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[/] [openrisc/] [trunk/] [gnu-src/] [gcc-4.5.1/] [gcc/] [config/] [m32c/] [m32c.c] - Blame information for rev 298

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1 282 jeremybenn
/* Target Code for R8C/M16C/M32C
2
   Copyright (C) 2005, 2006, 2007, 2008, 2009
3
   Free Software Foundation, Inc.
4
   Contributed by Red Hat.
5
 
6
   This file is part of GCC.
7
 
8
   GCC is free software; you can redistribute it and/or modify it
9
   under the terms of the GNU General Public License as published
10
   by the Free Software Foundation; either version 3, or (at your
11
   option) any later version.
12
 
13
   GCC is distributed in the hope that it will be useful, but WITHOUT
14
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
15
   or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public
16
   License for more details.
17
 
18
   You should have received a copy of the GNU General Public License
19
   along with GCC; see the file COPYING3.  If not see
20
   <http://www.gnu.org/licenses/>.  */
21
 
22
#include "config.h"
23
#include "system.h"
24
#include "coretypes.h"
25
#include "tm.h"
26
#include "rtl.h"
27
#include "regs.h"
28
#include "hard-reg-set.h"
29
#include "real.h"
30
#include "insn-config.h"
31
#include "conditions.h"
32
#include "insn-flags.h"
33
#include "output.h"
34
#include "insn-attr.h"
35
#include "flags.h"
36
#include "recog.h"
37
#include "reload.h"
38
#include "toplev.h"
39
#include "obstack.h"
40
#include "tree.h"
41
#include "expr.h"
42
#include "optabs.h"
43
#include "except.h"
44
#include "function.h"
45
#include "ggc.h"
46
#include "target.h"
47
#include "target-def.h"
48
#include "tm_p.h"
49
#include "langhooks.h"
50
#include "gimple.h"
51
#include "df.h"
52
 
53
/* Prototypes */
54
 
55
/* Used by m32c_pushm_popm.  */
56
typedef enum
57
{
58
  PP_pushm,
59
  PP_popm,
60
  PP_justcount
61
} Push_Pop_Type;
62
 
63
static bool m32c_function_needs_enter (void);
64
static tree interrupt_handler (tree *, tree, tree, int, bool *);
65
static tree function_vector_handler (tree *, tree, tree, int, bool *);
66
static int interrupt_p (tree node);
67
static int bank_switch_p (tree node);
68
static int fast_interrupt_p (tree node);
69
static int interrupt_p (tree node);
70
static bool m32c_asm_integer (rtx, unsigned int, int);
71
static int m32c_comp_type_attributes (const_tree, const_tree);
72
static bool m32c_fixed_condition_code_regs (unsigned int *, unsigned int *);
73
static struct machine_function *m32c_init_machine_status (void);
74
static void m32c_insert_attributes (tree, tree *);
75
static bool m32c_legitimate_address_p (enum machine_mode, rtx, bool);
76
static bool m32c_pass_by_reference (CUMULATIVE_ARGS *, enum machine_mode,
77
                                    const_tree, bool);
78
static bool m32c_promote_prototypes (const_tree);
79
static int m32c_pushm_popm (Push_Pop_Type);
80
static bool m32c_strict_argument_naming (CUMULATIVE_ARGS *);
81
static rtx m32c_struct_value_rtx (tree, int);
82
static rtx m32c_subreg (enum machine_mode, rtx, enum machine_mode, int);
83
static int need_to_save (int);
84
static rtx m32c_function_value (const_tree, const_tree, bool);
85
static rtx m32c_libcall_value (enum machine_mode, const_rtx);
86
 
87
int current_function_special_page_vector (rtx);
88
 
89
#define SYMBOL_FLAG_FUNCVEC_FUNCTION    (SYMBOL_FLAG_MACH_DEP << 0)
90
 
91
#define streq(a,b) (strcmp ((a), (b)) == 0)
92
 
93
/* Internal support routines */
94
 
95
/* Debugging statements are tagged with DEBUG0 only so that they can
96
   be easily enabled individually, by replacing the '0' with '1' as
97
   needed.  */
98
#define DEBUG0 0
99
#define DEBUG1 1
100
 
101
#if DEBUG0
102
/* This is needed by some of the commented-out debug statements
103
   below.  */
104
static char const *class_names[LIM_REG_CLASSES] = REG_CLASS_NAMES;
105
#endif
106
static int class_contents[LIM_REG_CLASSES][1] = REG_CLASS_CONTENTS;
107
 
108
/* These are all to support encode_pattern().  */
109
static char pattern[30], *patternp;
110
static GTY(()) rtx patternr[30];
111
#define RTX_IS(x) (streq (pattern, x))
112
 
113
/* Some macros to simplify the logic throughout this file.  */
114
#define IS_MEM_REGNO(regno) ((regno) >= MEM0_REGNO && (regno) <= MEM7_REGNO)
115
#define IS_MEM_REG(rtx) (GET_CODE (rtx) == REG && IS_MEM_REGNO (REGNO (rtx)))
116
 
117
#define IS_CR_REGNO(regno) ((regno) >= SB_REGNO && (regno) <= PC_REGNO)
118
#define IS_CR_REG(rtx) (GET_CODE (rtx) == REG && IS_CR_REGNO (REGNO (rtx)))
119
 
120
/* We do most RTX matching by converting the RTX into a string, and
121
   using string compares.  This vastly simplifies the logic in many of
122
   the functions in this file.
123
 
124
   On exit, pattern[] has the encoded string (use RTX_IS("...") to
125
   compare it) and patternr[] has pointers to the nodes in the RTX
126
   corresponding to each character in the encoded string.  The latter
127
   is mostly used by print_operand().
128
 
129
   Unrecognized patterns have '?' in them; this shows up when the
130
   assembler complains about syntax errors.
131
*/
132
 
133
static void
134
encode_pattern_1 (rtx x)
135
{
136
  int i;
137
 
138
  if (patternp == pattern + sizeof (pattern) - 2)
139
    {
140
      patternp[-1] = '?';
141
      return;
142
    }
143
 
144
  patternr[patternp - pattern] = x;
145
 
146
  switch (GET_CODE (x))
147
    {
148
    case REG:
149
      *patternp++ = 'r';
150
      break;
151
    case SUBREG:
152
      if (GET_MODE_SIZE (GET_MODE (x)) !=
153
          GET_MODE_SIZE (GET_MODE (XEXP (x, 0))))
154
        *patternp++ = 'S';
155
      encode_pattern_1 (XEXP (x, 0));
156
      break;
157
    case MEM:
158
      *patternp++ = 'm';
159
    case CONST:
160
      encode_pattern_1 (XEXP (x, 0));
161
      break;
162
    case PLUS:
163
      *patternp++ = '+';
164
      encode_pattern_1 (XEXP (x, 0));
165
      encode_pattern_1 (XEXP (x, 1));
166
      break;
167
    case PRE_DEC:
168
      *patternp++ = '>';
169
      encode_pattern_1 (XEXP (x, 0));
170
      break;
171
    case POST_INC:
172
      *patternp++ = '<';
173
      encode_pattern_1 (XEXP (x, 0));
174
      break;
175
    case LO_SUM:
176
      *patternp++ = 'L';
177
      encode_pattern_1 (XEXP (x, 0));
178
      encode_pattern_1 (XEXP (x, 1));
179
      break;
180
    case HIGH:
181
      *patternp++ = 'H';
182
      encode_pattern_1 (XEXP (x, 0));
183
      break;
184
    case SYMBOL_REF:
185
      *patternp++ = 's';
186
      break;
187
    case LABEL_REF:
188
      *patternp++ = 'l';
189
      break;
190
    case CODE_LABEL:
191
      *patternp++ = 'c';
192
      break;
193
    case CONST_INT:
194
    case CONST_DOUBLE:
195
      *patternp++ = 'i';
196
      break;
197
    case UNSPEC:
198
      *patternp++ = 'u';
199
      *patternp++ = '0' + XCINT (x, 1, UNSPEC);
200
      for (i = 0; i < XVECLEN (x, 0); i++)
201
        encode_pattern_1 (XVECEXP (x, 0, i));
202
      break;
203
    case USE:
204
      *patternp++ = 'U';
205
      break;
206
    case PARALLEL:
207
      *patternp++ = '|';
208
      for (i = 0; i < XVECLEN (x, 0); i++)
209
        encode_pattern_1 (XVECEXP (x, 0, i));
210
      break;
211
    case EXPR_LIST:
212
      *patternp++ = 'E';
213
      encode_pattern_1 (XEXP (x, 0));
214
      if (XEXP (x, 1))
215
        encode_pattern_1 (XEXP (x, 1));
216
      break;
217
    default:
218
      *patternp++ = '?';
219
#if DEBUG0
220
      fprintf (stderr, "can't encode pattern %s\n",
221
               GET_RTX_NAME (GET_CODE (x)));
222
      debug_rtx (x);
223
      gcc_unreachable ();
224
#endif
225
      break;
226
    }
227
}
228
 
229
static void
230
encode_pattern (rtx x)
231
{
232
  patternp = pattern;
233
  encode_pattern_1 (x);
234
  *patternp = 0;
235
}
236
 
237
/* Since register names indicate the mode they're used in, we need a
238
   way to determine which name to refer to the register with.  Called
239
   by print_operand().  */
240
 
241
static const char *
242
reg_name_with_mode (int regno, enum machine_mode mode)
243
{
244
  int mlen = GET_MODE_SIZE (mode);
245
  if (regno == R0_REGNO && mlen == 1)
246
    return "r0l";
247
  if (regno == R0_REGNO && (mlen == 3 || mlen == 4))
248
    return "r2r0";
249
  if (regno == R0_REGNO && mlen == 6)
250
    return "r2r1r0";
251
  if (regno == R0_REGNO && mlen == 8)
252
    return "r3r1r2r0";
253
  if (regno == R1_REGNO && mlen == 1)
254
    return "r1l";
255
  if (regno == R1_REGNO && (mlen == 3 || mlen == 4))
256
    return "r3r1";
257
  if (regno == A0_REGNO && TARGET_A16 && (mlen == 3 || mlen == 4))
258
    return "a1a0";
259
  return reg_names[regno];
260
}
261
 
262
/* How many bytes a register uses on stack when it's pushed.  We need
263
   to know this because the push opcode needs to explicitly indicate
264
   the size of the register, even though the name of the register
265
   already tells it that.  Used by m32c_output_reg_{push,pop}, which
266
   is only used through calls to ASM_OUTPUT_REG_{PUSH,POP}.  */
267
 
268
static int
269
reg_push_size (int regno)
270
{
271
  switch (regno)
272
    {
273
    case R0_REGNO:
274
    case R1_REGNO:
275
      return 2;
276
    case R2_REGNO:
277
    case R3_REGNO:
278
    case FLG_REGNO:
279
      return 2;
280
    case A0_REGNO:
281
    case A1_REGNO:
282
    case SB_REGNO:
283
    case FB_REGNO:
284
    case SP_REGNO:
285
      if (TARGET_A16)
286
        return 2;
287
      else
288
        return 3;
289
    default:
290
      gcc_unreachable ();
291
    }
292
}
293
 
294
static int *class_sizes = 0;
295
 
296
/* Given two register classes, find the largest intersection between
297
   them.  If there is no intersection, return RETURNED_IF_EMPTY
298
   instead.  */
299
static int
300
reduce_class (int original_class, int limiting_class, int returned_if_empty)
301
{
302
  int cc = class_contents[original_class][0];
303
  int i, best = NO_REGS;
304
  int best_size = 0;
305
 
306
  if (original_class == limiting_class)
307
    return original_class;
308
 
309
  if (!class_sizes)
310
    {
311
      int r;
312
      class_sizes = (int *) xmalloc (LIM_REG_CLASSES * sizeof (int));
313
      for (i = 0; i < LIM_REG_CLASSES; i++)
314
        {
315
          class_sizes[i] = 0;
316
          for (r = 0; r < FIRST_PSEUDO_REGISTER; r++)
317
            if (class_contents[i][0] & (1 << r))
318
              class_sizes[i]++;
319
        }
320
    }
321
 
322
  cc &= class_contents[limiting_class][0];
323
  for (i = 0; i < LIM_REG_CLASSES; i++)
324
    {
325
      int ic = class_contents[i][0];
326
 
327
      if ((~cc & ic) == 0)
328
        if (best_size < class_sizes[i])
329
          {
330
            best = i;
331
            best_size = class_sizes[i];
332
          }
333
 
334
    }
335
  if (best == NO_REGS)
336
    return returned_if_empty;
337
  return best;
338
}
339
 
340
/* Returns TRUE If there are any registers that exist in both register
341
   classes.  */
342
static int
343
classes_intersect (int class1, int class2)
344
{
345
  return class_contents[class1][0] & class_contents[class2][0];
346
}
347
 
348
/* Used by m32c_register_move_cost to determine if a move is
349
   impossibly expensive.  */
350
static int
351
class_can_hold_mode (int rclass, enum machine_mode mode)
352
{
353
  /* Cache the results:  0=untested  1=no  2=yes */
354
  static char results[LIM_REG_CLASSES][MAX_MACHINE_MODE];
355
  if (results[rclass][mode] == 0)
356
    {
357
      int r, n, i;
358
      results[rclass][mode] = 1;
359
      for (r = 0; r < FIRST_PSEUDO_REGISTER; r++)
360
        if (class_contents[rclass][0] & (1 << r)
361
            && HARD_REGNO_MODE_OK (r, mode))
362
          {
363
            int ok = 1;
364
            n = HARD_REGNO_NREGS (r, mode);
365
            for (i = 1; i < n; i++)
366
              if (!(class_contents[rclass][0] & (1 << (r + i))))
367
                ok = 0;
368
            if (ok)
369
              {
370
                results[rclass][mode] = 2;
371
                break;
372
              }
373
          }
374
    }
375
#if DEBUG0
376
  fprintf (stderr, "class %s can hold %s? %s\n",
377
           class_names[rclass], mode_name[mode],
378
           (results[rclass][mode] == 2) ? "yes" : "no");
379
#endif
380
  return results[rclass][mode] == 2;
381
}
382
 
383
/* Run-time Target Specification.  */
384
 
385
/* Memregs are memory locations that gcc treats like general
386
   registers, as there are a limited number of true registers and the
387
   m32c families can use memory in most places that registers can be
388
   used.
389
 
390
   However, since memory accesses are more expensive than registers,
391
   we allow the user to limit the number of memregs available, in
392
   order to try to persuade gcc to try harder to use real registers.
393
 
394
   Memregs are provided by m32c-lib1.S.
395
*/
396
 
397
int target_memregs = 16;
398
static bool target_memregs_set = FALSE;
399
int ok_to_change_target_memregs = TRUE;
400
 
401
#undef  TARGET_HANDLE_OPTION
402
#define TARGET_HANDLE_OPTION m32c_handle_option
403
static bool
404
m32c_handle_option (size_t code,
405
                    const char *arg ATTRIBUTE_UNUSED,
406
                    int value ATTRIBUTE_UNUSED)
407
{
408
  if (code == OPT_memregs_)
409
    {
410
      target_memregs_set = TRUE;
411
      target_memregs = atoi (arg);
412
    }
413
  return TRUE;
414
}
415
 
416
/* Implements OVERRIDE_OPTIONS.  We limit memregs to 0..16, and
417
   provide a default.  */
418
void
419
m32c_override_options (void)
420
{
421
  if (target_memregs_set)
422
    {
423
      if (target_memregs < 0 || target_memregs > 16)
424
        error ("invalid target memregs value '%d'", target_memregs);
425
    }
426
  else
427
    target_memregs = 16;
428
 
429
  if (TARGET_A24)
430
    flag_ivopts = 0;
431
}
432
 
433
/* Defining data structures for per-function information */
434
 
435
/* The usual; we set up our machine_function data.  */
436
static struct machine_function *
437
m32c_init_machine_status (void)
438
{
439
  struct machine_function *machine;
440
  machine =
441
    (machine_function *) ggc_alloc_cleared (sizeof (machine_function));
442
 
443
  return machine;
444
}
445
 
446
/* Implements INIT_EXPANDERS.  We just set up to call the above
447
   function.  */
448
void
449
m32c_init_expanders (void)
450
{
451
  init_machine_status = m32c_init_machine_status;
452
}
453
 
454
/* Storage Layout */
455
 
456
/* Register Basics */
457
 
458
/* Basic Characteristics of Registers */
459
 
460
/* Whether a mode fits in a register is complex enough to warrant a
461
   table.  */
462
static struct
463
{
464
  char qi_regs;
465
  char hi_regs;
466
  char pi_regs;
467
  char si_regs;
468
  char di_regs;
469
} nregs_table[FIRST_PSEUDO_REGISTER] =
470
{
471
  { 1, 1, 2, 2, 4 },            /* r0 */
472
  { 0, 1, 0, 0, 0 },                /* r2 */
473
  { 1, 1, 2, 2, 0 },             /* r1 */
474
  { 0, 1, 0, 0, 0 },                /* r3 */
475
  { 0, 1, 1, 0, 0 },               /* a0 */
476
  { 0, 1, 1, 0, 0 },               /* a1 */
477
  { 0, 1, 1, 0, 0 },               /* sb */
478
  { 0, 1, 1, 0, 0 },               /* fb */
479
  { 0, 1, 1, 0, 0 },               /* sp */
480
  { 1, 1, 1, 0, 0 },              /* pc */
481
  { 0, 0, 0, 0, 0 },         /* fl */
482
  { 1, 1, 1, 0, 0 },              /* ap */
483
  { 1, 1, 2, 2, 4 },            /* mem0 */
484
  { 1, 1, 2, 2, 4 },            /* mem1 */
485
  { 1, 1, 2, 2, 4 },            /* mem2 */
486
  { 1, 1, 2, 2, 4 },            /* mem3 */
487
  { 1, 1, 2, 2, 4 },            /* mem4 */
488
  { 1, 1, 2, 2, 0 },             /* mem5 */
489
  { 1, 1, 2, 2, 0 },             /* mem6 */
490
  { 1, 1, 0, 0, 0 },               /* mem7 */
491
};
492
 
493
/* Implements CONDITIONAL_REGISTER_USAGE.  We adjust the number of
494
   available memregs, and select which registers need to be preserved
495
   across calls based on the chip family.  */
496
 
497
void
498
m32c_conditional_register_usage (void)
499
{
500
  int i;
501
 
502
  if (0 <= target_memregs && target_memregs <= 16)
503
    {
504
      /* The command line option is bytes, but our "registers" are
505
         16-bit words.  */
506
      for (i = (target_memregs+1)/2; i < 8; i++)
507
        {
508
          fixed_regs[MEM0_REGNO + i] = 1;
509
          CLEAR_HARD_REG_BIT (reg_class_contents[MEM_REGS], MEM0_REGNO + i);
510
        }
511
    }
512
 
513
  /* M32CM and M32C preserve more registers across function calls.  */
514
  if (TARGET_A24)
515
    {
516
      call_used_regs[R1_REGNO] = 0;
517
      call_used_regs[R2_REGNO] = 0;
518
      call_used_regs[R3_REGNO] = 0;
519
      call_used_regs[A0_REGNO] = 0;
520
      call_used_regs[A1_REGNO] = 0;
521
    }
522
}
523
 
524
/* How Values Fit in Registers */
525
 
526
/* Implements HARD_REGNO_NREGS.  This is complicated by the fact that
527
   different registers are different sizes from each other, *and* may
528
   be different sizes in different chip families.  */
529
static int
530
m32c_hard_regno_nregs_1 (int regno, enum machine_mode mode)
531
{
532
  if (regno == FLG_REGNO && mode == CCmode)
533
    return 1;
534
  if (regno >= FIRST_PSEUDO_REGISTER)
535
    return ((GET_MODE_SIZE (mode) + UNITS_PER_WORD - 1) / UNITS_PER_WORD);
536
 
537
  if (regno >= MEM0_REGNO && regno <= MEM7_REGNO)
538
    return (GET_MODE_SIZE (mode) + 1) / 2;
539
 
540
  if (GET_MODE_SIZE (mode) <= 1)
541
    return nregs_table[regno].qi_regs;
542
  if (GET_MODE_SIZE (mode) <= 2)
543
    return nregs_table[regno].hi_regs;
544
  if (regno == A0_REGNO && mode == PSImode && TARGET_A16)
545
    return 2;
546
  if ((GET_MODE_SIZE (mode) <= 3 || mode == PSImode) && TARGET_A24)
547
    return nregs_table[regno].pi_regs;
548
  if (GET_MODE_SIZE (mode) <= 4)
549
    return nregs_table[regno].si_regs;
550
  if (GET_MODE_SIZE (mode) <= 8)
551
    return nregs_table[regno].di_regs;
552
  return 0;
553
}
554
 
555
int
556
m32c_hard_regno_nregs (int regno, enum machine_mode mode)
557
{
558
  int rv = m32c_hard_regno_nregs_1 (regno, mode);
559
  return rv ? rv : 1;
560
}
561
 
562
/* Implements HARD_REGNO_MODE_OK.  The above function does the work
563
   already; just test its return value.  */
564
int
565
m32c_hard_regno_ok (int regno, enum machine_mode mode)
566
{
567
  return m32c_hard_regno_nregs_1 (regno, mode) != 0;
568
}
569
 
570
/* Implements MODES_TIEABLE_P.  In general, modes aren't tieable since
571
   registers are all different sizes.  However, since most modes are
572
   bigger than our registers anyway, it's easier to implement this
573
   function that way, leaving QImode as the only unique case.  */
574
int
575
m32c_modes_tieable_p (enum machine_mode m1, enum machine_mode m2)
576
{
577
  if (GET_MODE_SIZE (m1) == GET_MODE_SIZE (m2))
578
    return 1;
579
 
580
#if 0
581
  if (m1 == QImode || m2 == QImode)
582
    return 0;
583
#endif
584
 
585
  return 1;
586
}
587
 
588
/* Register Classes */
589
 
590
/* Implements REGNO_REG_CLASS.  */
591
enum machine_mode
592
m32c_regno_reg_class (int regno)
593
{
594
  switch (regno)
595
    {
596
    case R0_REGNO:
597
      return R0_REGS;
598
    case R1_REGNO:
599
      return R1_REGS;
600
    case R2_REGNO:
601
      return R2_REGS;
602
    case R3_REGNO:
603
      return R3_REGS;
604
    case A0_REGNO:
605
    case A1_REGNO:
606
      return A_REGS;
607
    case SB_REGNO:
608
      return SB_REGS;
609
    case FB_REGNO:
610
      return FB_REGS;
611
    case SP_REGNO:
612
      return SP_REGS;
613
    case FLG_REGNO:
614
      return FLG_REGS;
615
    default:
616
      if (IS_MEM_REGNO (regno))
617
        return MEM_REGS;
618
      return ALL_REGS;
619
    }
620
}
621
 
622
/* Implements REG_CLASS_FROM_CONSTRAINT.  Note that some constraints only match
623
   for certain chip families.  */
624
int
625
m32c_reg_class_from_constraint (char c ATTRIBUTE_UNUSED, const char *s)
626
{
627
  if (memcmp (s, "Rsp", 3) == 0)
628
    return SP_REGS;
629
  if (memcmp (s, "Rfb", 3) == 0)
630
    return FB_REGS;
631
  if (memcmp (s, "Rsb", 3) == 0)
632
    return SB_REGS;
633
  if (memcmp (s, "Rcr", 3) == 0)
634
    return TARGET_A16 ? CR_REGS : NO_REGS;
635
  if (memcmp (s, "Rcl", 3) == 0)
636
    return TARGET_A24 ? CR_REGS : NO_REGS;
637
  if (memcmp (s, "R0w", 3) == 0)
638
    return R0_REGS;
639
  if (memcmp (s, "R1w", 3) == 0)
640
    return R1_REGS;
641
  if (memcmp (s, "R2w", 3) == 0)
642
    return R2_REGS;
643
  if (memcmp (s, "R3w", 3) == 0)
644
    return R3_REGS;
645
  if (memcmp (s, "R02", 3) == 0)
646
    return R02_REGS;
647
  if (memcmp (s, "R13", 3) == 0)
648
    return R13_REGS;
649
  if (memcmp (s, "R03", 3) == 0)
650
    return R03_REGS;
651
  if (memcmp (s, "Rdi", 3) == 0)
652
    return DI_REGS;
653
  if (memcmp (s, "Rhl", 3) == 0)
654
    return HL_REGS;
655
  if (memcmp (s, "R23", 3) == 0)
656
    return R23_REGS;
657
  if (memcmp (s, "Ra0", 3) == 0)
658
    return A0_REGS;
659
  if (memcmp (s, "Ra1", 3) == 0)
660
    return A1_REGS;
661
  if (memcmp (s, "Raa", 3) == 0)
662
    return A_REGS;
663
  if (memcmp (s, "Raw", 3) == 0)
664
    return TARGET_A16 ? A_REGS : NO_REGS;
665
  if (memcmp (s, "Ral", 3) == 0)
666
    return TARGET_A24 ? A_REGS : NO_REGS;
667
  if (memcmp (s, "Rqi", 3) == 0)
668
    return QI_REGS;
669
  if (memcmp (s, "Rad", 3) == 0)
670
    return AD_REGS;
671
  if (memcmp (s, "Rsi", 3) == 0)
672
    return SI_REGS;
673
  if (memcmp (s, "Rhi", 3) == 0)
674
    return HI_REGS;
675
  if (memcmp (s, "Rhc", 3) == 0)
676
    return HC_REGS;
677
  if (memcmp (s, "Rra", 3) == 0)
678
    return RA_REGS;
679
  if (memcmp (s, "Rfl", 3) == 0)
680
    return FLG_REGS;
681
  if (memcmp (s, "Rmm", 3) == 0)
682
    {
683
      if (fixed_regs[MEM0_REGNO])
684
        return NO_REGS;
685
      return MEM_REGS;
686
    }
687
 
688
  /* PSImode registers - i.e. whatever can hold a pointer.  */
689
  if (memcmp (s, "Rpi", 3) == 0)
690
    {
691
      if (TARGET_A16)
692
        return HI_REGS;
693
      else
694
        return RA_REGS; /* r2r0 and r3r1 can hold pointers.  */
695
    }
696
 
697
  /* We handle this one as an EXTRA_CONSTRAINT.  */
698
  if (memcmp (s, "Rpa", 3) == 0)
699
    return NO_REGS;
700
 
701
  if (*s == 'R')
702
    {
703
      fprintf(stderr, "unrecognized R constraint: %.3s\n", s);
704
      gcc_unreachable();
705
    }
706
 
707
  return NO_REGS;
708
}
709
 
710
/* Implements REGNO_OK_FOR_BASE_P.  */
711
int
712
m32c_regno_ok_for_base_p (int regno)
713
{
714
  if (regno == A0_REGNO
715
      || regno == A1_REGNO || regno >= FIRST_PSEUDO_REGISTER)
716
    return 1;
717
  return 0;
718
}
719
 
720
#define DEBUG_RELOAD 0
721
 
722
/* Implements PREFERRED_RELOAD_CLASS.  In general, prefer general
723
   registers of the appropriate size.  */
724
int
725
m32c_preferred_reload_class (rtx x, int rclass)
726
{
727
  int newclass = rclass;
728
 
729
#if DEBUG_RELOAD
730
  fprintf (stderr, "\npreferred_reload_class for %s is ",
731
           class_names[rclass]);
732
#endif
733
  if (rclass == NO_REGS)
734
    rclass = GET_MODE (x) == QImode ? HL_REGS : R03_REGS;
735
 
736
  if (classes_intersect (rclass, CR_REGS))
737
    {
738
      switch (GET_MODE (x))
739
        {
740
        case QImode:
741
          newclass = HL_REGS;
742
          break;
743
        default:
744
          /*      newclass = HI_REGS; */
745
          break;
746
        }
747
    }
748
 
749
  else if (newclass == QI_REGS && GET_MODE_SIZE (GET_MODE (x)) > 2)
750
    newclass = SI_REGS;
751
  else if (GET_MODE_SIZE (GET_MODE (x)) > 4
752
           && ~class_contents[rclass][0] & 0x000f)
753
    newclass = DI_REGS;
754
 
755
  rclass = reduce_class (rclass, newclass, rclass);
756
 
757
  if (GET_MODE (x) == QImode)
758
    rclass = reduce_class (rclass, HL_REGS, rclass);
759
 
760
#if DEBUG_RELOAD
761
  fprintf (stderr, "%s\n", class_names[rclass]);
762
  debug_rtx (x);
763
 
764
  if (GET_CODE (x) == MEM
765
      && GET_CODE (XEXP (x, 0)) == PLUS
766
      && GET_CODE (XEXP (XEXP (x, 0), 0)) == PLUS)
767
    fprintf (stderr, "Glorm!\n");
768
#endif
769
  return rclass;
770
}
771
 
772
/* Implements PREFERRED_OUTPUT_RELOAD_CLASS.  */
773
int
774
m32c_preferred_output_reload_class (rtx x, int rclass)
775
{
776
  return m32c_preferred_reload_class (x, rclass);
777
}
778
 
779
/* Implements LIMIT_RELOAD_CLASS.  We basically want to avoid using
780
   address registers for reloads since they're needed for address
781
   reloads.  */
782
int
783
m32c_limit_reload_class (enum machine_mode mode, int rclass)
784
{
785
#if DEBUG_RELOAD
786
  fprintf (stderr, "limit_reload_class for %s: %s ->",
787
           mode_name[mode], class_names[rclass]);
788
#endif
789
 
790
  if (mode == QImode)
791
    rclass = reduce_class (rclass, HL_REGS, rclass);
792
  else if (mode == HImode)
793
    rclass = reduce_class (rclass, HI_REGS, rclass);
794
  else if (mode == SImode)
795
    rclass = reduce_class (rclass, SI_REGS, rclass);
796
 
797
  if (rclass != A_REGS)
798
    rclass = reduce_class (rclass, DI_REGS, rclass);
799
 
800
#if DEBUG_RELOAD
801
  fprintf (stderr, " %s\n", class_names[rclass]);
802
#endif
803
  return rclass;
804
}
805
 
806
/* Implements SECONDARY_RELOAD_CLASS.  QImode have to be reloaded in
807
   r0 or r1, as those are the only real QImode registers.  CR regs get
808
   reloaded through appropriately sized general or address
809
   registers.  */
810
int
811
m32c_secondary_reload_class (int rclass, enum machine_mode mode, rtx x)
812
{
813
  int cc = class_contents[rclass][0];
814
#if DEBUG0
815
  fprintf (stderr, "\nsecondary reload class %s %s\n",
816
           class_names[rclass], mode_name[mode]);
817
  debug_rtx (x);
818
#endif
819
  if (mode == QImode
820
      && GET_CODE (x) == MEM && (cc & ~class_contents[R23_REGS][0]) == 0)
821
    return QI_REGS;
822
  if (classes_intersect (rclass, CR_REGS)
823
      && GET_CODE (x) == REG
824
      && REGNO (x) >= SB_REGNO && REGNO (x) <= SP_REGNO)
825
    return TARGET_A16 ? HI_REGS : A_REGS;
826
  return NO_REGS;
827
}
828
 
829
/* Implements CLASS_LIKELY_SPILLED_P.  A_REGS is needed for address
830
   reloads.  */
831
int
832
m32c_class_likely_spilled_p (int regclass)
833
{
834
  if (regclass == A_REGS)
835
    return 1;
836
  return reg_class_size[regclass] == 1;
837
}
838
 
839
/* Implements CLASS_MAX_NREGS.  We calculate this according to its
840
   documented meaning, to avoid potential inconsistencies with actual
841
   class definitions.  */
842
int
843
m32c_class_max_nregs (int regclass, enum machine_mode mode)
844
{
845
  int rn, max = 0;
846
 
847
  for (rn = 0; rn < FIRST_PSEUDO_REGISTER; rn++)
848
    if (class_contents[regclass][0] & (1 << rn))
849
      {
850
        int n = m32c_hard_regno_nregs (rn, mode);
851
        if (max < n)
852
          max = n;
853
      }
854
  return max;
855
}
856
 
857
/* Implements CANNOT_CHANGE_MODE_CLASS.  Only r0 and r1 can change to
858
   QI (r0l, r1l) because the chip doesn't support QI ops on other
859
   registers (well, it does on a0/a1 but if we let gcc do that, reload
860
   suffers).  Otherwise, we allow changes to larger modes.  */
861
int
862
m32c_cannot_change_mode_class (enum machine_mode from,
863
                               enum machine_mode to, int rclass)
864
{
865
  int rn;
866
#if DEBUG0
867
  fprintf (stderr, "cannot change from %s to %s in %s\n",
868
           mode_name[from], mode_name[to], class_names[rclass]);
869
#endif
870
 
871
  /* If the larger mode isn't allowed in any of these registers, we
872
     can't allow the change.  */
873
  for (rn = 0; rn < FIRST_PSEUDO_REGISTER; rn++)
874
    if (class_contents[rclass][0] & (1 << rn))
875
      if (! m32c_hard_regno_ok (rn, to))
876
        return 1;
877
 
878
  if (to == QImode)
879
    return (class_contents[rclass][0] & 0x1ffa);
880
 
881
  if (class_contents[rclass][0] & 0x0005 /* r0, r1 */
882
      && GET_MODE_SIZE (from) > 1)
883
    return 0;
884
  if (GET_MODE_SIZE (from) > 2) /* all other regs */
885
    return 0;
886
 
887
  return 1;
888
}
889
 
890
/* Helpers for the rest of the file.  */
891
/* TRUE if the rtx is a REG rtx for the given register.  */
892
#define IS_REG(rtx,regno) (GET_CODE (rtx) == REG \
893
                           && REGNO (rtx) == regno)
894
/* TRUE if the rtx is a pseudo - specifically, one we can use as a
895
   base register in address calculations (hence the "strict"
896
   argument).  */
897
#define IS_PSEUDO(rtx,strict) (!strict && GET_CODE (rtx) == REG \
898
                               && (REGNO (rtx) == AP_REGNO \
899
                                   || REGNO (rtx) >= FIRST_PSEUDO_REGISTER))
900
 
901
/* Implements CONST_OK_FOR_CONSTRAINT_P.  Currently, all constant
902
   constraints start with 'I', with the next two characters indicating
903
   the type and size of the range allowed.  */
904
int
905
m32c_const_ok_for_constraint_p (HOST_WIDE_INT value,
906
                                char c ATTRIBUTE_UNUSED, const char *str)
907
{
908
  /* s=signed u=unsigned n=nonzero m=minus l=log2able,
909
     [sun] bits [SUN] bytes, p=pointer size
910
     I[-0-9][0-9] matches that number */
911
  if (memcmp (str, "Is3", 3) == 0)
912
    {
913
      return (-8 <= value && value <= 7);
914
    }
915
  if (memcmp (str, "IS1", 3) == 0)
916
    {
917
      return (-128 <= value && value <= 127);
918
    }
919
  if (memcmp (str, "IS2", 3) == 0)
920
    {
921
      return (-32768 <= value && value <= 32767);
922
    }
923
  if (memcmp (str, "IU2", 3) == 0)
924
    {
925
      return (0 <= value && value <= 65535);
926
    }
927
  if (memcmp (str, "IU3", 3) == 0)
928
    {
929
      return (0 <= value && value <= 0x00ffffff);
930
    }
931
  if (memcmp (str, "In4", 3) == 0)
932
    {
933
      return (-8 <= value && value && value <= 8);
934
    }
935
  if (memcmp (str, "In5", 3) == 0)
936
    {
937
      return (-16 <= value && value && value <= 16);
938
    }
939
  if (memcmp (str, "In6", 3) == 0)
940
    {
941
      return (-32 <= value && value && value <= 32);
942
    }
943
  if (memcmp (str, "IM2", 3) == 0)
944
    {
945
      return (-65536 <= value && value && value <= -1);
946
    }
947
  if (memcmp (str, "Ilb", 3) == 0)
948
    {
949
      int b = exact_log2 (value);
950
      return (b >= 0 && b <= 7);
951
    }
952
  if (memcmp (str, "Imb", 3) == 0)
953
    {
954
      int b = exact_log2 ((value ^ 0xff) & 0xff);
955
      return (b >= 0 && b <= 7);
956
    }
957
  if (memcmp (str, "ImB", 3) == 0)
958
    {
959
      int b = exact_log2 ((value ^ 0xffff) & 0xffff);
960
      return (b >= 0 && b <= 7);
961
    }
962
  if (memcmp (str, "Ilw", 3) == 0)
963
    {
964
      int b = exact_log2 (value);
965
      return (b >= 0 && b <= 15);
966
    }
967
  if (memcmp (str, "Imw", 3) == 0)
968
    {
969
      int b = exact_log2 ((value ^ 0xffff) & 0xffff);
970
      return (b >= 0 && b <= 15);
971
    }
972
  if (memcmp (str, "I00", 3) == 0)
973
    {
974
      return (value == 0);
975
    }
976
  return 0;
977
}
978
 
979
/* Implements EXTRA_CONSTRAINT_STR (see next function too).  'S' is
980
   for memory constraints, plus "Rpa" for PARALLEL rtx's we use for
981
   call return values.  */
982
int
983
m32c_extra_constraint_p2 (rtx value, char c ATTRIBUTE_UNUSED, const char *str)
984
{
985
  encode_pattern (value);
986
  if (memcmp (str, "Sd", 2) == 0)
987
    {
988
      /* This is the common "src/dest" address */
989
      rtx r;
990
      if (GET_CODE (value) == MEM && CONSTANT_P (XEXP (value, 0)))
991
        return 1;
992
      if (RTX_IS ("ms") || RTX_IS ("m+si"))
993
        return 1;
994
      if (RTX_IS ("m++rii"))
995
        {
996
          if (REGNO (patternr[3]) == FB_REGNO
997
              && INTVAL (patternr[4]) == 0)
998
            return 1;
999
        }
1000
      if (RTX_IS ("mr"))
1001
        r = patternr[1];
1002
      else if (RTX_IS ("m+ri") || RTX_IS ("m+rs") || RTX_IS ("m+r+si"))
1003
        r = patternr[2];
1004
      else
1005
        return 0;
1006
      if (REGNO (r) == SP_REGNO)
1007
        return 0;
1008
      return m32c_legitimate_address_p (GET_MODE (value), XEXP (value, 0), 1);
1009
    }
1010
  else if (memcmp (str, "Sa", 2) == 0)
1011
    {
1012
      rtx r;
1013
      if (RTX_IS ("mr"))
1014
        r = patternr[1];
1015
      else if (RTX_IS ("m+ri"))
1016
        r = patternr[2];
1017
      else
1018
        return 0;
1019
      return (IS_REG (r, A0_REGNO) || IS_REG (r, A1_REGNO));
1020
    }
1021
  else if (memcmp (str, "Si", 2) == 0)
1022
    {
1023
      return (RTX_IS ("mi") || RTX_IS ("ms") || RTX_IS ("m+si"));
1024
    }
1025
  else if (memcmp (str, "Ss", 2) == 0)
1026
    {
1027
      return ((RTX_IS ("mr")
1028
               && (IS_REG (patternr[1], SP_REGNO)))
1029
              || (RTX_IS ("m+ri") && (IS_REG (patternr[2], SP_REGNO))));
1030
    }
1031
  else if (memcmp (str, "Sf", 2) == 0)
1032
    {
1033
      return ((RTX_IS ("mr")
1034
               && (IS_REG (patternr[1], FB_REGNO)))
1035
              || (RTX_IS ("m+ri") && (IS_REG (patternr[2], FB_REGNO))));
1036
    }
1037
  else if (memcmp (str, "Sb", 2) == 0)
1038
    {
1039
      return ((RTX_IS ("mr")
1040
               && (IS_REG (patternr[1], SB_REGNO)))
1041
              || (RTX_IS ("m+ri") && (IS_REG (patternr[2], SB_REGNO))));
1042
    }
1043
  else if (memcmp (str, "Sp", 2) == 0)
1044
    {
1045
      /* Absolute addresses 0..0x1fff used for bit addressing (I/O ports) */
1046
      return (RTX_IS ("mi")
1047
              && !(INTVAL (patternr[1]) & ~0x1fff));
1048
    }
1049
  else if (memcmp (str, "S1", 2) == 0)
1050
    {
1051
      return r1h_operand (value, QImode);
1052
    }
1053
 
1054
  gcc_assert (str[0] != 'S');
1055
 
1056
  if (memcmp (str, "Rpa", 2) == 0)
1057
    return GET_CODE (value) == PARALLEL;
1058
 
1059
  return 0;
1060
}
1061
 
1062
/* This is for when we're debugging the above.  */
1063
int
1064
m32c_extra_constraint_p (rtx value, char c, const char *str)
1065
{
1066
  int rv = m32c_extra_constraint_p2 (value, c, str);
1067
#if DEBUG0
1068
  fprintf (stderr, "\nconstraint %.*s: %d\n", CONSTRAINT_LEN (c, str), str,
1069
           rv);
1070
  debug_rtx (value);
1071
#endif
1072
  return rv;
1073
}
1074
 
1075
/* Implements EXTRA_MEMORY_CONSTRAINT.  Currently, we only use strings
1076
   starting with 'S'.  */
1077
int
1078
m32c_extra_memory_constraint (char c, const char *str ATTRIBUTE_UNUSED)
1079
{
1080
  return c == 'S';
1081
}
1082
 
1083
/* Implements EXTRA_ADDRESS_CONSTRAINT.  We reserve 'A' strings for these,
1084
   but don't currently define any.  */
1085
int
1086
m32c_extra_address_constraint (char c, const char *str ATTRIBUTE_UNUSED)
1087
{
1088
  return c == 'A';
1089
}
1090
 
1091
/* STACK AND CALLING */
1092
 
1093
/* Frame Layout */
1094
 
1095
/* Implements RETURN_ADDR_RTX.  Note that R8C and M16C push 24 bits
1096
   (yes, THREE bytes) onto the stack for the return address, but we
1097
   don't support pointers bigger than 16 bits on those chips.  This
1098
   will likely wreak havoc with exception unwinding.  FIXME.  */
1099
rtx
1100
m32c_return_addr_rtx (int count)
1101
{
1102
  enum machine_mode mode;
1103
  int offset;
1104
  rtx ra_mem;
1105
 
1106
  if (count)
1107
    return NULL_RTX;
1108
  /* we want 2[$fb] */
1109
 
1110
  if (TARGET_A24)
1111
    {
1112
      /* It's four bytes */
1113
      mode = PSImode;
1114
      offset = 4;
1115
    }
1116
  else
1117
    {
1118
      /* FIXME: it's really 3 bytes */
1119
      mode = HImode;
1120
      offset = 2;
1121
    }
1122
 
1123
  ra_mem =
1124
    gen_rtx_MEM (mode, plus_constant (gen_rtx_REG (Pmode, FP_REGNO), offset));
1125
  return copy_to_mode_reg (mode, ra_mem);
1126
}
1127
 
1128
/* Implements INCOMING_RETURN_ADDR_RTX.  See comment above.  */
1129
rtx
1130
m32c_incoming_return_addr_rtx (void)
1131
{
1132
  /* we want [sp] */
1133
  return gen_rtx_MEM (PSImode, gen_rtx_REG (PSImode, SP_REGNO));
1134
}
1135
 
1136
/* Exception Handling Support */
1137
 
1138
/* Implements EH_RETURN_DATA_REGNO.  Choose registers able to hold
1139
   pointers.  */
1140
int
1141
m32c_eh_return_data_regno (int n)
1142
{
1143
  switch (n)
1144
    {
1145
    case 0:
1146
      return A0_REGNO;
1147
    case 1:
1148
      if (TARGET_A16)
1149
        return R3_REGNO;
1150
      else
1151
        return R1_REGNO;
1152
    default:
1153
      return INVALID_REGNUM;
1154
    }
1155
}
1156
 
1157
/* Implements EH_RETURN_STACKADJ_RTX.  Saved and used later in
1158
   m32c_emit_eh_epilogue.  */
1159
rtx
1160
m32c_eh_return_stackadj_rtx (void)
1161
{
1162
  if (!cfun->machine->eh_stack_adjust)
1163
    {
1164
      rtx sa;
1165
 
1166
      sa = gen_rtx_REG (Pmode, R0_REGNO);
1167
      cfun->machine->eh_stack_adjust = sa;
1168
    }
1169
  return cfun->machine->eh_stack_adjust;
1170
}
1171
 
1172
/* Registers That Address the Stack Frame */
1173
 
1174
/* Implements DWARF_FRAME_REGNUM and DBX_REGISTER_NUMBER.  Note that
1175
   the original spec called for dwarf numbers to vary with register
1176
   width as well, for example, r0l, r0, and r2r0 would each have
1177
   different dwarf numbers.  GCC doesn't support this, and we don't do
1178
   it, and gdb seems to like it this way anyway.  */
1179
unsigned int
1180
m32c_dwarf_frame_regnum (int n)
1181
{
1182
  switch (n)
1183
    {
1184
    case R0_REGNO:
1185
      return 5;
1186
    case R1_REGNO:
1187
      return 6;
1188
    case R2_REGNO:
1189
      return 7;
1190
    case R3_REGNO:
1191
      return 8;
1192
    case A0_REGNO:
1193
      return 9;
1194
    case A1_REGNO:
1195
      return 10;
1196
    case FB_REGNO:
1197
      return 11;
1198
    case SB_REGNO:
1199
      return 19;
1200
 
1201
    case SP_REGNO:
1202
      return 12;
1203
    case PC_REGNO:
1204
      return 13;
1205
    default:
1206
      return DWARF_FRAME_REGISTERS + 1;
1207
    }
1208
}
1209
 
1210
/* The frame looks like this:
1211
 
1212
   ap -> +------------------------------
1213
         | Return address (3 or 4 bytes)
1214
         | Saved FB (2 or 4 bytes)
1215
   fb -> +------------------------------
1216
         | local vars
1217
         | register saves fb
1218
         |        through r0 as needed
1219
   sp -> +------------------------------
1220
*/
1221
 
1222
/* We use this to wrap all emitted insns in the prologue.  */
1223
static rtx
1224
F (rtx x)
1225
{
1226
  RTX_FRAME_RELATED_P (x) = 1;
1227
  return x;
1228
}
1229
 
1230
/* This maps register numbers to the PUSHM/POPM bitfield, and tells us
1231
   how much the stack pointer moves for each, for each cpu family.  */
1232
static struct
1233
{
1234
  int reg1;
1235
  int bit;
1236
  int a16_bytes;
1237
  int a24_bytes;
1238
} pushm_info[] =
1239
{
1240
  /* These are in reverse push (nearest-to-sp) order.  */
1241
  { R0_REGNO, 0x80, 2, 2 },
1242
  { R1_REGNO, 0x40, 2, 2 },
1243
  { R2_REGNO, 0x20, 2, 2 },
1244
  { R3_REGNO, 0x10, 2, 2 },
1245
  { A0_REGNO, 0x08, 2, 4 },
1246
  { A1_REGNO, 0x04, 2, 4 },
1247
  { SB_REGNO, 0x02, 2, 4 },
1248
  { FB_REGNO, 0x01, 2, 4 }
1249
};
1250
 
1251
#define PUSHM_N (sizeof(pushm_info)/sizeof(pushm_info[0]))
1252
 
1253
/* Returns TRUE if we need to save/restore the given register.  We
1254
   save everything for exception handlers, so that any register can be
1255
   unwound.  For interrupt handlers, we save everything if the handler
1256
   calls something else (because we don't know what *that* function
1257
   might do), but try to be a bit smarter if the handler is a leaf
1258
   function.  We always save $a0, though, because we use that in the
1259
   epilogue to copy $fb to $sp.  */
1260
static int
1261
need_to_save (int regno)
1262
{
1263
  if (fixed_regs[regno])
1264
    return 0;
1265
  if (crtl->calls_eh_return)
1266
    return 1;
1267
  if (regno == FP_REGNO)
1268
    return 0;
1269
  if (cfun->machine->is_interrupt
1270
      && (!cfun->machine->is_leaf
1271
          || (regno == A0_REGNO
1272
              && m32c_function_needs_enter ())
1273
          ))
1274
    return 1;
1275
  if (df_regs_ever_live_p (regno)
1276
      && (!call_used_regs[regno] || cfun->machine->is_interrupt))
1277
    return 1;
1278
  return 0;
1279
}
1280
 
1281
/* This function contains all the intelligence about saving and
1282
   restoring registers.  It always figures out the register save set.
1283
   When called with PP_justcount, it merely returns the size of the
1284
   save set (for eliminating the frame pointer, for example).  When
1285
   called with PP_pushm or PP_popm, it emits the appropriate
1286
   instructions for saving (pushm) or restoring (popm) the
1287
   registers.  */
1288
static int
1289
m32c_pushm_popm (Push_Pop_Type ppt)
1290
{
1291
  int reg_mask = 0;
1292
  int byte_count = 0, bytes;
1293
  int i;
1294
  rtx dwarf_set[PUSHM_N];
1295
  int n_dwarfs = 0;
1296
  int nosave_mask = 0;
1297
 
1298
  if (crtl->return_rtx
1299
      && GET_CODE (crtl->return_rtx) == PARALLEL
1300
      && !(crtl->calls_eh_return || cfun->machine->is_interrupt))
1301
    {
1302
      rtx exp = XVECEXP (crtl->return_rtx, 0, 0);
1303
      rtx rv = XEXP (exp, 0);
1304
      int rv_bytes = GET_MODE_SIZE (GET_MODE (rv));
1305
 
1306
      if (rv_bytes > 2)
1307
        nosave_mask |= 0x20;    /* PSI, SI */
1308
      else
1309
        nosave_mask |= 0xf0;    /* DF */
1310
      if (rv_bytes > 4)
1311
        nosave_mask |= 0x50;    /* DI */
1312
    }
1313
 
1314
  for (i = 0; i < (int) PUSHM_N; i++)
1315
    {
1316
      /* Skip if neither register needs saving.  */
1317
      if (!need_to_save (pushm_info[i].reg1))
1318
        continue;
1319
 
1320
      if (pushm_info[i].bit & nosave_mask)
1321
        continue;
1322
 
1323
      reg_mask |= pushm_info[i].bit;
1324
      bytes = TARGET_A16 ? pushm_info[i].a16_bytes : pushm_info[i].a24_bytes;
1325
 
1326
      if (ppt == PP_pushm)
1327
        {
1328
          enum machine_mode mode = (bytes == 2) ? HImode : SImode;
1329
          rtx addr;
1330
 
1331
          /* Always use stack_pointer_rtx instead of calling
1332
             rtx_gen_REG ourselves.  Code elsewhere in GCC assumes
1333
             that there is a single rtx representing the stack pointer,
1334
             namely stack_pointer_rtx, and uses == to recognize it.  */
1335
          addr = stack_pointer_rtx;
1336
 
1337
          if (byte_count != 0)
1338
            addr = gen_rtx_PLUS (GET_MODE (addr), addr, GEN_INT (byte_count));
1339
 
1340
          dwarf_set[n_dwarfs++] =
1341
            gen_rtx_SET (VOIDmode,
1342
                         gen_rtx_MEM (mode, addr),
1343
                         gen_rtx_REG (mode, pushm_info[i].reg1));
1344
          F (dwarf_set[n_dwarfs - 1]);
1345
 
1346
        }
1347
      byte_count += bytes;
1348
    }
1349
 
1350
  if (cfun->machine->is_interrupt)
1351
    {
1352
      cfun->machine->intr_pushm = reg_mask & 0xfe;
1353
      reg_mask = 0;
1354
      byte_count = 0;
1355
    }
1356
 
1357
  if (cfun->machine->is_interrupt)
1358
    for (i = MEM0_REGNO; i <= MEM7_REGNO; i++)
1359
      if (need_to_save (i))
1360
        {
1361
          byte_count += 2;
1362
          cfun->machine->intr_pushmem[i - MEM0_REGNO] = 1;
1363
        }
1364
 
1365
  if (ppt == PP_pushm && byte_count)
1366
    {
1367
      rtx note = gen_rtx_SEQUENCE (VOIDmode, rtvec_alloc (n_dwarfs + 1));
1368
      rtx pushm;
1369
 
1370
      if (reg_mask)
1371
        {
1372
          XVECEXP (note, 0, 0)
1373
            = gen_rtx_SET (VOIDmode,
1374
                           stack_pointer_rtx,
1375
                           gen_rtx_PLUS (GET_MODE (stack_pointer_rtx),
1376
                                         stack_pointer_rtx,
1377
                                         GEN_INT (-byte_count)));
1378
          F (XVECEXP (note, 0, 0));
1379
 
1380
          for (i = 0; i < n_dwarfs; i++)
1381
            XVECEXP (note, 0, i + 1) = dwarf_set[i];
1382
 
1383
          pushm = F (emit_insn (gen_pushm (GEN_INT (reg_mask))));
1384
 
1385
          REG_NOTES (pushm) = gen_rtx_EXPR_LIST (REG_FRAME_RELATED_EXPR, note,
1386
                                                 REG_NOTES (pushm));
1387
        }
1388
 
1389
      if (cfun->machine->is_interrupt)
1390
        for (i = MEM0_REGNO; i <= MEM7_REGNO; i++)
1391
          if (cfun->machine->intr_pushmem[i - MEM0_REGNO])
1392
            {
1393
              if (TARGET_A16)
1394
                pushm = emit_insn (gen_pushhi_16 (gen_rtx_REG (HImode, i)));
1395
              else
1396
                pushm = emit_insn (gen_pushhi_24 (gen_rtx_REG (HImode, i)));
1397
              F (pushm);
1398
            }
1399
    }
1400
  if (ppt == PP_popm && byte_count)
1401
    {
1402
      if (cfun->machine->is_interrupt)
1403
        for (i = MEM7_REGNO; i >= MEM0_REGNO; i--)
1404
          if (cfun->machine->intr_pushmem[i - MEM0_REGNO])
1405
            {
1406
              if (TARGET_A16)
1407
                emit_insn (gen_pophi_16 (gen_rtx_REG (HImode, i)));
1408
              else
1409
                emit_insn (gen_pophi_24 (gen_rtx_REG (HImode, i)));
1410
            }
1411
      if (reg_mask)
1412
        emit_insn (gen_popm (GEN_INT (reg_mask)));
1413
    }
1414
 
1415
  return byte_count;
1416
}
1417
 
1418
/* Implements INITIAL_ELIMINATION_OFFSET.  See the comment above that
1419
   diagrams our call frame.  */
1420
int
1421
m32c_initial_elimination_offset (int from, int to)
1422
{
1423
  int ofs = 0;
1424
 
1425
  if (from == AP_REGNO)
1426
    {
1427
      if (TARGET_A16)
1428
        ofs += 5;
1429
      else
1430
        ofs += 8;
1431
    }
1432
 
1433
  if (to == SP_REGNO)
1434
    {
1435
      ofs += m32c_pushm_popm (PP_justcount);
1436
      ofs += get_frame_size ();
1437
    }
1438
 
1439
  /* Account for push rounding.  */
1440
  if (TARGET_A24)
1441
    ofs = (ofs + 1) & ~1;
1442
#if DEBUG0
1443
  fprintf (stderr, "initial_elimination_offset from=%d to=%d, ofs=%d\n", from,
1444
           to, ofs);
1445
#endif
1446
  return ofs;
1447
}
1448
 
1449
/* Passing Function Arguments on the Stack */
1450
 
1451
/* Implements PUSH_ROUNDING.  The R8C and M16C have byte stacks, the
1452
   M32C has word stacks.  */
1453
int
1454
m32c_push_rounding (int n)
1455
{
1456
  if (TARGET_R8C || TARGET_M16C)
1457
    return n;
1458
  return (n + 1) & ~1;
1459
}
1460
 
1461
/* Passing Arguments in Registers */
1462
 
1463
/* Implements FUNCTION_ARG.  Arguments are passed partly in registers,
1464
   partly on stack.  If our function returns a struct, a pointer to a
1465
   buffer for it is at the top of the stack (last thing pushed).  The
1466
   first few real arguments may be in registers as follows:
1467
 
1468
   R8C/M16C:    arg1 in r1 if it's QI or HI (else it's pushed on stack)
1469
                arg2 in r2 if it's HI (else pushed on stack)
1470
                rest on stack
1471
   M32C:        arg1 in r0 if it's QI or HI (else it's pushed on stack)
1472
                rest on stack
1473
 
1474
   Structs are not passed in registers, even if they fit.  Only
1475
   integer and pointer types are passed in registers.
1476
 
1477
   Note that when arg1 doesn't fit in r1, arg2 may still be passed in
1478
   r2 if it fits.  */
1479
rtx
1480
m32c_function_arg (CUMULATIVE_ARGS * ca,
1481
                   enum machine_mode mode, tree type, int named)
1482
{
1483
  /* Can return a reg, parallel, or 0 for stack */
1484
  rtx rv = NULL_RTX;
1485
#if DEBUG0
1486
  fprintf (stderr, "func_arg %d (%s, %d)\n",
1487
           ca->parm_num, mode_name[mode], named);
1488
  debug_tree (type);
1489
#endif
1490
 
1491
  if (mode == VOIDmode)
1492
    return GEN_INT (0);
1493
 
1494
  if (ca->force_mem || !named)
1495
    {
1496
#if DEBUG0
1497
      fprintf (stderr, "func arg: force %d named %d, mem\n", ca->force_mem,
1498
               named);
1499
#endif
1500
      return NULL_RTX;
1501
    }
1502
 
1503
  if (type && INTEGRAL_TYPE_P (type) && POINTER_TYPE_P (type))
1504
    return NULL_RTX;
1505
 
1506
  if (type && AGGREGATE_TYPE_P (type))
1507
    return NULL_RTX;
1508
 
1509
  switch (ca->parm_num)
1510
    {
1511
    case 1:
1512
      if (GET_MODE_SIZE (mode) == 1 || GET_MODE_SIZE (mode) == 2)
1513
        rv = gen_rtx_REG (mode, TARGET_A16 ? R1_REGNO : R0_REGNO);
1514
      break;
1515
 
1516
    case 2:
1517
      if (TARGET_A16 && GET_MODE_SIZE (mode) == 2)
1518
        rv = gen_rtx_REG (mode, R2_REGNO);
1519
      break;
1520
    }
1521
 
1522
#if DEBUG0
1523
  debug_rtx (rv);
1524
#endif
1525
  return rv;
1526
}
1527
 
1528
#undef TARGET_PASS_BY_REFERENCE
1529
#define TARGET_PASS_BY_REFERENCE m32c_pass_by_reference
1530
static bool
1531
m32c_pass_by_reference (CUMULATIVE_ARGS * ca ATTRIBUTE_UNUSED,
1532
                        enum machine_mode mode ATTRIBUTE_UNUSED,
1533
                        const_tree type ATTRIBUTE_UNUSED,
1534
                        bool named ATTRIBUTE_UNUSED)
1535
{
1536
  return 0;
1537
}
1538
 
1539
/* Implements INIT_CUMULATIVE_ARGS.  */
1540
void
1541
m32c_init_cumulative_args (CUMULATIVE_ARGS * ca,
1542
                           tree fntype,
1543
                           rtx libname ATTRIBUTE_UNUSED,
1544
                           tree fndecl,
1545
                           int n_named_args ATTRIBUTE_UNUSED)
1546
{
1547
  if (fntype && aggregate_value_p (TREE_TYPE (fntype), fndecl))
1548
    ca->force_mem = 1;
1549
  else
1550
    ca->force_mem = 0;
1551
  ca->parm_num = 1;
1552
}
1553
 
1554
/* Implements FUNCTION_ARG_ADVANCE.  force_mem is set for functions
1555
   returning structures, so we always reset that.  Otherwise, we only
1556
   need to know the sequence number of the argument to know what to do
1557
   with it.  */
1558
void
1559
m32c_function_arg_advance (CUMULATIVE_ARGS * ca,
1560
                           enum machine_mode mode ATTRIBUTE_UNUSED,
1561
                           tree type ATTRIBUTE_UNUSED,
1562
                           int named ATTRIBUTE_UNUSED)
1563
{
1564
  if (ca->force_mem)
1565
    ca->force_mem = 0;
1566
  else
1567
    ca->parm_num++;
1568
}
1569
 
1570
/* Implements FUNCTION_ARG_REGNO_P.  */
1571
int
1572
m32c_function_arg_regno_p (int r)
1573
{
1574
  if (TARGET_A24)
1575
    return (r == R0_REGNO);
1576
  return (r == R1_REGNO || r == R2_REGNO);
1577
}
1578
 
1579
/* HImode and PSImode are the two "native" modes as far as GCC is
1580
   concerned, but the chips also support a 32-bit mode which is used
1581
   for some opcodes in R8C/M16C and for reset vectors and such.  */
1582
#undef TARGET_VALID_POINTER_MODE
1583
#define TARGET_VALID_POINTER_MODE m32c_valid_pointer_mode
1584
static bool
1585
m32c_valid_pointer_mode (enum machine_mode mode)
1586
{
1587
  if (mode == HImode
1588
      || mode == PSImode
1589
      || mode == SImode
1590
      )
1591
    return 1;
1592
  return 0;
1593
}
1594
 
1595
/* How Scalar Function Values Are Returned */
1596
 
1597
/* Implements TARGET_LIBCALL_VALUE.  Most values are returned in $r0, or some
1598
   combination of registers starting there (r2r0 for longs, r3r1r2r0
1599
   for long long, r3r2r1r0 for doubles), except that that ABI
1600
   currently doesn't work because it ends up using all available
1601
   general registers and gcc often can't compile it.  So, instead, we
1602
   return anything bigger than 16 bits in "mem0" (effectively, a
1603
   memory location).  */
1604
 
1605
#undef TARGET_LIBCALL_VALUE
1606
#define TARGET_LIBCALL_VALUE m32c_libcall_value
1607
 
1608
static rtx
1609
m32c_libcall_value (enum machine_mode mode, const_rtx fun ATTRIBUTE_UNUSED)
1610
{
1611
  /* return reg or parallel */
1612
#if 0
1613
  /* FIXME: GCC has difficulty returning large values in registers,
1614
     because that ties up most of the general registers and gives the
1615
     register allocator little to work with.  Until we can resolve
1616
     this, large values are returned in memory.  */
1617
  if (mode == DFmode)
1618
    {
1619
      rtx rv;
1620
 
1621
      rv = gen_rtx_PARALLEL (mode, rtvec_alloc (4));
1622
      XVECEXP (rv, 0, 0) = gen_rtx_EXPR_LIST (VOIDmode,
1623
                                              gen_rtx_REG (HImode,
1624
                                                           R0_REGNO),
1625
                                              GEN_INT (0));
1626
      XVECEXP (rv, 0, 1) = gen_rtx_EXPR_LIST (VOIDmode,
1627
                                              gen_rtx_REG (HImode,
1628
                                                           R1_REGNO),
1629
                                              GEN_INT (2));
1630
      XVECEXP (rv, 0, 2) = gen_rtx_EXPR_LIST (VOIDmode,
1631
                                              gen_rtx_REG (HImode,
1632
                                                           R2_REGNO),
1633
                                              GEN_INT (4));
1634
      XVECEXP (rv, 0, 3) = gen_rtx_EXPR_LIST (VOIDmode,
1635
                                              gen_rtx_REG (HImode,
1636
                                                           R3_REGNO),
1637
                                              GEN_INT (6));
1638
      return rv;
1639
    }
1640
 
1641
  if (TARGET_A24 && GET_MODE_SIZE (mode) > 2)
1642
    {
1643
      rtx rv;
1644
 
1645
      rv = gen_rtx_PARALLEL (mode, rtvec_alloc (1));
1646
      XVECEXP (rv, 0, 0) = gen_rtx_EXPR_LIST (VOIDmode,
1647
                                              gen_rtx_REG (mode,
1648
                                                           R0_REGNO),
1649
                                              GEN_INT (0));
1650
      return rv;
1651
    }
1652
#endif
1653
 
1654
  if (GET_MODE_SIZE (mode) > 2)
1655
    return gen_rtx_REG (mode, MEM0_REGNO);
1656
  return gen_rtx_REG (mode, R0_REGNO);
1657
}
1658
 
1659
/* Implements TARGET_FUNCTION_VALUE.  Functions and libcalls have the same
1660
   conventions.  */
1661
 
1662
#undef TARGET_FUNCTION_VALUE
1663
#define TARGET_FUNCTION_VALUE m32c_function_value
1664
 
1665
static rtx
1666
m32c_function_value (const_tree valtype,
1667
                     const_tree fn_decl_or_type ATTRIBUTE_UNUSED,
1668
                     bool outgoing ATTRIBUTE_UNUSED)
1669
{
1670
  /* return reg or parallel */
1671
  const enum machine_mode mode = TYPE_MODE (valtype);
1672
  return m32c_libcall_value (mode, NULL_RTX);
1673
}
1674
 
1675
/* Implements FUNCTION_VALUE_REGNO_P.  */
1676
 
1677
bool
1678
m32c_function_value_regno_p (const unsigned int regno)
1679
{
1680
  return (regno == R0_REGNO || regno == MEM0_REGNO);
1681
}
1682
 
1683
/* How Large Values Are Returned */
1684
 
1685
/* We return structures by pushing the address on the stack, even if
1686
   we use registers for the first few "real" arguments.  */
1687
#undef TARGET_STRUCT_VALUE_RTX
1688
#define TARGET_STRUCT_VALUE_RTX m32c_struct_value_rtx
1689
static rtx
1690
m32c_struct_value_rtx (tree fndecl ATTRIBUTE_UNUSED,
1691
                       int incoming ATTRIBUTE_UNUSED)
1692
{
1693
  return 0;
1694
}
1695
 
1696
/* Function Entry and Exit */
1697
 
1698
/* Implements EPILOGUE_USES.  Interrupts restore all registers.  */
1699
int
1700
m32c_epilogue_uses (int regno ATTRIBUTE_UNUSED)
1701
{
1702
  if (cfun->machine->is_interrupt)
1703
    return 1;
1704
  return 0;
1705
}
1706
 
1707
/* Implementing the Varargs Macros */
1708
 
1709
#undef TARGET_STRICT_ARGUMENT_NAMING
1710
#define TARGET_STRICT_ARGUMENT_NAMING m32c_strict_argument_naming
1711
static bool
1712
m32c_strict_argument_naming (CUMULATIVE_ARGS * ca ATTRIBUTE_UNUSED)
1713
{
1714
  return 1;
1715
}
1716
 
1717
/* Trampolines for Nested Functions */
1718
 
1719
/*
1720
   m16c:
1721
   1 0000 75C43412              mov.w   #0x1234,a0
1722
   2 0004 FC000000              jmp.a   label
1723
 
1724
   m32c:
1725
   1 0000 BC563412              mov.l:s #0x123456,a0
1726
   2 0004 CC000000              jmp.a   label
1727
*/
1728
 
1729
/* Implements TRAMPOLINE_SIZE.  */
1730
int
1731
m32c_trampoline_size (void)
1732
{
1733
  /* Allocate extra space so we can avoid the messy shifts when we
1734
     initialize the trampoline; we just write past the end of the
1735
     opcode.  */
1736
  return TARGET_A16 ? 8 : 10;
1737
}
1738
 
1739
/* Implements TRAMPOLINE_ALIGNMENT.  */
1740
int
1741
m32c_trampoline_alignment (void)
1742
{
1743
  return 2;
1744
}
1745
 
1746
/* Implements TARGET_TRAMPOLINE_INIT.  */
1747
 
1748
#undef TARGET_TRAMPOLINE_INIT
1749
#define TARGET_TRAMPOLINE_INIT m32c_trampoline_init
1750
static void
1751
m32c_trampoline_init (rtx m_tramp, tree fndecl, rtx chainval)
1752
{
1753
  rtx function = XEXP (DECL_RTL (fndecl), 0);
1754
 
1755
#define A0(m,i) adjust_address (m_tramp, m, i)
1756
  if (TARGET_A16)
1757
    {
1758
      /* Note: we subtract a "word" because the moves want signed
1759
         constants, not unsigned constants.  */
1760
      emit_move_insn (A0 (HImode, 0), GEN_INT (0xc475 - 0x10000));
1761
      emit_move_insn (A0 (HImode, 2), chainval);
1762
      emit_move_insn (A0 (QImode, 4), GEN_INT (0xfc - 0x100));
1763
      /* We use 16-bit addresses here, but store the zero to turn it
1764
         into a 24-bit offset.  */
1765
      emit_move_insn (A0 (HImode, 5), function);
1766
      emit_move_insn (A0 (QImode, 7), GEN_INT (0x00));
1767
    }
1768
  else
1769
    {
1770
      /* Note that the PSI moves actually write 4 bytes.  Make sure we
1771
         write stuff out in the right order, and leave room for the
1772
         extra byte at the end.  */
1773
      emit_move_insn (A0 (QImode, 0), GEN_INT (0xbc - 0x100));
1774
      emit_move_insn (A0 (PSImode, 1), chainval);
1775
      emit_move_insn (A0 (QImode, 4), GEN_INT (0xcc - 0x100));
1776
      emit_move_insn (A0 (PSImode, 5), function);
1777
    }
1778
#undef A0
1779
}
1780
 
1781
/* Implicit Calls to Library Routines */
1782
 
1783
#undef TARGET_INIT_LIBFUNCS
1784
#define TARGET_INIT_LIBFUNCS m32c_init_libfuncs
1785
static void
1786
m32c_init_libfuncs (void)
1787
{
1788
  /* We do this because the M32C has an HImode operand, but the
1789
     M16C has an 8-bit operand.  Since gcc looks at the match data
1790
     and not the expanded rtl, we have to reset the optab so that
1791
     the right modes are found. */
1792
  if (TARGET_A24)
1793
    {
1794
      optab_handler (cstore_optab, QImode)->insn_code = CODE_FOR_cstoreqi4_24;
1795
      optab_handler (cstore_optab, HImode)->insn_code = CODE_FOR_cstorehi4_24;
1796
      optab_handler (cstore_optab, PSImode)->insn_code = CODE_FOR_cstorepsi4_24;
1797
    }
1798
}
1799
 
1800
/* Addressing Modes */
1801
 
1802
/* The r8c/m32c family supports a wide range of non-orthogonal
1803
   addressing modes, including the ability to double-indirect on *some*
1804
   of them.  Not all insns support all modes, either, but we rely on
1805
   predicates and constraints to deal with that.  */
1806
#undef TARGET_LEGITIMATE_ADDRESS_P
1807
#define TARGET_LEGITIMATE_ADDRESS_P m32c_legitimate_address_p
1808
bool
1809
m32c_legitimate_address_p (enum machine_mode mode, rtx x, bool strict)
1810
{
1811
  int mode_adjust;
1812
  if (CONSTANT_P (x))
1813
    return 1;
1814
 
1815
  /* Wide references to memory will be split after reload, so we must
1816
     ensure that all parts of such splits remain legitimate
1817
     addresses.  */
1818
  mode_adjust = GET_MODE_SIZE (mode) - 1;
1819
 
1820
  /* allowing PLUS yields mem:HI(plus:SI(mem:SI(plus:SI in m32c_split_move */
1821
  if (GET_CODE (x) == PRE_DEC
1822
      || GET_CODE (x) == POST_INC || GET_CODE (x) == PRE_MODIFY)
1823
    {
1824
      return (GET_CODE (XEXP (x, 0)) == REG
1825
              && REGNO (XEXP (x, 0)) == SP_REGNO);
1826
    }
1827
 
1828
#if 0
1829
  /* This is the double indirection detection, but it currently
1830
     doesn't work as cleanly as this code implies, so until we've had
1831
     a chance to debug it, leave it disabled.  */
1832
  if (TARGET_A24 && GET_CODE (x) == MEM && GET_CODE (XEXP (x, 0)) != PLUS)
1833
    {
1834
#if DEBUG_DOUBLE
1835
      fprintf (stderr, "double indirect\n");
1836
#endif
1837
      x = XEXP (x, 0);
1838
    }
1839
#endif
1840
 
1841
  encode_pattern (x);
1842
  if (RTX_IS ("r"))
1843
    {
1844
      /* Most indexable registers can be used without displacements,
1845
         although some of them will be emitted with an explicit zero
1846
         to please the assembler.  */
1847
      switch (REGNO (patternr[0]))
1848
        {
1849
        case A0_REGNO:
1850
        case A1_REGNO:
1851
        case SB_REGNO:
1852
        case FB_REGNO:
1853
        case SP_REGNO:
1854
          return 1;
1855
 
1856
        default:
1857
          if (IS_PSEUDO (patternr[0], strict))
1858
            return 1;
1859
          return 0;
1860
        }
1861
    }
1862
  if (RTX_IS ("+ri"))
1863
    {
1864
      /* This is more interesting, because different base registers
1865
         allow for different displacements - both range and signedness
1866
         - and it differs from chip series to chip series too.  */
1867
      int rn = REGNO (patternr[1]);
1868
      HOST_WIDE_INT offs = INTVAL (patternr[2]);
1869
      switch (rn)
1870
        {
1871
        case A0_REGNO:
1872
        case A1_REGNO:
1873
        case SB_REGNO:
1874
          /* The syntax only allows positive offsets, but when the
1875
             offsets span the entire memory range, we can simulate
1876
             negative offsets by wrapping.  */
1877
          if (TARGET_A16)
1878
            return (offs >= -65536 && offs <= 65535 - mode_adjust);
1879
          if (rn == SB_REGNO)
1880
            return (offs >= 0 && offs <= 65535 - mode_adjust);
1881
          /* A0 or A1 */
1882
          return (offs >= -16777216 && offs <= 16777215);
1883
 
1884
        case FB_REGNO:
1885
          if (TARGET_A16)
1886
            return (offs >= -128 && offs <= 127 - mode_adjust);
1887
          return (offs >= -65536 && offs <= 65535 - mode_adjust);
1888
 
1889
        case SP_REGNO:
1890
          return (offs >= -128 && offs <= 127 - mode_adjust);
1891
 
1892
        default:
1893
          if (IS_PSEUDO (patternr[1], strict))
1894
            return 1;
1895
          return 0;
1896
        }
1897
    }
1898
  if (RTX_IS ("+rs") || RTX_IS ("+r+si"))
1899
    {
1900
      rtx reg = patternr[1];
1901
 
1902
      /* We don't know where the symbol is, so only allow base
1903
         registers which support displacements spanning the whole
1904
         address range.  */
1905
      switch (REGNO (reg))
1906
        {
1907
        case A0_REGNO:
1908
        case A1_REGNO:
1909
          /* $sb needs a secondary reload, but since it's involved in
1910
             memory address reloads too, we don't deal with it very
1911
             well.  */
1912
          /*    case SB_REGNO: */
1913
          return 1;
1914
        default:
1915
          if (IS_PSEUDO (reg, strict))
1916
            return 1;
1917
          return 0;
1918
        }
1919
    }
1920
  return 0;
1921
}
1922
 
1923
/* Implements REG_OK_FOR_BASE_P.  */
1924
int
1925
m32c_reg_ok_for_base_p (rtx x, int strict)
1926
{
1927
  if (GET_CODE (x) != REG)
1928
    return 0;
1929
  switch (REGNO (x))
1930
    {
1931
    case A0_REGNO:
1932
    case A1_REGNO:
1933
    case SB_REGNO:
1934
    case FB_REGNO:
1935
    case SP_REGNO:
1936
      return 1;
1937
    default:
1938
      if (IS_PSEUDO (x, strict))
1939
        return 1;
1940
      return 0;
1941
    }
1942
}
1943
 
1944
/* We have three choices for choosing fb->aN offsets.  If we choose -128,
1945
   we need one MOVA -128[fb],aN opcode and 16-bit aN displacements,
1946
   like this:
1947
       EB 4B FF    mova    -128[$fb],$a0
1948
       D8 0C FF FF mov.w:Q #0,-1[$a0]
1949
 
1950
   Alternately, we subtract the frame size, and hopefully use 8-bit aN
1951
   displacements:
1952
       7B F4       stc $fb,$a0
1953
       77 54 00 01 sub #256,$a0
1954
       D8 08 01    mov.w:Q #0,1[$a0]
1955
 
1956
   If we don't offset (i.e. offset by zero), we end up with:
1957
       7B F4       stc $fb,$a0
1958
       D8 0C 00 FF mov.w:Q #0,-256[$a0]
1959
 
1960
   We have to subtract *something* so that we have a PLUS rtx to mark
1961
   that we've done this reload.  The -128 offset will never result in
1962
   an 8-bit aN offset, and the payoff for the second case is five
1963
   loads *if* those loads are within 256 bytes of the other end of the
1964
   frame, so the third case seems best.  Note that we subtract the
1965
   zero, but detect that in the addhi3 pattern.  */
1966
 
1967
#define BIG_FB_ADJ 0
1968
 
1969
/* Implements LEGITIMIZE_ADDRESS.  The only address we really have to
1970
   worry about is frame base offsets, as $fb has a limited
1971
   displacement range.  We deal with this by attempting to reload $fb
1972
   itself into an address register; that seems to result in the best
1973
   code.  */
1974
#undef TARGET_LEGITIMIZE_ADDRESS
1975
#define TARGET_LEGITIMIZE_ADDRESS m32c_legitimize_address
1976
static rtx
1977
m32c_legitimize_address (rtx x, rtx oldx ATTRIBUTE_UNUSED,
1978
                         enum machine_mode mode)
1979
{
1980
#if DEBUG0
1981
  fprintf (stderr, "m32c_legitimize_address for mode %s\n", mode_name[mode]);
1982
  debug_rtx (x);
1983
  fprintf (stderr, "\n");
1984
#endif
1985
 
1986
  if (GET_CODE (x) == PLUS
1987
      && GET_CODE (XEXP (x, 0)) == REG
1988
      && REGNO (XEXP (x, 0)) == FB_REGNO
1989
      && GET_CODE (XEXP (x, 1)) == CONST_INT
1990
      && (INTVAL (XEXP (x, 1)) < -128
1991
          || INTVAL (XEXP (x, 1)) > (128 - GET_MODE_SIZE (mode))))
1992
    {
1993
      /* reload FB to A_REGS */
1994
      rtx temp = gen_reg_rtx (Pmode);
1995
      x = copy_rtx (x);
1996
      emit_insn (gen_rtx_SET (VOIDmode, temp, XEXP (x, 0)));
1997
      XEXP (x, 0) = temp;
1998
    }
1999
 
2000
  return x;
2001
}
2002
 
2003
/* Implements LEGITIMIZE_RELOAD_ADDRESS.  See comment above.  */
2004
int
2005
m32c_legitimize_reload_address (rtx * x,
2006
                                enum machine_mode mode,
2007
                                int opnum,
2008
                                int type, int ind_levels ATTRIBUTE_UNUSED)
2009
{
2010
#if DEBUG0
2011
  fprintf (stderr, "\nm32c_legitimize_reload_address for mode %s\n",
2012
           mode_name[mode]);
2013
  debug_rtx (*x);
2014
#endif
2015
 
2016
  /* At one point, this function tried to get $fb copied to an address
2017
     register, which in theory would maximize sharing, but gcc was
2018
     *also* still trying to reload the whole address, and we'd run out
2019
     of address registers.  So we let gcc do the naive (but safe)
2020
     reload instead, when the above function doesn't handle it for
2021
     us.
2022
 
2023
     The code below is a second attempt at the above.  */
2024
 
2025
  if (GET_CODE (*x) == PLUS
2026
      && GET_CODE (XEXP (*x, 0)) == REG
2027
      && REGNO (XEXP (*x, 0)) == FB_REGNO
2028
      && GET_CODE (XEXP (*x, 1)) == CONST_INT
2029
      && (INTVAL (XEXP (*x, 1)) < -128
2030
          || INTVAL (XEXP (*x, 1)) > (128 - GET_MODE_SIZE (mode))))
2031
    {
2032
      rtx sum;
2033
      int offset = INTVAL (XEXP (*x, 1));
2034
      int adjustment = -BIG_FB_ADJ;
2035
 
2036
      sum = gen_rtx_PLUS (Pmode, XEXP (*x, 0),
2037
                          GEN_INT (adjustment));
2038
      *x = gen_rtx_PLUS (Pmode, sum, GEN_INT (offset - adjustment));
2039
      if (type == RELOAD_OTHER)
2040
        type = RELOAD_FOR_OTHER_ADDRESS;
2041
      push_reload (sum, NULL_RTX, &XEXP (*x, 0), NULL,
2042
                   A_REGS, Pmode, VOIDmode, 0, 0, opnum,
2043
                   type);
2044
      return 1;
2045
    }
2046
 
2047
  if (GET_CODE (*x) == PLUS
2048
      && GET_CODE (XEXP (*x, 0)) == PLUS
2049
      && GET_CODE (XEXP (XEXP (*x, 0), 0)) == REG
2050
      && REGNO (XEXP (XEXP (*x, 0), 0)) == FB_REGNO
2051
      && GET_CODE (XEXP (XEXP (*x, 0), 1)) == CONST_INT
2052
      && GET_CODE (XEXP (*x, 1)) == CONST_INT
2053
      )
2054
    {
2055
      if (type == RELOAD_OTHER)
2056
        type = RELOAD_FOR_OTHER_ADDRESS;
2057
      push_reload (XEXP (*x, 0), NULL_RTX, &XEXP (*x, 0), NULL,
2058
                   A_REGS, Pmode, VOIDmode, 0, 0, opnum,
2059
                   type);
2060
      return 1;
2061
    }
2062
 
2063
  return 0;
2064
}
2065
 
2066
/* Implements LEGITIMATE_CONSTANT_P.  We split large constants anyway,
2067
   so we can allow anything.  */
2068
int
2069
m32c_legitimate_constant_p (rtx x ATTRIBUTE_UNUSED)
2070
{
2071
  return 1;
2072
}
2073
 
2074
 
2075
/* Condition Code Status */
2076
 
2077
#undef TARGET_FIXED_CONDITION_CODE_REGS
2078
#define TARGET_FIXED_CONDITION_CODE_REGS m32c_fixed_condition_code_regs
2079
static bool
2080
m32c_fixed_condition_code_regs (unsigned int *p1, unsigned int *p2)
2081
{
2082
  *p1 = FLG_REGNO;
2083
  *p2 = INVALID_REGNUM;
2084
  return true;
2085
}
2086
 
2087
/* Describing Relative Costs of Operations */
2088
 
2089
/* Implements REGISTER_MOVE_COST.  We make impossible moves
2090
   prohibitively expensive, like trying to put QIs in r2/r3 (there are
2091
   no opcodes to do that).  We also discourage use of mem* registers
2092
   since they're really memory.  */
2093
int
2094
m32c_register_move_cost (enum machine_mode mode, int from, int to)
2095
{
2096
  int cost = COSTS_N_INSNS (3);
2097
  int cc = class_contents[from][0] | class_contents[to][0];
2098
  /* FIXME: pick real values, but not 2 for now.  */
2099
  if (mode == QImode && (cc & class_contents[R23_REGS][0]))
2100
    {
2101
      if (!(cc & ~class_contents[R23_REGS][0]))
2102
        cost = COSTS_N_INSNS (1000);
2103
      else
2104
        cost = COSTS_N_INSNS (80);
2105
    }
2106
 
2107
  if (!class_can_hold_mode (from, mode) || !class_can_hold_mode (to, mode))
2108
    cost = COSTS_N_INSNS (1000);
2109
 
2110
  if (classes_intersect (from, CR_REGS))
2111
    cost += COSTS_N_INSNS (5);
2112
 
2113
  if (classes_intersect (to, CR_REGS))
2114
    cost += COSTS_N_INSNS (5);
2115
 
2116
  if (from == MEM_REGS || to == MEM_REGS)
2117
    cost += COSTS_N_INSNS (50);
2118
  else if (classes_intersect (from, MEM_REGS)
2119
           || classes_intersect (to, MEM_REGS))
2120
    cost += COSTS_N_INSNS (10);
2121
 
2122
#if DEBUG0
2123
  fprintf (stderr, "register_move_cost %s from %s to %s = %d\n",
2124
           mode_name[mode], class_names[from], class_names[to], cost);
2125
#endif
2126
  return cost;
2127
}
2128
 
2129
/*  Implements MEMORY_MOVE_COST.  */
2130
int
2131
m32c_memory_move_cost (enum machine_mode mode ATTRIBUTE_UNUSED,
2132
                       int reg_class ATTRIBUTE_UNUSED,
2133
                       int in ATTRIBUTE_UNUSED)
2134
{
2135
  /* FIXME: pick real values.  */
2136
  return COSTS_N_INSNS (10);
2137
}
2138
 
2139
/* Here we try to describe when we use multiple opcodes for one RTX so
2140
   that gcc knows when to use them.  */
2141
#undef TARGET_RTX_COSTS
2142
#define TARGET_RTX_COSTS m32c_rtx_costs
2143
static bool
2144
m32c_rtx_costs (rtx x, int code, int outer_code, int *total,
2145
                bool speed ATTRIBUTE_UNUSED)
2146
{
2147
  switch (code)
2148
    {
2149
    case REG:
2150
      if (REGNO (x) >= MEM0_REGNO && REGNO (x) <= MEM7_REGNO)
2151
        *total += COSTS_N_INSNS (500);
2152
      else
2153
        *total += COSTS_N_INSNS (1);
2154
      return true;
2155
 
2156
    case ASHIFT:
2157
    case LSHIFTRT:
2158
    case ASHIFTRT:
2159
      if (GET_CODE (XEXP (x, 1)) != CONST_INT)
2160
        {
2161
          /* mov.b r1l, r1h */
2162
          *total +=  COSTS_N_INSNS (1);
2163
          return true;
2164
        }
2165
      if (INTVAL (XEXP (x, 1)) > 8
2166
          || INTVAL (XEXP (x, 1)) < -8)
2167
        {
2168
          /* mov.b #N, r1l */
2169
          /* mov.b r1l, r1h */
2170
          *total +=  COSTS_N_INSNS (2);
2171
          return true;
2172
        }
2173
      return true;
2174
 
2175
    case LE:
2176
    case LEU:
2177
    case LT:
2178
    case LTU:
2179
    case GT:
2180
    case GTU:
2181
    case GE:
2182
    case GEU:
2183
    case NE:
2184
    case EQ:
2185
      if (outer_code == SET)
2186
        {
2187
          *total += COSTS_N_INSNS (2);
2188
          return true;
2189
        }
2190
      break;
2191
 
2192
    case ZERO_EXTRACT:
2193
      {
2194
        rtx dest = XEXP (x, 0);
2195
        rtx addr = XEXP (dest, 0);
2196
        switch (GET_CODE (addr))
2197
          {
2198
          case CONST_INT:
2199
            *total += COSTS_N_INSNS (1);
2200
            break;
2201
          case SYMBOL_REF:
2202
            *total += COSTS_N_INSNS (3);
2203
            break;
2204
          default:
2205
            *total += COSTS_N_INSNS (2);
2206
            break;
2207
          }
2208
        return true;
2209
      }
2210
      break;
2211
 
2212
    default:
2213
      /* Reasonable default.  */
2214
      if (TARGET_A16 && GET_MODE(x) == SImode)
2215
        *total += COSTS_N_INSNS (2);
2216
      break;
2217
    }
2218
  return false;
2219
}
2220
 
2221
#undef TARGET_ADDRESS_COST
2222
#define TARGET_ADDRESS_COST m32c_address_cost
2223
static int
2224
m32c_address_cost (rtx addr, bool speed ATTRIBUTE_UNUSED)
2225
{
2226
  int i;
2227
  /*  fprintf(stderr, "\naddress_cost\n");
2228
      debug_rtx(addr);*/
2229
  switch (GET_CODE (addr))
2230
    {
2231
    case CONST_INT:
2232
      i = INTVAL (addr);
2233
      if (i == 0)
2234
        return COSTS_N_INSNS(1);
2235
      if (0 < i && i <= 255)
2236
        return COSTS_N_INSNS(2);
2237
      if (0 < i && i <= 65535)
2238
        return COSTS_N_INSNS(3);
2239
      return COSTS_N_INSNS(4);
2240
    case SYMBOL_REF:
2241
      return COSTS_N_INSNS(4);
2242
    case REG:
2243
      return COSTS_N_INSNS(1);
2244
    case PLUS:
2245
      if (GET_CODE (XEXP (addr, 1)) == CONST_INT)
2246
        {
2247
          i = INTVAL (XEXP (addr, 1));
2248
          if (i == 0)
2249
            return COSTS_N_INSNS(1);
2250
          if (0 < i && i <= 255)
2251
            return COSTS_N_INSNS(2);
2252
          if (0 < i && i <= 65535)
2253
            return COSTS_N_INSNS(3);
2254
        }
2255
      return COSTS_N_INSNS(4);
2256
    default:
2257
      return 0;
2258
    }
2259
}
2260
 
2261
/* Defining the Output Assembler Language */
2262
 
2263
/* The Overall Framework of an Assembler File */
2264
 
2265
#undef TARGET_HAVE_NAMED_SECTIONS
2266
#define TARGET_HAVE_NAMED_SECTIONS true
2267
 
2268
/* Output of Data */
2269
 
2270
/* We may have 24 bit sizes, which is the native address size.
2271
   Currently unused, but provided for completeness.  */
2272
#undef TARGET_ASM_INTEGER
2273
#define TARGET_ASM_INTEGER m32c_asm_integer
2274
static bool
2275
m32c_asm_integer (rtx x, unsigned int size, int aligned_p)
2276
{
2277
  switch (size)
2278
    {
2279
    case 3:
2280
      fprintf (asm_out_file, "\t.3byte\t");
2281
      output_addr_const (asm_out_file, x);
2282
      fputc ('\n', asm_out_file);
2283
      return true;
2284
    case 4:
2285
      if (GET_CODE (x) == SYMBOL_REF)
2286
        {
2287
          fprintf (asm_out_file, "\t.long\t");
2288
          output_addr_const (asm_out_file, x);
2289
          fputc ('\n', asm_out_file);
2290
          return true;
2291
        }
2292
      break;
2293
    }
2294
  return default_assemble_integer (x, size, aligned_p);
2295
}
2296
 
2297
/* Output of Assembler Instructions */
2298
 
2299
/* We use a lookup table because the addressing modes are non-orthogonal.  */
2300
 
2301
static struct
2302
{
2303
  char code;
2304
  char const *pattern;
2305
  char const *format;
2306
}
2307
const conversions[] = {
2308
  { 0, "r", "0" },
2309
 
2310
  { 0, "mr", "z[1]" },
2311
  { 0, "m+ri", "3[2]" },
2312
  { 0, "m+rs", "3[2]" },
2313
  { 0, "m+r+si", "4+5[2]" },
2314
  { 0, "ms", "1" },
2315
  { 0, "mi", "1" },
2316
  { 0, "m+si", "2+3" },
2317
 
2318
  { 0, "mmr", "[z[2]]" },
2319
  { 0, "mm+ri", "[4[3]]" },
2320
  { 0, "mm+rs", "[4[3]]" },
2321
  { 0, "mm+r+si", "[5+6[3]]" },
2322
  { 0, "mms", "[[2]]" },
2323
  { 0, "mmi", "[[2]]" },
2324
  { 0, "mm+si", "[4[3]]" },
2325
 
2326
  { 0, "i", "#0" },
2327
  { 0, "s", "#0" },
2328
  { 0, "+si", "#1+2" },
2329
  { 0, "l", "#0" },
2330
 
2331
  { 'l', "l", "0" },
2332
  { 'd', "i", "0" },
2333
  { 'd', "s", "0" },
2334
  { 'd', "+si", "1+2" },
2335
  { 'D', "i", "0" },
2336
  { 'D', "s", "0" },
2337
  { 'D', "+si", "1+2" },
2338
  { 'x', "i", "#0" },
2339
  { 'X', "i", "#0" },
2340
  { 'm', "i", "#0" },
2341
  { 'b', "i", "#0" },
2342
  { 'B', "i", "0" },
2343
  { 'p', "i", "0" },
2344
 
2345
  { 0, 0, 0 }
2346
};
2347
 
2348
/* This is in order according to the bitfield that pushm/popm use.  */
2349
static char const *pushm_regs[] = {
2350
  "fb", "sb", "a1", "a0", "r3", "r2", "r1", "r0"
2351
};
2352
 
2353
/* Implements PRINT_OPERAND.  */
2354
void
2355
m32c_print_operand (FILE * file, rtx x, int code)
2356
{
2357
  int i, j, b;
2358
  const char *comma;
2359
  HOST_WIDE_INT ival;
2360
  int unsigned_const = 0;
2361
  int force_sign;
2362
 
2363
  /* Multiplies; constants are converted to sign-extended format but
2364
   we need unsigned, so 'u' and 'U' tell us what size unsigned we
2365
   need.  */
2366
  if (code == 'u')
2367
    {
2368
      unsigned_const = 2;
2369
      code = 0;
2370
    }
2371
  if (code == 'U')
2372
    {
2373
      unsigned_const = 1;
2374
      code = 0;
2375
    }
2376
  /* This one is only for debugging; you can put it in a pattern to
2377
     force this error.  */
2378
  if (code == '!')
2379
    {
2380
      fprintf (stderr, "dj: unreviewed pattern:");
2381
      if (current_output_insn)
2382
        debug_rtx (current_output_insn);
2383
      gcc_unreachable ();
2384
    }
2385
  /* PSImode operations are either .w or .l depending on the target.  */
2386
  if (code == '&')
2387
    {
2388
      if (TARGET_A16)
2389
        fprintf (file, "w");
2390
      else
2391
        fprintf (file, "l");
2392
      return;
2393
    }
2394
  /* Inverted conditionals.  */
2395
  if (code == 'C')
2396
    {
2397
      switch (GET_CODE (x))
2398
        {
2399
        case LE:
2400
          fputs ("gt", file);
2401
          break;
2402
        case LEU:
2403
          fputs ("gtu", file);
2404
          break;
2405
        case LT:
2406
          fputs ("ge", file);
2407
          break;
2408
        case LTU:
2409
          fputs ("geu", file);
2410
          break;
2411
        case GT:
2412
          fputs ("le", file);
2413
          break;
2414
        case GTU:
2415
          fputs ("leu", file);
2416
          break;
2417
        case GE:
2418
          fputs ("lt", file);
2419
          break;
2420
        case GEU:
2421
          fputs ("ltu", file);
2422
          break;
2423
        case NE:
2424
          fputs ("eq", file);
2425
          break;
2426
        case EQ:
2427
          fputs ("ne", file);
2428
          break;
2429
        default:
2430
          gcc_unreachable ();
2431
        }
2432
      return;
2433
    }
2434
  /* Regular conditionals.  */
2435
  if (code == 'c')
2436
    {
2437
      switch (GET_CODE (x))
2438
        {
2439
        case LE:
2440
          fputs ("le", file);
2441
          break;
2442
        case LEU:
2443
          fputs ("leu", file);
2444
          break;
2445
        case LT:
2446
          fputs ("lt", file);
2447
          break;
2448
        case LTU:
2449
          fputs ("ltu", file);
2450
          break;
2451
        case GT:
2452
          fputs ("gt", file);
2453
          break;
2454
        case GTU:
2455
          fputs ("gtu", file);
2456
          break;
2457
        case GE:
2458
          fputs ("ge", file);
2459
          break;
2460
        case GEU:
2461
          fputs ("geu", file);
2462
          break;
2463
        case NE:
2464
          fputs ("ne", file);
2465
          break;
2466
        case EQ:
2467
          fputs ("eq", file);
2468
          break;
2469
        default:
2470
          gcc_unreachable ();
2471
        }
2472
      return;
2473
    }
2474
  /* Used in negsi2 to do HImode ops on the two parts of an SImode
2475
     operand.  */
2476
  if (code == 'h' && GET_MODE (x) == SImode)
2477
    {
2478
      x = m32c_subreg (HImode, x, SImode, 0);
2479
      code = 0;
2480
    }
2481
  if (code == 'H' && GET_MODE (x) == SImode)
2482
    {
2483
      x = m32c_subreg (HImode, x, SImode, 2);
2484
      code = 0;
2485
    }
2486
  if (code == 'h' && GET_MODE (x) == HImode)
2487
    {
2488
      x = m32c_subreg (QImode, x, HImode, 0);
2489
      code = 0;
2490
    }
2491
  if (code == 'H' && GET_MODE (x) == HImode)
2492
    {
2493
      /* We can't actually represent this as an rtx.  Do it here.  */
2494
      if (GET_CODE (x) == REG)
2495
        {
2496
          switch (REGNO (x))
2497
            {
2498
            case R0_REGNO:
2499
              fputs ("r0h", file);
2500
              return;
2501
            case R1_REGNO:
2502
              fputs ("r1h", file);
2503
              return;
2504
            default:
2505
              gcc_unreachable();
2506
            }
2507
        }
2508
      /* This should be a MEM.  */
2509
      x = m32c_subreg (QImode, x, HImode, 1);
2510
      code = 0;
2511
    }
2512
  /* This is for BMcond, which always wants word register names.  */
2513
  if (code == 'h' && GET_MODE (x) == QImode)
2514
    {
2515
      if (GET_CODE (x) == REG)
2516
        x = gen_rtx_REG (HImode, REGNO (x));
2517
      code = 0;
2518
    }
2519
  /* 'x' and 'X' need to be ignored for non-immediates.  */
2520
  if ((code == 'x' || code == 'X') && GET_CODE (x) != CONST_INT)
2521
    code = 0;
2522
 
2523
  encode_pattern (x);
2524
  force_sign = 0;
2525
  for (i = 0; conversions[i].pattern; i++)
2526
    if (conversions[i].code == code
2527
        && streq (conversions[i].pattern, pattern))
2528
      {
2529
        for (j = 0; conversions[i].format[j]; j++)
2530
          /* backslash quotes the next character in the output pattern.  */
2531
          if (conversions[i].format[j] == '\\')
2532
            {
2533
              fputc (conversions[i].format[j + 1], file);
2534
              j++;
2535
            }
2536
          /* Digits in the output pattern indicate that the
2537
             corresponding RTX is to be output at that point.  */
2538
          else if (ISDIGIT (conversions[i].format[j]))
2539
            {
2540
              rtx r = patternr[conversions[i].format[j] - '0'];
2541
              switch (GET_CODE (r))
2542
                {
2543
                case REG:
2544
                  fprintf (file, "%s",
2545
                           reg_name_with_mode (REGNO (r), GET_MODE (r)));
2546
                  break;
2547
                case CONST_INT:
2548
                  switch (code)
2549
                    {
2550
                    case 'b':
2551
                    case 'B':
2552
                      {
2553
                        int v = INTVAL (r);
2554
                        int i = (int) exact_log2 (v);
2555
                        if (i == -1)
2556
                          i = (int) exact_log2 ((v ^ 0xffff) & 0xffff);
2557
                        if (i == -1)
2558
                          i = (int) exact_log2 ((v ^ 0xff) & 0xff);
2559
                        /* Bit position.  */
2560
                        fprintf (file, "%d", i);
2561
                      }
2562
                      break;
2563
                    case 'x':
2564
                      /* Unsigned byte.  */
2565
                      fprintf (file, HOST_WIDE_INT_PRINT_HEX,
2566
                               INTVAL (r) & 0xff);
2567
                      break;
2568
                    case 'X':
2569
                      /* Unsigned word.  */
2570
                      fprintf (file, HOST_WIDE_INT_PRINT_HEX,
2571
                               INTVAL (r) & 0xffff);
2572
                      break;
2573
                    case 'p':
2574
                      /* pushm and popm encode a register set into a single byte.  */
2575
                      comma = "";
2576
                      for (b = 7; b >= 0; b--)
2577
                        if (INTVAL (r) & (1 << b))
2578
                          {
2579
                            fprintf (file, "%s%s", comma, pushm_regs[b]);
2580
                            comma = ",";
2581
                          }
2582
                      break;
2583
                    case 'm':
2584
                      /* "Minus".  Output -X  */
2585
                      ival = (-INTVAL (r) & 0xffff);
2586
                      if (ival & 0x8000)
2587
                        ival = ival - 0x10000;
2588
                      fprintf (file, HOST_WIDE_INT_PRINT_DEC, ival);
2589
                      break;
2590
                    default:
2591
                      ival = INTVAL (r);
2592
                      if (conversions[i].format[j + 1] == '[' && ival < 0)
2593
                        {
2594
                          /* We can simulate negative displacements by
2595
                             taking advantage of address space
2596
                             wrapping when the offset can span the
2597
                             entire address range.  */
2598
                          rtx base =
2599
                            patternr[conversions[i].format[j + 2] - '0'];
2600
                          if (GET_CODE (base) == REG)
2601
                            switch (REGNO (base))
2602
                              {
2603
                              case A0_REGNO:
2604
                              case A1_REGNO:
2605
                                if (TARGET_A24)
2606
                                  ival = 0x1000000 + ival;
2607
                                else
2608
                                  ival = 0x10000 + ival;
2609
                                break;
2610
                              case SB_REGNO:
2611
                                if (TARGET_A16)
2612
                                  ival = 0x10000 + ival;
2613
                                break;
2614
                              }
2615
                        }
2616
                      else if (code == 'd' && ival < 0 && j == 0)
2617
                        /* The "mova" opcode is used to do addition by
2618
                           computing displacements, but again, we need
2619
                           displacements to be unsigned *if* they're
2620
                           the only component of the displacement
2621
                           (i.e. no "symbol-4" type displacement).  */
2622
                        ival = (TARGET_A24 ? 0x1000000 : 0x10000) + ival;
2623
 
2624
                      if (conversions[i].format[j] == '0')
2625
                        {
2626
                          /* More conversions to unsigned.  */
2627
                          if (unsigned_const == 2)
2628
                            ival &= 0xffff;
2629
                          if (unsigned_const == 1)
2630
                            ival &= 0xff;
2631
                        }
2632
                      if (streq (conversions[i].pattern, "mi")
2633
                          || streq (conversions[i].pattern, "mmi"))
2634
                        {
2635
                          /* Integers used as addresses are unsigned.  */
2636
                          ival &= (TARGET_A24 ? 0xffffff : 0xffff);
2637
                        }
2638
                      if (force_sign && ival >= 0)
2639
                        fputc ('+', file);
2640
                      fprintf (file, HOST_WIDE_INT_PRINT_DEC, ival);
2641
                      break;
2642
                    }
2643
                  break;
2644
                case CONST_DOUBLE:
2645
                  /* We don't have const_double constants.  If it
2646
                     happens, make it obvious.  */
2647
                  fprintf (file, "[const_double 0x%lx]",
2648
                           (unsigned long) CONST_DOUBLE_HIGH (r));
2649
                  break;
2650
                case SYMBOL_REF:
2651
                  assemble_name (file, XSTR (r, 0));
2652
                  break;
2653
                case LABEL_REF:
2654
                  output_asm_label (r);
2655
                  break;
2656
                default:
2657
                  fprintf (stderr, "don't know how to print this operand:");
2658
                  debug_rtx (r);
2659
                  gcc_unreachable ();
2660
                }
2661
            }
2662
          else
2663
            {
2664
              if (conversions[i].format[j] == 'z')
2665
                {
2666
                  /* Some addressing modes *must* have a displacement,
2667
                     so insert a zero here if needed.  */
2668
                  int k;
2669
                  for (k = j + 1; conversions[i].format[k]; k++)
2670
                    if (ISDIGIT (conversions[i].format[k]))
2671
                      {
2672
                        rtx reg = patternr[conversions[i].format[k] - '0'];
2673
                        if (GET_CODE (reg) == REG
2674
                            && (REGNO (reg) == SB_REGNO
2675
                                || REGNO (reg) == FB_REGNO
2676
                                || REGNO (reg) == SP_REGNO))
2677
                          fputc ('0', file);
2678
                      }
2679
                  continue;
2680
                }
2681
              /* Signed displacements off symbols need to have signs
2682
                 blended cleanly.  */
2683
              if (conversions[i].format[j] == '+'
2684
                  && (!code || code == 'D' || code == 'd')
2685
                  && ISDIGIT (conversions[i].format[j + 1])
2686
                  && (GET_CODE (patternr[conversions[i].format[j + 1] - '0'])
2687
                      == CONST_INT))
2688
                {
2689
                  force_sign = 1;
2690
                  continue;
2691
                }
2692
              fputc (conversions[i].format[j], file);
2693
            }
2694
        break;
2695
      }
2696
  if (!conversions[i].pattern)
2697
    {
2698
      fprintf (stderr, "unconvertible operand %c `%s'", code ? code : '-',
2699
               pattern);
2700
      debug_rtx (x);
2701
      fprintf (file, "[%c.%s]", code ? code : '-', pattern);
2702
    }
2703
 
2704
  return;
2705
}
2706
 
2707
/* Implements PRINT_OPERAND_PUNCT_VALID_P.  See m32c_print_operand
2708
   above for descriptions of what these do.  */
2709
int
2710
m32c_print_operand_punct_valid_p (int c)
2711
{
2712
  if (c == '&' || c == '!')
2713
    return 1;
2714
  return 0;
2715
}
2716
 
2717
/* Implements PRINT_OPERAND_ADDRESS.  Nothing unusual here.  */
2718
void
2719
m32c_print_operand_address (FILE * stream, rtx address)
2720
{
2721
  if (GET_CODE (address) == MEM)
2722
    address = XEXP (address, 0);
2723
  else
2724
    /* cf: gcc.dg/asm-4.c.  */
2725
    gcc_assert (GET_CODE (address) == REG);
2726
 
2727
  m32c_print_operand (stream, address, 0);
2728
}
2729
 
2730
/* Implements ASM_OUTPUT_REG_PUSH.  Control registers are pushed
2731
   differently than general registers.  */
2732
void
2733
m32c_output_reg_push (FILE * s, int regno)
2734
{
2735
  if (regno == FLG_REGNO)
2736
    fprintf (s, "\tpushc\tflg\n");
2737
  else
2738
    fprintf (s, "\tpush.%c\t%s\n",
2739
             " bwll"[reg_push_size (regno)], reg_names[regno]);
2740
}
2741
 
2742
/* Likewise for ASM_OUTPUT_REG_POP.  */
2743
void
2744
m32c_output_reg_pop (FILE * s, int regno)
2745
{
2746
  if (regno == FLG_REGNO)
2747
    fprintf (s, "\tpopc\tflg\n");
2748
  else
2749
    fprintf (s, "\tpop.%c\t%s\n",
2750
             " bwll"[reg_push_size (regno)], reg_names[regno]);
2751
}
2752
 
2753
/* Defining target-specific uses of `__attribute__' */
2754
 
2755
/* Used to simplify the logic below.  Find the attributes wherever
2756
   they may be.  */
2757
#define M32C_ATTRIBUTES(decl) \
2758
  (TYPE_P (decl)) ? TYPE_ATTRIBUTES (decl) \
2759
                : DECL_ATTRIBUTES (decl) \
2760
                  ? (DECL_ATTRIBUTES (decl)) \
2761
                  : TYPE_ATTRIBUTES (TREE_TYPE (decl))
2762
 
2763
/* Returns TRUE if the given tree has the "interrupt" attribute.  */
2764
static int
2765
interrupt_p (tree node ATTRIBUTE_UNUSED)
2766
{
2767
  tree list = M32C_ATTRIBUTES (node);
2768
  while (list)
2769
    {
2770
      if (is_attribute_p ("interrupt", TREE_PURPOSE (list)))
2771
        return 1;
2772
      list = TREE_CHAIN (list);
2773
    }
2774
  return fast_interrupt_p (node);
2775
}
2776
 
2777
/* Returns TRUE if the given tree has the "bank_switch" attribute.  */
2778
static int
2779
bank_switch_p (tree node ATTRIBUTE_UNUSED)
2780
{
2781
  tree list = M32C_ATTRIBUTES (node);
2782
  while (list)
2783
    {
2784
      if (is_attribute_p ("bank_switch", TREE_PURPOSE (list)))
2785
        return 1;
2786
      list = TREE_CHAIN (list);
2787
    }
2788
  return 0;
2789
}
2790
 
2791
/* Returns TRUE if the given tree has the "fast_interrupt" attribute.  */
2792
static int
2793
fast_interrupt_p (tree node ATTRIBUTE_UNUSED)
2794
{
2795
  tree list = M32C_ATTRIBUTES (node);
2796
  while (list)
2797
    {
2798
      if (is_attribute_p ("fast_interrupt", TREE_PURPOSE (list)))
2799
        return 1;
2800
      list = TREE_CHAIN (list);
2801
    }
2802
  return 0;
2803
}
2804
 
2805
static tree
2806
interrupt_handler (tree * node ATTRIBUTE_UNUSED,
2807
                   tree name ATTRIBUTE_UNUSED,
2808
                   tree args ATTRIBUTE_UNUSED,
2809
                   int flags ATTRIBUTE_UNUSED,
2810
                   bool * no_add_attrs ATTRIBUTE_UNUSED)
2811
{
2812
  return NULL_TREE;
2813
}
2814
 
2815
/* Returns TRUE if given tree has the "function_vector" attribute. */
2816
int
2817
m32c_special_page_vector_p (tree func)
2818
{
2819
  tree list;
2820
 
2821
  if (TREE_CODE (func) != FUNCTION_DECL)
2822
    return 0;
2823
 
2824
  list = M32C_ATTRIBUTES (func);
2825
  while (list)
2826
    {
2827
      if (is_attribute_p ("function_vector", TREE_PURPOSE (list)))
2828
        return 1;
2829
      list = TREE_CHAIN (list);
2830
    }
2831
  return 0;
2832
}
2833
 
2834
static tree
2835
function_vector_handler (tree * node ATTRIBUTE_UNUSED,
2836
                         tree name ATTRIBUTE_UNUSED,
2837
                         tree args ATTRIBUTE_UNUSED,
2838
                         int flags ATTRIBUTE_UNUSED,
2839
                         bool * no_add_attrs ATTRIBUTE_UNUSED)
2840
{
2841
  if (TARGET_R8C)
2842
    {
2843
      /* The attribute is not supported for R8C target.  */
2844
      warning (OPT_Wattributes,
2845
                "%qE attribute is not supported for R8C target",
2846
                name);
2847
      *no_add_attrs = true;
2848
    }
2849
  else if (TREE_CODE (*node) != FUNCTION_DECL)
2850
    {
2851
      /* The attribute must be applied to functions only.  */
2852
      warning (OPT_Wattributes,
2853
                "%qE attribute applies only to functions",
2854
                name);
2855
      *no_add_attrs = true;
2856
    }
2857
  else if (TREE_CODE (TREE_VALUE (args)) != INTEGER_CST)
2858
    {
2859
      /* The argument must be a constant integer.  */
2860
      warning (OPT_Wattributes,
2861
                "%qE attribute argument not an integer constant",
2862
                name);
2863
      *no_add_attrs = true;
2864
    }
2865
  else if (TREE_INT_CST_LOW (TREE_VALUE (args)) < 18
2866
           || TREE_INT_CST_LOW (TREE_VALUE (args)) > 255)
2867
    {
2868
      /* The argument value must be between 18 to 255.  */
2869
      warning (OPT_Wattributes,
2870
                "%qE attribute argument should be between 18 to 255",
2871
                name);
2872
      *no_add_attrs = true;
2873
    }
2874
  return NULL_TREE;
2875
}
2876
 
2877
/* If the function is assigned the attribute 'function_vector', it
2878
   returns the function vector number, otherwise returns zero.  */
2879
int
2880
current_function_special_page_vector (rtx x)
2881
{
2882
  int num;
2883
 
2884
  if ((GET_CODE(x) == SYMBOL_REF)
2885
      && (SYMBOL_REF_FLAGS (x) & SYMBOL_FLAG_FUNCVEC_FUNCTION))
2886
    {
2887
      tree list;
2888
      tree t = SYMBOL_REF_DECL (x);
2889
 
2890
      if (TREE_CODE (t) != FUNCTION_DECL)
2891
        return 0;
2892
 
2893
      list = M32C_ATTRIBUTES (t);
2894
      while (list)
2895
        {
2896
          if (is_attribute_p ("function_vector", TREE_PURPOSE (list)))
2897
            {
2898
              num = TREE_INT_CST_LOW (TREE_VALUE (TREE_VALUE (list)));
2899
              return num;
2900
            }
2901
 
2902
          list = TREE_CHAIN (list);
2903
        }
2904
 
2905
      return 0;
2906
    }
2907
  else
2908
    return 0;
2909
}
2910
 
2911
#undef TARGET_ATTRIBUTE_TABLE
2912
#define TARGET_ATTRIBUTE_TABLE m32c_attribute_table
2913
static const struct attribute_spec m32c_attribute_table[] = {
2914
  {"interrupt", 0, 0, false, false, false, interrupt_handler},
2915
  {"bank_switch", 0, 0, false, false, false, interrupt_handler},
2916
  {"fast_interrupt", 0, 0, false, false, false, interrupt_handler},
2917
  {"function_vector", 1, 1, true,  false, false, function_vector_handler},
2918
  {0, 0, 0, 0, 0, 0, 0}
2919
};
2920
 
2921
#undef TARGET_COMP_TYPE_ATTRIBUTES
2922
#define TARGET_COMP_TYPE_ATTRIBUTES m32c_comp_type_attributes
2923
static int
2924
m32c_comp_type_attributes (const_tree type1 ATTRIBUTE_UNUSED,
2925
                           const_tree type2 ATTRIBUTE_UNUSED)
2926
{
2927
  /* 0=incompatible 1=compatible 2=warning */
2928
  return 1;
2929
}
2930
 
2931
#undef TARGET_INSERT_ATTRIBUTES
2932
#define TARGET_INSERT_ATTRIBUTES m32c_insert_attributes
2933
static void
2934
m32c_insert_attributes (tree node ATTRIBUTE_UNUSED,
2935
                        tree * attr_ptr ATTRIBUTE_UNUSED)
2936
{
2937
  /* Nothing to do here.  */
2938
}
2939
 
2940
/* Predicates */
2941
 
2942
/* This is a list of legal subregs of hard regs.  */
2943
static const struct {
2944
  unsigned char outer_mode_size;
2945
  unsigned char inner_mode_size;
2946
  unsigned char byte_mask;
2947
  unsigned char legal_when;
2948
  unsigned int regno;
2949
} legal_subregs[] = {
2950
  {1, 2, 0x03, 1, R0_REGNO}, /* r0h r0l */
2951
  {1, 2, 0x03, 1, R1_REGNO}, /* r1h r1l */
2952
  {1, 2, 0x01, 1, A0_REGNO},
2953
  {1, 2, 0x01, 1, A1_REGNO},
2954
 
2955
  {1, 4, 0x01, 1, A0_REGNO},
2956
  {1, 4, 0x01, 1, A1_REGNO},
2957
 
2958
  {2, 4, 0x05, 1, R0_REGNO}, /* r2 r0 */
2959
  {2, 4, 0x05, 1, R1_REGNO}, /* r3 r1 */
2960
  {2, 4, 0x05, 16, A0_REGNO}, /* a1 a0 */
2961
  {2, 4, 0x01, 24, A0_REGNO}, /* a1 a0 */
2962
  {2, 4, 0x01, 24, A1_REGNO}, /* a1 a0 */
2963
 
2964
  {4, 8, 0x55, 1, R0_REGNO}, /* r3 r1 r2 r0 */
2965
};
2966
 
2967
/* Returns TRUE if OP is a subreg of a hard reg which we don't
2968
   support.  */
2969
bool
2970
m32c_illegal_subreg_p (rtx op)
2971
{
2972
  int offset;
2973
  unsigned int i;
2974
  int src_mode, dest_mode;
2975
 
2976
  if (GET_CODE (op) != SUBREG)
2977
    return false;
2978
 
2979
  dest_mode = GET_MODE (op);
2980
  offset = SUBREG_BYTE (op);
2981
  op = SUBREG_REG (op);
2982
  src_mode = GET_MODE (op);
2983
 
2984
  if (GET_MODE_SIZE (dest_mode) == GET_MODE_SIZE (src_mode))
2985
    return false;
2986
  if (GET_CODE (op) != REG)
2987
    return false;
2988
  if (REGNO (op) >= MEM0_REGNO)
2989
    return false;
2990
 
2991
  offset = (1 << offset);
2992
 
2993
  for (i = 0; i < ARRAY_SIZE (legal_subregs); i ++)
2994
    if (legal_subregs[i].outer_mode_size == GET_MODE_SIZE (dest_mode)
2995
        && legal_subregs[i].regno == REGNO (op)
2996
        && legal_subregs[i].inner_mode_size == GET_MODE_SIZE (src_mode)
2997
        && legal_subregs[i].byte_mask & offset)
2998
      {
2999
        switch (legal_subregs[i].legal_when)
3000
          {
3001
          case 1:
3002
            return false;
3003
          case 16:
3004
            if (TARGET_A16)
3005
              return false;
3006
            break;
3007
          case 24:
3008
            if (TARGET_A24)
3009
              return false;
3010
            break;
3011
          }
3012
      }
3013
  return true;
3014
}
3015
 
3016
/* Returns TRUE if we support a move between the first two operands.
3017
   At the moment, we just want to discourage mem to mem moves until
3018
   after reload, because reload has a hard time with our limited
3019
   number of address registers, and we can get into a situation where
3020
   we need three of them when we only have two.  */
3021
bool
3022
m32c_mov_ok (rtx * operands, enum machine_mode mode ATTRIBUTE_UNUSED)
3023
{
3024
  rtx op0 = operands[0];
3025
  rtx op1 = operands[1];
3026
 
3027
  if (TARGET_A24)
3028
    return true;
3029
 
3030
#define DEBUG_MOV_OK 0
3031
#if DEBUG_MOV_OK
3032
  fprintf (stderr, "m32c_mov_ok %s\n", mode_name[mode]);
3033
  debug_rtx (op0);
3034
  debug_rtx (op1);
3035
#endif
3036
 
3037
  if (GET_CODE (op0) == SUBREG)
3038
    op0 = XEXP (op0, 0);
3039
  if (GET_CODE (op1) == SUBREG)
3040
    op1 = XEXP (op1, 0);
3041
 
3042
  if (GET_CODE (op0) == MEM
3043
      && GET_CODE (op1) == MEM
3044
      && ! reload_completed)
3045
    {
3046
#if DEBUG_MOV_OK
3047
      fprintf (stderr, " - no, mem to mem\n");
3048
#endif
3049
      return false;
3050
    }
3051
 
3052
#if DEBUG_MOV_OK
3053
  fprintf (stderr, " - ok\n");
3054
#endif
3055
  return true;
3056
}
3057
 
3058
/* Returns TRUE if two consecutive HImode mov instructions, generated
3059
   for moving an immediate double data to a double data type variable
3060
   location, can be combined into single SImode mov instruction.  */
3061
bool
3062
m32c_immd_dbl_mov (rtx * operands,
3063
                   enum machine_mode mode ATTRIBUTE_UNUSED)
3064
{
3065
  int flag = 0, okflag = 0, offset1 = 0, offset2 = 0, offsetsign = 0;
3066
  const char *str1;
3067
  const char *str2;
3068
 
3069
  if (GET_CODE (XEXP (operands[0], 0)) == SYMBOL_REF
3070
      && MEM_SCALAR_P (operands[0])
3071
      && !MEM_IN_STRUCT_P (operands[0])
3072
      && GET_CODE (XEXP (operands[2], 0)) == CONST
3073
      && GET_CODE (XEXP (XEXP (operands[2], 0), 0)) == PLUS
3074
      && GET_CODE (XEXP (XEXP (XEXP (operands[2], 0), 0), 0)) == SYMBOL_REF
3075
      && GET_CODE (XEXP (XEXP (XEXP (operands[2], 0), 0), 1)) == CONST_INT
3076
      && MEM_SCALAR_P (operands[2])
3077
      && !MEM_IN_STRUCT_P (operands[2]))
3078
    flag = 1;
3079
 
3080
  else if (GET_CODE (XEXP (operands[0], 0)) == CONST
3081
           && GET_CODE (XEXP (XEXP (operands[0], 0), 0)) == PLUS
3082
           && GET_CODE (XEXP (XEXP (XEXP (operands[0], 0), 0), 0)) == SYMBOL_REF
3083
           && MEM_SCALAR_P (operands[0])
3084
           && !MEM_IN_STRUCT_P (operands[0])
3085
           && !(INTVAL (XEXP (XEXP (XEXP (operands[0], 0), 0), 1)) %4)
3086
           && GET_CODE (XEXP (operands[2], 0)) == CONST
3087
           && GET_CODE (XEXP (XEXP (operands[2], 0), 0)) == PLUS
3088
           && GET_CODE (XEXP (XEXP (XEXP (operands[2], 0), 0), 0)) == SYMBOL_REF
3089
           && MEM_SCALAR_P (operands[2])
3090
           && !MEM_IN_STRUCT_P (operands[2]))
3091
    flag = 2;
3092
 
3093
  else if (GET_CODE (XEXP (operands[0], 0)) == PLUS
3094
           &&  GET_CODE (XEXP (XEXP (operands[0], 0), 0)) == REG
3095
           &&  REGNO (XEXP (XEXP (operands[0], 0), 0)) == FB_REGNO
3096
           &&  GET_CODE (XEXP (XEXP (operands[0], 0), 1)) == CONST_INT
3097
           &&  MEM_SCALAR_P (operands[0])
3098
           &&  !MEM_IN_STRUCT_P (operands[0])
3099
           &&  !(INTVAL (XEXP (XEXP (operands[0], 0), 1)) %4)
3100
           &&  REGNO (XEXP (XEXP (operands[2], 0), 0)) == FB_REGNO
3101
           &&  GET_CODE (XEXP (XEXP (operands[2], 0), 1)) == CONST_INT
3102
           &&  MEM_SCALAR_P (operands[2])
3103
           &&  !MEM_IN_STRUCT_P (operands[2]))
3104
    flag = 3;
3105
 
3106
  else
3107
    return false;
3108
 
3109
  switch (flag)
3110
    {
3111
    case 1:
3112
      str1 = XSTR (XEXP (operands[0], 0), 0);
3113
      str2 = XSTR (XEXP (XEXP (XEXP (operands[2], 0), 0), 0), 0);
3114
      if (strcmp (str1, str2) == 0)
3115
        okflag = 1;
3116
      else
3117
        okflag = 0;
3118
      break;
3119
    case 2:
3120
      str1 = XSTR (XEXP (XEXP (XEXP (operands[0], 0), 0), 0), 0);
3121
      str2 = XSTR (XEXP (XEXP (XEXP (operands[2], 0), 0), 0), 0);
3122
      if (strcmp(str1,str2) == 0)
3123
        okflag = 1;
3124
      else
3125
        okflag = 0;
3126
      break;
3127
    case 3:
3128
      offset1 = INTVAL (XEXP (XEXP (operands[0], 0), 1));
3129
      offset2 = INTVAL (XEXP (XEXP (operands[2], 0), 1));
3130
      offsetsign = offset1 >> ((sizeof (offset1) * 8) -1);
3131
      if (((offset2-offset1) == 2) && offsetsign != 0)
3132
        okflag = 1;
3133
      else
3134
        okflag = 0;
3135
      break;
3136
    default:
3137
      okflag = 0;
3138
    }
3139
 
3140
  if (okflag == 1)
3141
    {
3142
      HOST_WIDE_INT val;
3143
      operands[4] = gen_rtx_MEM (SImode, XEXP (operands[0], 0));
3144
 
3145
      val = (INTVAL (operands[3]) << 16) + (INTVAL (operands[1]) & 0xFFFF);
3146
      operands[5] = gen_rtx_CONST_INT (VOIDmode, val);
3147
 
3148
      return true;
3149
    }
3150
 
3151
  return false;
3152
}
3153
 
3154
/* Expanders */
3155
 
3156
/* Subregs are non-orthogonal for us, because our registers are all
3157
   different sizes.  */
3158
static rtx
3159
m32c_subreg (enum machine_mode outer,
3160
             rtx x, enum machine_mode inner, int byte)
3161
{
3162
  int r, nr = -1;
3163
 
3164
  /* Converting MEMs to different types that are the same size, we
3165
     just rewrite them.  */
3166
  if (GET_CODE (x) == SUBREG
3167
      && SUBREG_BYTE (x) == 0
3168
      && GET_CODE (SUBREG_REG (x)) == MEM
3169
      && (GET_MODE_SIZE (GET_MODE (x))
3170
          == GET_MODE_SIZE (GET_MODE (SUBREG_REG (x)))))
3171
    {
3172
      rtx oldx = x;
3173
      x = gen_rtx_MEM (GET_MODE (x), XEXP (SUBREG_REG (x), 0));
3174
      MEM_COPY_ATTRIBUTES (x, SUBREG_REG (oldx));
3175
    }
3176
 
3177
  /* Push/pop get done as smaller push/pops.  */
3178
  if (GET_CODE (x) == MEM
3179
      && (GET_CODE (XEXP (x, 0)) == PRE_DEC
3180
          || GET_CODE (XEXP (x, 0)) == POST_INC))
3181
    return gen_rtx_MEM (outer, XEXP (x, 0));
3182
  if (GET_CODE (x) == SUBREG
3183
      && GET_CODE (XEXP (x, 0)) == MEM
3184
      && (GET_CODE (XEXP (XEXP (x, 0), 0)) == PRE_DEC
3185
          || GET_CODE (XEXP (XEXP (x, 0), 0)) == POST_INC))
3186
    return gen_rtx_MEM (outer, XEXP (XEXP (x, 0), 0));
3187
 
3188
  if (GET_CODE (x) != REG)
3189
    return simplify_gen_subreg (outer, x, inner, byte);
3190
 
3191
  r = REGNO (x);
3192
  if (r >= FIRST_PSEUDO_REGISTER || r == AP_REGNO)
3193
    return simplify_gen_subreg (outer, x, inner, byte);
3194
 
3195
  if (IS_MEM_REGNO (r))
3196
    return simplify_gen_subreg (outer, x, inner, byte);
3197
 
3198
  /* This is where the complexities of our register layout are
3199
     described.  */
3200
  if (byte == 0)
3201
    nr = r;
3202
  else if (outer == HImode)
3203
    {
3204
      if (r == R0_REGNO && byte == 2)
3205
        nr = R2_REGNO;
3206
      else if (r == R0_REGNO && byte == 4)
3207
        nr = R1_REGNO;
3208
      else if (r == R0_REGNO && byte == 6)
3209
        nr = R3_REGNO;
3210
      else if (r == R1_REGNO && byte == 2)
3211
        nr = R3_REGNO;
3212
      else if (r == A0_REGNO && byte == 2)
3213
        nr = A1_REGNO;
3214
    }
3215
  else if (outer == SImode)
3216
    {
3217
      if (r == R0_REGNO && byte == 0)
3218
        nr = R0_REGNO;
3219
      else if (r == R0_REGNO && byte == 4)
3220
        nr = R1_REGNO;
3221
    }
3222
  if (nr == -1)
3223
    {
3224
      fprintf (stderr, "m32c_subreg %s %s %d\n",
3225
               mode_name[outer], mode_name[inner], byte);
3226
      debug_rtx (x);
3227
      gcc_unreachable ();
3228
    }
3229
  return gen_rtx_REG (outer, nr);
3230
}
3231
 
3232
/* Used to emit move instructions.  We split some moves,
3233
   and avoid mem-mem moves.  */
3234
int
3235
m32c_prepare_move (rtx * operands, enum machine_mode mode)
3236
{
3237
  if (TARGET_A16 && mode == PSImode)
3238
    return m32c_split_move (operands, mode, 1);
3239
  if ((GET_CODE (operands[0]) == MEM)
3240
      && (GET_CODE (XEXP (operands[0], 0)) == PRE_MODIFY))
3241
    {
3242
      rtx pmv = XEXP (operands[0], 0);
3243
      rtx dest_reg = XEXP (pmv, 0);
3244
      rtx dest_mod = XEXP (pmv, 1);
3245
 
3246
      emit_insn (gen_rtx_SET (Pmode, dest_reg, dest_mod));
3247
      operands[0] = gen_rtx_MEM (mode, dest_reg);
3248
    }
3249
  if (can_create_pseudo_p () && MEM_P (operands[0]) && MEM_P (operands[1]))
3250
    operands[1] = copy_to_mode_reg (mode, operands[1]);
3251
  return 0;
3252
}
3253
 
3254
#define DEBUG_SPLIT 0
3255
 
3256
/* Returns TRUE if the given PSImode move should be split.  We split
3257
   for all r8c/m16c moves, since it doesn't support them, and for
3258
   POP.L as we can only *push* SImode.  */
3259
int
3260
m32c_split_psi_p (rtx * operands)
3261
{
3262
#if DEBUG_SPLIT
3263
  fprintf (stderr, "\nm32c_split_psi_p\n");
3264
  debug_rtx (operands[0]);
3265
  debug_rtx (operands[1]);
3266
#endif
3267
  if (TARGET_A16)
3268
    {
3269
#if DEBUG_SPLIT
3270
      fprintf (stderr, "yes, A16\n");
3271
#endif
3272
      return 1;
3273
    }
3274
  if (GET_CODE (operands[1]) == MEM
3275
      && GET_CODE (XEXP (operands[1], 0)) == POST_INC)
3276
    {
3277
#if DEBUG_SPLIT
3278
      fprintf (stderr, "yes, pop.l\n");
3279
#endif
3280
      return 1;
3281
    }
3282
#if DEBUG_SPLIT
3283
  fprintf (stderr, "no, default\n");
3284
#endif
3285
  return 0;
3286
}
3287
 
3288
/* Split the given move.  SPLIT_ALL is 0 if splitting is optional
3289
   (define_expand), 1 if it is not optional (define_insn_and_split),
3290
   and 3 for define_split (alternate api). */
3291
int
3292
m32c_split_move (rtx * operands, enum machine_mode mode, int split_all)
3293
{
3294
  rtx s[4], d[4];
3295
  int parts, si, di, rev = 0;
3296
  int rv = 0, opi = 2;
3297
  enum machine_mode submode = HImode;
3298
  rtx *ops, local_ops[10];
3299
 
3300
  /* define_split modifies the existing operands, but the other two
3301
     emit new insns.  OPS is where we store the operand pairs, which
3302
     we emit later.  */
3303
  if (split_all == 3)
3304
    ops = operands;
3305
  else
3306
    ops = local_ops;
3307
 
3308
  /* Else HImode.  */
3309
  if (mode == DImode)
3310
    submode = SImode;
3311
 
3312
  /* Before splitting mem-mem moves, force one operand into a
3313
     register.  */
3314
  if (can_create_pseudo_p () && MEM_P (operands[0]) && MEM_P (operands[1]))
3315
    {
3316
#if DEBUG0
3317
      fprintf (stderr, "force_reg...\n");
3318
      debug_rtx (operands[1]);
3319
#endif
3320
      operands[1] = force_reg (mode, operands[1]);
3321
#if DEBUG0
3322
      debug_rtx (operands[1]);
3323
#endif
3324
    }
3325
 
3326
  parts = 2;
3327
 
3328
#if DEBUG_SPLIT
3329
  fprintf (stderr, "\nsplit_move %d all=%d\n", !can_create_pseudo_p (),
3330
           split_all);
3331
  debug_rtx (operands[0]);
3332
  debug_rtx (operands[1]);
3333
#endif
3334
 
3335
  /* Note that split_all is not used to select the api after this
3336
     point, so it's safe to set it to 3 even with define_insn.  */
3337
  /* None of the chips can move SI operands to sp-relative addresses,
3338
     so we always split those.  */
3339
  if (m32c_extra_constraint_p (operands[0], 'S', "Ss"))
3340
    split_all = 3;
3341
 
3342
  /* We don't need to split these.  */
3343
  if (TARGET_A24
3344
      && split_all != 3
3345
      && (mode == SImode || mode == PSImode)
3346
      && !(GET_CODE (operands[1]) == MEM
3347
           && GET_CODE (XEXP (operands[1], 0)) == POST_INC))
3348
    return 0;
3349
 
3350
  /* First, enumerate the subregs we'll be dealing with.  */
3351
  for (si = 0; si < parts; si++)
3352
    {
3353
      d[si] =
3354
        m32c_subreg (submode, operands[0], mode,
3355
                     si * GET_MODE_SIZE (submode));
3356
      s[si] =
3357
        m32c_subreg (submode, operands[1], mode,
3358
                     si * GET_MODE_SIZE (submode));
3359
    }
3360
 
3361
  /* Split pushes by emitting a sequence of smaller pushes.  */
3362
  if (GET_CODE (d[0]) == MEM && GET_CODE (XEXP (d[0], 0)) == PRE_DEC)
3363
    {
3364
      for (si = parts - 1; si >= 0; si--)
3365
        {
3366
          ops[opi++] = gen_rtx_MEM (submode,
3367
                                    gen_rtx_PRE_DEC (Pmode,
3368
                                                     gen_rtx_REG (Pmode,
3369
                                                                  SP_REGNO)));
3370
          ops[opi++] = s[si];
3371
        }
3372
 
3373
      rv = 1;
3374
    }
3375
  /* Likewise for pops.  */
3376
  else if (GET_CODE (s[0]) == MEM && GET_CODE (XEXP (s[0], 0)) == POST_INC)
3377
    {
3378
      for (di = 0; di < parts; di++)
3379
        {
3380
          ops[opi++] = d[di];
3381
          ops[opi++] = gen_rtx_MEM (submode,
3382
                                    gen_rtx_POST_INC (Pmode,
3383
                                                      gen_rtx_REG (Pmode,
3384
                                                                   SP_REGNO)));
3385
        }
3386
      rv = 1;
3387
    }
3388
  else if (split_all)
3389
    {
3390
      /* if d[di] == s[si] for any di < si, we'll early clobber. */
3391
      for (di = 0; di < parts - 1; di++)
3392
        for (si = di + 1; si < parts; si++)
3393
          if (reg_mentioned_p (d[di], s[si]))
3394
            rev = 1;
3395
 
3396
      if (rev)
3397
        for (si = 0; si < parts; si++)
3398
          {
3399
            ops[opi++] = d[si];
3400
            ops[opi++] = s[si];
3401
          }
3402
      else
3403
        for (si = parts - 1; si >= 0; si--)
3404
          {
3405
            ops[opi++] = d[si];
3406
            ops[opi++] = s[si];
3407
          }
3408
      rv = 1;
3409
    }
3410
  /* Now emit any moves we may have accumulated.  */
3411
  if (rv && split_all != 3)
3412
    {
3413
      int i;
3414
      for (i = 2; i < opi; i += 2)
3415
        emit_move_insn (ops[i], ops[i + 1]);
3416
    }
3417
  return rv;
3418
}
3419
 
3420
/* The m32c has a number of opcodes that act like memcpy, strcmp, and
3421
   the like.  For the R8C they expect one of the addresses to be in
3422
   R1L:An so we need to arrange for that.  Otherwise, it's just a
3423
   matter of picking out the operands we want and emitting the right
3424
   pattern for them.  All these expanders, which correspond to
3425
   patterns in blkmov.md, must return nonzero if they expand the insn,
3426
   or zero if they should FAIL.  */
3427
 
3428
/* This is a memset() opcode.  All operands are implied, so we need to
3429
   arrange for them to be in the right registers.  The opcode wants
3430
   addresses, not [mem] syntax.  $0 is the destination (MEM:BLK), $1
3431
   the count (HI), and $2 the value (QI).  */
3432
int
3433
m32c_expand_setmemhi(rtx *operands)
3434
{
3435
  rtx desta, count, val;
3436
  rtx desto, counto;
3437
 
3438
  desta = XEXP (operands[0], 0);
3439
  count = operands[1];
3440
  val = operands[2];
3441
 
3442
  desto = gen_reg_rtx (Pmode);
3443
  counto = gen_reg_rtx (HImode);
3444
 
3445
  if (GET_CODE (desta) != REG
3446
      || REGNO (desta) < FIRST_PSEUDO_REGISTER)
3447
    desta = copy_to_mode_reg (Pmode, desta);
3448
 
3449
  /* This looks like an arbitrary restriction, but this is by far the
3450
     most common case.  For counts 8..14 this actually results in
3451
     smaller code with no speed penalty because the half-sized
3452
     constant can be loaded with a shorter opcode.  */
3453
  if (GET_CODE (count) == CONST_INT
3454
      && GET_CODE (val) == CONST_INT
3455
      && ! (INTVAL (count) & 1)
3456
      && (INTVAL (count) > 1)
3457
      && (INTVAL (val) <= 7 && INTVAL (val) >= -8))
3458
    {
3459
      unsigned v = INTVAL (val) & 0xff;
3460
      v = v | (v << 8);
3461
      count = copy_to_mode_reg (HImode, GEN_INT (INTVAL (count) / 2));
3462
      val = copy_to_mode_reg (HImode, GEN_INT (v));
3463
      if (TARGET_A16)
3464
        emit_insn (gen_setmemhi_whi_op (desto, counto, val, desta, count));
3465
      else
3466
        emit_insn (gen_setmemhi_wpsi_op (desto, counto, val, desta, count));
3467
      return 1;
3468
    }
3469
 
3470
  /* This is the generalized memset() case.  */
3471
  if (GET_CODE (val) != REG
3472
      || REGNO (val) < FIRST_PSEUDO_REGISTER)
3473
    val = copy_to_mode_reg (QImode, val);
3474
 
3475
  if (GET_CODE (count) != REG
3476
      || REGNO (count) < FIRST_PSEUDO_REGISTER)
3477
    count = copy_to_mode_reg (HImode, count);
3478
 
3479
  if (TARGET_A16)
3480
    emit_insn (gen_setmemhi_bhi_op (desto, counto, val, desta, count));
3481
  else
3482
    emit_insn (gen_setmemhi_bpsi_op (desto, counto, val, desta, count));
3483
 
3484
  return 1;
3485
}
3486
 
3487
/* This is a memcpy() opcode.  All operands are implied, so we need to
3488
   arrange for them to be in the right registers.  The opcode wants
3489
   addresses, not [mem] syntax.  $0 is the destination (MEM:BLK), $1
3490
   is the source (MEM:BLK), and $2 the count (HI).  */
3491
int
3492
m32c_expand_movmemhi(rtx *operands)
3493
{
3494
  rtx desta, srca, count;
3495
  rtx desto, srco, counto;
3496
 
3497
  desta = XEXP (operands[0], 0);
3498
  srca = XEXP (operands[1], 0);
3499
  count = operands[2];
3500
 
3501
  desto = gen_reg_rtx (Pmode);
3502
  srco = gen_reg_rtx (Pmode);
3503
  counto = gen_reg_rtx (HImode);
3504
 
3505
  if (GET_CODE (desta) != REG
3506
      || REGNO (desta) < FIRST_PSEUDO_REGISTER)
3507
    desta = copy_to_mode_reg (Pmode, desta);
3508
 
3509
  if (GET_CODE (srca) != REG
3510
      || REGNO (srca) < FIRST_PSEUDO_REGISTER)
3511
    srca = copy_to_mode_reg (Pmode, srca);
3512
 
3513
  /* Similar to setmem, but we don't need to check the value.  */
3514
  if (GET_CODE (count) == CONST_INT
3515
      && ! (INTVAL (count) & 1)
3516
      && (INTVAL (count) > 1))
3517
    {
3518
      count = copy_to_mode_reg (HImode, GEN_INT (INTVAL (count) / 2));
3519
      if (TARGET_A16)
3520
        emit_insn (gen_movmemhi_whi_op (desto, srco, counto, desta, srca, count));
3521
      else
3522
        emit_insn (gen_movmemhi_wpsi_op (desto, srco, counto, desta, srca, count));
3523
      return 1;
3524
    }
3525
 
3526
  /* This is the generalized memset() case.  */
3527
  if (GET_CODE (count) != REG
3528
      || REGNO (count) < FIRST_PSEUDO_REGISTER)
3529
    count = copy_to_mode_reg (HImode, count);
3530
 
3531
  if (TARGET_A16)
3532
    emit_insn (gen_movmemhi_bhi_op (desto, srco, counto, desta, srca, count));
3533
  else
3534
    emit_insn (gen_movmemhi_bpsi_op (desto, srco, counto, desta, srca, count));
3535
 
3536
  return 1;
3537
}
3538
 
3539
/* This is a stpcpy() opcode.  $0 is the destination (MEM:BLK) after
3540
   the copy, which should point to the NUL at the end of the string,
3541
   $1 is the destination (MEM:BLK), and $2 is the source (MEM:BLK).
3542
   Since our opcode leaves the destination pointing *after* the NUL,
3543
   we must emit an adjustment.  */
3544
int
3545
m32c_expand_movstr(rtx *operands)
3546
{
3547
  rtx desta, srca;
3548
  rtx desto, srco;
3549
 
3550
  desta = XEXP (operands[1], 0);
3551
  srca = XEXP (operands[2], 0);
3552
 
3553
  desto = gen_reg_rtx (Pmode);
3554
  srco = gen_reg_rtx (Pmode);
3555
 
3556
  if (GET_CODE (desta) != REG
3557
      || REGNO (desta) < FIRST_PSEUDO_REGISTER)
3558
    desta = copy_to_mode_reg (Pmode, desta);
3559
 
3560
  if (GET_CODE (srca) != REG
3561
      || REGNO (srca) < FIRST_PSEUDO_REGISTER)
3562
    srca = copy_to_mode_reg (Pmode, srca);
3563
 
3564
  emit_insn (gen_movstr_op (desto, srco, desta, srca));
3565
  /* desto ends up being a1, which allows this type of add through MOVA.  */
3566
  emit_insn (gen_addpsi3 (operands[0], desto, GEN_INT (-1)));
3567
 
3568
  return 1;
3569
}
3570
 
3571
/* This is a strcmp() opcode.  $0 is the destination (HI) which holds
3572
   <=>0 depending on the comparison, $1 is one string (MEM:BLK), and
3573
   $2 is the other (MEM:BLK).  We must do the comparison, and then
3574
   convert the flags to a signed integer result.  */
3575
int
3576
m32c_expand_cmpstr(rtx *operands)
3577
{
3578
  rtx src1a, src2a;
3579
 
3580
  src1a = XEXP (operands[1], 0);
3581
  src2a = XEXP (operands[2], 0);
3582
 
3583
  if (GET_CODE (src1a) != REG
3584
      || REGNO (src1a) < FIRST_PSEUDO_REGISTER)
3585
    src1a = copy_to_mode_reg (Pmode, src1a);
3586
 
3587
  if (GET_CODE (src2a) != REG
3588
      || REGNO (src2a) < FIRST_PSEUDO_REGISTER)
3589
    src2a = copy_to_mode_reg (Pmode, src2a);
3590
 
3591
  emit_insn (gen_cmpstrhi_op (src1a, src2a, src1a, src2a));
3592
  emit_insn (gen_cond_to_int (operands[0]));
3593
 
3594
  return 1;
3595
}
3596
 
3597
 
3598
typedef rtx (*shift_gen_func)(rtx, rtx, rtx);
3599
 
3600
static shift_gen_func
3601
shift_gen_func_for (int mode, int code)
3602
{
3603
#define GFF(m,c,f) if (mode == m && code == c) return f
3604
  GFF(QImode,  ASHIFT,   gen_ashlqi3_i);
3605
  GFF(QImode,  ASHIFTRT, gen_ashrqi3_i);
3606
  GFF(QImode,  LSHIFTRT, gen_lshrqi3_i);
3607
  GFF(HImode,  ASHIFT,   gen_ashlhi3_i);
3608
  GFF(HImode,  ASHIFTRT, gen_ashrhi3_i);
3609
  GFF(HImode,  LSHIFTRT, gen_lshrhi3_i);
3610
  GFF(PSImode, ASHIFT,   gen_ashlpsi3_i);
3611
  GFF(PSImode, ASHIFTRT, gen_ashrpsi3_i);
3612
  GFF(PSImode, LSHIFTRT, gen_lshrpsi3_i);
3613
  GFF(SImode,  ASHIFT,   TARGET_A16 ? gen_ashlsi3_16 : gen_ashlsi3_24);
3614
  GFF(SImode,  ASHIFTRT, TARGET_A16 ? gen_ashrsi3_16 : gen_ashrsi3_24);
3615
  GFF(SImode,  LSHIFTRT, TARGET_A16 ? gen_lshrsi3_16 : gen_lshrsi3_24);
3616
#undef GFF
3617
  gcc_unreachable ();
3618
}
3619
 
3620
/* The m32c only has one shift, but it takes a signed count.  GCC
3621
   doesn't want this, so we fake it by negating any shift count when
3622
   we're pretending to shift the other way.  Also, the shift count is
3623
   limited to -8..8.  It's slightly better to use two shifts for 9..15
3624
   than to load the count into r1h, so we do that too.  */
3625
int
3626
m32c_prepare_shift (rtx * operands, int scale, int shift_code)
3627
{
3628
  enum machine_mode mode = GET_MODE (operands[0]);
3629
  shift_gen_func func = shift_gen_func_for (mode, shift_code);
3630
  rtx temp;
3631
 
3632
  if (GET_CODE (operands[2]) == CONST_INT)
3633
    {
3634
      int maxc = TARGET_A24 && (mode == PSImode || mode == SImode) ? 32 : 8;
3635
      int count = INTVAL (operands[2]) * scale;
3636
 
3637
      while (count > maxc)
3638
        {
3639
          temp = gen_reg_rtx (mode);
3640
          emit_insn (func (temp, operands[1], GEN_INT (maxc)));
3641
          operands[1] = temp;
3642
          count -= maxc;
3643
        }
3644
      while (count < -maxc)
3645
        {
3646
          temp = gen_reg_rtx (mode);
3647
          emit_insn (func (temp, operands[1], GEN_INT (-maxc)));
3648
          operands[1] = temp;
3649
          count += maxc;
3650
        }
3651
      emit_insn (func (operands[0], operands[1], GEN_INT (count)));
3652
      return 1;
3653
    }
3654
 
3655
  temp = gen_reg_rtx (QImode);
3656
  if (scale < 0)
3657
    /* The pattern has a NEG that corresponds to this. */
3658
    emit_move_insn (temp, gen_rtx_NEG (QImode, operands[2]));
3659
  else if (TARGET_A16 && mode == SImode)
3660
    /* We do this because the code below may modify this, we don't
3661
       want to modify the origin of this value.  */
3662
    emit_move_insn (temp, operands[2]);
3663
  else
3664
    /* We'll only use it for the shift, no point emitting a move.  */
3665
    temp = operands[2];
3666
 
3667
  if (TARGET_A16 && GET_MODE_SIZE (mode) == 4)
3668
    {
3669
      /* The m16c has a limit of -16..16 for SI shifts, even when the
3670
         shift count is in a register.  Since there are so many targets
3671
         of these shifts, it's better to expand the RTL here than to
3672
         call a helper function.
3673
 
3674
         The resulting code looks something like this:
3675
 
3676
                cmp.b   r1h,-16
3677
                jge.b   1f
3678
                shl.l   -16,dest
3679
                add.b   r1h,16
3680
        1f:     cmp.b   r1h,16
3681
                jle.b   1f
3682
                shl.l   16,dest
3683
                sub.b   r1h,16
3684
        1f:     shl.l   r1h,dest
3685
 
3686
         We take advantage of the fact that "negative" shifts are
3687
         undefined to skip one of the comparisons.  */
3688
 
3689
      rtx count;
3690
      rtx label, lref, insn, tempvar;
3691
 
3692
      emit_move_insn (operands[0], operands[1]);
3693
 
3694
      count = temp;
3695
      label = gen_label_rtx ();
3696
      lref = gen_rtx_LABEL_REF (VOIDmode, label);
3697
      LABEL_NUSES (label) ++;
3698
 
3699
      tempvar = gen_reg_rtx (mode);
3700
 
3701
      if (shift_code == ASHIFT)
3702
        {
3703
          /* This is a left shift.  We only need check positive counts.  */
3704
          emit_jump_insn (gen_cbranchqi4 (gen_rtx_LE (VOIDmode, 0, 0),
3705
                                          count, GEN_INT (16), label));
3706
          emit_insn (func (tempvar, operands[0], GEN_INT (8)));
3707
          emit_insn (func (operands[0], tempvar, GEN_INT (8)));
3708
          insn = emit_insn (gen_addqi3 (count, count, GEN_INT (-16)));
3709
          emit_label_after (label, insn);
3710
        }
3711
      else
3712
        {
3713
          /* This is a right shift.  We only need check negative counts.  */
3714
          emit_jump_insn (gen_cbranchqi4 (gen_rtx_GE (VOIDmode, 0, 0),
3715
                                          count, GEN_INT (-16), label));
3716
          emit_insn (func (tempvar, operands[0], GEN_INT (-8)));
3717
          emit_insn (func (operands[0], tempvar, GEN_INT (-8)));
3718
          insn = emit_insn (gen_addqi3 (count, count, GEN_INT (16)));
3719
          emit_label_after (label, insn);
3720
        }
3721
      operands[1] = operands[0];
3722
      emit_insn (func (operands[0], operands[0], count));
3723
      return 1;
3724
    }
3725
 
3726
  operands[2] = temp;
3727
  return 0;
3728
}
3729
 
3730
/* The m32c has a limited range of operations that work on PSImode
3731
   values; we have to expand to SI, do the math, and truncate back to
3732
   PSI.  Yes, this is expensive, but hopefully gcc will learn to avoid
3733
   those cases.  */
3734
void
3735
m32c_expand_neg_mulpsi3 (rtx * operands)
3736
{
3737
  /* operands: a = b * i */
3738
  rtx temp1; /* b as SI */
3739
  rtx scale /* i as SI */;
3740
  rtx temp2; /* a*b as SI */
3741
 
3742
  temp1 = gen_reg_rtx (SImode);
3743
  temp2 = gen_reg_rtx (SImode);
3744
  if (GET_CODE (operands[2]) != CONST_INT)
3745
    {
3746
      scale = gen_reg_rtx (SImode);
3747
      emit_insn (gen_zero_extendpsisi2 (scale, operands[2]));
3748
    }
3749
  else
3750
    scale = copy_to_mode_reg (SImode, operands[2]);
3751
 
3752
  emit_insn (gen_zero_extendpsisi2 (temp1, operands[1]));
3753
  temp2 = expand_simple_binop (SImode, MULT, temp1, scale, temp2, 1, OPTAB_LIB);
3754
  emit_insn (gen_truncsipsi2 (operands[0], temp2));
3755
}
3756
 
3757
/* Pattern Output Functions */
3758
 
3759
int
3760
m32c_expand_movcc (rtx *operands)
3761
{
3762
  rtx rel = operands[1];
3763
  rtx cmp;
3764
 
3765
  if (GET_CODE (rel) != EQ && GET_CODE (rel) != NE)
3766
    return 1;
3767
  if (GET_CODE (operands[2]) != CONST_INT
3768
      || GET_CODE (operands[3]) != CONST_INT)
3769
    return 1;
3770
  if (GET_CODE (rel) == NE)
3771
    {
3772
      rtx tmp = operands[2];
3773
      operands[2] = operands[3];
3774
      operands[3] = tmp;
3775
      rel = gen_rtx_EQ (GET_MODE (rel), XEXP (rel, 0), XEXP (rel, 1));
3776
    }
3777
 
3778
  emit_move_insn (operands[0],
3779
                  gen_rtx_IF_THEN_ELSE (GET_MODE (operands[0]),
3780
                                        rel,
3781
                                        operands[2],
3782
                                        operands[3]));
3783
  return 0;
3784
}
3785
 
3786
/* Used for the "insv" pattern.  Return nonzero to fail, else done.  */
3787
int
3788
m32c_expand_insv (rtx *operands)
3789
{
3790
  rtx op0, src0, p;
3791
  int mask;
3792
 
3793
  if (INTVAL (operands[1]) != 1)
3794
    return 1;
3795
 
3796
  /* Our insv opcode (bset, bclr) can only insert a one-bit constant.  */
3797
  if (GET_CODE (operands[3]) != CONST_INT)
3798
    return 1;
3799
  if (INTVAL (operands[3]) != 0
3800
      && INTVAL (operands[3]) != 1
3801
      && INTVAL (operands[3]) != -1)
3802
    return 1;
3803
 
3804
  mask = 1 << INTVAL (operands[2]);
3805
 
3806
  op0 = operands[0];
3807
  if (GET_CODE (op0) == SUBREG
3808
      && SUBREG_BYTE (op0) == 0)
3809
    {
3810
      rtx sub = SUBREG_REG (op0);
3811
      if (GET_MODE (sub) == HImode || GET_MODE (sub) == QImode)
3812
        op0 = sub;
3813
    }
3814
 
3815
  if (!can_create_pseudo_p ()
3816
      || (GET_CODE (op0) == MEM && MEM_VOLATILE_P (op0)))
3817
    src0 = op0;
3818
  else
3819
    {
3820
      src0 = gen_reg_rtx (GET_MODE (op0));
3821
      emit_move_insn (src0, op0);
3822
    }
3823
 
3824
  if (GET_MODE (op0) == HImode
3825
      && INTVAL (operands[2]) >= 8
3826
      && GET_MODE (op0) == MEM)
3827
    {
3828
      /* We are little endian.  */
3829
      rtx new_mem = gen_rtx_MEM (QImode, plus_constant (XEXP (op0, 0), 1));
3830
      MEM_COPY_ATTRIBUTES (new_mem, op0);
3831
      mask >>= 8;
3832
    }
3833
 
3834
  /* First, we generate a mask with the correct polarity.  If we are
3835
     storing a zero, we want an AND mask, so invert it.  */
3836
  if (INTVAL (operands[3]) == 0)
3837
    {
3838
      /* Storing a zero, use an AND mask */
3839
      if (GET_MODE (op0) == HImode)
3840
        mask ^= 0xffff;
3841
      else
3842
        mask ^= 0xff;
3843
    }
3844
  /* Now we need to properly sign-extend the mask in case we need to
3845
     fall back to an AND or OR opcode.  */
3846
  if (GET_MODE (op0) == HImode)
3847
    {
3848
      if (mask & 0x8000)
3849
        mask -= 0x10000;
3850
    }
3851
  else
3852
    {
3853
      if (mask & 0x80)
3854
        mask -= 0x100;
3855
    }
3856
 
3857
  switch (  (INTVAL (operands[3]) ? 4 : 0)
3858
          + ((GET_MODE (op0) == HImode) ? 2 : 0)
3859
          + (TARGET_A24 ? 1 : 0))
3860
    {
3861
    case 0: p = gen_andqi3_16 (op0, src0, GEN_INT (mask)); break;
3862
    case 1: p = gen_andqi3_24 (op0, src0, GEN_INT (mask)); break;
3863
    case 2: p = gen_andhi3_16 (op0, src0, GEN_INT (mask)); break;
3864
    case 3: p = gen_andhi3_24 (op0, src0, GEN_INT (mask)); break;
3865
    case 4: p = gen_iorqi3_16 (op0, src0, GEN_INT (mask)); break;
3866
    case 5: p = gen_iorqi3_24 (op0, src0, GEN_INT (mask)); break;
3867
    case 6: p = gen_iorhi3_16 (op0, src0, GEN_INT (mask)); break;
3868
    case 7: p = gen_iorhi3_24 (op0, src0, GEN_INT (mask)); break;
3869
    default: p = NULL_RTX; break; /* Not reached, but silences a warning.  */
3870
    }
3871
 
3872
  emit_insn (p);
3873
  return 0;
3874
}
3875
 
3876
const char *
3877
m32c_scc_pattern(rtx *operands, RTX_CODE code)
3878
{
3879
  static char buf[30];
3880
  if (GET_CODE (operands[0]) == REG
3881
      && REGNO (operands[0]) == R0_REGNO)
3882
    {
3883
      if (code == EQ)
3884
        return "stzx\t#1,#0,r0l";
3885
      if (code == NE)
3886
        return "stzx\t#0,#1,r0l";
3887
    }
3888
  sprintf(buf, "bm%s\t0,%%h0\n\tand.b\t#1,%%0", GET_RTX_NAME (code));
3889
  return buf;
3890
}
3891
 
3892
/* Encode symbol attributes of a SYMBOL_REF into its
3893
   SYMBOL_REF_FLAGS. */
3894
static void
3895
m32c_encode_section_info (tree decl, rtx rtl, int first)
3896
{
3897
  int extra_flags = 0;
3898
 
3899
  default_encode_section_info (decl, rtl, first);
3900
  if (TREE_CODE (decl) == FUNCTION_DECL
3901
      && m32c_special_page_vector_p (decl))
3902
 
3903
    extra_flags = SYMBOL_FLAG_FUNCVEC_FUNCTION;
3904
 
3905
  if (extra_flags)
3906
    SYMBOL_REF_FLAGS (XEXP (rtl, 0)) |= extra_flags;
3907
}
3908
 
3909
/* Returns TRUE if the current function is a leaf, and thus we can
3910
   determine which registers an interrupt function really needs to
3911
   save.  The logic below is mostly about finding the insn sequence
3912
   that's the function, versus any sequence that might be open for the
3913
   current insn.  */
3914
static int
3915
m32c_leaf_function_p (void)
3916
{
3917
  rtx saved_first, saved_last;
3918
  struct sequence_stack *seq;
3919
  int rv;
3920
 
3921
  saved_first = crtl->emit.x_first_insn;
3922
  saved_last = crtl->emit.x_last_insn;
3923
  for (seq = crtl->emit.sequence_stack; seq && seq->next; seq = seq->next)
3924
    ;
3925
  if (seq)
3926
    {
3927
      crtl->emit.x_first_insn = seq->first;
3928
      crtl->emit.x_last_insn = seq->last;
3929
    }
3930
 
3931
  rv = leaf_function_p ();
3932
 
3933
  crtl->emit.x_first_insn = saved_first;
3934
  crtl->emit.x_last_insn = saved_last;
3935
  return rv;
3936
}
3937
 
3938
/* Returns TRUE if the current function needs to use the ENTER/EXIT
3939
   opcodes.  If the function doesn't need the frame base or stack
3940
   pointer, it can use the simpler RTS opcode.  */
3941
static bool
3942
m32c_function_needs_enter (void)
3943
{
3944
  rtx insn;
3945
  struct sequence_stack *seq;
3946
  rtx sp = gen_rtx_REG (Pmode, SP_REGNO);
3947
  rtx fb = gen_rtx_REG (Pmode, FB_REGNO);
3948
 
3949
  insn = get_insns ();
3950
  for (seq = crtl->emit.sequence_stack;
3951
       seq;
3952
       insn = seq->first, seq = seq->next);
3953
 
3954
  while (insn)
3955
    {
3956
      if (reg_mentioned_p (sp, insn))
3957
        return true;
3958
      if (reg_mentioned_p (fb, insn))
3959
        return true;
3960
      insn = NEXT_INSN (insn);
3961
    }
3962
  return false;
3963
}
3964
 
3965
/* Mark all the subexpressions of the PARALLEL rtx PAR as
3966
   frame-related.  Return PAR.
3967
 
3968
   dwarf2out.c:dwarf2out_frame_debug_expr ignores sub-expressions of a
3969
   PARALLEL rtx other than the first if they do not have the
3970
   FRAME_RELATED flag set on them.  So this function is handy for
3971
   marking up 'enter' instructions.  */
3972
static rtx
3973
m32c_all_frame_related (rtx par)
3974
{
3975
  int len = XVECLEN (par, 0);
3976
  int i;
3977
 
3978
  for (i = 0; i < len; i++)
3979
    F (XVECEXP (par, 0, i));
3980
 
3981
  return par;
3982
}
3983
 
3984
/* Emits the prologue.  See the frame layout comment earlier in this
3985
   file.  We can reserve up to 256 bytes with the ENTER opcode, beyond
3986
   that we manually update sp.  */
3987
void
3988
m32c_emit_prologue (void)
3989
{
3990
  int frame_size, extra_frame_size = 0, reg_save_size;
3991
  int complex_prologue = 0;
3992
 
3993
  cfun->machine->is_leaf = m32c_leaf_function_p ();
3994
  if (interrupt_p (cfun->decl))
3995
    {
3996
      cfun->machine->is_interrupt = 1;
3997
      complex_prologue = 1;
3998
    }
3999
  else if (bank_switch_p (cfun->decl))
4000
    warning (OPT_Wattributes,
4001
             "%<bank_switch%> has no effect on non-interrupt functions");
4002
 
4003
  reg_save_size = m32c_pushm_popm (PP_justcount);
4004
 
4005
  if (interrupt_p (cfun->decl))
4006
    {
4007
      if (bank_switch_p (cfun->decl))
4008
        emit_insn (gen_fset_b ());
4009
      else if (cfun->machine->intr_pushm)
4010
        emit_insn (gen_pushm (GEN_INT (cfun->machine->intr_pushm)));
4011
    }
4012
 
4013
  frame_size =
4014
    m32c_initial_elimination_offset (FB_REGNO, SP_REGNO) - reg_save_size;
4015
  if (frame_size == 0
4016
      && !m32c_function_needs_enter ())
4017
    cfun->machine->use_rts = 1;
4018
 
4019
  if (frame_size > 254)
4020
    {
4021
      extra_frame_size = frame_size - 254;
4022
      frame_size = 254;
4023
    }
4024
  if (cfun->machine->use_rts == 0)
4025
    F (emit_insn (m32c_all_frame_related
4026
                  (TARGET_A16
4027
                   ? gen_prologue_enter_16 (GEN_INT (frame_size + 2))
4028
                   : gen_prologue_enter_24 (GEN_INT (frame_size + 4)))));
4029
 
4030
  if (extra_frame_size)
4031
    {
4032
      complex_prologue = 1;
4033
      if (TARGET_A16)
4034
        F (emit_insn (gen_addhi3 (gen_rtx_REG (HImode, SP_REGNO),
4035
                                  gen_rtx_REG (HImode, SP_REGNO),
4036
                                  GEN_INT (-extra_frame_size))));
4037
      else
4038
        F (emit_insn (gen_addpsi3 (gen_rtx_REG (PSImode, SP_REGNO),
4039
                                   gen_rtx_REG (PSImode, SP_REGNO),
4040
                                   GEN_INT (-extra_frame_size))));
4041
    }
4042
 
4043
  complex_prologue += m32c_pushm_popm (PP_pushm);
4044
 
4045
  /* This just emits a comment into the .s file for debugging.  */
4046
  if (complex_prologue)
4047
    emit_insn (gen_prologue_end ());
4048
}
4049
 
4050
/* Likewise, for the epilogue.  The only exception is that, for
4051
   interrupts, we must manually unwind the frame as the REIT opcode
4052
   doesn't do that.  */
4053
void
4054
m32c_emit_epilogue (void)
4055
{
4056
  /* This just emits a comment into the .s file for debugging.  */
4057
  if (m32c_pushm_popm (PP_justcount) > 0 || cfun->machine->is_interrupt)
4058
    emit_insn (gen_epilogue_start ());
4059
 
4060
  m32c_pushm_popm (PP_popm);
4061
 
4062
  if (cfun->machine->is_interrupt)
4063
    {
4064
      enum machine_mode spmode = TARGET_A16 ? HImode : PSImode;
4065
 
4066
      /* REIT clears B flag and restores $fp for us, but we still
4067
         have to fix up the stack.  USE_RTS just means we didn't
4068
         emit ENTER.  */
4069
      if (!cfun->machine->use_rts)
4070
        {
4071
          emit_move_insn (gen_rtx_REG (spmode, A0_REGNO),
4072
                          gen_rtx_REG (spmode, FP_REGNO));
4073
          emit_move_insn (gen_rtx_REG (spmode, SP_REGNO),
4074
                          gen_rtx_REG (spmode, A0_REGNO));
4075
          /* We can't just add this to the POPM because it would be in
4076
             the wrong order, and wouldn't fix the stack if we're bank
4077
             switching.  */
4078
          if (TARGET_A16)
4079
            emit_insn (gen_pophi_16 (gen_rtx_REG (HImode, FP_REGNO)));
4080
          else
4081
            emit_insn (gen_poppsi (gen_rtx_REG (PSImode, FP_REGNO)));
4082
        }
4083
      if (!bank_switch_p (cfun->decl) && cfun->machine->intr_pushm)
4084
        emit_insn (gen_popm (GEN_INT (cfun->machine->intr_pushm)));
4085
 
4086
      /* The FREIT (Fast REturn from InTerrupt) instruction should be
4087
         generated only for M32C/M32CM targets (generate the REIT
4088
         instruction otherwise).  */
4089
      if (fast_interrupt_p (cfun->decl))
4090
        {
4091
          /* Check if fast_attribute is set for M32C or M32CM.  */
4092
          if (TARGET_A24)
4093
            {
4094
              emit_jump_insn (gen_epilogue_freit ());
4095
            }
4096
          /* If fast_interrupt attribute is set for an R8C or M16C
4097
             target ignore this attribute and generated REIT
4098
             instruction.  */
4099
          else
4100
            {
4101
              warning (OPT_Wattributes,
4102
                       "%<fast_interrupt%> attribute directive ignored");
4103
              emit_jump_insn (gen_epilogue_reit_16 ());
4104
            }
4105
        }
4106
      else if (TARGET_A16)
4107
        emit_jump_insn (gen_epilogue_reit_16 ());
4108
      else
4109
        emit_jump_insn (gen_epilogue_reit_24 ());
4110
    }
4111
  else if (cfun->machine->use_rts)
4112
    emit_jump_insn (gen_epilogue_rts ());
4113
  else if (TARGET_A16)
4114
    emit_jump_insn (gen_epilogue_exitd_16 ());
4115
  else
4116
    emit_jump_insn (gen_epilogue_exitd_24 ());
4117
  emit_barrier ();
4118
}
4119
 
4120
void
4121
m32c_emit_eh_epilogue (rtx ret_addr)
4122
{
4123
  /* R0[R2] has the stack adjustment.  R1[R3] has the address to
4124
     return to.  We have to fudge the stack, pop everything, pop SP
4125
     (fudged), and return (fudged).  This is actually easier to do in
4126
     assembler, so punt to libgcc.  */
4127
  emit_jump_insn (gen_eh_epilogue (ret_addr, cfun->machine->eh_stack_adjust));
4128
  /*  emit_clobber (gen_rtx_REG (HImode, R0L_REGNO)); */
4129
  emit_barrier ();
4130
}
4131
 
4132
/* Indicate which flags must be properly set for a given conditional.  */
4133
static int
4134
flags_needed_for_conditional (rtx cond)
4135
{
4136
  switch (GET_CODE (cond))
4137
    {
4138
    case LE:
4139
    case GT:
4140
      return FLAGS_OSZ;
4141
    case LEU:
4142
    case GTU:
4143
      return FLAGS_ZC;
4144
    case LT:
4145
    case GE:
4146
      return FLAGS_OS;
4147
    case LTU:
4148
    case GEU:
4149
      return FLAGS_C;
4150
    case EQ:
4151
    case NE:
4152
      return FLAGS_Z;
4153
    default:
4154
      return FLAGS_N;
4155
    }
4156
}
4157
 
4158
#define DEBUG_CMP 0
4159
 
4160
/* Returns true if a compare insn is redundant because it would only
4161
   set flags that are already set correctly.  */
4162
static bool
4163
m32c_compare_redundant (rtx cmp, rtx *operands)
4164
{
4165
  int flags_needed;
4166
  int pflags;
4167
  rtx prev, pp, next;
4168
  rtx op0, op1, op2;
4169
#if DEBUG_CMP
4170
  int prev_icode, i;
4171
#endif
4172
 
4173
  op0 = operands[0];
4174
  op1 = operands[1];
4175
  op2 = operands[2];
4176
 
4177
#if DEBUG_CMP
4178
  fprintf(stderr, "\n\033[32mm32c_compare_redundant\033[0m\n");
4179
  debug_rtx(cmp);
4180
  for (i=0; i<2; i++)
4181
    {
4182
      fprintf(stderr, "operands[%d] = ", i);
4183
      debug_rtx(operands[i]);
4184
    }
4185
#endif
4186
 
4187
  next = next_nonnote_insn (cmp);
4188
  if (!next || !INSN_P (next))
4189
    {
4190
#if DEBUG_CMP
4191
      fprintf(stderr, "compare not followed by insn\n");
4192
      debug_rtx(next);
4193
#endif
4194
      return false;
4195
    }
4196
  if (GET_CODE (PATTERN (next)) == SET
4197
      && GET_CODE (XEXP ( PATTERN (next), 1)) == IF_THEN_ELSE)
4198
    {
4199
      next = XEXP (XEXP (PATTERN (next), 1), 0);
4200
    }
4201
  else if (GET_CODE (PATTERN (next)) == SET)
4202
    {
4203
      /* If this is a conditional, flags_needed will be something
4204
         other than FLAGS_N, which we test below.  */
4205
      next = XEXP (PATTERN (next), 1);
4206
    }
4207
  else
4208
    {
4209
#if DEBUG_CMP
4210
      fprintf(stderr, "compare not followed by conditional\n");
4211
      debug_rtx(next);
4212
#endif
4213
      return false;
4214
    }
4215
#if DEBUG_CMP
4216
  fprintf(stderr, "conditional is: ");
4217
  debug_rtx(next);
4218
#endif
4219
 
4220
  flags_needed = flags_needed_for_conditional (next);
4221
  if (flags_needed == FLAGS_N)
4222
    {
4223
#if DEBUG_CMP
4224
      fprintf(stderr, "compare not followed by conditional\n");
4225
      debug_rtx(next);
4226
#endif
4227
      return false;
4228
    }
4229
 
4230
  /* Compare doesn't set overflow and carry the same way that
4231
     arithmetic instructions do, so we can't replace those.  */
4232
  if (flags_needed & FLAGS_OC)
4233
    return false;
4234
 
4235
  prev = cmp;
4236
  do {
4237
    prev = prev_nonnote_insn (prev);
4238
    if (!prev)
4239
      {
4240
#if DEBUG_CMP
4241
        fprintf(stderr, "No previous insn.\n");
4242
#endif
4243
        return false;
4244
      }
4245
    if (!INSN_P (prev))
4246
      {
4247
#if DEBUG_CMP
4248
        fprintf(stderr, "Previous insn is a non-insn.\n");
4249
#endif
4250
        return false;
4251
      }
4252
    pp = PATTERN (prev);
4253
    if (GET_CODE (pp) != SET)
4254
      {
4255
#if DEBUG_CMP
4256
        fprintf(stderr, "Previous insn is not a SET.\n");
4257
#endif
4258
        return false;
4259
      }
4260
    pflags = get_attr_flags (prev);
4261
 
4262
    /* Looking up attributes of previous insns corrupted the recog
4263
       tables.  */
4264
    INSN_UID (cmp) = -1;
4265
    recog (PATTERN (cmp), cmp, 0);
4266
 
4267
    if (pflags == FLAGS_N
4268
        && reg_mentioned_p (op0, pp))
4269
      {
4270
#if DEBUG_CMP
4271
        fprintf(stderr, "intermediate non-flags insn uses op:\n");
4272
        debug_rtx(prev);
4273
#endif
4274
        return false;
4275
      }
4276
 
4277
    /* Check for comparisons against memory - between volatiles and
4278
       aliases, we just can't risk this one.  */
4279
    if (GET_CODE (operands[0]) == MEM
4280
        || GET_CODE (operands[0]) == MEM)
4281
      {
4282
#if DEBUG_CMP
4283
        fprintf(stderr, "comparisons with memory:\n");
4284
        debug_rtx(prev);
4285
#endif
4286
        return false;
4287
      }
4288
 
4289
    /* Check for PREV changing a register that's used to compute a
4290
       value in CMP, even if it doesn't otherwise change flags.  */
4291
    if (GET_CODE (operands[0]) == REG
4292
        && rtx_referenced_p (SET_DEST (PATTERN (prev)), operands[0]))
4293
      {
4294
#if DEBUG_CMP
4295
        fprintf(stderr, "sub-value affected, op0:\n");
4296
        debug_rtx(prev);
4297
#endif
4298
        return false;
4299
      }
4300
    if (GET_CODE (operands[1]) == REG
4301
        && rtx_referenced_p (SET_DEST (PATTERN (prev)), operands[1]))
4302
      {
4303
#if DEBUG_CMP
4304
        fprintf(stderr, "sub-value affected, op1:\n");
4305
        debug_rtx(prev);
4306
#endif
4307
        return false;
4308
      }
4309
 
4310
  } while (pflags == FLAGS_N);
4311
#if DEBUG_CMP
4312
  fprintf(stderr, "previous flag-setting insn:\n");
4313
  debug_rtx(prev);
4314
  debug_rtx(pp);
4315
#endif
4316
 
4317
  if (GET_CODE (pp) == SET
4318
      && GET_CODE (XEXP (pp, 0)) == REG
4319
      && REGNO (XEXP (pp, 0)) == FLG_REGNO
4320
      && GET_CODE (XEXP (pp, 1)) == COMPARE)
4321
    {
4322
      /* Adjacent cbranches must have the same operands to be
4323
         redundant.  */
4324
      rtx pop0 = XEXP (XEXP (pp, 1), 0);
4325
      rtx pop1 = XEXP (XEXP (pp, 1), 1);
4326
#if DEBUG_CMP
4327
      fprintf(stderr, "adjacent cbranches\n");
4328
      debug_rtx(pop0);
4329
      debug_rtx(pop1);
4330
#endif
4331
      if (rtx_equal_p (op0, pop0)
4332
          && rtx_equal_p (op1, pop1))
4333
        return true;
4334
#if DEBUG_CMP
4335
      fprintf(stderr, "prev cmp not same\n");
4336
#endif
4337
      return false;
4338
    }
4339
 
4340
  /* Else the previous insn must be a SET, with either the source or
4341
     dest equal to operands[0], and operands[1] must be zero.  */
4342
 
4343
  if (!rtx_equal_p (op1, const0_rtx))
4344
    {
4345
#if DEBUG_CMP
4346
      fprintf(stderr, "operands[1] not const0_rtx\n");
4347
#endif
4348
      return false;
4349
    }
4350
  if (GET_CODE (pp) != SET)
4351
    {
4352
#if DEBUG_CMP
4353
      fprintf (stderr, "pp not set\n");
4354
#endif
4355
      return false;
4356
    }
4357
  if (!rtx_equal_p (op0, SET_SRC (pp))
4358
      && !rtx_equal_p (op0, SET_DEST (pp)))
4359
    {
4360
#if DEBUG_CMP
4361
      fprintf(stderr, "operands[0] not found in set\n");
4362
#endif
4363
      return false;
4364
    }
4365
 
4366
#if DEBUG_CMP
4367
  fprintf(stderr, "cmp flags %x prev flags %x\n", flags_needed, pflags);
4368
#endif
4369
  if ((pflags & flags_needed) == flags_needed)
4370
    return true;
4371
 
4372
  return false;
4373
}
4374
 
4375
/* Return the pattern for a compare.  This will be commented out if
4376
   the compare is redundant, else a normal pattern is returned.  Thus,
4377
   the assembler output says where the compare would have been.  */
4378
char *
4379
m32c_output_compare (rtx insn, rtx *operands)
4380
{
4381
  static char templ[] = ";cmp.b\t%1,%0";
4382
  /*                             ^ 5  */
4383
 
4384
  templ[5] = " bwll"[GET_MODE_SIZE(GET_MODE(operands[0]))];
4385
  if (m32c_compare_redundant (insn, operands))
4386
    {
4387
#if DEBUG_CMP
4388
      fprintf(stderr, "cbranch: cmp not needed\n");
4389
#endif
4390
      return templ;
4391
    }
4392
 
4393
#if DEBUG_CMP
4394
  fprintf(stderr, "cbranch: cmp needed: `%s'\n", templ + 1);
4395
#endif
4396
  return templ + 1;
4397
}
4398
 
4399
#undef TARGET_ENCODE_SECTION_INFO
4400
#define TARGET_ENCODE_SECTION_INFO m32c_encode_section_info
4401
 
4402
/* If the frame pointer isn't used, we detect it manually.  But the
4403
   stack pointer doesn't have as flexible addressing as the frame
4404
   pointer, so we always assume we have it.  */
4405
 
4406
#undef TARGET_FRAME_POINTER_REQUIRED
4407
#define TARGET_FRAME_POINTER_REQUIRED hook_bool_void_true
4408
 
4409
/* The Global `targetm' Variable. */
4410
 
4411
struct gcc_target targetm = TARGET_INITIALIZER;
4412
 
4413
#include "gt-m32c.h"

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