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

Subversion Repositories openrisc_me

[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [gdb/] [or32-tdep.c] - Blame information for rev 452

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

Line No. Rev Author Line
1 227 jeremybenn
/* Target-dependent code for the 32-bit OpenRISC 1000, for the GNU Debugger.
2
 
3
   Copyright 1988-2008, Free Software Foundation, Inc.
4
   Copyright (C) 2008, 2010 Embecosm Limited
5
 
6
   Contributed by Alessandro Forin(af@cs.cmu.edu at CMU
7
   and by Per Bothner(bothner@cs.wisc.edu) at U.Wisconsin.
8
   Contributor Jeremy Bennett <jeremy.bennett@embecosm.com>
9
 
10
   This file is part of GDB.
11
 
12
   This program is free software; you can redistribute it and/or modify it
13
   under the terms of the GNU General Public License as published by the Free
14
   Software Foundation; either version 3 of the License, or (at your option)
15
   any later version.
16
 
17
   This program is distributed in the hope that it will be useful, but WITHOUT
18
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
19
   FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
20
   more details.
21
 
22
   You should have received a copy of the GNU General Public License along
23
   with this program.  If not, see <http://www.gnu.org/licenses/>.  */
24
 
25
/*-----------------------------------------------------------------------------
26
   This version for the OpenRISC 1000 architecture is a rewrite by Jeremy
27
   Bennett of the old GDB 5.3 interface to make use of gdbarch for GDB 6.8.
28
 
29
   The code tries to follow the GDB coding style.
30
 
31
   Commenting is Doxygen compatible.
32
 
33
   Much has been stripped out in the interests of getting a basic working
34
   system. This is described as the OpenRISC 1000 target architecture, so
35
   should work with 16, 32 and 64 bit versions of that architecture and should
36
   work whether or not they have floating point and/or vector registers.
37
 
38
   There was never a capability to run simulator commands (no remote target
39
   implemented the required function), so that has been removed.
40
 
41
   The info trace command has been removed. The meaning of this is not clear -
42
   it relies on a value in register 255 of the debug group, which is
43
   undocumented.
44
 
45
   All the hardware trace has been removed for the time being. The new debug
46
   interface does not support hardware trace, so there is no plan to reinstate
47
   this functionality.
48
 
49
   Support for multiple contexts (which was rudimentary, and not working) has
50
   been removed. */
51
/*---------------------------------------------------------------------------*/
52
 
53
#include "demangle.h"
54
#include "defs.h"
55
#include "gdb_string.h"
56
#include "frame.h"
57
#include "inferior.h"
58
#include "symtab.h"
59
#include "value.h"
60
#include "gdbcmd.h"
61
#include "language.h"
62
#include "gdbcore.h"
63
#include "symfile.h"
64
#include "objfiles.h"
65
#include "gdbtypes.h"
66
#include "target.h"
67
#include "regcache.h"
68
 
69
#include "opcode/or32.h"
70
#include "or32-tdep.h"
71
 
72
#include "safe-ctype.h"
73
#include "block.h"
74
#include "reggroups.h"
75
#include "arch-utils.h"
76
#include "frame.h"
77
#include "frame-unwind.h"
78
#include "frame-base.h"
79
#include "dwarf2-frame.h"
80
#include "trad-frame.h"
81
 
82
#include <inttypes.h>
83
 
84
 
85
 
86
 
87
/* Support functions for the architecture definition */
88
 
89
 
90
/*----------------------------------------------------------------------------*/
91
/*!Get an instruction
92
 
93
   This reads from memory. The old version relied on the frame, this relies
94
   just on the architecture. The old version also guaranteed not to get a
95
   software breakpoint if one had been set. However that seems to happen just
96
   before execution and is removed immediately after, so we believe should not
97
   happen. The old function from GDB 6.8 to do this has been deleted.
98
 
99
   @param[in] gdbarch  Architecture for which we are getting the instruction.
100
   @param[in] addr     Address from which to get the instruction
101
 
102
   @return  The instruction */
103
/*---------------------------------------------------------------------------*/
104
 
105
static ULONGEST
106
or32_fetch_instruction (struct gdbarch *gdbarch,
107
                        CORE_ADDR       addr)
108
{
109
  enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
110
  char            buf[OR32_INSTLEN];
111
  int             status;
112
 
113
  status = target_read_memory (addr, buf, OR32_INSTLEN);
114
 
115
  if (status)
116
    {
117
      memory_error (status, addr);
118
    }
119
 
120
  return  extract_unsigned_integer (buf, OR32_INSTLEN, byte_order);
121
 
122
}       /* or32_fetch_instruction() */
123
 
124
 
125
/*---------------------------------------------------------------------------*/
126
/*!Generic function to read bits from an instruction
127
 
128
   printf style. Basic syntax
129
 
130
      or32_analyse_inst (inst, format, &arg1, &arg2 ...)
131
 
132
   Format string can contain the following characters:
133
 
134
   - SPACE:  Ignored, just for layout
135
   - 0:      Match with a zero bit
136
   - 1:      Match with a one bit
137
   - %<n>b:  Match <n> bits to the next argument (n decimal)
138
 
139
   If the arg corresponding to a bit field is non-null, the value will be
140
   assigned to that argument (using NULL allows fields to be skipped).
141
 
142
   Any bad string will cause a fatal error. These are constant strings, so
143
   should be correct.
144
 
145
   The bit field must be 32 bits long. A failure here will cause a fatal error
146
   for the same reason.
147
 
148
   @note The format string is presented MS field to LS field, left to
149
         right. This means that it is read lowest numbered char first.
150
 
151
   @note Some of the arg fields may be populated, even if recognition
152
         ultimately fails.
153
 
154
   @param[in]  inst    The instruction to analyse
155
   @param[in]  format  The format string
156
   @param[out] ...     Argument fields
157
 
158
   @return  1 (TRUE) if the instruction matches, 0 (FALSE) otherwise.        */
159
/*---------------------------------------------------------------------------*/
160
static int
161
or32_analyse_inst (uint32_t    inst,
162
                   const char *format,
163
                   ...)
164
{
165
  /* Break out each field in turn, validating as we go. */
166
  va_list     ap;
167
 
168
  int         i;
169
  int         iptr = 0;                  /* Instruction pointer */
170
 
171
  va_start (ap, format);
172
 
173
  for (i = 0; 0 != format[i];)
174
    {
175
      const char *start_ptr;
176
      char       *end_ptr;
177
 
178
      uint32_t    bits;                 /* Bit substring of interest */
179
      uint32_t    width;                /* Substring width */
180
      uint32_t   *arg_ptr;
181
 
182
      switch (format[i])
183
        {
184
        case ' ': i++; break;   /* Formatting: ignored */
185
 
186
        case '0': case '1':     /* Constant bit field */
187
          bits = (inst >> (OR32_INSTBITLEN - iptr - 1)) & 0x1;
188
 
189
          if ((format[i] - '0') != bits)
190
            {
191
              return  0;
192
            }
193
 
194
          iptr++;
195
          i++;
196
          break;
197
 
198
        case '%':               /* Bit field */
199
          i++;
200
          start_ptr = &(format[i]);
201
          width     = strtoul (start_ptr, &end_ptr, 10);
202
 
203
          /* Check we got something, and if so skip on */
204
          if (start_ptr == end_ptr)
205
            {
206
              fatal ("bitstring \"%s\" at offset %d has no length field.\n",
207
                     format, i);
208
            }
209
 
210
          i += end_ptr - start_ptr;
211
 
212
          /* Look for and skip the terminating 'b'. If it's not there, we
213
             still give a fatal error, because these are fixed strings that
214
             just should not be wrong. */
215
          if ('b' != format[i++])
216
            {
217
              fatal ("bitstring \"%s\" at offset %d has no terminating 'b'.\n",
218
                     format, i);
219
            }
220
 
221
          /* Break out the field. There is a special case with a bit width of
222
             32. */
223
          if (32 == width)
224
            {
225
              bits = inst;
226
            }
227
          else
228
            {
229
              bits = (inst >> (OR32_INSTBITLEN - iptr - width)) & ((1 << width) - 1);
230
            }
231
 
232
          arg_ptr   = va_arg (ap, uint32_t *);
233
          *arg_ptr  = bits;
234
          iptr     += width;
235
          break;
236
 
237
        default:
238
          fatal ("invalid character in bitstring \"%s\" at offset %d.\n",
239
                 format, i);
240
          break;
241
        }
242
    }
243
 
244
  /* Is the length OK? */
245
  gdb_assert (OR32_INSTBITLEN == iptr);
246
 
247
  return  1;                            /* We succeeded */
248
 
249
}       /* or32_analyse_inst () */
250
 
251
 
252
/*---------------------------------------------------------------------------*/
253
/*!Analyse a l.addi instruction
254
 
255
   General form is:
256
 
257
     l.addi  rD,rA,I
258
 
259
   Makes use of the generic analysis function (@see or32_analyse_inst ()).
260
 
261
   @param[in]  inst      The instruction to analyse.
262
   @param[out] rd_ptr    Pointer to the rD value.
263
   @param[out] ra_ptr    Pointer to the rA value.
264
   @param[out] simm_ptr  Pointer to the signed immediate value.
265
 
266
   @return  1 (TRUE) if the instruction matches, 0 (FALSE) otherwise.        */
267
/*---------------------------------------------------------------------------*/
268
static int
269
or32_analyse_l_addi (uint32_t      inst,
270
                     unsigned int *rd_ptr,
271
                     unsigned int *ra_ptr,
272
                     int          *simm_ptr)
273
{
274
  /* Instruction fields */
275
  uint32_t  rd, ra, i;
276
 
277
  if (or32_analyse_inst (inst, "10 0111 %5b %5b %16b", &rd, &ra, &i))
278
    {
279
      /* Found it. Construct the result fields */
280
      *rd_ptr   = (unsigned int) rd;
281
      *ra_ptr   = (unsigned int) ra;
282
      *simm_ptr = (int) (((i & 0x8000) == 0x8000) ? 0xffff0000 | i : i);
283
 
284
      return  1;                /* Success */
285
    }
286
  else
287
    {
288
      return  0;         /* Failure */
289
    }
290
}       /* or32_analyse_l_addi () */
291
 
292
 
293
/*---------------------------------------------------------------------------*/
294
/*!Analyse a l.sw instruction
295
 
296
   General form is:
297
 
298
     l.sw  I(rA),rB
299
 
300
   Makes use of the generic analysis function (@see or32_analyse_inst ()).
301
 
302
   @param[in]  inst      The instruction to analyse.
303
   @param[out] simm_ptr  Pointer to the signed immediate value.
304
   @param[out] ra_ptr    Pointer to the rA value.
305
   @param[out] rb_ptr    Pointer to the rB value.
306
 
307
   @return  1 (TRUE) if the instruction matches, 0 (FALSE) otherwise.        */
308
/*---------------------------------------------------------------------------*/
309
static int
310
or32_analyse_l_sw (uint32_t      inst,
311
                   int          *simm_ptr,
312
                   unsigned int *ra_ptr,
313
                   unsigned int *rb_ptr)
314
{
315
  /* Instruction fields */
316
  uint32_t  ihi, ilo, ra, rb;
317
 
318
  if (or32_analyse_inst (inst, "11 0101 %5b %5b %5b %11b", &ihi, &ra, &rb,
319
                         &ilo))
320
 
321
    {
322
      /* Found it. Construct the result fields */
323
      *simm_ptr  = (int) ((ihi << 11) | ilo);
324
      *simm_ptr |= ((ihi & 0x10) == 0x10) ? 0xffff0000 : 0;
325
 
326
      *ra_ptr    = (unsigned int) ra;
327
      *rb_ptr    = (unsigned int) rb;
328
 
329
      return  1;                /* Success */
330
    }
331
  else
332
    {
333
      return  0;         /* Failure */
334
    }
335
}       /* or32_analyse_l_sw () */
336
 
337
 
338
 
339
 
340
/* Functions defining the architecture */
341
 
342
 
343
/*----------------------------------------------------------------------------*/
344
/*!Determine the return convention used for a given type
345
 
346
   Optionally, fetch or set the return value via "readbuf" or "writebuf"
347
   respectively using "regcache" for the register values.
348
 
349
   The OpenRISC 1000 returns scalar values via R11 and (for 64 bit values on
350
   32 bit architectures) R12. Structs and unions are returned by reference,
351
   with the address in R11
352
 
353
   The result returned is independent of the function type, so we ignore that.
354
 
355
   Throughout use read_memory(), not target_read_memory(), since the address
356
   may be invalid and we want an error reported (read_memory() is
357
   target_read_memory() with error reporting).
358
 
359
   @todo This implementation is labelled OR32, but in fact is just for the 32
360
         bit version, OR32. This should be made explicit
361
 
362
   @param[in]  gdbarch   The GDB architecture being used
363
   @param[in]  functype  The type of the function to be called (may be NULL)
364
   @param[in]  valtype   The type of the entity to be returned
365
   @param[in]  regcache  The register cache
366
   @param[in]  readbuf   Buffer into which the return value should be written
367
   @param[out] writebuf  Buffer from which the return value should be written
368
 
369
   @return  The type of return value */
370
/*---------------------------------------------------------------------------*/
371
 
372
static enum return_value_convention
373
or32_return_value (struct gdbarch  *gdbarch,
374
                   struct type     *functype,
375
                   struct type     *valtype,
376
                   struct regcache *regcache,
377
                   gdb_byte        *readbuf,
378
                   const gdb_byte  *writebuf)
379
{
380
  enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
381
  enum type_code  rv_type    = TYPE_CODE (valtype);
382
  unsigned int    rv_size    = TYPE_LENGTH (valtype);
383
  ULONGEST        tmp;
384
 
385
  /* Deal with struct/union and large scalars first. Large (> 4 byte) scalars
386
     are returned via a pointer (despite what is says in the architecture
387
     document). Result pointed to by R11 */
388
 
389
  if((TYPE_CODE_STRUCT == rv_type) ||
390
     (TYPE_CODE_UNION  == rv_type) ||
391
     (rv_size          >  4))
392
    {
393
      if (readbuf)
394
        {
395
          regcache_cooked_read_unsigned (regcache, OR32_RV_REGNUM, &tmp);
396
          read_memory (tmp, readbuf, rv_size);
397
        }
398
      if (writebuf)
399
        {
400
          regcache_cooked_read_unsigned (regcache, OR32_RV_REGNUM, &tmp);
401
          write_memory (tmp, writebuf, rv_size);
402
        }
403
 
404
      return RETURN_VALUE_ABI_RETURNS_ADDRESS;
405
    }
406
 
407
  /* 1-4 byte scalars are returned in R11 */
408
 
409
  if (readbuf)
410
    {
411
      regcache_cooked_read_unsigned (regcache, OR32_RV_REGNUM, &tmp);
412
      store_unsigned_integer (readbuf, rv_size, byte_order, tmp);
413
    }
414
  if (writebuf)
415
    {
416
      gdb_byte buf[4];
417
      memset (buf, 0, sizeof (buf));     /* Pad with zeros if < 4 bytes */
418
 
419
      if (BFD_ENDIAN_BIG == byte_order)
420
        {
421
          memcpy (buf + sizeof (buf) - rv_size, writebuf, rv_size);
422
        }
423
      else
424
        {
425
          memcpy (buf,                          writebuf, rv_size);
426
        }
427
 
428
      regcache_cooked_write (regcache, OR32_RV_REGNUM, buf);
429
    }
430
 
431
  return RETURN_VALUE_REGISTER_CONVENTION;
432
 
433
}       /* or32_return_value() */
434
 
435
 
436
/*----------------------------------------------------------------------------*/
437
/*!Determine the instruction to use for a breakpoint.
438
 
439
   Given the address at which to insert a breakpoint (bp_addr), what will
440
   that breakpoint be?
441
 
442
   For or32, we have a breakpoint instruction. Since all or32 instructions
443
   are 32 bits, this is all we need, regardless of address.
444
 
445
   @param[in]  gdbarch  The GDB architecture being used
446
   @param[in]  bp_addr  The breakpoint address in question
447
   @param[out] bp_size  The size of instruction selected
448
 
449
   @return  The chosen breakpoint instruction */
450
/*---------------------------------------------------------------------------*/
451
 
452
static const gdb_byte *
453
or32_breakpoint_from_pc (struct gdbarch *gdbarch,
454
                         CORE_ADDR      *bp_addr,
455
                         int            *bp_size)
456
{
457
  static const gdb_byte breakpoint[] = OR32_BRK_INSTR_STRUCT;
458
 
459
  *bp_size = OR32_INSTLEN;
460
  return breakpoint;
461
 
462
}       /* or32_breakpoint_from_pc() */
463
 
464
 
465
/*----------------------------------------------------------------------------*/
466
/*!Determine if we are executing a delay slot
467
 
468
   Looks at the instruction at the previous instruction to see if it was one
469
   with a delay slot. But it also has to be the address prior to NPC, because
470
   we may have just taken an exception.
471
 
472
   @param[in] gdbarch     The GDB architecture being used
473
   @param[in] this_frame  Information about THIS frame
474
 
475
   @return  1 (true) if this instruction is executing a delay slot, 0 (false)
476
   otherwise. */
477
/*--------------------------------------------------------------------------*/
478
 
479
static int
480
or32_single_step_through_delay( struct gdbarch    *gdbarch,
481
                                struct frame_info *this_frame )
482
{
483
  struct regcache   *regcache = get_current_regcache ();
484
  ULONGEST           val;
485
  CORE_ADDR          ppc;
486
  CORE_ADDR          npc;
487
  int                index;
488
 
489
  /* Get and the previous and current instruction addresses. If they are not
490
     adjacent, we cannot be in a delay slot. */
491
  regcache_cooked_read_unsigned (regcache, OR32_PPC_REGNUM, &val);
492
  ppc        = (CORE_ADDR) val;
493
  regcache_cooked_read_unsigned (regcache, OR32_NPC_REGNUM, &val);
494
  npc        = (CORE_ADDR) val;
495
 
496
  if (0x4 != (npc - ppc))
497
    {
498
      return  0;
499
    }
500
 
501
  /* Decode the previous instruction to see if it was a branch or a jump, and
502
     hence we are in a delay slot. */
503
  index = insn_decode (or32_fetch_instruction (gdbarch, ppc));
504
  return  or32_opcodes[index].flags & OR32_IF_DELAY;
505
 
506
}       /* or32_single_step_through_delay() */
507
 
508
 
509
/*----------------------------------------------------------------------------*/
510
/*!Read a pseudo register
511
 
512
   Since we have no pseudo registers this is a null function for now.
513
 
514
   @todo The floating point and vector registers ought to be done as
515
         pseudo-registers.
516
 
517
   @param[in]  gdbarch   The GDB architecture to consider
518
   @param[in]  regcache  The cached register values as an array
519
   @param[in]  regnum    The register to read
520
   @param[out] buf       A buffer to put the result in */
521
/*---------------------------------------------------------------------------*/
522
 
523
static void
524
or32_pseudo_register_read (struct gdbarch  *gdbarch,
525
                           struct regcache *regcache,
526
                           int              regnum,
527
                           gdb_byte        *buf)
528
{
529
  return;
530
 
531
}       /* or32_pseudo_register_read() */
532
 
533
 
534
/*----------------------------------------------------------------------------*/
535
/*!Write a pseudo register
536
 
537
   Since we have no pseudo registers this is a null function for now.
538
 
539
   @todo The floating point and vector registers ought to be done as
540
         pseudo-registers.
541
 
542
   @param[in] gdbarch   The GDB architecture to consider
543
   @param[in] regcache  The cached register values as an array
544
   @param[in] regnum    The register to read
545
   @param[in] buf       A buffer with the value to write */
546
/*---------------------------------------------------------------------------*/
547
 
548
static void
549
or32_pseudo_register_write (struct gdbarch  *gdbarch,
550
                            struct regcache *regcache,
551
                            int              regnum,
552
                            const gdb_byte  *buf)
553
{
554
  return;
555
 
556
}       /* or32_pseudo_register_write() */
557
 
558
 
559
/*----------------------------------------------------------------------------*/
560
/*!Return the register name for the OpenRISC 1000 architecture
561
 
562
   This version converted to ANSI C, made static and incorporates the static
563
   table of register names (this is the only place it is referenced).
564
 
565
   @todo The floating point and vector registers ought to be done as
566
         pseudo-registers.
567
 
568
   @param[in] gdbarch  The GDB architecture being used
569
   @param[in] regnum    The register number
570
 
571
   @return  The textual name of the register */
572
/*---------------------------------------------------------------------------*/
573
 
574
static const char *
575
or32_register_name (struct gdbarch *gdbarch,
576
                    int             regnum)
577
{
578
  static char *or32_gdb_reg_names[OR32_TOTAL_NUM_REGS] =
579
    {
580
      /* general purpose registers */
581 244 jeremybenn
      "r0",  "r1",  "r2",  "r3",  "r4",  "r5",  "r6",  "r7",
582
      "r8",  "r9",  "r10", "r11", "r12", "r13", "r14", "r15",
583
      "r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23",
584
      "r24", "r25", "r26", "r27", "r28", "r29", "r30", "r31",
585 227 jeremybenn
 
586
      /* previous program counter, next program counter and status register */
587
      "ppc",   "npc",   "sr"
588
 
589
      /* Floating point and vector registers may appear as pseudo registers in
590
         the future. */
591
    };
592
 
593
  return or32_gdb_reg_names[regnum];
594
 
595
}       /* or32_register_name() */
596
 
597
 
598
/*----------------------------------------------------------------------------*/
599
/*!Identify the type of a register
600
 
601
   @todo I don't fully understand exactly what this does, but I think this
602
         makes sense!
603
 
604
   @param[in] arch     The GDB architecture to consider
605
   @param[in] regnum   The register to identify
606
 
607
   @return  The type of the register */
608
/*---------------------------------------------------------------------------*/
609
 
610
static struct type *
611
or32_register_type (struct gdbarch *arch,
612
                    int             regnum)
613
{
614
  static struct type *void_func_ptr = NULL;
615
  static struct type *void_ptr      = NULL;
616
 
617
  /* Set up the static pointers once, the first time*/
618
  if (NULL == void_func_ptr)
619
    {
620
      struct type *void_type = builtin_type (arch)->builtin_void;
621
 
622
      void_ptr      = lookup_pointer_type (void_type);
623
      void_func_ptr = lookup_pointer_type (lookup_function_type (void_type));
624
    }
625
 
626
  if((regnum >= 0) && (regnum < OR32_TOTAL_NUM_REGS))
627
    {
628
      switch (regnum)
629
        {
630
        case OR32_PPC_REGNUM:
631
        case OR32_NPC_REGNUM:
632
          return void_func_ptr;                 /* Pointer to code */
633
 
634
        case OR32_SP_REGNUM:
635
        case OR32_FP_REGNUM:
636
          return void_ptr;                              /* Pointer to data */
637
 
638
        default:
639
          return builtin_type (arch)->builtin_uint32;   /* Data */
640
        }
641
    }
642
 
643
  internal_error (__FILE__, __LINE__,
644
                  _("or32_register_type: illegal register number %d"), regnum);
645
 
646
}       /* or32_register_type() */
647
 
648
 
649
/*----------------------------------------------------------------------------*/
650
/*!Handle the "info register" command
651
 
652
   Print the identified register, unless it is -1, in which case print all
653
   the registers. If all is 1 means all registers, otherwise only the core
654
   GPRs.
655
 
656
   @todo At present all registers are printed with the default method. Should
657
         there be something special for FP registers?
658
 
659
   @param[in] gdbarch  The GDB architecture being used
660
   @param[in] file     File handle for use with any custom I/O
661
   @param[in] frame    Frame info for use with custom output
662
   @param[in] regnum   Register of interest, or -1 if all registers
663
   @param[in] all      1 if all means all, 0 if all means just GPRs
664
 
665
   @return  The aligned stack frame address */
666
/*---------------------------------------------------------------------------*/
667
 
668
static void
669
or32_registers_info (struct gdbarch    *gdbarch,
670
                     struct ui_file    *file,
671
                     struct frame_info *frame,
672
                     int                regnum,
673
                     int                all)
674
{
675
  if (-1 == regnum)
676
    {
677
      /* Do all (valid) registers */
678
      unsigned int  lim = all ? OR32_NUM_REGS : OR32_MAX_GPR_REGS;
679
 
680
      for (regnum = 0; regnum < lim; regnum++) {
681
        if ('\0' != *(or32_register_name (gdbarch, regnum)))
682
          {
683
            or32_registers_info (gdbarch, file, frame, regnum, all);
684
          }
685
      }
686
    }
687
  else
688
    {
689
      /* Do one specified register - if it is part of this architecture */
690
      if ('\0' == *(or32_register_name (gdbarch, regnum)))
691
        {
692
          error ("Not a valid register for the current processor type");
693
        }
694
      else
695
        {
696
          default_print_registers_info (gdbarch, file, frame, regnum, all);
697
        }
698
    }
699
}       /* or32_registers_info() */
700
 
701
 
702
/*----------------------------------------------------------------------------*/
703
/*!Identify if a register belongs to a specified group
704
 
705
   Return true if the specified register is a member of the specified
706
   register group.
707
 
708
   These are the groups of registers that can be displayed via "info reg".
709
 
710
   @todo The Vector and Floating Point registers ought to be displayed as
711
         pseudo-registers.
712
 
713
   @param[in] gdbarch  The GDB architecture to consider
714
   @param[in] regnum   The register to consider
715
   @param[in] group    The group to consider
716
 
717
   @return  True (1) if regnum is a member of group */
718
/*---------------------------------------------------------------------------*/
719
 
720
static int
721
or32_register_reggroup_p (struct gdbarch  *gdbarch,
722
                          int              regnum,
723
                          struct reggroup *group)
724
{
725
  struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
726
 
727
  /* All register group */
728
  if (group == all_reggroup)
729
    {
730
      return ((regnum >= 0) &&
731
              (regnum < OR32_TOTAL_NUM_REGS) &&
732
              (or32_register_name (gdbarch, regnum)[0] != '\0'));
733
    }
734
 
735
  /* For now everything except the PC */
736
  if (group == general_reggroup)
737
    {
738
      return ((regnum >= OR32_ZERO_REGNUM) &&
739
              (regnum <  tdep->num_gpr_regs) &&
740
              (regnum != OR32_PPC_REGNUM) &&
741
              (regnum != OR32_NPC_REGNUM));
742
    }
743
 
744
  if (group == float_reggroup)
745
    {
746
      return 0;                  /* No float regs.  */
747
    }
748
 
749
  if (group == vector_reggroup)
750
    {
751
      return 0;                  /* No vector regs.  */
752
    }
753
 
754
  /* For any that are not handled above.  */
755
  return default_register_reggroup_p (gdbarch, regnum, group);
756
 
757
}       /* or32_register_reggroup_p() */
758
 
759
 
760
/*----------------------------------------------------------------------------*/
761 244 jeremybenn
/*!Is this one of the registers used for passing arguments?
762
 
763
   These are r3-r8 in the API.
764
 
765
   @param[in] regnum  The register to consider
766
 
767
   @return  Non-zero (TRUE) if it is an argument register, zero (FALSE)
768
            otherwise.                                                        */
769
/*----------------------------------------------------------------------------*/
770
static int
771
or32_is_arg_reg (unsigned int  regnum)
772
{
773
  return (OR32_FIRST_ARG_REGNUM <= regnum) && (regnum <= OR32_LAST_ARG_REGNUM);
774
 
775
}       /* or32_is_arg_reg () */
776
 
777
 
778
/*----------------------------------------------------------------------------*/
779
/*!Is this a callee saved register?
780
 
781
   These are r10, r12, r14, r16, r18, r20, r22, r24, r26, r28 and r30 in the
782
   API.
783
 
784
   @param[in] regnum  The register to consider
785
 
786
   @return  Non-zero (TRUE) if it is a callee saved register, zero (FALSE)
787
            otherwise.                                                        */
788
/*----------------------------------------------------------------------------*/
789
static int
790
or32_is_callee_saved_reg (unsigned int  regnum)
791
{
792
  return (OR32_FIRST_SAVED_REGNUM <= regnum) && (0 == regnum % 2);
793
 
794
}       /* or32_is_callee_saved_reg () */
795
 
796
 
797
/*----------------------------------------------------------------------------*/
798 227 jeremybenn
/*!Skip a function prolog
799
 
800
   If the input address, PC, is in a function prologue, return the address of
801
   the end of the prologue, otherwise return the input  address.
802
 
803
   @see For details of the stack frame, see the function
804 244 jeremybenn
        or32_frame_cache().
805 227 jeremybenn
 
806 244 jeremybenn
   @note The old version of this function used to use skip_prologue_using_sal
807
         to skip the prologue without checking if it had actually worked. It
808
         doesn't for STABS, so we had better check for a valid result.
809
 
810 227 jeremybenn
   This function reuses the helper functions from or32_frame_cache() to
811
   locate the various parts of the prolog, any or all of which may be missing.
812
 
813
   @param[in] gdbarch  The GDB architecture being used
814
   @param[in] pc       Current program counter
815
 
816
   @return  The address of the end of the prolog if the PC is in a function
817
            prologue, otherwise the input  address.                           */
818
/*----------------------------------------------------------------------------*/
819
static CORE_ADDR
820
or32_skip_prologue (struct gdbarch *gdbarch,
821
                    CORE_ADDR       pc)
822
{
823 252 jeremybenn
  CORE_ADDR     start_pc;
824 227 jeremybenn
  CORE_ADDR     addr;
825
  uint32_t      inst;
826
 
827
  unsigned int  ra, rb, rd;             /* For instruction analysis */
828
  int           simm;
829
 
830
  int           frame_size = 0;
831
 
832 252 jeremybenn
  /* Try using SAL first if we have symbolic information available. This only
833
     works for DWARF 2, not STABS. */
834
  if (find_pc_partial_function (pc, NULL, &start_pc, NULL))
835
    {
836
      CORE_ADDR  prologue_end = skip_prologue_using_sal( gdbarch, pc );
837 227 jeremybenn
 
838 252 jeremybenn
      if (0 != prologue_end)
839
        {
840
          struct symtab_and_line  prologue_sal = find_pc_line (start_pc, 0);
841
          char *debug_format = prologue_sal.symtab->debugformat;
842 227 jeremybenn
 
843 252 jeremybenn
          if ((strlen ("dwarf") <= strlen (debug_format))
844
              && (0 == strncasecmp ("dwarf", debug_format, strlen ("dwarf"))))
845
            {
846
              return  (prologue_end > pc) ? prologue_end : pc;
847
            }
848
        }
849
    }
850
 
851 227 jeremybenn
  /* Look to see if we can find any of the standard prologue sequence. All
852
     quite difficult, since any or all of it may be missing. So this is just a
853
     best guess! */
854
  addr = pc;                            /* Where we have got to */
855
  inst = or32_fetch_instruction (gdbarch, addr);
856
 
857
  /* Look for the new stack pointer being set up. */
858
  if (or32_analyse_l_addi (inst, &rd, &ra, &simm) &&
859
      (OR32_SP_REGNUM == rd) && (OR32_SP_REGNUM == ra) &&
860
      (simm < 0) && (0 == (simm % 4)))
861
    {
862
      frame_size  = -simm;
863
      addr       += OR32_INSTLEN;
864
      inst        = or32_fetch_instruction (gdbarch, addr);
865
    }
866
 
867
  /* Look for the frame pointer being manipulated. */
868
  if (or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
869
      (OR32_SP_REGNUM == ra) && (OR32_FP_REGNUM == rb) &&
870
      (simm >= 0) && (0 == (simm % 4)))
871
    {
872
      addr += OR32_INSTLEN;
873
      inst  = or32_fetch_instruction (gdbarch, addr);
874
 
875
      gdb_assert (or32_analyse_l_addi (inst, &rd, &ra, &simm) &&
876
                  (OR32_FP_REGNUM == rd) && (OR32_SP_REGNUM == ra) &&
877
                  (simm == frame_size));
878
 
879
      addr += OR32_INSTLEN;
880
      inst  = or32_fetch_instruction (gdbarch, addr);
881
    }
882
 
883
  /* Look for the link register being saved */
884
  if (or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
885
      (OR32_SP_REGNUM == ra) && (OR32_LR_REGNUM == rb) &&
886
      (simm >= 0) && (0 == (simm % 4)))
887
    {
888
      addr += OR32_INSTLEN;
889
      inst  = or32_fetch_instruction (gdbarch, addr);
890
    }
891
 
892 244 jeremybenn
  /* Look for arguments or callee-saved register being saved. The register
893
     must be one of the arguments (r3-r8) or the 10 callee saved registers
894
     (r10, r12, r14, r16, r18, r20, r22, r24, r26, r28, r30). The base
895
     register must be the FP (for the args) or the SP (for the callee_saved
896
     registers). */
897 227 jeremybenn
  while (1)
898
    {
899
      if (or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
900 244 jeremybenn
          (((OR32_FP_REGNUM == ra) && or32_is_arg_reg (rb)) ||
901
           ((OR32_SP_REGNUM == ra) && or32_is_callee_saved_reg (rb))) &&
902
          (0 == (simm % 4)))
903 227 jeremybenn
        {
904
          addr += OR32_INSTLEN;
905
          inst  = or32_fetch_instruction (gdbarch, addr);
906
        }
907
      else
908
        {
909
          /* Nothing else to look for. We have found the end of the prologue. */
910
          return  addr;
911
        }
912
    }
913
}       /* or32_skip_prologue() */
914
 
915
 
916
/*----------------------------------------------------------------------------*/
917
/*!Align the stack frame
918
 
919
   OpenRISC 1000 uses a falling stack frame, so this aligns down to the
920
   nearest 8 bytes. Useful when we'be building a dummy frame.
921
 
922
   @param[in] gdbarch  The GDB architecture being used
923
   @param[in] sp       Current stack pointer
924
 
925
   @return  The aligned stack frame address */
926
/*---------------------------------------------------------------------------*/
927
 
928
static CORE_ADDR
929
or32_frame_align (struct gdbarch *gdbarch,
930
                  CORE_ADDR       sp)
931
{
932
  return align_down (sp, OR32_STACK_ALIGN);
933
 
934
}       /* or32_frame_align() */
935
 
936
 
937
/*----------------------------------------------------------------------------*/
938
/*!Unwind the program counter from a stack frame
939
 
940
   This just uses the built in frame unwinder
941
 
942
   @param[in] gdbarch     The GDB architecture being used
943
   @param[in] next_frame  Frame info for the NEXT frame
944
 
945
   @return  The program counter for THIS frame */
946
/*---------------------------------------------------------------------------*/
947
 
948
static CORE_ADDR
949
or32_unwind_pc (struct gdbarch    *gdbarch,
950
                struct frame_info *next_frame)
951
{
952
  CORE_ADDR pc = frame_unwind_register_unsigned (next_frame, OR32_NPC_REGNUM);
953
 
954
  return pc;
955
 
956
}       /* or32_unwind_pc() */
957
 
958
 
959
/*----------------------------------------------------------------------------*/
960
/*!Unwind the stack pointer from a stack frame
961
 
962
   This just uses the built in frame unwinder
963
 
964
   @param[in] gdbarch     The GDB architecture being used
965
   @param[in] next_frame  Frame info for the NEXT frame
966
 
967
   @return  The stack pointer for THIS frame */
968
/*---------------------------------------------------------------------------*/
969
 
970
static CORE_ADDR
971
or32_unwind_sp (struct gdbarch    *gdbarch,
972
                struct frame_info *next_frame)
973
{
974
  CORE_ADDR sp = frame_unwind_register_unsigned (next_frame, OR32_SP_REGNUM);
975
 
976
  return sp;
977
 
978
}       /* or32_unwind_sp() */
979
 
980
 
981
/*----------------------------------------------------------------------------*/
982
/*!Create a dummy stack frame
983
 
984
   The arguments are placed in registers and/or pushed on the stack as per the
985
   OR32 ABI.
986
 
987
   @param[in] gdbarch        The architecture to use
988
   @param[in] function       Pointer to the function that will be called
989
   @param[in] regcache       The register cache to use
990
   @param[in] bp_addr        Breakpoint address
991
   @param[in] nargs          Number of ags to push
992
   @param[in] args           The arguments
993
   @param[in] sp             The stack pointer
994
   @param[in] struct_return  True (1) if this returns a structure
995
   @param[in] struct_addr    Address for returning structures
996
 
997
   @return  The updated stack pointer */
998
/*---------------------------------------------------------------------------*/
999
 
1000
static CORE_ADDR
1001
or32_push_dummy_call (struct gdbarch  *gdbarch,
1002
                      struct value    *function,
1003
                      struct regcache *regcache,
1004
                      CORE_ADDR        bp_addr,
1005
                      int              nargs,
1006
                      struct value   **args,
1007
                      CORE_ADDR        sp,
1008
                      int              struct_return,
1009
                      CORE_ADDR        struct_addr)
1010
{
1011
  enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
1012
 
1013
  int             argreg;
1014
  int             argnum;
1015
  int             first_stack_arg;
1016
  int             stack_offset = 0;
1017
 
1018
  unsigned int    bpa = (gdbarch_tdep (gdbarch))->bytes_per_address;
1019
  unsigned int    bpw = (gdbarch_tdep (gdbarch))->bytes_per_word;
1020
 
1021
  /* Return address */
1022
  regcache_cooked_write_unsigned (regcache, OR32_LR_REGNUM, bp_addr);
1023
 
1024
  /* Register for the next argument */
1025
  argreg = OR32_FIRST_ARG_REGNUM;
1026
 
1027
  /* Location for a returned structure. This is passed as a silent first
1028
     argument. */
1029
 
1030
  if (struct_return)
1031
    {
1032
      regcache_cooked_write_unsigned (regcache, OR32_FIRST_ARG_REGNUM,
1033
                                      struct_addr);
1034
      argreg++;
1035
    }
1036
 
1037
  /* Put as many args as possible in registers */
1038
  for (argnum = 0; argnum < nargs; argnum++)
1039
    {
1040
      char           *val;
1041
      char            valbuf[sizeof (ULONGEST) ];
1042
 
1043
      struct value   *arg      = args[argnum];
1044
      struct type    *arg_type = check_typedef (value_type (arg));
1045
      int             len      = arg_type->length;
1046
      enum type_code  typecode = arg_type->main_type->code;
1047
 
1048
      /* The EABI passes structures that do not fit in a register by
1049
         reference. In all other cases, pass the structure by value.  */
1050
      if((len > bpw) &&
1051
         ((TYPE_CODE_STRUCT == typecode) || (TYPE_CODE_UNION == typecode)))
1052
        {
1053
 
1054
          store_unsigned_integer (valbuf, bpa, byte_order, value_offset (arg));
1055
          len      = bpa;
1056
          val      = valbuf;
1057
        }
1058
      else
1059
        {
1060
          val = (char *)value_contents (arg);
1061
        }
1062
 
1063
      if((len > bpw) && (argreg <= (OR32_LAST_ARG_REGNUM - 1)))
1064
        {
1065
 
1066 249 jeremybenn
          /* Big scalars use two registers, but need NOT be pair aligned. This
1067
             code breaks if we can have quad-word scalars (e.g. long
1068
             double). */
1069 227 jeremybenn
          ULONGEST regval = extract_unsigned_integer (val, len, byte_order);
1070
 
1071 249 jeremybenn
          unsigned int  bits_per_word = bpw * 8;
1072
          ULONGEST      mask          = (((ULONGEST) 1) << bits_per_word) - 1;
1073
          ULONGEST      lo            = regval & mask;
1074
          ULONGEST      hi            = regval >> bits_per_word;
1075
 
1076 227 jeremybenn
          gdb_assert (len <= (bpw * 2));
1077
 
1078 249 jeremybenn
          regcache_cooked_write_unsigned (regcache, argreg,     hi);
1079
          regcache_cooked_write_unsigned (regcache, argreg + 1, lo);
1080 227 jeremybenn
          argreg += 2;
1081
        }
1082
      else if (argreg <= OR32_LAST_ARG_REGNUM)
1083
        {
1084 249 jeremybenn
          printf ("Writing 0x%08llx to r%d\n",
1085
                  extract_unsigned_integer (val, len, byte_order), argreg);
1086
 
1087 227 jeremybenn
          regcache_cooked_write_unsigned (regcache, argreg,
1088
                                          extract_unsigned_integer (val, len,
1089
                                                                   byte_order));
1090
          argreg++;
1091
        }
1092
      else
1093
        {
1094
          /* Run out of regs */
1095
          break;
1096
        }
1097
    }
1098
 
1099
  first_stack_arg = argnum;
1100
 
1101
  /* If we get here with argnum < nargs, then arguments remain to be placed on
1102
     the stack. This is tricky, since they must be pushed in reverse order and
1103
     the stack in the end must be aligned. The only solution is to do it in
1104
     two stages, the first to compute the stack size, the second to save the
1105
     args. */
1106
 
1107
  for (argnum = first_stack_arg; argnum < nargs; argnum++)
1108
    {
1109
      struct value   *arg      = args[argnum];
1110
      struct type    *arg_type = check_typedef (value_type (arg));
1111
      int             len      = arg_type->length;
1112
      enum type_code  typecode = arg_type->main_type->code;
1113
 
1114
      if((len > bpw) &&
1115
         ((TYPE_CODE_STRUCT == typecode) || (TYPE_CODE_UNION == typecode)))
1116
        {
1117
          /* Large structures are passed as addresses */
1118
          sp -= bpa;
1119
        }
1120
      else
1121
        {
1122
        /* Big scalars use more than one word. Code here allows for future
1123
         quad-word entities (e.g. long double) */
1124
          sp -= ((len + bpw - 1) / bpw) * bpw;
1125
        }
1126
    }
1127
 
1128
  sp           = gdbarch_frame_align (gdbarch, sp);
1129
  stack_offset = 0;
1130
 
1131
  /* Push the remaining args on the stack */
1132
  for (argnum = first_stack_arg; argnum < nargs; argnum++)
1133
    {
1134
      char           *val;
1135
      char            valbuf[sizeof (ULONGEST) ];
1136
 
1137
      struct value   *arg      = args[argnum];
1138
      struct type    *arg_type = check_typedef (value_type (arg));
1139
      int             len      = arg_type->length;
1140
      enum type_code  typecode = arg_type->main_type->code;
1141
 
1142
      /* The EABI passes structures that do not fit in a register by
1143
         reference. In all other cases, pass the structure by value.  */
1144
      if((len > bpw) &&
1145
         ((TYPE_CODE_STRUCT == typecode) || (TYPE_CODE_UNION == typecode)))
1146
        {
1147
 
1148
          store_unsigned_integer (valbuf, bpa, byte_order, value_offset (arg));
1149
          len      = bpa;
1150
          val      = valbuf;
1151
        }
1152
      else
1153
        {
1154
          val = (char *)value_contents (arg);
1155
        }
1156
 
1157
      gdb_assert (len <= (bpw * 2));
1158
 
1159
      write_memory (sp + stack_offset, val, len);
1160
      stack_offset += ((len + bpw - 1) / bpw) * bpw;
1161
    }
1162
 
1163
  /* Save the updated stack pointer */
1164
  regcache_cooked_write_unsigned (regcache, OR32_SP_REGNUM, sp);
1165
 
1166
  return sp;
1167
 
1168
}       /* or32_push_dummy_call() */
1169
 
1170
 
1171
/*----------------------------------------------------------------------------*/
1172
/*!Return the frame ID for a dummy stack frame
1173
 
1174
   Tear down a dummy frame created by or32_push_dummy_call(). This data has to
1175
   be constructed manually from the data in our hand.
1176
 
1177
   The stack pointer and program counter can be obtained from the frame info.
1178
 
1179
   @param[in] gdbarch     The architecture to use
1180
   @param[in] this_frame  Information about this frame
1181
 
1182
   @return  Frame ID of this frame */
1183
/*---------------------------------------------------------------------------*/
1184
 
1185
static struct frame_id
1186
or32_dummy_id (struct gdbarch    *gdbarch,
1187
               struct frame_info *this_frame)
1188
{
1189
  return  frame_id_build (get_frame_sp (this_frame), get_frame_pc (this_frame));
1190
 
1191
}       /* or32_dummy_id() */
1192
 
1193
 
1194
 
1195
 
1196
/* Support functions for frame handling */
1197
 
1198
/* -------------------------------------------------------------------------- */
1199
/*!Initialize a prologue cache
1200
 
1201
   This function is changed from its GDB 6.8 version (named
1202
   or32_frame_unwind_cache), in that it is based on THIS frame, not the NEXT
1203
   frame.
1204
 
1205 249 jeremybenn
   We build a cache, saying where registers of the PREV frame can be found
1206
   from the data so far set up in this THIS.
1207 227 jeremybenn
 
1208 249 jeremybenn
   We also compute a unique ID for this frame, based on the function start
1209
   address and the stack pointer (as it will be, even if it has yet to be
1210
   computed.
1211
 
1212 227 jeremybenn
   STACK FORMAT
1213
   ============
1214
 
1215
   The OR32 has a falling stack frame and a simple prolog. The Stack pointer
1216
   is R1 and the frame pointer R2. The frame base is therefore the address
1217
   held in R2 and the stack pointer (R1) is the frame base of the NEXT frame.
1218
 
1219
   @verbatim
1220
   l.addi  r1,r1,-frame_size    # SP now points to end of new stack frame
1221
   @endverbatim
1222
 
1223
   The stack pointer may not be set up in a frameless function (e.g. a simple
1224
   leaf function).
1225
 
1226
   @verbatim
1227
   l.sw    fp_loc(r1),r2        # old FP saved in new stack frame
1228
   l.addi  r2,r1,frame_size     # FP now points to base of new stack frame
1229
   @endverbatim
1230
 
1231
   The frame pointer is not necessarily saved right at the end of the stack
1232
   frame - OR32 saves enough space for any args to called functions right at
1233
   the end (this is a difference from the Architecture Manual).
1234
 
1235
   @verbatim
1236
   l.sw    lr_loc(r1),r9        # Link (return) address
1237
   @endverbatim
1238
 
1239
   The link register is usally saved at fp_loc - 4. It may not be saved at all
1240
   in a leaf function.
1241
 
1242
   @verbatim
1243
   l.sw    reg_loc(r1),ry       # Save any callee saved regs
1244
   @endverbatim
1245
 
1246
   The offsets x for the callee saved registers generally (always?) rise in
1247
   increments of 4, starting at fp_loc + 4. If the frame pointer is omitted
1248
   (an option to GCC), then it may not be saved at all. There may be no callee
1249
   saved registers.
1250
 
1251
   So in summary none of this may be present. However what is present seems
1252
   always to follow this fixed order, and occur before any substantive code
1253
   (it is possible for GCC to have more flexible scheduling of the prologue,
1254
   but this does not seem to occur for OR32).
1255
 
1256
   ANALYSIS
1257
   ========
1258
 
1259
   This prolog is used, even for -O3 with GCC.
1260
 
1261
   All this analysis must allow for the possibility that the PC is in the
1262 249 jeremybenn
   middle of the prologue. Data in the cache should only be set up insofar as
1263
   it has been computed.
1264 227 jeremybenn
 
1265 249 jeremybenn
   HOWEVER. The frame_id must be created with the SP *as it will be* at the
1266
   end of the Prologue. Otherwise a recursive call, checking the frame with
1267
   the PC at the start address will end up with the same frame_id as the
1268
   caller.
1269
 
1270 227 jeremybenn
   A suite of "helper" routines are used, allowing reuse for
1271
   or32_skip_prologue().
1272
 
1273
   Reportedly, this is only valid for frames less than 0x7fff in size.
1274
 
1275
   @param[in]     this_frame      Our stack frame.
1276
   @param[in,out] prologue_cache  The prologue cache. If not supplied, we
1277
                                  build it.
1278
 
1279
   @return  The prolog cache (duplicates the return through the argument) */
1280
/* ---------------------------------------------------------------------------*/
1281
static struct trad_frame_cache *
1282
or32_frame_cache (struct frame_info  *this_frame,
1283
                  void              **prologue_cache)
1284
{
1285
  struct gdbarch          *gdbarch;
1286
  struct trad_frame_cache *info;
1287
 
1288
  CORE_ADDR                this_pc;
1289
  CORE_ADDR                this_sp;
1290 249 jeremybenn
  CORE_ADDR                this_sp_for_id;
1291 227 jeremybenn
  int                      frame_size = 0;
1292
 
1293
  CORE_ADDR                start_addr;
1294
  CORE_ADDR                end_addr;
1295
 
1296
  /* Nothing to do if we already have this info */
1297
  if (NULL != *prologue_cache)
1298
    {
1299
      return *prologue_cache;
1300
    }
1301
 
1302
  /* Get a new prologue cache and populate it with default values */
1303
  info                 = trad_frame_cache_zalloc (this_frame);
1304
  *prologue_cache = info;
1305
 
1306
  /* Find the start address of THIS function (which is a NORMAL frame, even if
1307
     the NEXT frame is the sentinel frame) and the end of its prologue.  */
1308
  this_pc = get_frame_pc (this_frame);
1309
  find_pc_partial_function (this_pc, NULL, &start_addr, NULL);
1310
 
1311
  /* Return early if GDB couldn't find the function.  */
1312
  if (start_addr == 0)
1313
    {
1314
      return  info;
1315
    }
1316
 
1317
  /* Get the stack pointer if we have one (if there's no process executing yet
1318
     we won't have a frame. */
1319
  this_sp = (NULL == this_frame) ? 0 :
1320
                                   get_frame_register_unsigned (this_frame,
1321
                                                                OR32_SP_REGNUM);
1322
 
1323 249 jeremybenn
  /* The default frame base of THIS frame (for ID purposes only - frame base
1324
     is an overloaded term) is its stack pointer. For now we use the value of
1325
     the SP register in THIS frame. However if the PC is in the prologue of
1326
     THIS frame, before the SP has been set up, then the value will actually
1327
     be that of the PREV frame, and we'll need to adjust it later. */
1328 227 jeremybenn
  trad_frame_set_this_base (info, this_sp);
1329 249 jeremybenn
  this_sp_for_id = this_sp;
1330 227 jeremybenn
 
1331
  /* The default is to find the PC of the PREVIOUS frame in the link register
1332
     of this frame. This may be changed if we find the link register was saved
1333
     on the stack. */
1334
  trad_frame_set_reg_realreg (info, OR32_NPC_REGNUM, OR32_LR_REGNUM);
1335
 
1336 249 jeremybenn
  /* We should only examine code that is in the prologue. This is all code up
1337
     to (but not including) end_addr. We should only populate the cache while
1338
     the address is up to (but not including) the PC or end_addr, whichever is
1339
     first. */
1340 227 jeremybenn
  gdbarch = get_frame_arch (this_frame);
1341
  end_addr = or32_skip_prologue (gdbarch, start_addr);
1342
 
1343
  /* All the following analysis only occurs if we are in the prologue and have
1344
     executed the code. Check we have a sane prologue size, and if zero we
1345
     are frameless and can give up here. */
1346
  if (end_addr < start_addr)
1347
    {
1348
      fatal ("end addr 0x%08x is less than start addr 0x%08x\n",
1349
             (unsigned int) end_addr, (unsigned int) start_addr);
1350
    }
1351
 
1352
  if (end_addr == start_addr)
1353
    {
1354
      frame_size = 0;
1355
    }
1356
  else
1357
    {
1358
      /* have a frame. Look for the various components */
1359
      CORE_ADDR  addr = start_addr;     /* Where we have got to */
1360
      uint32_t   inst = or32_fetch_instruction (gdbarch, addr);
1361
 
1362
      unsigned int  ra, rb, rd;         /* For instruction analysis */
1363
      int           simm;
1364
 
1365
      /* Look for the new stack pointer being set up. */
1366
      if (or32_analyse_l_addi (inst, &rd, &ra, &simm) &&
1367
          (OR32_SP_REGNUM == rd) && (OR32_SP_REGNUM == ra) &&
1368
          (simm < 0) && (0 == (simm % 4)))
1369
        {
1370
          frame_size  = -simm;
1371
          addr       += OR32_INSTLEN;
1372
          inst        = or32_fetch_instruction (gdbarch, addr);
1373
 
1374 249 jeremybenn
          /* If the PC has not actually got to this point, then the frame base
1375
             will be wrong, and we adjust it.
1376
 
1377
             If we are past this point, then we need to populate the stack
1378
             accoringly. */
1379
          if (this_pc <= addr)
1380
            {
1381
              /* Only do if executing */
1382
              if (0 != this_sp)
1383
                {
1384
                  this_sp_for_id = this_sp + frame_size;
1385
                  trad_frame_set_this_base (info, this_sp_for_id);
1386
                }
1387
            }
1388
          else
1389
            {
1390
              /* We are past this point, so the stack pointer of the PREV
1391
                 frame is frame_size greater than the stack pointer of THIS
1392
                 frame. */
1393
              trad_frame_set_reg_value (info, OR32_SP_REGNUM,
1394
                                        this_sp + frame_size);
1395
            }
1396 227 jeremybenn
        }
1397
 
1398 249 jeremybenn
      /* From now on we are only populating the cache, so we stop once we get
1399
         to either the end OR the current PC. */
1400
      end_addr = (this_pc < end_addr) ? this_pc : end_addr;
1401
 
1402 227 jeremybenn
      /* Look for the frame pointer being manipulated. */
1403
      if ((addr < end_addr) &&
1404
          or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
1405
          (OR32_SP_REGNUM == ra) && (OR32_FP_REGNUM == rb) &&
1406
          (simm >= 0) && (0 == (simm % 4)))
1407
        {
1408
          addr += OR32_INSTLEN;
1409
          inst  = or32_fetch_instruction (gdbarch, addr);
1410
 
1411
          /* At this stage, we can find the frame pointer of the PREVIOUS
1412
             frame on the stack of the current frame. */
1413
          trad_frame_set_reg_addr (info, OR32_FP_REGNUM, this_sp + simm);
1414
 
1415
          /* Look for the new frame pointer being set up */
1416
          if (addr < end_addr)
1417
            {
1418
              gdb_assert (or32_analyse_l_addi (inst, &rd, &ra, &simm) &&
1419
                          (OR32_FP_REGNUM == rd) && (OR32_SP_REGNUM == ra) &&
1420
                          (simm == frame_size));
1421
 
1422
              addr += OR32_INSTLEN;
1423
              inst  = or32_fetch_instruction (gdbarch, addr);
1424
 
1425
              /* If we have got this far, the stack pointer of the PREVIOUS
1426
                 frame is the frame pointer of THIS frame. */
1427
              trad_frame_set_reg_realreg (info, OR32_SP_REGNUM, OR32_FP_REGNUM);
1428
            }
1429
        }
1430
 
1431
      /* Look for the link register being saved */
1432
      if ((addr < end_addr) &&
1433
          or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
1434
          (OR32_SP_REGNUM == ra) && (OR32_LR_REGNUM == rb) &&
1435
          (simm >= 0) && (0 == (simm % 4)))
1436
        {
1437
          addr += OR32_INSTLEN;
1438
          inst  = or32_fetch_instruction (gdbarch, addr);
1439
 
1440
          /* If the link register is saved in the THIS frame, it holds the
1441
             value of the PC in the PREVIOUS frame. This overwrites the
1442
             previous information about finding the PC in the link
1443
             register. */
1444
          trad_frame_set_reg_addr (info, OR32_NPC_REGNUM, this_sp + simm);
1445
        }
1446
 
1447 244 jeremybenn
      /* Look for arguments or callee-saved register being saved. The register
1448
         must be one of the arguments (r3-r8) or the 10 callee saved registers
1449
         (r10, r12, r14, r16, r18, r20, r22, r24, r26, r28, r30). The base
1450
         register must be the FP (for the args) or the SP (for the
1451
         callee_saved registers). */
1452 227 jeremybenn
      while (addr < end_addr)
1453
        {
1454
          if (or32_analyse_l_sw (inst, &simm, &ra, &rb) &&
1455 244 jeremybenn
              (((OR32_FP_REGNUM == ra) && or32_is_arg_reg (rb)) ||
1456
               ((OR32_SP_REGNUM == ra) && or32_is_callee_saved_reg (rb))) &&
1457
              (0 == (simm % 4)))
1458 227 jeremybenn
            {
1459
              addr += OR32_INSTLEN;
1460
              inst  = or32_fetch_instruction (gdbarch, addr);
1461
 
1462
              /* The register in the PREVIOUS frame can be found at this
1463
                 location in THIS frame */
1464
              trad_frame_set_reg_addr (info, rb, this_sp + simm);
1465
            }
1466
          else
1467
            {
1468
              break;                    /* Not a register save instruction */
1469
            }
1470
        }
1471
    }
1472
 
1473
  /* Build the frame ID */
1474 249 jeremybenn
  trad_frame_set_id (info, frame_id_build (this_sp_for_id, start_addr));
1475 227 jeremybenn
 
1476
  return info;
1477
 
1478
}       /* or32_frame_cache() */
1479
 
1480
 
1481
/* -------------------------------------------------------------------------- */
1482
/*!Find the frame ID of this frame
1483
 
1484
   This function has changed since GDB 6.8 to use THIS frame, rather than the
1485
   NEXT frame.
1486
 
1487
   Given a GDB frame, return its frame_id.
1488
 
1489
   @param[in]  this_frame      Our frame, for which the ID is wanted.
1490
   @param[in]  prologue_cache  Any cached prologue for THIS function.
1491
   @param[out] this_id         Frame ID of our own frame.
1492
 
1493
   @return  Frame ID for THIS frame */
1494
/* ------------------------------------------------------------------------- */
1495
static void
1496
or32_frame_this_id (struct frame_info  *this_frame,
1497
                    void              **prologue_cache,
1498
                    struct frame_id    *this_id)
1499
{
1500
  struct trad_frame_cache *info =
1501
    or32_frame_cache (this_frame, prologue_cache);
1502
 
1503
  trad_frame_get_id (info, this_id);
1504
 
1505
}       /* or32_frame_this_id() */
1506
 
1507
 
1508
/*----------------------------------------------------------------------------*/
1509
/*!Get a register from the PREVIOUS frame
1510
 
1511
   This function has changed from GDB 6.8. It now takes a reference to THIS
1512
   frame, not the NEXT frame. It returns it results via a structure, not its
1513
   argument list.
1514
 
1515
   Given a pointer to the THIS frame, return the details of a register in the
1516
   PREVIOUS frame.
1517
 
1518
   @param[in] this_frame      The stack frame under consideration
1519
   @param[in] prologue_cache  Any cached prologue associated with THIS frame,
1520
                              which may therefore tell us about registers in
1521
                              the PREVIOUS frame.
1522
   @param[in] regnum          The register of interest in the PREVIOUS frame
1523
 
1524
   @return  A value structure representing the register.                      */
1525
/* -------------------------------------------------------------------------- */
1526
static struct value *
1527
or32_frame_prev_register (struct frame_info  *this_frame,
1528
                          void              **prologue_cache,
1529
                          int                 regnum)
1530
{
1531
  struct trad_frame_cache *info = or32_frame_cache (this_frame,
1532
                                                    prologue_cache);
1533
 
1534
  return  trad_frame_get_register (info, this_frame, regnum);
1535
 
1536
}       /* or32_frame_prev_register() */
1537
 
1538
 
1539
/* -------------------------------------------------------------------------- */
1540
/*!Structure defining the OR32 frame unwind functions
1541
 
1542
   Must be global (to this file), since referred to by multiple functions.
1543
 
1544
   Since we are the fallback unwinder, we use the default frame sniffer, which
1545
   always accepts the frame
1546
 
1547
   This applies to NORMAL frames only. We provide the following functions.
1548
   - to give the ID of THIS frame
1549
   - to give the details of a register in PREVIOUS frame
1550
   - a frame sniffer.                                                         */
1551
/* -------------------------------------------------------------------------- */
1552
static const struct frame_unwind or32_frame_unwind = {
1553
  .type          = NORMAL_FRAME,
1554
  .this_id       = or32_frame_this_id,
1555
  .prev_register = or32_frame_prev_register,
1556
  .unwind_data   = NULL,
1557
  .sniffer       = default_frame_sniffer,
1558
  .dealloc_cache = NULL,
1559
  .prev_arch     = NULL
1560
};
1561
 
1562
 
1563
/*----------------------------------------------------------------------------*/
1564
/*!Return the base address of the frame
1565
 
1566
   The implementations has changed since GDB 6.8, since we are now provided
1567
   with the address of THIS frame, rather than the NEXT frame.
1568
 
1569 244 jeremybenn
   For the OR32, the base address is the frame pointer
1570 227 jeremybenn
 
1571
   @param[in] this_frame      The current stack frame.
1572
   @param[in] prologue_cache  Any cached prologue for THIS function.
1573
 
1574
   @return  The frame base address */
1575
/*---------------------------------------------------------------------------*/
1576
 
1577
static CORE_ADDR
1578
or32_frame_base_address (struct frame_info  *this_frame,
1579
                         void              **prologue_cache)
1580
{
1581 244 jeremybenn
  return  (CORE_ADDR) get_frame_register_unsigned (this_frame, OR32_FP_REGNUM);
1582 227 jeremybenn
 
1583
}       /* or32_frame_base_address() */
1584
 
1585
 
1586
/* -------------------------------------------------------------------------- */
1587
/*!Identify our frame base sniffer functions
1588
 
1589
   This function just identifies our family of frame sniffing functions.
1590
 
1591
   @param[in] this_frame  The frame of THIS function. Not used here.
1592
 
1593
   @return  A pointer to a struct identifying the frame base sniffing
1594
            functions.                                                        */
1595
/* -------------------------------------------------------------------------- */
1596
static const struct frame_base *
1597
or32_frame_base_sniffer (struct frame_info *this_frame)
1598
{
1599
  /* Structure defining how the frame base is to be identified. */
1600
  static const struct frame_base  or32_frame_base =
1601
    {
1602
      .unwind      = &or32_frame_unwind,
1603
      .this_base   = or32_frame_base_address,
1604
      .this_locals = or32_frame_base_address,
1605
      .this_args   = or32_frame_base_address
1606
    };
1607
 
1608
  return &or32_frame_base;
1609
 
1610
}       /* or32_frame_base_sniffer () */
1611
 
1612
 
1613
/* -------------------------------------------------------------------------- */
1614
/*!Architecture initialization for OpenRISC 1000
1615
 
1616
   Looks for a candidate architecture in the list of architectures supplied
1617
   using the info supplied. If none match, create a new architecture.
1618
 
1619
   @param[in] info    Information about the target architecture
1620
   @param[in] arches  The list of currently know architectures
1621
 
1622
   @return  A structure describing the target architecture                    */
1623
/* -------------------------------------------------------------------------- */
1624
static struct gdbarch *
1625
or32_gdbarch_init (struct gdbarch_info  info,
1626
                   struct gdbarch_list *arches)
1627
{
1628
  static struct frame_base     or32_frame_base;
1629
  struct        gdbarch       *gdbarch;
1630
  struct        gdbarch_tdep  *tdep;
1631
  const struct  bfd_arch_info *binfo;
1632
 
1633
  /* Find a candidate among the list of pre-declared architectures.  */
1634
  arches = gdbarch_list_lookup_by_info (arches, &info);
1635
  if (NULL != arches)
1636
    {
1637
      return arches->gdbarch;
1638
    }
1639
 
1640
  /* None found, create a new architecture from the information
1641
     provided. Can't initialize all the target dependencies until we actually
1642
     know which target we are talking to, but put in some defaults for now. */
1643
 
1644
  binfo                   = info.bfd_arch_info;
1645
  tdep                    = xmalloc (sizeof *tdep);
1646
  tdep->num_matchpoints   = OR32_MAX_MATCHPOINTS;
1647
  tdep->num_gpr_regs      = OR32_MAX_GPR_REGS;
1648
  tdep->bytes_per_word    = binfo->bits_per_word    / binfo->bits_per_byte;
1649
  tdep->bytes_per_address = binfo->bits_per_address / binfo->bits_per_byte;
1650
  gdbarch                 = gdbarch_alloc (&info, tdep);
1651
 
1652
  /* Target data types.  */
1653
  set_gdbarch_short_bit             (gdbarch, 16);
1654
  set_gdbarch_int_bit               (gdbarch, 32);
1655
  set_gdbarch_long_bit              (gdbarch, 32);
1656
  set_gdbarch_long_long_bit         (gdbarch, 64);
1657
  set_gdbarch_float_bit             (gdbarch, 32);
1658
  set_gdbarch_float_format          (gdbarch, floatformats_ieee_single);
1659
  set_gdbarch_double_bit            (gdbarch, 64);
1660
  set_gdbarch_double_format         (gdbarch, floatformats_ieee_double);
1661
  set_gdbarch_long_double_bit       (gdbarch, 64);
1662
  set_gdbarch_long_double_format    (gdbarch, floatformats_ieee_double);
1663
  set_gdbarch_ptr_bit               (gdbarch, binfo->bits_per_address);
1664
  set_gdbarch_addr_bit              (gdbarch, binfo->bits_per_address);
1665
  set_gdbarch_char_signed           (gdbarch, 1);
1666
 
1667
  /* Information about the target architecture */
1668
  set_gdbarch_return_value          (gdbarch, or32_return_value);
1669
  set_gdbarch_breakpoint_from_pc    (gdbarch, or32_breakpoint_from_pc);
1670
  set_gdbarch_single_step_through_delay
1671
                                    (gdbarch, or32_single_step_through_delay);
1672
  set_gdbarch_have_nonsteppable_watchpoint
1673
                                    (gdbarch, 1);
1674
  switch (gdbarch_byte_order (gdbarch))
1675
    {
1676
    case BFD_ENDIAN_BIG:
1677
      set_gdbarch_print_insn        (gdbarch, print_insn_big_or32);
1678
      break;
1679
 
1680
    case BFD_ENDIAN_LITTLE:
1681
      set_gdbarch_print_insn        (gdbarch, print_insn_little_or32);
1682
      break;
1683
 
1684
    case BFD_ENDIAN_UNKNOWN:
1685
      error ("or32_gdbarch_init: Unknown endianness");
1686
      break;
1687
    }
1688
 
1689
  /* Register architecture */
1690
  set_gdbarch_pseudo_register_read  (gdbarch, or32_pseudo_register_read);
1691
  set_gdbarch_pseudo_register_write (gdbarch, or32_pseudo_register_write);
1692
  set_gdbarch_num_regs              (gdbarch, OR32_NUM_REGS);
1693
  set_gdbarch_num_pseudo_regs       (gdbarch, OR32_NUM_PSEUDO_REGS);
1694
  set_gdbarch_sp_regnum             (gdbarch, OR32_SP_REGNUM);
1695
  set_gdbarch_pc_regnum             (gdbarch, OR32_NPC_REGNUM);
1696
  set_gdbarch_ps_regnum             (gdbarch, OR32_SR_REGNUM);
1697
  set_gdbarch_deprecated_fp_regnum  (gdbarch, OR32_FP_REGNUM);
1698
 
1699
  /* Functions to supply register information */
1700
  set_gdbarch_register_name         (gdbarch, or32_register_name);
1701
  set_gdbarch_register_type         (gdbarch, or32_register_type);
1702
  set_gdbarch_print_registers_info  (gdbarch, or32_registers_info);
1703
  set_gdbarch_register_reggroup_p   (gdbarch, or32_register_reggroup_p);
1704
 
1705
  /* Functions to analyse frames */
1706
  set_gdbarch_skip_prologue         (gdbarch, or32_skip_prologue);
1707
  set_gdbarch_inner_than            (gdbarch, core_addr_lessthan);
1708
  set_gdbarch_frame_align           (gdbarch, or32_frame_align);
1709
  set_gdbarch_frame_red_zone_size   (gdbarch, OR32_FRAME_RED_ZONE_SIZE);
1710
 
1711
  /* Functions to access frame data */
1712
  set_gdbarch_unwind_pc             (gdbarch, or32_unwind_pc);
1713
  set_gdbarch_unwind_sp             (gdbarch, or32_unwind_sp);
1714
 
1715
  /* Functions handling dummy frames */
1716
  set_gdbarch_push_dummy_call       (gdbarch, or32_push_dummy_call);
1717
  set_gdbarch_dummy_id              (gdbarch, or32_dummy_id);
1718
 
1719
  /* Set up sniffers for the frame base. Use DWARF debug info if available,
1720
     otherwise use our own sniffer. */
1721
  frame_base_append_sniffer (gdbarch, dwarf2_frame_base_sniffer);
1722
  frame_base_append_sniffer (gdbarch, or32_frame_base_sniffer);
1723
 
1724
  /* Frame unwinders. Use DWARF debug info if available, otherwise use our
1725
     own unwinder. */
1726
  dwarf2_append_unwinders (gdbarch);
1727
  frame_unwind_append_unwinder (gdbarch, &or32_frame_unwind);
1728
 
1729
  return gdbarch;
1730
 
1731
}       /* or32_gdbarch_init() */
1732
 
1733
 
1734
/*----------------------------------------------------------------------------*/
1735
/*!Dump the target specific data for this architecture
1736
 
1737
   @param[in] gdbarch  The architecture of interest
1738
   @param[in] file     Where to dump the data */
1739
/*---------------------------------------------------------------------------*/
1740
 
1741
static void
1742
or32_dump_tdep (struct gdbarch *gdbarch,
1743
                struct ui_file *file)
1744
{
1745
  struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
1746
 
1747
  if (NULL == tdep)
1748
    {
1749
      return;                   /* Nothing to report */
1750
    }
1751
 
1752
  fprintf_unfiltered (file, "or32_dump_tdep: %d matchpoints available\n",
1753
                      tdep->num_matchpoints);
1754
  fprintf_unfiltered (file, "or32_dump_tdep: %d general purpose registers\n",
1755
                      tdep->num_gpr_regs);
1756
  fprintf_unfiltered (file, "or32_dump_tdep: %d bytes per word\n",
1757
                      tdep->bytes_per_word);
1758
  fprintf_unfiltered (file, "or32_dump_tdep: %d bytes per address\n",
1759
                      tdep->bytes_per_address);
1760
 
1761
}       /* or32_dump_tdep() */
1762
 
1763
 
1764
 
1765
/* Functions to add extra commands to GDB */
1766
 
1767
 
1768
/*----------------------------------------------------------------------------*/
1769
/*!Returns a special purpose register group name
1770
 
1771
   @param[in]  group  The SPR group number
1772
 
1773
   @return  The SPR name (pointer to the name argument) */
1774
/*---------------------------------------------------------------------------*/
1775
 
1776
static const char *
1777
or32_spr_group_name (int  group)
1778
{
1779
  static const char *or32_group_names[OR32_NUM_SPGS] =
1780
    {
1781
      "SYS",
1782
      "DMMU",
1783
      "IMMU",
1784
      "DCACHE",
1785
      "ICACHE",
1786
      "MAC",
1787
      "DEBUG",
1788
      "PERF",
1789
      "POWER",
1790
      "PIC",
1791
      "TIMER",
1792
      "FPU"
1793
    };
1794
 
1795
  if ((0 <= group) && (group < OR32_NUM_SPGS))
1796
    {
1797
      return or32_group_names[group];
1798
    }
1799
  else
1800
    {
1801
      return "";
1802
    }
1803
}       /* or32_spr_group_name() */
1804
 
1805
 
1806
/*----------------------------------------------------------------------------*/
1807
/*!Returns a special purpose register name
1808
 
1809
   @param[in]  group  The SPR group
1810
   @param[in]  index  The index within the SPR group
1811
   @param[out] name   Array to put the name in
1812
 
1813
   @return  The SPR name (pointer to the name argument) */
1814
/*---------------------------------------------------------------------------*/
1815
 
1816
static char *
1817
or32_spr_register_name (int   group,
1818
                        int   index,
1819
                        char *name)
1820
{
1821
  char di;
1822
 
1823
  switch (group)
1824
    {
1825
 
1826
    case OR32_SPG_SYS:
1827
      /* 1:1 names */
1828
      switch (index)
1829
        {
1830
        case OR32_SPG_SYS_VR:       sprintf (name, "VR"      ); return  name;
1831
        case OR32_SPG_SYS_UPR:      sprintf (name, "UPR"     ); return  name;
1832
        case OR32_SPG_SYS_CPUCFGR:  sprintf (name, "CPUCFGR" ); return  name;
1833
        case OR32_SPG_SYS_DMMUCFGR: sprintf (name, "DMMUCFGR"); return  name;
1834
        case OR32_SPG_SYS_IMMUCFGR: sprintf (name, "IMMUCFGR"); return  name;
1835
        case OR32_SPG_SYS_DCCFGR:   sprintf (name, "DCCFGR"  ); return  name;
1836
        case OR32_SPG_SYS_ICCFGR:   sprintf (name, "ICCFGR"  ); return  name;
1837
        case OR32_SPG_SYS_DCFGR:    sprintf (name, "DCFGR"   ); return  name;
1838
        case OR32_SPG_SYS_PCCFGR:   sprintf (name, "PCCFGR"  ); return  name;
1839
        case OR32_SPG_SYS_NPC:      sprintf (name, "NPC"     ); return  name;
1840
        case OR32_SPG_SYS_SR:       sprintf (name, "SR"      ); return  name;
1841
        case OR32_SPG_SYS_PPC:      sprintf (name, "PPC"     ); return  name;
1842
        case OR32_SPG_SYS_FPCSR:    sprintf (name, "FPCSR"   ); return  name;
1843
        }
1844
 
1845
      /* Exception PC regs */
1846
      if((OR32_SPG_SYS_EPCR <= index) &&
1847
         (index             <= OR32_SPG_SYS_EPCR_END))
1848
        {
1849
          sprintf (name, "EPCR%d", index - OR32_SPG_SYS_EPCR);
1850
          return  name;
1851
        }
1852
 
1853
      /* Exception EA regs */
1854
      if((OR32_SPG_SYS_EEAR <= index) &&
1855
         (index             <= OR32_SPG_SYS_EEAR_END))
1856
        {
1857
          sprintf (name, "EEAR%d", index - OR32_SPG_SYS_EEAR);
1858
          return  name;
1859
        }
1860
 
1861
      /* Exception SR regs */
1862
      if((OR32_SPG_SYS_ESR <= index) &&
1863
         (index            <= OR32_SPG_SYS_ESR_END))
1864
        {
1865
          sprintf (name, "ESR%d", index - OR32_SPG_SYS_ESR);
1866
          return  name;
1867
        }
1868
 
1869
      /* GPRs */
1870
      if((OR32_SPG_SYS_GPR <= index) &&
1871
         (index            <= OR32_SPG_SYS_GPR_END))
1872
        {
1873
          sprintf (name, "GPR%d", index - OR32_SPG_SYS_GPR);
1874
          return  name;
1875
        }
1876
 
1877
      break;
1878
 
1879
    case OR32_SPG_DMMU:
1880
    case OR32_SPG_IMMU:
1881
      /* MMU registers. Use DMMU constants throughout, but these are identical
1882
         to the corresponding IMMU constants */
1883
      di = OR32_SPG_DMMU == group ? 'D' : 'I';
1884
 
1885
      /* 1:1 names */
1886
      switch (index)
1887
        {
1888
        case OR32_SPG_DMMU_DMMUCR:
1889
          sprintf (name, "%cMMUCR",  di); return  name;
1890
        case OR32_SPG_DMMU_DMMUPR:
1891
          sprintf (name, "%cMMUPR",  di); return  name;
1892
        case OR32_SPG_DMMU_DTLBEIR:
1893
          sprintf (name, "%cTLBEIR", di); return  name;
1894
        }
1895
 
1896
      /* ATB Match registers */
1897
      if((OR32_SPG_DMMU_DATBMR <= index) &&
1898
         (index                <= OR32_SPG_DMMU_DATBMR_END))
1899
        {
1900
          sprintf (name, "%cATBMR%d", di, index - OR32_SPG_DMMU_DATBMR);
1901
          return  name;
1902
        }
1903
 
1904
      /* ATB Translate registers */
1905
      if((OR32_SPG_DMMU_DATBTR <= index) &&
1906
         (index                <= OR32_SPG_DMMU_DATBTR_END))
1907
        {
1908
          sprintf (name, "%cATBTR%d", di, index - OR32_SPG_DMMU_DATBTR);
1909
          return  name;
1910
        }
1911
 
1912
      /* TLB Way 1 Match registers */
1913
      if((OR32_SPG_DMMU_DTLBW1MR <= index) &&
1914
         (index                <= OR32_SPG_DMMU_DTLBW1MR_END))
1915
        {
1916
          sprintf (name, "%cTLBW1MR%d", di, index - OR32_SPG_DMMU_DTLBW1MR);
1917
          return  name;
1918
        }
1919
 
1920
      /* TLB Way 1 Translate registers */
1921
      if((OR32_SPG_DMMU_DTLBW1TR <= index) &&
1922
         (index                <= OR32_SPG_DMMU_DTLBW1TR_END))
1923
        {
1924
          sprintf (name, "%cTLBW1TR%d", di, index - OR32_SPG_DMMU_DTLBW1TR);
1925
          return  name;
1926
        }
1927
 
1928
      /* TLB Way 2 Match registers */
1929
      if((OR32_SPG_DMMU_DTLBW2MR <= index) &&
1930
         (index                <= OR32_SPG_DMMU_DTLBW2MR_END))
1931
        {
1932
          sprintf (name, "%cTLBW2MR%d", di, index - OR32_SPG_DMMU_DTLBW2MR);
1933
          return  name;
1934
        }
1935
 
1936
      /* TLB Way 2 Translate registers */
1937
      if((OR32_SPG_DMMU_DTLBW2TR <= index) &&
1938
         (index                <= OR32_SPG_DMMU_DTLBW2TR_END))
1939
        {
1940
          sprintf (name, "%cTLBW2TR%d", di, index - OR32_SPG_DMMU_DTLBW2TR);
1941
          return  name;
1942
        }
1943
 
1944
      /* TLB Way 3 Match registers */
1945
      if((OR32_SPG_DMMU_DTLBW3MR <= index) &&
1946
         (index                <= OR32_SPG_DMMU_DTLBW3MR_END))
1947
        {
1948
          sprintf (name, "%cTLBW3MR%d", di, index - OR32_SPG_DMMU_DTLBW3MR);
1949
          return  name;
1950
        }
1951
 
1952
      /* TLB Way 3 Translate registers */
1953
      if((OR32_SPG_DMMU_DTLBW3TR <= index) &&
1954
         (index                <= OR32_SPG_DMMU_DTLBW3TR_END))
1955
        {
1956
          sprintf (name, "%cTLBW3TR%d", di, index - OR32_SPG_DMMU_DTLBW3TR);
1957
          return  name;
1958
        }
1959
 
1960
      break;
1961
 
1962
    case OR32_SPG_DC:
1963
      /* Data cache registers. These do not have an exact correspondence with
1964
         their instruction cache counterparts, so must be done separately. */
1965
 
1966
      /* 1:1 names */
1967
      switch (index)
1968
        {
1969
        case OR32_SPG_DC_DCCR:  sprintf (name, "DCCR" ); return  name;
1970
        case OR32_SPG_DC_DCBPR: sprintf (name, "DCBPR"); return  name;
1971
        case OR32_SPG_DC_DCBFR: sprintf (name, "DCBFR"); return  name;
1972
        case OR32_SPG_DC_DCBIR: sprintf (name, "DCBIR"); return  name;
1973
        case OR32_SPG_DC_DCBWR: sprintf (name, "DCBWR"); return  name;
1974
        case OR32_SPG_DC_DCBLR: sprintf (name, "DCBLR"); return  name;
1975
        }
1976
 
1977
      break;
1978
 
1979
    case OR32_SPG_IC:
1980
      /* Instruction cache registers */
1981
 
1982
      /* 1:1 names */
1983
      switch (index)
1984
        {
1985
        case OR32_SPG_IC_ICCR:  sprintf (name, "ICCR" ); return  name;
1986
        case OR32_SPG_IC_ICBPR: sprintf (name, "ICBPR"); return  name;
1987
        case OR32_SPG_IC_ICBIR: sprintf (name, "ICBIR"); return  name;
1988
        case OR32_SPG_IC_ICBLR: sprintf (name, "ICBLR"); return  name;
1989
        }
1990
 
1991
      break;
1992
 
1993
    case OR32_SPG_MAC:
1994
      /* MAC registers */
1995
 
1996
      /* 1:1 names */
1997
      switch (index)
1998
        {
1999
        case OR32_SPG_MAC_MACLO: sprintf (name, "MACLO"); return  name;
2000
        case OR32_SPG_MAC_MACHI: sprintf (name, "MACHI"); return  name;
2001
        }
2002
 
2003
      break;
2004
 
2005
    case OR32_SPG_DEBUG:
2006
      /* Debug registers */
2007
 
2008
      /* Debug Value registers */
2009
      if((OR32_SPG_DEBUG_DVR <= index) &&
2010
         (index                <= OR32_SPG_DEBUG_DVR_END))
2011
        {
2012
          sprintf (name, "DVR%d", index - OR32_SPG_DEBUG_DVR);
2013
          return  name;
2014
        }
2015
 
2016
      /* Debug Control registers */
2017
      if((OR32_SPG_DEBUG_DCR <= index) &&
2018
         (index                <= OR32_SPG_DEBUG_DCR_END))
2019
        {
2020
          sprintf (name, "DCR%d", index - OR32_SPG_DEBUG_DCR);
2021
          return  name;
2022
        }
2023
 
2024
      /* 1:1 names */
2025
      switch (index)
2026
        {
2027
        case OR32_SPG_DEBUG_DMR1:  sprintf (name, "DMR1" ); return  name;
2028
        case OR32_SPG_DEBUG_DMR2:  sprintf (name, "DMR2" ); return  name;
2029
        case OR32_SPG_DEBUG_DCWR0: sprintf (name, "DCWR0"); return  name;
2030
        case OR32_SPG_DEBUG_DCWR1: sprintf (name, "DCWR1"); return  name;
2031
        case OR32_SPG_DEBUG_DSR:   sprintf (name, "DSR"  ); return  name;
2032
        case OR32_SPG_DEBUG_DRR:   sprintf (name, "DRR"  ); return  name;
2033
        }
2034
 
2035
      break;
2036
 
2037
    case OR32_SPG_PC:
2038
      /* Performance Counter registers */
2039
 
2040
      /* Performance Counters Count registers */
2041
      if((OR32_SPG_PC_PCCR <= index) &&
2042
         (index                <= OR32_SPG_PC_PCCR_END))
2043
        {
2044
          sprintf (name, "PCCR%d", index - OR32_SPG_PC_PCCR);
2045
          return  name;
2046
        }
2047
 
2048
      /* Performance Counters Mode registers */
2049
      if((OR32_SPG_PC_PCMR <= index) &&
2050
         (index                <= OR32_SPG_PC_PCMR_END))
2051
        {
2052
          sprintf (name, "PCMR%d", index - OR32_SPG_PC_PCMR);
2053
          return  name;
2054
        }
2055
 
2056
      break;
2057
 
2058
    case OR32_SPG_PM:
2059
      /* Power Management registers */
2060
 
2061
      /* 1:1 names */
2062
      switch (index)
2063
        {
2064
        case OR32_SPG_PM_PMR:  sprintf (name, "PMR"); return  name;
2065
        }
2066
 
2067
      break;
2068
 
2069
    case OR32_SPG_PIC:
2070
      /* Programmable Interrupt Controller registers */
2071
 
2072
      /* 1:1 names */
2073
      switch (index)
2074
        {
2075
        case OR32_SPG_PIC_PICMR:  sprintf (name, "PICMR"); return  name;
2076
        case OR32_SPG_PIC_PICSR:  sprintf (name, "PICSR"); return  name;
2077
        }
2078
 
2079
      break;
2080
 
2081
    case OR32_SPG_TT:
2082
      /* Tick Timer registers */
2083
 
2084
      /* 1:1 names */
2085
      switch (index)
2086
        {
2087
        case OR32_SPG_TT_TTMR:  sprintf (name, "TTMR"); return  name;
2088
        case OR32_SPG_TT_TTCR:  sprintf (name, "TTCR"); return  name;
2089
        }
2090
 
2091
      break;
2092
 
2093
    case OR32_SPG_FPU:
2094
 
2095
      break;
2096
    }
2097
 
2098
  /* Not a recognized register */
2099
  strcpy (name, "");
2100
  return  name;
2101
 
2102
}       /* or32_spr_register_name() */
2103
 
2104
 
2105
/*----------------------------------------------------------------------------*/
2106
/*!Get SPR group number from a name
2107
 
2108
   @param[in] group_name  SPR register group
2109
 
2110
   @return  The index, or negative if no match. */
2111
/*----------------------------------------------------------------------------*/
2112
 
2113
static int
2114
or32_groupnum_from_name (char *group_name)
2115
{
2116
  int  group;
2117
 
2118
  for (group = 0; group < OR32_NUM_SPGS; group++)
2119
    {
2120
      if (0 == strcasecmp (group_name, or32_spr_group_name (group)))
2121
        {
2122
          return group;
2123
        }
2124
    }
2125
 
2126
  return -1;
2127
 
2128
}       /* or32_groupnum_from_name() */
2129
 
2130
 
2131
/*----------------------------------------------------------------------------*/
2132
/*!Get register index in special purpose register group from name
2133
 
2134
   The name may either be SPR<group_num>_<index> or a known unique name. In
2135
   either case the group number must match the supplied group number.
2136
 
2137
   @param[in] group  SPR register group
2138
   @param[in] name   Register name
2139
 
2140
   @return  The index, or negative if no match. */
2141
/*----------------------------------------------------------------------------*/
2142
 
2143
static int
2144
or32_regnum_from_name (int   group,
2145
                       char *name)
2146
{
2147
  /* Last valid register in each group. */
2148
  static const int  or32_spr_group_last[OR32_NUM_SPGS] =
2149
    {
2150
      OR32_SPG_SYS_LAST,
2151
      OR32_SPG_DMMU_LAST,
2152
      OR32_SPG_IMMU_LAST,
2153
      OR32_SPG_DC_LAST,
2154
      OR32_SPG_IC_LAST,
2155
      OR32_SPG_MAC_LAST,
2156
      OR32_SPG_DEBUG_LAST,
2157
      OR32_SPG_PC_LAST,
2158
      OR32_SPG_PM_LAST,
2159
      OR32_SPG_PIC_LAST,
2160
      OR32_SPG_TT_LAST,
2161
      OR32_SPG_FPU_LAST
2162
    };
2163
 
2164
  int  i;
2165
  char  spr_name[32];
2166
 
2167
  if (0 == strcasecmp (name, "SPR"))
2168
    {
2169
      char *ptr_c;
2170
 
2171
      /* Skip SPR */
2172
      name += 3;
2173
 
2174
      /* Get group number */
2175
      i = (int) strtoul (name, &ptr_c, 10);
2176
      if (*ptr_c != '_' || i != group)
2177
        {
2178
          return -1;
2179
        }
2180
 
2181
      /* Get index */
2182
      ptr_c++;
2183
      i = (int) strtoul (name, &ptr_c, 10);
2184
      if (*ptr_c)
2185
        {
2186
          return -1;
2187
        }
2188
      else
2189
        {
2190
          return  i;
2191
        }
2192
    }
2193
 
2194
  /* Look for a "known" name in this group */
2195
  for (i = 0; i <= or32_spr_group_last[group]; i++)
2196
    {
2197
      char *s = or32_spr_register_name (group, i, spr_name);
2198
 
2199
      if (0 == strcasecmp (name, s))
2200
        {
2201
          return i;
2202
        }
2203
    }
2204
 
2205
  /* Failure */
2206
  return -1;
2207
 
2208
}       /* or32_regnum_from_name() */
2209
 
2210
 
2211
/*----------------------------------------------------------------------------*/
2212
/*!Get the next token from a string
2213
 
2214
   I can't believe there isn't a library argument for this, but strtok is
2215
   deprecated.
2216
 
2217
   Take a string and find the start of the next token and its length. A token
2218
   is anything containing non-blank characters.
2219
 
2220
   @param[in]  str  The string to look at (may be NULL).
2221
   @param[out] tok  Pointer to the start of the token within str. May be NULL
2222
                    if this result is not wanted (e.g. just the length is
2223
                    wanted. If no token is found will be the NULL char at the
2224
                    end of the string, if the original str was NULL, this will
2225
                    be NULL.
2226
 
2227
                    @return  The length of the token found */
2228
/*----------------------------------------------------------------------------*/
2229
 
2230
static int
2231
or32_tokenize (char  *str,
2232
               char **tok)
2233
{
2234
  char *ptr;
2235
  int   len;
2236
 
2237
  /* Deal with NULL argument */
2238
  if (NULL == str)
2239
    {
2240
      if (NULL != tok)
2241
        {
2242
          *tok = NULL;
2243
        }
2244
      return 0;
2245
    }
2246
 
2247
  /* Find the start */
2248
  for (ptr = str; ISBLANK (*ptr) ; ptr++)
2249
    {
2250
      continue;
2251
    }
2252
 
2253
  /* Return the start pointer if requested */
2254
  if (NULL != tok)
2255
    {
2256
      *tok = ptr;
2257
    }
2258
 
2259
  /* Find the end and put in EOS */
2260
  for (len = 0;  ('\0' != ptr[len]) && (!ISBLANK (ptr[len])); len++)
2261
    {
2262
      continue;
2263
    }
2264
 
2265
  return len;
2266
 
2267
}       /* or32_tokenize() */
2268
 
2269
 
2270
/*----------------------------------------------------------------------------*/
2271
/*!Parses args for spr commands
2272
 
2273
   Determines the special purpose register (SPR) name and puts result into
2274
   group and index
2275
 
2276
   Syntax is:
2277
 
2278
   @verbatim
2279
   <spr_args>    -> <group_ref> | <reg_name>
2280
   <group_ref>   -> <group_id> <index>
2281
   <group_id>    -> <group_num> | <group_name>
2282
   @endverbatim
2283
 
2284
   Where the indices/names have to be valid.
2285
 
2286
   So to parse, we look for 1 or 2 args. If 1 it must be a unique register
2287
   name. If 2, the first must be a group number or name and the second an
2288
   index within that group.
2289
 
2290
   Also responsible for providing diagnostics if the arguments do not match.
2291
 
2292
   Rewritten for GDB 6.8 to use the new UI calls and remove assorted
2293
   bugs. Syntax also slightly restricted to be more comprehensible.
2294
 
2295
   @param[in]  arg_str  The argument string
2296
   @param[out] group    The group this SPR belongs in, or -1 to indicate
2297
                        failure
2298
   @param[out] index    Index of the register within the group, or -1 to
2299
                        indicate the whole group
2300
   @param[in]  is_set   1 (true) if we are called from the "spr" command (so
2301
                        there is an extra arg) rather than the "info spr"
2302
                        command. Needed to distinguish between the case where
2303
                        info is sought from a register specified as group and
2304
                        index and setting a uniquely identified register to a
2305
                        value.
2306
 
2307
                        @return  A pointer to any remaining args */
2308
/*---------------------------------------------------------------------------*/
2309
 
2310
static char *
2311
or32_parse_spr_params (char *arg_str,
2312
                       int  *group,
2313
                       int  *index,
2314
                       int   is_set)
2315
{
2316
  struct {
2317
    char              *str;
2318
    int                len;
2319
    unsigned long int  val;
2320
    int                is_num;
2321
  } arg[3] = {
2322
    {
2323
      .str    = NULL,
2324
      .len    = 0,
2325
      .val    = 0,
2326
      .is_num = 0,
2327
    },
2328
   {
2329
      .str    = NULL,
2330
      .len    = 0,
2331
      .val    = 0,
2332
      .is_num = 0,
2333
    },
2334
   {
2335
      .str    = NULL,
2336
      .len    = 0,
2337
      .val    = 0,
2338
      .is_num = 0,
2339
    }
2340
  };
2341
 
2342
  int   num_args;
2343
  char *trailer  = arg_str;
2344
  char *tmp_str;
2345
  int   i;
2346
 
2347
  char  spr_name[32];
2348
 
2349
  /* Break out the arguments. Note that the strings are NOT null terminated
2350
     (we don't want to change arg_str), so we must rely on len. The stroul
2351
     call will still work, since there is always a non-digit char (possibly EOS)
2352
     after the last digit. */
2353
  if (NULL == arg_str)
2354
    {
2355
      num_args = 0;
2356
    }
2357
  else
2358
    {
2359
      for (num_args = 0; num_args < 3; num_args++)
2360
        {
2361
          arg[num_args].len = or32_tokenize (trailer, &(arg[num_args].str));
2362
          trailer           = arg[num_args].str + arg[num_args].len;
2363
 
2364
          if (0 == arg[num_args].len)
2365
            {
2366
              break;
2367
            }
2368
        }
2369
    }
2370
 
2371
  /* Patch nulls into the arg strings and see about values. Couldn't do this
2372
     earlier, since we needed the next char clean to check later args. This
2373
     means advancing trailer, UNLESS it was already at EOS */
2374
 
2375
  if((NULL != arg_str) && ('\0' != *trailer))
2376
    {
2377
      trailer++;
2378
    }
2379
 
2380
  for (i = 0; i < num_args; i++)
2381
    {
2382
      (arg[i].str)[arg[i].len] = '\0';
2383
      errno                    = 0;
2384
      arg[i].val               = strtoul (arg[i].str, &tmp_str, 0);
2385
      arg[i].is_num            = (0 == errno) && ('\0' == *tmp_str);
2386
    }
2387
 
2388
  /* Deal with the case where we are setting a register, so the final argument
2389
     should be disregarded (it is the trailer). Do this anyway if we get a
2390
     third argument */
2391
  if ((is_set & (num_args > 0)) || (num_args > 2))
2392
    {
2393
      trailer = arg[num_args - 1].str;
2394
      num_args--;
2395
    }
2396
 
2397
  /* Deal with different numbers of args */
2398
 
2399
  switch (num_args)
2400
    {
2401
 
2402
    case 0:
2403
      ui_out_message (uiout, 0,
2404
                      "Usage: <command> <register>      |\n"
2405
                      "       <command> <group>         |\n"
2406
                      "       <command> <group> <index>\n"
2407
                      "Valid groups are:\n");
2408
      for (i = 0; i < OR32_NUM_SPGS; i++)
2409
        {
2410
          ui_out_field_string (uiout, NULL, or32_spr_group_name  (i));
2411
          ui_out_spaces (uiout, 1);
2412
          ui_out_wrap_hint (uiout, NULL);
2413
        }
2414
      ui_out_field_string (uiout, NULL, "\n");
2415
 
2416
      *index = -1;
2417
      return  trailer;
2418
 
2419
    case 1:
2420
      /* See if it is a numeric group */
2421
      if (arg[0].is_num)
2422
        {
2423
          if (arg[0].val < OR32_NUM_SPGS)
2424
            {
2425
              *group = arg[0].val;
2426
              *index = -1;
2427
              return trailer;
2428
            }
2429
          else
2430
            {
2431
              ui_out_message (uiout, 0,
2432
                              "Group index should be in the range 0 - %d\n",
2433
                              OR32_NUM_SPGS);
2434
              *group = -1;
2435
              *index = -1;
2436
              return trailer;
2437
            }
2438
        }
2439
 
2440
      /* Is is it a group name? */
2441
      *group = or32_groupnum_from_name (arg[0].str);
2442
      if (*group >= 0)
2443
        {
2444
          *index = -1;
2445
          return trailer;
2446
        }
2447
 
2448
      /* See if it is a valid register name in any group */
2449
      for (*group = 0; *group < OR32_NUM_SPGS; (*group)++)
2450
        {
2451
          *index = or32_regnum_from_name (*group, arg[0].str);
2452
 
2453
          if (*index >= 0)
2454
            {
2455
              return  trailer;
2456
            }
2457
        }
2458
 
2459
      /* Couldn't find it - print out a rude message */
2460
      ui_out_message (uiout, 0,
2461
                      "Group or register name not recognized.\n"
2462
                      "Valid groups are:\n");
2463
      for (i = 0; i < OR32_NUM_SPGS; i++)
2464
        {
2465
          ui_out_field_string (uiout, NULL, or32_spr_group_name (i));
2466
          ui_out_spaces (uiout, 1);
2467
          ui_out_wrap_hint (uiout, NULL);
2468
        }
2469
      ui_out_field_string (uiout, NULL, "\n");
2470
 
2471
      *group = -1;
2472
      *index = -1;
2473
      return  trailer;
2474
 
2475
    case 2:
2476
      /* See if first arg is a numeric group */
2477
      if (arg[0].is_num)
2478
        {
2479
          if (arg[0].val < OR32_NUM_SPGS)
2480
            {
2481
              *group = arg[0].val;
2482
              *index = -1;
2483
            }
2484
          else
2485
            {
2486
              ui_out_message (uiout, 0,
2487
                              "Group index should be in the range 0 - %d\n",
2488
                              OR32_NUM_SPGS - 1);
2489
              *group = -1;
2490
              *index = -1;
2491
              return trailer;
2492
            }
2493
        }
2494
      else
2495
        {
2496
          /* Is is it a group name? */
2497
          *group = or32_groupnum_from_name (arg[0].str);
2498
          if (*group >= 0)
2499
            {
2500
              *index = -1;
2501
            }
2502
          else
2503
            {
2504
              ui_out_message (uiout, 0,
2505
                              "Group name not recognized.\n"
2506
                              "Valid groups are:\n");
2507
              for (i = 0; i < OR32_NUM_SPGS; i++)
2508
                {
2509
                  ui_out_field_string (uiout, NULL, or32_spr_group_name (i));
2510
                  ui_out_spaces (uiout, 1);
2511
                  ui_out_wrap_hint (uiout, NULL);
2512
                }
2513
              ui_out_field_string (uiout, NULL, "\n");
2514
 
2515
              *group = -1;
2516
              *index = -1;
2517
              return  trailer;
2518
            }
2519
        }
2520
 
2521
      /* Is second arg an index or name? */
2522
      if (arg[1].is_num)
2523
        {
2524
          if (arg[1].val < OR32_SPG_SIZE)
2525
            {
2526
              /* Check this really is a register */
2527
              if (0 != strlen (or32_spr_register_name (*group, arg[1].val,
2528
                                                       spr_name)))
2529
                {
2530
                  *index = arg[1].val;
2531
                  return trailer;
2532
                }
2533
              else
2534
                {
2535
                  ui_out_message (uiout, 0,
2536
                                  "No valid register at that index in group\n");
2537
                  *group = -1;
2538
                  *index = -1;
2539
                  return  trailer;
2540
                }
2541
            }
2542
          else
2543
            {
2544
              ui_out_message (uiout, 0,
2545
                              "Register index should be in the range 0 - %d\n",
2546
                              OR32_SPG_SIZE - 1);
2547
              *group = -1;
2548
              *index = -1;
2549
              return  trailer;
2550
            }
2551
        }
2552
 
2553
      /* Must be a name */
2554
      *index = or32_regnum_from_name (*group, arg[1].str);
2555
 
2556
      if (*index >= 0)
2557
        {
2558
          return trailer;
2559
        }
2560
 
2561
      /* Couldn't find it - print out a rude message */
2562
      ui_out_message (uiout, 0, "Register name not recognized in group.\n");
2563
      *group = -1;
2564
      *index = -1;
2565
      return  trailer;
2566
 
2567
    default:
2568
      /* Anything else is an error */
2569
      ui_out_message (uiout, 0, "Unable to parse arguments\n");
2570
      *group = -1;
2571
      *index = -1;
2572
      return  trailer;
2573
    }
2574
}       /* or32_parse_spr_params() */
2575
 
2576
 
2577
/*---------------------------------------------------------------------------*/
2578
/*!Read a special purpose register from the target
2579
 
2580
   This has to be done using the target remote command "readspr"
2581
 
2582
   @param[in] regnum  The register to read
2583
 
2584
   @return  The value read */
2585
/*---------------------------------------------------------------------------*/
2586
 
2587
static ULONGEST
2588
or32_read_spr (unsigned int  regnum)
2589
{
2590
  struct ui_file    *uibuf = mem_fileopen ();
2591
  char               cmd[sizeof ("readspr ffff")];
2592
  unsigned long int  data;
2593
  char              *res;
2594
  long int           len;
2595
 
2596
  /* Create the command string and pass it to target remote command function */
2597
  sprintf (cmd, "readspr %4x", regnum);
2598
  target_rcmd (cmd, uibuf);
2599
 
2600
  /* Get the output for the UI file as a string */
2601
  res = ui_file_xstrdup (uibuf, &len);
2602
  sscanf (res, "%lx", &data);
2603
 
2604
  /* Tidy up */
2605
  xfree (res);
2606
  ui_file_delete (uibuf);
2607
 
2608
  return  (ULONGEST)data;
2609
 
2610
}       /* or32_read_spr() */
2611
 
2612
 
2613
/*---------------------------------------------------------------------------*/
2614
/*!Write a special purpose register on the target
2615
 
2616
   This has to be done using the target remote command "writespr"
2617
 
2618
   Since the SPRs may map to GPR's or the other GDB register (PPC, NPC, SR),
2619
   any register cache is flushed.
2620
 
2621
   @param[in] regnum  The register to write
2622
   @param[in] data  The value to write */
2623
/*---------------------------------------------------------------------------*/
2624
 
2625
static void
2626
or32_write_spr (unsigned int  regnum,
2627
                ULONGEST      data)
2628
{
2629
  struct ui_file    *uibuf = mem_fileopen ();
2630
  char               cmd[sizeof ("writespr ffff ffffffff")];
2631
  char              *res;
2632
  long int           len;
2633
 
2634
  /* Create the command string and pass it to target remote command function */
2635
  sprintf (cmd, "writespr %4x %8llx", regnum, (long long unsigned int)data);
2636
  target_rcmd (cmd, uibuf);
2637
 
2638
  /* Flush the register cache */
2639
  registers_changed ();
2640
 
2641
  /* We ignore the result - Rcmd can put out its own error messages. Just
2642
     tidy up */
2643
  ui_file_delete (uibuf);
2644
 
2645
}       /* or32_write_spr() */
2646
 
2647
 
2648
/*----------------------------------------------------------------------------*/
2649
/*!Show the value of a special purpose register or group
2650
 
2651
   This is a custom extension to the GDB info command.
2652
 
2653
   @param[in] args
2654
   @param[in] from_tty  True (1) if GDB is running from a TTY, false (0)
2655
   otherwise. */
2656
/*---------------------------------------------------------------------------*/
2657
 
2658
static void
2659
or32_info_spr_command (char *args,
2660
                       int   from_tty)
2661
{
2662
  int  group;
2663
  int  index;
2664
 
2665
  char  spr_name[32];
2666
 
2667
  or32_parse_spr_params (args, &group, &index, 0);
2668
 
2669
  if (group < 0)
2670
    {
2671
      return;                   /* Couldn't parse the args */
2672
    }
2673
 
2674
  if (index >= 0)
2675
    {
2676
      ULONGEST  value = or32_read_spr (OR32_SPR (group, index));
2677
 
2678
      ui_out_field_fmt (uiout, NULL, "%s.%s = SPR%i_%i = %llu (0x%llx)\n",
2679
                        or32_spr_group_name (group),
2680
                        or32_spr_register_name (group, index, spr_name), group,
2681
                        index, (long long unsigned int)value, (long long unsigned int)value);
2682
    }
2683
  else
2684
    {
2685
      /* Print all valid registers in the group */
2686
      for (index = 0; index < OR32_SPG_SIZE; index++)
2687
        {
2688
          if (0 != strlen (or32_spr_register_name (group, index, spr_name)))
2689
            {
2690
              ULONGEST  value = or32_read_spr (OR32_SPR (group, index));
2691
 
2692
              ui_out_field_fmt (uiout, NULL,
2693
                                "%s.%s = SPR%i_%i = %llu (0x%llx)\n",
2694
                                or32_spr_group_name (group),
2695
                                or32_spr_register_name (group, index, spr_name),
2696
                                group, index, (long long unsigned int)value, (long long unsigned int)value);
2697
            }
2698
        }
2699
    }
2700
}       /* or32_info_spr_command() */
2701
 
2702
 
2703
/*----------------------------------------------------------------------------*/
2704
/*!Set a special purpose register
2705
 
2706
   This is a custom command added to GDB.
2707
 
2708
   @param[in] args
2709
   @param[in] from_tty  True (1) if GDB is running from a TTY, false (0)
2710
   otherwise. */
2711
/*---------------------------------------------------------------------------*/
2712
 
2713
static void
2714
or32_spr_command (char *args,
2715
                  int   from_tty)
2716
{
2717
  int   group;
2718
  int   index;
2719
  char *tmp_str;
2720
  char *nargs = or32_parse_spr_params (args, &group, &index, 1);
2721
 
2722
  ULONGEST  old_val;
2723
  ULONGEST  new_val;
2724
 
2725
  char  spr_name[32];
2726
 
2727
  /* Do we have a valid register spec? */
2728
  if (index < 0)
2729
    {
2730
      return;           /* Parser will have printed the error message */
2731
    }
2732
 
2733
  /* Do we have a value to set? */
2734
 
2735
  errno = 0;
2736
  new_val = (ULONGEST)strtoul (nargs, &tmp_str, 0);
2737
 
2738
  if((0 != errno) || ('\0' != *tmp_str))
2739
    {
2740
      ui_out_message (uiout, 0, "Invalid value - register not changed\n");
2741
      return;
2742
    }
2743
 
2744
  old_val = or32_read_spr (OR32_SPR (group, index));
2745
 
2746
  or32_write_spr (OR32_SPR (group, index) , new_val);
2747
 
2748
  ui_out_field_fmt (uiout, NULL,
2749
                    "%s.%s (SPR%i_%i) set to %llu (0x%llx), "
2750
                    "was: %llu (0x%llx)\n",
2751
                    or32_spr_group_name (group),
2752
                    or32_spr_register_name (group, index, spr_name) , group,
2753
                    index, (long long unsigned int)new_val, (long long unsigned int)new_val, (long long unsigned int)old_val, (long long unsigned int)old_val);
2754
 
2755
}       /* or32_spr_command() */
2756
 
2757
 
2758
/*----------------------------------------------------------------------------*/
2759
/*!Main entry point for target architecture initialization
2760
 
2761
   In this version initializes the architecture via
2762
   registers_gdbarch_init(). Add a command to set and show special purpose
2763
   registers. */
2764
/*---------------------------------------------------------------------------*/
2765
 
2766
void
2767
_initialize_or32_tdep (void)
2768
{
2769
  /* Register this architecture. We should do this for or16 and or64 when
2770
     they have their BFD defined. */
2771
  gdbarch_register (bfd_arch_or32, or32_gdbarch_init, or32_dump_tdep);
2772
 
2773
  /* Initialize the automata for the assembler */
2774
  build_automata();
2775
 
2776
  /* Commands to show and set special purpose registers */
2777
  add_info ("spr", or32_info_spr_command,
2778
            "Show the value of a special purpose register");
2779
  add_com ("spr", class_support, or32_spr_command,
2780
           "Set a special purpose register");
2781
 
2782
}       /* _initialize_or32_tdep() */

powered by: WebSVN 2.1.0

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