 
 
841 
  fde = get_fde_for_addr (context->ra - 1);
842 
 
843 
  if (fde == NULL)
844 
    return;
845 
 
846 
  fs->pc = fde->initial_location;
847 
 
848 
  gdb_assert (fde->cie_ptr != NULL);
849 
 
850 
  cie = fde->cie_ptr;
851 
 
852 
  fs->code_align = cie->code_align;
853 
  fs->data_align = cie->data_align;
854 
  fs->retaddr_column = cie->ra;
855 
  fs->addr_encoding = cie->addr_encoding;
856 
  fs->objfile = cie->objfile;
857 
 
858 
  execute_cfa_program (cie->objfile, cie->data,
859 
                       cie->data + cie->data_length, context, fs);
860 
  execute_cfa_program (cie->objfile, fde->data,
861 
                       fde->data + fde->data_length, context, fs);
862 
}
863 
 
864 
static void
865 
get_reg (char *reg, struct context *context, int regnum)
866 
{
867 
  switch (context->reg[regnum].how)
868 
    {
869 
    case REG_CTX_UNSAVED:
870 
      read_register_gen (regnum, reg);
871 
      break;
872 
    case REG_CTX_SAVED_OFFSET:
873 
      target_read_memory (context->cfa + context->reg[regnum].loc.offset,
874 
                          reg, REGISTER_RAW_SIZE (regnum));
875 
      break;
876 
    case REG_CTX_SAVED_REG:
877 
      read_register_gen (context->reg[regnum].loc.reg, reg);
878 
      break;
879 
    case REG_CTX_SAVED_ADDR:
880 
      target_read_memory (context->reg[regnum].loc.addr,
881 
                          reg, REGISTER_RAW_SIZE (regnum));
882 
      break;
883 
    case REG_CTX_VALUE:
884 
      memcpy (reg, &context->reg[regnum].loc.addr,
885 
              REGISTER_RAW_SIZE (regnum));
886 
      break;
887 
    default:
888 
      internal_error (__FILE__, __LINE__, "get_reg: unknown register rule");
889 
    }
890 
}
891 
 
892 
/* Decode a DW_OP stack program.  Return the top of stack.  Push INITIAL
893 
   onto the stack to start.  */
894 
static CORE_ADDR
895 
execute_stack_op (struct objfile *objfile,
896 
                  char *op_ptr, char *op_end, struct context *context,
897 
                  CORE_ADDR initial)
898 
{
899 
  CORE_ADDR stack[64];          /* ??? Assume this is enough. */
900 
  int stack_elt;
901 
 
902 
  stack[0] = initial;
903 
  stack_elt = 1;
904 
 
905 
  while (op_ptr < op_end)
906 
    {
907 
      enum dwarf_location_atom op = *op_ptr++;
908 
      CORE_ADDR result;
909 
      ULONGEST reg;
910 
      LONGEST offset;
911 
 
912 
      switch (op)
913 
        {
914 
        case DW_OP_lit0:
915 
        case DW_OP_lit1:
916 
        case DW_OP_lit2:
917 
        case DW_OP_lit3:
918 
        case DW_OP_lit4:
919 
        case DW_OP_lit5:
920 
        case DW_OP_lit6:
921 
        case DW_OP_lit7:
922 
        case DW_OP_lit8:
923 
        case DW_OP_lit9:
924 
        case DW_OP_lit10:
925 
        case DW_OP_lit11:
926 
        case DW_OP_lit12:
927 
        case DW_OP_lit13:
928 
        case DW_OP_lit14:
929 
        case DW_OP_lit15:
930 
        case DW_OP_lit16:
931 
        case DW_OP_lit17:
932 
        case DW_OP_lit18:
933 
        case DW_OP_lit19:
934 
        case DW_OP_lit20:
935 
        case DW_OP_lit21:
936 
        case DW_OP_lit22:
937 
        case DW_OP_lit23:
938 
        case DW_OP_lit24:
939 
        case DW_OP_lit25:
940 
        case DW_OP_lit26:
941 
        case DW_OP_lit27:
942 
        case DW_OP_lit28:
943 
        case DW_OP_lit29:
944 
        case DW_OP_lit30:
945 
        case DW_OP_lit31:
946 
          result = op - DW_OP_lit0;
947 
          break;
948 
 
949 
        case DW_OP_addr:
950 
          result = read_pointer (objfile->obfd, &op_ptr);
951 
          break;
952 
 
953 
        case DW_OP_const1u:
954 
          result = read_1u (objfile->obfd, &op_ptr);
955 
          break;
956 
        case DW_OP_const1s:
957 
          result = read_1s (objfile->obfd, &op_ptr);
958 
          break;
959 
        case DW_OP_const2u:
960 
          result = read_2u (objfile->obfd, &op_ptr);
961 
          break;
962 
        case DW_OP_const2s:
963 
          result = read_2s (objfile->obfd, &op_ptr);
964 
          break;
965 
        case DW_OP_const4u:
966 
          result = read_4u (objfile->obfd, &op_ptr);
967 
          break;
968 
        case DW_OP_const4s:
969 
          result = read_4s (objfile->obfd, &op_ptr);
970 
          break;
971 
        case DW_OP_const8u:
972 
          result = read_8u (objfile->obfd, &op_ptr);
973 
          break;
974 
        case DW_OP_const8s:
975 
          result = read_8s (objfile->obfd, &op_ptr);
976 
          break;
977 
        case DW_OP_constu:
978 
          result = read_uleb128 (objfile->obfd, &op_ptr);
979 
          break;
980 
        case DW_OP_consts:
981 
          result = read_sleb128 (objfile->obfd, &op_ptr);
982 
          break;
983 
 
984 
        case DW_OP_reg0:
985 
        case DW_OP_reg1:
986 
        case DW_OP_reg2:
987 
        case DW_OP_reg3:
988 
        case DW_OP_reg4:
989 
        case DW_OP_reg5:
990 
        case DW_OP_reg6:
991 
        case DW_OP_reg7:
992 
        case DW_OP_reg8:
993 
        case DW_OP_reg9:
994 
        case DW_OP_reg10:
995 
        case DW_OP_reg11:
996 
        case DW_OP_reg12:
997 
        case DW_OP_reg13:
998 
        case DW_OP_reg14:
999 
        case DW_OP_reg15:
1000 
        case DW_OP_reg16:
1001 
        case DW_OP_reg17:
1002 
        case DW_OP_reg18:
1003 
        case DW_OP_reg19:
1004 
        case DW_OP_reg20:
1005 
        case DW_OP_reg21:
1006 
        case DW_OP_reg22:
1007 
        case DW_OP_reg23:
1008 
        case DW_OP_reg24:
1009 
        case DW_OP_reg25:
1010 
        case DW_OP_reg26:
1011 
        case DW_OP_reg27:
1012 
        case DW_OP_reg28:
1013 
        case DW_OP_reg29:
1014 
        case DW_OP_reg30:
1015 
        case DW_OP_reg31:
1016 
          get_reg ((char *) &result, context, op - DW_OP_reg0);
1017 
          break;
1018 
        case DW_OP_regx:
1019 
          reg = read_uleb128 (objfile->obfd, &op_ptr);
1020 
          get_reg ((char *) &result, context, reg);
1021 
          break;
1022 
 
1023 
        case DW_OP_breg0:
1024 
        case DW_OP_breg1:
1025 
        case DW_OP_breg2:
1026 
        case DW_OP_breg3:
1027 
        case DW_OP_breg4:
1028 
        case DW_OP_breg5:
1029 
        case DW_OP_breg6:
1030 
        case DW_OP_breg7:
1031 
        case DW_OP_breg8:
1032 
        case DW_OP_breg9:
1033 
        case DW_OP_breg10:
1034 
        case DW_OP_breg11:
1035 
        case DW_OP_breg12:
1036 
        case DW_OP_breg13:
1037 
        case DW_OP_breg14:
1038 
        case DW_OP_breg15:
1039 
        case DW_OP_breg16:
1040 
        case DW_OP_breg17:
1041 
        case DW_OP_breg18:
1042 
        case DW_OP_breg19:
1043 
        case DW_OP_breg20:
1044 
        case DW_OP_breg21:
1045 
        case DW_OP_breg22:
1046 
        case DW_OP_breg23:
1047 
        case DW_OP_breg24:
1048 
        case DW_OP_breg25:
1049 
        case DW_OP_breg26:
1050 
        case DW_OP_breg27:
1051 
        case DW_OP_breg28:
1052 
        case DW_OP_breg29:
1053 
        case DW_OP_breg30:
1054 
        case DW_OP_breg31:
1055 
          offset = read_sleb128 (objfile->obfd, &op_ptr);
1056 
          get_reg ((char *) &result, context, op - DW_OP_breg0);
1057 
          result += offset;
1058 
          break;
1059 
        case DW_OP_bregx:
1060 
          reg = read_uleb128 (objfile->obfd, &op_ptr);
1061 
          offset = read_sleb128 (objfile->obfd, &op_ptr);
1062 
          get_reg ((char *) &result, context, reg);
1063 
          result += offset;
1064 
          break;
1065 
 
1066 
        case DW_OP_dup:
1067 
          if (stack_elt < 1)
1068 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1069 
          result = stack[stack_elt - 1];
1070 
          break;
1071 
 
1072 
        case DW_OP_drop:
1073 
          if (--stack_elt < 0)
1074 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1075 
          goto no_push;
1076 
 
1077 
        case DW_OP_pick:
1078 
          offset = *op_ptr++;
1079 
          if (offset >= stack_elt - 1)
1080 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1081 
          result = stack[stack_elt - 1 - offset];
1082 
          break;
1083 
 
1084 
        case DW_OP_over:
1085 
          if (stack_elt < 2)
1086 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1087 
          result = stack[stack_elt - 2];
1088 
          break;
1089 
 
1090 
        case DW_OP_rot:
1091 
          {
1092 
            CORE_ADDR t1, t2, t3;
1093 
 
1094 
            if (stack_elt < 3)
1095 
              internal_error (__FILE__, __LINE__, "execute_stack_op error");
1096 
            t1 = stack[stack_elt - 1];
1097 
            t2 = stack[stack_elt - 2];
1098 
            t3 = stack[stack_elt - 3];
1099 
            stack[stack_elt - 1] = t2;
1100 
            stack[stack_elt - 2] = t3;
1101 
            stack[stack_elt - 3] = t1;
1102 
            goto no_push;
1103 
          }
1104 
 
1105 
        case DW_OP_deref:
1106 
        case DW_OP_deref_size:
1107 
        case DW_OP_abs:
1108 
        case DW_OP_neg:
1109 
        case DW_OP_not:
1110 
        case DW_OP_plus_uconst:
1111 
          /* Unary operations.  */
1112 
          if (--stack_elt < 0)
1113 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1114 
          result = stack[stack_elt];
1115 
 
1116 
          switch (op)
1117 
            {
1118 
            case DW_OP_deref:
1119 
              {
1120 
                int len = TARGET_ADDR_BIT / TARGET_CHAR_BIT;
1121 
                if (len != 4 && len != 8)
1122 
                  internal_error (__FILE__, __LINE__,
1123 
                                  "execute_stack_op error");
1124 
                result = read_memory_unsigned_integer (result, len);
1125 
              }
1126 
              break;
1127 
 
1128 
            case DW_OP_deref_size:
1129 
              {
1130 
                int len = *op_ptr++;
1131 
                if (len != 1 && len != 2 && len != 4 && len !=8)
1132 
                  internal_error (__FILE__, __LINE__,
1133 
                                  "execute_stack_op error");
1134 
                result = read_memory_unsigned_integer (result, len);
1135 
              }
1136 
              break;
1137 
 
1138 
            case DW_OP_abs:
1139 
              if (result < 0)
1140 
                result = -result;
1141 
              break;
1142 
            case DW_OP_neg:
1143 
              result = -result;
1144 
              break;
1145 
            case DW_OP_not:
1146 
              result = ~result;
1147 
              break;
1148 
            case DW_OP_plus_uconst:
1149 
              result += read_uleb128 (objfile->obfd, &op_ptr);
1150 
              break;
1151 
            default:
1152 
              break;
1153 
            }
1154 
          break;
1155 
 
1156 
        case DW_OP_and:
1157 
        case DW_OP_div:
1158 
        case DW_OP_minus:
1159 
        case DW_OP_mod:
1160 
        case DW_OP_mul:
1161 
        case DW_OP_or:
1162 
        case DW_OP_plus:
1163 
        case DW_OP_le:
1164 
        case DW_OP_ge:
1165 
        case DW_OP_eq:
1166 
        case DW_OP_lt:
1167 
        case DW_OP_gt:
1168 
        case DW_OP_ne:
1169 
          {
1170 
            /* Binary operations.  */
1171 
            CORE_ADDR first, second;
1172 
            if ((stack_elt -= 2) < 0)
1173 
              internal_error (__FILE__, __LINE__, "execute_stack_op error");
1174 
            second = stack[stack_elt];
1175 
            first = stack[stack_elt + 1];
1176 
 
1177 
            switch (op)
1178 
              {
1179 
              case DW_OP_and:
1180 
                result = second & first;
1181 
                break;
1182 
              case DW_OP_div:
1183 
                result = (LONGEST) second / (LONGEST) first;
1184 
                break;
1185 
              case DW_OP_minus:
1186 
                result = second - first;
1187 
                break;
1188 
              case DW_OP_mod:
1189 
                result = (LONGEST) second % (LONGEST) first;
1190 
                break;
1191 
              case DW_OP_mul:
1192 
                result = second * first;
1193 
                break;
1194 
              case DW_OP_or:
1195 
                result = second | first;
1196 
                break;
1197 
              case DW_OP_plus:
1198 
                result = second + first;
1199 
                break;
1200 
              case DW_OP_shl:
1201 
                result = second << first;
1202 
                break;
1203 
              case DW_OP_shr:
1204 
                result = second >> first;
1205 
                break;
1206 
              case DW_OP_shra:
1207 
                result = (LONGEST) second >> first;
1208 
                break;
1209 
              case DW_OP_xor:
1210 
                result = second ^ first;
1211 
                break;
1212 
              case DW_OP_le:
1213 
                result = (LONGEST) first <= (LONGEST) second;
1214 
                break;
1215 
              case DW_OP_ge:
1216 
                result = (LONGEST) first >= (LONGEST) second;
1217 
                break;
1218 
              case DW_OP_eq:
1219 
                result = (LONGEST) first == (LONGEST) second;
1220 
                break;
1221 
              case DW_OP_lt:
1222 
                result = (LONGEST) first < (LONGEST) second;
1223 
                break;
1224 
              case DW_OP_gt:
1225 
                result = (LONGEST) first > (LONGEST) second;
1226 
                break;
1227 
              case DW_OP_ne:
1228 
                result = (LONGEST) first != (LONGEST) second;
1229 
                break;
1230 
              default:
1231 
                error ("execute_stack_op: Unknown DW_OP_ value");
1232 
                break;
1233 
              }
1234 
          }
1235 
          break;
1236 
 
1237 
        case DW_OP_skip:
1238 
          offset = read_2s (objfile->obfd, &op_ptr);
1239 
          op_ptr += offset;
1240 
          goto no_push;
1241 
 
1242 
        case DW_OP_bra:
1243 
          if (--stack_elt < 0)
1244 
            internal_error (__FILE__, __LINE__, "execute_stack_op error");
1245 
          offset = read_2s (objfile->obfd, &op_ptr);
1246 
          if (stack[stack_elt] != 0)
1247 
            op_ptr += offset;
1248 
          goto no_push;
1249 
 
1250 
        case DW_OP_nop:
1251 
          goto no_push;
1252 
 
1253 
        default:
1254 
          internal_error (__FILE__, __LINE__, "execute_stack_op error");
1255 
        }
1256 
 
1257 
      /* Most things push a result value.  */
1258 
      if ((size_t) stack_elt >= sizeof (stack) / sizeof (*stack))
1259 
        internal_error (__FILE__, __LINE__, "execute_stack_op error");
1260 
      stack[++stack_elt] = result;
1261 
    no_push:;
1262 
    }
1263 
 
1264 
  /* We were executing this program to get a value.  It should be
1265 
     at top of stack.  */
1266 
  if (--stack_elt < 0)
1267 
    internal_error (__FILE__, __LINE__, "execute_stack_op error");
1268 
  return stack[stack_elt];
1269 
}
1270 
 
1271 
static void
1272 
update_context (struct context *context, struct frame_state *fs, int chain)
1273 
{
1274 
  struct context *orig_context;
1275 
  CORE_ADDR cfa = 0;
1276 
  long i;
1277 
 
1278 
  unwind_tmp_obstack_init ();
1279 
 
1280 
  orig_context = context_alloc ();
1281 
  context_cpy (orig_context, context);
1282 
 
1283 
  /* Compute this frame's CFA.  */
1284 
  switch (fs->cfa_how)
1285 
    {
1286 
    case CFA_REG_OFFSET:
1287 
      get_reg ((char *) &cfa, context, fs->cfa_reg);
1288 
      cfa += fs->cfa_offset;
1289 
      break;
1290 
 
1291 
    case CFA_EXP:
1292 
      /* ??? No way of knowing what register number is the stack pointer
1293 
         to do the same sort of handling as above.  Assume that if the
1294 
         CFA calculation is so complicated as to require a stack program
1295 
         that this will not be a problem.  */
1296 
      {
1297 
        char *exp = fs->cfa_exp;
1298 
        ULONGEST len;
1299 
 
1300 
        len = read_uleb128 (fs->objfile->obfd, &exp);
1301 
        cfa = (CORE_ADDR) execute_stack_op (fs->objfile, exp,
1302 
                                            exp + len, context, 0);
1303 
        break;
1304 
      }
1305 
    default:
1306 
      break;
1307 
    }
1308 
  context->cfa = cfa;
1309 
 
1310 
  if (!chain)
1311 
    orig_context->cfa = cfa;
1312 
 
1313 
  /* Compute the addresses of all registers saved in this frame.  */
1314 
  for (i = 0; i < NUM_REGS; ++i)
1315 
    switch (fs->regs.reg[i].how)
1316 
      {
1317 
      case REG_UNSAVED:
1318 
        if (i == SP_REGNUM)
1319 
          {
1320 
            context->reg[i].how = REG_CTX_VALUE;
1321 
            context->reg[i].loc.addr = cfa;
1322 
          }
1323 
        else
1324 
          context->reg[i].how = REG_CTX_UNSAVED;
1325 
        break;
1326 
      case REG_SAVED_OFFSET:
1327 
        context->reg[i].how = REG_CTX_SAVED_OFFSET;
1328 
        context->reg[i].loc.offset = fs->regs.reg[i].loc.offset;
1329 
        break;
1330 
      case REG_SAVED_REG:
1331 
        switch (orig_context->reg[fs->regs.reg[i].loc.reg].how)
1332 
          {
1333 
          case REG_CTX_UNSAVED:
1334 
            context->reg[i].how = REG_CTX_UNSAVED;
1335 
            break;
1336 
          case REG_CTX_SAVED_OFFSET:
1337 
            context->reg[i].how = REG_CTX_SAVED_OFFSET;
1338 
            context->reg[i].loc.offset = orig_context->cfa - context->cfa +
1339 
              orig_context->reg[fs->regs.reg[i].loc.reg].loc.offset;
1340 
            break;
1341 
          case REG_CTX_SAVED_REG:
1342 
            context->reg[i].how = REG_CTX_SAVED_REG;
1343 
            context->reg[i].loc.reg =
1344 
              orig_context->reg[fs->regs.reg[i].loc.reg].loc.reg;
1345 
            break;
1346 
          case REG_CTX_SAVED_ADDR:
1347 
            context->reg[i].how = REG_CTX_SAVED_ADDR;
1348 
            context->reg[i].loc.addr =
1349 
              orig_context->reg[fs->regs.reg[i].loc.reg].loc.addr;
1350 
            break;
1351 
          default:
1352 
            internal_error (__FILE__, __LINE__, "bad switch");
1353 
          }
1354 
        break;
1355 
      case REG_SAVED_EXP:
1356 
        {
1357 
          char *exp = fs->regs.reg[i].loc.exp;
1358 
          ULONGEST len;
1359 
          CORE_ADDR val;
1360 
 
1361 
          len = read_uleb128 (fs->objfile->obfd, &exp);
1362 
          val = execute_stack_op (fs->objfile, exp, exp + len,
1363 
                                  orig_context, cfa);
1364 
          context->reg[i].how = REG_CTX_SAVED_ADDR;
1365 
          context->reg[i].loc.addr = val;
1366 
        }
1367 
        break;
1368 
      default:
1369 
        internal_error (__FILE__, __LINE__, "bad switch");
1370 
      }
1371 
  get_reg ((char *) &context->ra, context, fs->retaddr_column);
1372 
  unwind_tmp_obstack_free ();
1373 
}
1374 
 
1375 
static int
1376 
is_cie (ULONGEST cie_id, int dwarf64)
1377 
{
1378 
  return dwarf64 ? (cie_id == 0xffffffffffffffff) : (cie_id == 0xffffffff);
1379 
}
1380 
 
1381 
static int
1382 
compare_fde_unit (const void *a, const void *b)
1383 
{
1384 
  struct fde_unit **first, **second;
1385 
  first = (struct fde_unit **) a;
1386 
  second = (struct fde_unit **) b;
1387 
  if ((*first)->initial_location > (*second)->initial_location)
1388 
    return 1;
1389 
  else if ((*first)->initial_location < (*second)->initial_location)
1390 
    return -1;
1391 
  else
1392 
    return 0;
1393 
}
1394 
 
1395 
/*  Build the cie_chunks and fde_chunks tables from informations
1396 
    found in .debug_frame and .eh_frame sections.  */
1397 
/* We can handle both of these sections almost in the same way, however there
1398 
   are some exceptions:
1399 
   - CIE ID is -1 in debug_frame, but 0 in eh_frame
1400 
   - eh_frame may contain some more information that are used only by gcc
1401 
     (eg. personality pointer, LSDA pointer, ...). Most of them we can ignore.
1402 
   - In debug_frame FDE's item cie_id contains offset of it's parent CIE.
1403 
     In eh_frame FDE's item cie_id is a relative pointer to the parent CIE.
1404 
     Anyway we don't need to bother with this, because we are smart enough
1405 
     to keep the pointer to the parent CIE of oncomming FDEs in 'last_cie'.
1406 
   - Although debug_frame items can contain Augmentation as well as
1407 
     eh_frame ones, I have never seen them non-empty. Thus only in eh_frame
1408 
     we can encounter for example non-absolute pointers (Aug. 'R').
1409 
                                                              -- mludvig  */
1410 
static void
1411 
parse_frame_info (struct objfile *objfile, file_ptr frame_offset,
1412 
                  unsigned int frame_size, int eh_frame)
1413 
{
1414 
  bfd *abfd = objfile->obfd;
1415 
  asection *curr_section_ptr;
1416 
  char *start = NULL;
1417 
  char *end = NULL;
1418 
  char *frame_buffer = NULL;
1419 
  char *curr_section_name, *aug_data;
1420 
  struct cie_unit *last_cie = NULL;
1421 
  int last_dup_fde = 0;
1422 
  int aug_len, i;
1423 
  CORE_ADDR curr_section_vma = 0;
1424 
 
1425 
  unwind_tmp_obstack_init ();
1426 
 
1427 
  frame_buffer = dwarf2_read_section (objfile, frame_offset, frame_size);
1428 
 
1429 
  start = frame_buffer;
1430 
  end = frame_buffer + frame_size;
1431 
 
1432 
  curr_section_name = eh_frame ? ".eh_frame" : ".debug_frame";
1433 
  curr_section_ptr = bfd_get_section_by_name (abfd, curr_section_name);
1434 
  if (curr_section_ptr)
1435 
    curr_section_vma = curr_section_ptr->vma;
1436 
 
1437 
  if (start)
1438 
    {
1439 
      while (start < end)
1440 
        {
1441 
          unsigned long length;
1442 
          ULONGEST cie_id;
1443 
          ULONGEST unit_offset = start - frame_buffer;
1444 
          int bytes_read, dwarf64;
1445 
          char *block_end;
1446 
 
1447 
          length = read_initial_length (abfd, start, &bytes_read);
1448 
          start += bytes_read;
1449 
          dwarf64 = (bytes_read == 12);
1450 
          block_end = start + length;
1451 
 
1452 
          if (length == 0)
1453 
            {
1454 
              start = block_end;
1455 
              continue;
1456 
            }
1457 
 
1458 
          cie_id = read_length (abfd, start, &bytes_read, dwarf64);
1459 
          start += bytes_read;
1460 
 
1461 
          if ((eh_frame && cie_id == 0) || is_cie (cie_id, dwarf64))
1462 
            {
1463 
              struct cie_unit *cie = cie_unit_alloc ();
1464 
              char *aug;
1465 
 
1466 
              cie->objfile = objfile;
1467 
              cie->next = cie_chunks;
1468 
              cie_chunks = cie;
1469 
 
1470 
              cie->objfile = objfile;
1471 
 
1472 
              cie->offset = unit_offset;
1473 
 
1474 
              start++;          /* version */
1475 
 
1476 
              cie->augmentation = aug = start;
1477 
              while (*start++); /* Skips last NULL as well */
1478 
 
1479 
              cie->code_align = read_uleb128 (abfd, &start);
1480 
              cie->data_align = read_sleb128 (abfd, &start);
1481 
              cie->ra = read_1u (abfd, &start);
1482 
 
1483 
              /* Augmentation:
1484 
                 z      Indicates that a uleb128 is present to size the
1485 
                 augmentation section.
1486 
                 L      Indicates the encoding (and thus presence) of
1487 
                 an LSDA pointer in the FDE augmentation.
1488 
                 R      Indicates a non-default pointer encoding for
1489 
                 FDE code pointers.
1490 
                 P      Indicates the presence of an encoding + language
1491 
                 personality routine in the CIE augmentation.
1492 
 
1493 
                 [This info comes from GCC's dwarf2out.c]
1494 
               */
1495 
              if (*aug == 'z')
1496 
                {
1497 
                  aug_len = read_uleb128 (abfd, &start);
1498 
                  aug_data = start;
1499 
                  start += aug_len;
1500 
                  ++aug;
1501 
                }
1502 
 
1503 
              cie->data = start;
1504 
              cie->data_length = block_end - cie->data;
1505 
 
1506 
              while (*aug != '\0')
1507 
                {
1508 
                  if (aug[0] == 'e' && aug[1] == 'h')
1509 
                    {
1510 
                      aug_data += sizeof (void *);
1511 
                      aug++;
1512 
                    }
1513 
                  else if (aug[0] == 'R')
1514 
                    cie->addr_encoding = *aug_data++;
1515 
                  else if (aug[0] == 'P')
1516 
                    {
1517 
                      CORE_ADDR pers_addr;
1518 
                      int pers_addr_enc;
1519 
 
1520 
                      pers_addr_enc = *aug_data++;
1521 
                      /* We don't need pers_addr value and so we
1522 
                         don't care about it's encoding.  */
1523 
                      pers_addr = read_encoded_pointer (abfd, &aug_data,
1524 
                                                        pers_addr_enc);
1525 
                    }
1526 
                  else if (aug[0] == 'L' && eh_frame)
1527 
                    {
1528 
                      int lsda_addr_enc;
1529 
 
1530 
                      /* Perhaps we should save this to CIE for later use?
1531 
                         Do we need it for something in GDB?  */
1532 
                      lsda_addr_enc = *aug_data++;
1533 
                    }
1534 
                  else
1535 
                    warning ("CFI warning: unknown augmentation \"%c\""
1536 
                             " in \"%s\" of\n"
1537 
                             "\t%s", aug[0], curr_section_name,
1538 
                             objfile->name);
1539 
                  aug++;
1540 
                }
1541 
 
1542 
              last_cie = cie;
1543 
            }
1544 
          else
1545 
            {
1546 
              struct fde_unit *fde;
1547 
              struct cie_unit *cie;
1548 
              int dup = 0;
1549 
              CORE_ADDR init_loc;
1550 
 
1551 
              /* We assume that debug_frame is in order
1552 
                 CIE,FDE,CIE,FDE,FDE,...  and thus the CIE for this FDE
1553 
                 should be stored in last_cie pointer. If not, we'll
1554 
                 try to find it by the older way.  */
1555 
              if (last_cie)
1556 
                cie = last_cie;
1557 
              else
1558 
                {
1559 
                  warning ("CFI: last_cie == NULL. "
1560 
                           "Perhaps a malformed %s section in '%s'...?\n",
1561 
                           curr_section_name, objfile->name);
1562 
 
1563 
                  cie = cie_chunks;
1564 
                  while (cie)
1565 
                    {
1566 
                      if (cie->objfile == objfile)
1567 
                        {
1568 
                          if (eh_frame &&
1569 
                              (cie->offset ==
1570 
                               (unit_offset + bytes_read - cie_id)))
1571 
                            break;
1572 
                          if (!eh_frame && (cie->offset == cie_id))
1573 
                            break;
1574 
                        }
1575 
 
1576 
                      cie = cie->next;
1577 
                    }
1578 
                  if (!cie)
1579 
                    error ("CFI: can't find CIE pointer");
1580 
                }
1581 
 
1582 
              init_loc = read_encoded_pointer (abfd, &start,
1583 
                                               cie->addr_encoding);
1584 
 
1585 
              switch (pointer_encoding (cie->addr_encoding))
1586 
                {
1587 
                case PE_absptr:
1588 
                  break;
1589 
                case PE_pcrel:
1590 
                  /* start-frame_buffer gives offset from
1591 
                     the beginning of actual section.  */
1592 
                  init_loc += curr_section_vma + start - frame_buffer;
1593 
                  break;
1594 
                default:
1595 
                  warning ("CFI: Unsupported pointer encoding\n");
1596 
                }
1597 
 
1598 
              /* For relocatable objects we must add an offset telling
1599 
                 where the section is actually mapped in the memory.  */
1600 
              init_loc += ANOFFSET (objfile->section_offsets,
1601 
                                    SECT_OFF_TEXT (objfile));
1602 
 
1603 
              /* If we have both .debug_frame and .eh_frame present in
1604 
                 a file, we must eliminate duplicate FDEs. For now we'll
1605 
                 run through all entries in fde_chunks and check it one
1606 
                 by one. Perhaps in the future we can implement a faster
1607 
                 searching algorithm.  */
1608 
              /* eh_frame==2 indicates, that this file has an already
1609 
                 parsed .debug_frame too. When eh_frame==1 it means, that no
1610 
                 .debug_frame is present and thus we don't need to check for
1611 
                 duplicities. eh_frame==0 means, that we parse .debug_frame
1612 
                 and don't need to care about duplicate FDEs, because
1613 
                 .debug_frame is parsed first.  */
1614 
              if (eh_frame == 2)
1615 
                for (i = 0; eh_frame == 2 && i < fde_chunks.elems; i++)
1616 
                  {
1617 
                    /* We assume that FDEs in .debug_frame and .eh_frame
1618 
                       have the same order (if they are present, of course).
1619 
                       If we find a duplicate entry for one FDE and save
1620 
                       it's index to last_dup_fde it's very likely, that
1621 
                       we'll find an entry for the following FDE right after
1622 
                       the previous one. Thus in many cases we'll run this
1623 
                       loop only once.  */
1624 
                    last_dup_fde = (last_dup_fde + i) % fde_chunks.elems;
1625 
                    if (fde_chunks.array[last_dup_fde]->initial_location
1626 
                        == init_loc)
1627 
                      {
1628 
                        dup = 1;
1629 
                        break;
1630 
                      }
1631 
                  }
1632 
 
1633 
              /* Allocate a new entry only if this FDE isn't a duplicate of
1634 
                 something we have already seen.   */
1635 
              if (!dup)
1636 
                {
1637 
                  fde_chunks_need_space ();
1638 
                  fde = fde_unit_alloc ();
1639 
 
1640 
                  fde_chunks.array[fde_chunks.elems++] = fde;
1641 
 
1642 
                  fde->initial_location = init_loc;
1643 
                  fde->address_range = read_encoded_pointer (abfd, &start,
1644 
                                                             cie->
1645 
                                                             addr_encoding);
1646 
 
1647 
                  fde->cie_ptr = cie;
1648 
 
1649 
                  /* Here we intentionally ignore augmentation data
1650 
                     from FDE, because we don't need them.  */
1651 
                  if (cie->augmentation[0] == 'z')
1652 
                    start += read_uleb128 (abfd, &start);
1653 
 
1654 
                  fde->data = start;
1655 
                  fde->data_length = block_end - start;
1656 
                }
1657 
            }
1658 
          start = block_end;
1659 
        }
1660 
      qsort (fde_chunks.array, fde_chunks.elems,
1661 
             sizeof (struct fde_unit *), compare_fde_unit);
1662 
    }
1663 
}
1664 
 
1665 
/* We must parse both .debug_frame section and .eh_frame because
1666 
 * not all frames must be present in both of these sections. */
1667 
void
1668 
dwarf2_build_frame_info (struct objfile *objfile)
1669 
{
1670 
  int after_debug_frame = 0;
1671 
 
1672 
  /* If we have .debug_frame then the parser is called with
1673 
     eh_frame==0 for .debug_frame and eh_frame==2 for .eh_frame,
1674 
     otherwise it's only called once for .eh_frame with argument
1675 
     eh_frame==1.  */
1676 
 
1677 
  if (dwarf_frame_offset)
1678 
    {
1679 
      parse_frame_info (objfile, dwarf_frame_offset,
1680 
                        dwarf_frame_size, 0 /* = debug_frame */ );
1681 
      after_debug_frame = 1;
1682 
    }
1683 
 
1684 
  if (dwarf_eh_frame_offset)
1685 
    parse_frame_info (objfile, dwarf_eh_frame_offset, dwarf_eh_frame_size,
1686 
                      1 /* = eh_frame */  + after_debug_frame);
1687 
}
1688 
 
1689 
/* Return the frame address.  */
1690 
CORE_ADDR
1691 
cfi_read_fp (void)
1692 
{
1693 
  struct context *context;
1694 
  struct frame_state *fs;
1695 
  CORE_ADDR cfa;
1696 
 
1697 
  unwind_tmp_obstack_init ();
1698 
 
1699 
  context = context_alloc ();
1700 
  fs = frame_state_alloc ();
1701 
 
1702 
  context->ra = read_pc () + 1;
1703 
 
1704 
  frame_state_for (context, fs);
1705 
  update_context (context, fs, 0);
1706 
 
1707 
  cfa = context->cfa;
1708 
 
1709 
  unwind_tmp_obstack_free ();
1710 
 
1711 
  return cfa;
1712 
}
1713 
 
1714 
/* Store the frame address.  This function is not used.  */
1715 
 
1716 
void
1717 
cfi_write_fp (CORE_ADDR val)
1718 
{
1719 
  struct context *context;
1720 
  struct frame_state *fs;
1721 
 
1722 
  unwind_tmp_obstack_init ();
1723 
 
1724 
  context = context_alloc ();
1725 
  fs = frame_state_alloc ();
1726 
 
1727 
  context->ra = read_pc () + 1;
1728 
 
1729 
  frame_state_for (context, fs);
1730 
 
1731 
  if (fs->cfa_how == CFA_REG_OFFSET)
1732 
    {
1733 
      val -= fs->cfa_offset;
1734 
      write_register_gen (fs->cfa_reg, (char *) &val);
1735 
    }
1736 
  else
1737 
    warning ("Can't write fp.");
1738 
 
1739 
  unwind_tmp_obstack_free ();
1740 
}
1741 
 
1742 
/* Restore the machine to the state it had before the current frame
1743 
   was created.  */
1744 
void
1745 
cfi_pop_frame (struct frame_info *fi)
1746 
{
1747 
  char *regbuf = alloca (MAX_REGISTER_RAW_SIZE);
1748 
  int regnum;
1749 
 
1750 
  for (regnum = 0; regnum < NUM_REGS; regnum++)
1751 
    {
1752 
      get_reg (regbuf, UNWIND_CONTEXT (fi), regnum);
1753 
      write_register_bytes (REGISTER_BYTE (regnum), regbuf,
1754 
                            REGISTER_RAW_SIZE (regnum));
1755 
    }
1756 
  write_register (PC_REGNUM, UNWIND_CONTEXT (fi)->ra);
1757 
 
1758 
  flush_cached_frames ();
1759 
}
1760 
 
1761 
/* Determine the address of the calling function's frame.  */
1762 
CORE_ADDR
1763 
cfi_frame_chain (struct frame_info *fi)
1764 
{
1765 
  struct context *context;
1766 
  struct frame_state *fs;
1767 
  CORE_ADDR cfa;
1768 
 
1769 
  unwind_tmp_obstack_init ();
1770 
 
1771 
  context = context_alloc ();
1772 
  fs = frame_state_alloc ();
1773 
  context_cpy (context, UNWIND_CONTEXT (fi));
1774 
 
1775 
  /* outermost frame */
1776 
  if (context->ra == 0)
1777 
    {
1778 
      unwind_tmp_obstack_free ();
1779 
      return 0;
1780 
    }
1781 
 
1782 
  frame_state_for (context, fs);
1783 
  update_context (context, fs, 1);
1784 
 
1785 
  cfa = context->cfa;
1786 
  unwind_tmp_obstack_free ();
1787 
 
1788 
  return cfa;
1789 
}
1790 
 
1791 
/* Sets the pc of the frame.  */
1792 
void
1793 
cfi_init_frame_pc (int fromleaf, struct frame_info *fi)
1794 
{
1795 
  if (fi->next)
1796 
    get_reg ((char *) &(fi->pc), UNWIND_CONTEXT (fi->next), PC_REGNUM);
1797 
  else
1798 
    fi->pc = read_pc ();
1799 
}
1800 
 
1801 
/* Initialize unwind context informations of the frame.  */
1802 
void
1803 
cfi_init_extra_frame_info (int fromleaf, struct frame_info *fi)
1804 
{
1805 
  struct frame_state *fs;
1806 
 
1807 
  unwind_tmp_obstack_init ();
1808 
 
1809 
  fs = frame_state_alloc ();
1810 
  fi->context = frame_obstack_alloc (sizeof (struct context));
1811 
  UNWIND_CONTEXT (fi)->reg =
1812 
    frame_obstack_alloc (sizeof (struct context_reg) * NUM_REGS);
1813 
  memset (UNWIND_CONTEXT (fi)->reg, 0,
1814 
          sizeof (struct context_reg) * NUM_REGS);
1815 
 
1816 
  if (fi->next)
1817 
    {
1818 
      context_cpy (UNWIND_CONTEXT (fi), UNWIND_CONTEXT (fi->next));
1819 
      frame_state_for (UNWIND_CONTEXT (fi), fs);
1820 
      update_context (UNWIND_CONTEXT (fi), fs, 1);
1821 
    }
1822 
  else
1823 
    {
1824 
      UNWIND_CONTEXT (fi)->ra = fi->pc + 1;
1825 
      frame_state_for (UNWIND_CONTEXT (fi), fs);
1826 
      update_context (UNWIND_CONTEXT (fi), fs, 0);
1827 
    }
1828 
 
1829 
  unwind_tmp_obstack_free ();
1830 
}
1831 
 
1832 
/* Obtain return address of the frame.  */
1833 
CORE_ADDR
1834 
cfi_get_ra (struct frame_info *fi)
1835 
{
1836 
  return UNWIND_CONTEXT (fi)->ra;
1837 
}
1838 
 
1839 
/* Find register number REGNUM relative to FRAME and put its
1840 
   (raw) contents in *RAW_BUFFER.  Set *OPTIMIZED if the variable
1841 
   was optimized out (and thus can't be fetched).  If the variable
1842 
   was fetched from memory, set *ADDRP to where it was fetched from,
1843 
   otherwise it was fetched from a register.
1844 
 
1845 
   The argument RAW_BUFFER must point to aligned memory.  */
1846 
void
1847 
cfi_get_saved_register (char *raw_buffer,
1848 
                        int *optimized,
1849 
                        CORE_ADDR *addrp,
1850 
                        struct frame_info *frame,
1851 
                        int regnum, enum lval_type *lval)
1852 
{
1853 
  if (!target_has_registers)
1854 
    error ("No registers.");
1855 
 
1856 
  /* Normal systems don't optimize out things with register numbers.  */
1857 
  if (optimized != NULL)
1858 
    *optimized = 0;
1859 
 
1860 
  if (addrp)                    /* default assumption: not found in memory */
1861 
    *addrp = 0;
1862 
 
1863 
  if (!frame->next)
1864 
    {
1865 
      read_register_gen (regnum, raw_buffer);
1866 
      if (lval != NULL)
1867 
        *lval = lval_register;
1868 
      if (addrp != NULL)
1869 
        *addrp = REGISTER_BYTE (regnum);
1870 
    }
1871 
  else
1872 
    {
1873 
      frame = frame->next;
1874 
      switch (UNWIND_CONTEXT (frame)->reg[regnum].how)
1875 
        {
1876 
        case REG_CTX_UNSAVED:
1877 
          read_register_gen (regnum, raw_buffer);
1878 
          if (lval != NULL)
1879 
            *lval = not_lval;
1880 
          if (optimized != NULL)
1881 
            *optimized = 1;
1882 
          break;
1883 
        case REG_CTX_SAVED_OFFSET:
1884 
          target_read_memory (UNWIND_CONTEXT (frame)->cfa +
1885 
                              UNWIND_CONTEXT (frame)->reg[regnum].loc.offset,
1886 
                              raw_buffer, REGISTER_RAW_SIZE (regnum));
1887 
          if (lval != NULL)
1888 
            *lval = lval_memory;
1889 
          if (addrp != NULL)
1890 
            *addrp =
1891 
              UNWIND_CONTEXT (frame)->cfa +
1892 
              UNWIND_CONTEXT (frame)->reg[regnum].loc.offset;
1893 
          break;
1894 
        case REG_CTX_SAVED_REG:
1895 
          read_register_gen (UNWIND_CONTEXT (frame)->reg[regnum].loc.reg,
1896 
                             raw_buffer);
1897 
          if (lval != NULL)
1898 
            *lval = lval_register;
1899 
          if (addrp != NULL)
1900 
            *addrp =
1901 
              REGISTER_BYTE (UNWIND_CONTEXT (frame)->reg[regnum].loc.reg);
1902 
          break;
1903 
        case REG_CTX_SAVED_ADDR:
1904 
          target_read_memory (UNWIND_CONTEXT (frame)->reg[regnum].loc.addr,
1905 
                              raw_buffer, REGISTER_RAW_SIZE (regnum));
1906 
          if (lval != NULL)
1907 
            *lval = lval_memory;
1908 
          if (addrp != NULL)
1909 
            *addrp = UNWIND_CONTEXT (frame)->reg[regnum].loc.addr;
1910 
          break;
1911 
        case REG_CTX_VALUE:
1912 
          memcpy (raw_buffer, &UNWIND_CONTEXT (frame)->reg[regnum].loc.addr,
1913 
                  REGISTER_RAW_SIZE (regnum));
1914 
          if (lval != NULL)
1915 
            *lval = not_lval;
1916 
          if (optimized != NULL)
1917 
            *optimized = 0;
1918 
          break;
1919 
        default:
1920 
          internal_error (__FILE__, __LINE__,
1921 
                          "cfi_get_saved_register: unknown register rule");
1922 
        }
1923 
    }
1924 
}
1925 
 
1926 
/*  Return the register that the function uses for a frame pointer,
1927 
    plus any necessary offset to be applied to the register before
1928 
    any frame pointer offsets.  */
1929 
void
1930 
cfi_virtual_frame_pointer (CORE_ADDR pc, int *frame_reg,
1931 
                           LONGEST * frame_offset)
1932 
{
1933 
  struct context *context;
1934 
  struct frame_state *fs;
1935 
 
1936 
  unwind_tmp_obstack_init ();
1937 
 
1938 
  context = context_alloc ();
1939 
  fs = frame_state_alloc ();
1940 
 
1941 
  context->ra = read_pc () + 1;
1942 
 
1943 
  frame_state_for (context, fs);
1944 
 
1945 
  if (fs->cfa_how == CFA_REG_OFFSET)
1946 
    {
1947 
      *frame_reg = fs->cfa_reg;
1948 
      *frame_offset = fs->cfa_offset;
1949 
    }
1950 
  else
1951 
    error ("dwarf cfi error: CFA is not defined as CFA_REG_OFFSET");
1952 
 
1953 
  unwind_tmp_obstack_free ();
1954 
}

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.