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[/] [openrisc/] [trunk/] [gnu-stable/] [gdb-7.2/] [sim/] [v850/] [simops.c] - Blame information for rev 853

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Line No. Rev Author Line
1 330 jeremybenn
#include "sim-main.h"
2
#include "v850_sim.h"
3
#include "simops.h"
4
 
5
#include <sys/types.h>
6
 
7
#ifdef HAVE_UTIME_H
8
#include <utime.h>
9
#endif
10
 
11
#ifdef HAVE_TIME_H
12
#include <time.h>
13
#endif
14
 
15
#ifdef HAVE_UNISTD_H
16
#include <unistd.h>
17
#endif
18
 
19
#ifdef HAVE_STRING_H
20
#include <string.h>
21
#else
22
#ifdef HAVE_STRINGS_H
23
#include <strings.h>
24
#endif
25
#endif
26
 
27
#include "targ-vals.h"
28
 
29
#include "libiberty.h"
30
 
31
#include <errno.h>
32
#if !defined(__GO32__) && !defined(_WIN32)
33
#include <sys/stat.h>
34
#include <sys/times.h>
35
#include <sys/time.h>
36
#endif
37
 
38
/* This is an array of the bit positions of registers r20 .. r31 in
39
   that order in a prepare/dispose instruction.  */
40
int type1_regs[12] = { 27, 26, 25, 24, 31, 30, 29, 28, 23, 22, 0, 21 };
41
/* This is an array of the bit positions of registers r16 .. r31 in
42
   that order in a push/pop instruction.  */
43
int type2_regs[16] = { 3, 2, 1, 0, 27, 26, 25, 24, 31, 30, 29, 28, 23, 22, 20, 21};
44
/* This is an array of the bit positions of registers r1 .. r15 in
45
   that order in a push/pop instruction.  */
46
int type3_regs[15] = { 2, 1, 0, 27, 26, 25, 24, 31, 30, 29, 28, 23, 22, 20, 21};
47
 
48
#ifdef DEBUG
49
#ifndef SIZE_INSTRUCTION
50
#define SIZE_INSTRUCTION 18
51
#endif
52
 
53
#ifndef SIZE_VALUES
54
#define SIZE_VALUES 11
55
#endif
56
 
57
 
58
unsigned32 trace_values[3];
59
int trace_num_values;
60
unsigned32 trace_pc;
61
const char *trace_name;
62
int trace_module;
63
 
64
 
65
void
66
trace_input (name, type, size)
67
     char *name;
68
     enum op_types type;
69
     int size;
70
{
71
 
72
  if (!TRACE_ALU_P (STATE_CPU (simulator, 0)))
73
    return;
74
 
75
  trace_pc = PC;
76
  trace_name = name;
77
  trace_module = TRACE_ALU_IDX;
78
 
79
  switch (type)
80
    {
81
    default:
82
    case OP_UNKNOWN:
83
    case OP_NONE:
84
    case OP_TRAP:
85
      trace_num_values = 0;
86
      break;
87
 
88
    case OP_REG:
89
    case OP_REG_REG_MOVE:
90
      trace_values[0] = State.regs[OP[0]];
91
      trace_num_values = 1;
92
      break;
93
 
94
    case OP_BIT_CHANGE:
95
    case OP_REG_REG:
96
    case OP_REG_REG_CMP:
97
      trace_values[0] = State.regs[OP[1]];
98
      trace_values[1] = State.regs[OP[0]];
99
      trace_num_values = 2;
100
      break;
101
 
102
    case OP_IMM_REG:
103
    case OP_IMM_REG_CMP:
104
      trace_values[0] = SEXT5 (OP[0]);
105
      trace_values[1] = OP[1];
106
      trace_num_values = 2;
107
      break;
108
 
109
    case OP_IMM_REG_MOVE:
110
      trace_values[0] = SEXT5 (OP[0]);
111
      trace_num_values = 1;
112
      break;
113
 
114
    case OP_COND_BR:
115
      trace_values[0] = State.pc;
116
      trace_values[1] = SEXT9 (OP[0]);
117
      trace_values[2] = PSW;
118
      trace_num_values = 3;
119
      break;
120
 
121
    case OP_LOAD16:
122
      trace_values[0] = OP[1] * size;
123
      trace_values[1] = State.regs[30];
124
      trace_num_values = 2;
125
      break;
126
 
127
    case OP_STORE16:
128
      trace_values[0] = State.regs[OP[0]];
129
      trace_values[1] = OP[1] * size;
130
      trace_values[2] = State.regs[30];
131
      trace_num_values = 3;
132
      break;
133
 
134
    case OP_LOAD32:
135
      trace_values[0] = EXTEND16 (OP[2]);
136
      trace_values[1] = State.regs[OP[0]];
137
      trace_num_values = 2;
138
      break;
139
 
140
    case OP_STORE32:
141
      trace_values[0] = State.regs[OP[1]];
142
      trace_values[1] = EXTEND16 (OP[2]);
143
      trace_values[2] = State.regs[OP[0]];
144
      trace_num_values = 3;
145
      break;
146
 
147
    case OP_JUMP:
148
      trace_values[0] = SEXT22 (OP[0]);
149
      trace_values[1] = State.pc;
150
      trace_num_values = 2;
151
      break;
152
 
153
    case OP_IMM_REG_REG:
154
      trace_values[0] = EXTEND16 (OP[0]) << size;
155
      trace_values[1] = State.regs[OP[1]];
156
      trace_num_values = 2;
157
      break;
158
 
159
    case OP_IMM16_REG_REG:
160
      trace_values[0] = EXTEND16 (OP[2]) << size;
161
      trace_values[1] = State.regs[OP[1]];
162
      trace_num_values = 2;
163
      break;
164
 
165
    case OP_UIMM_REG_REG:
166
      trace_values[0] = (OP[0] & 0xffff) << size;
167
      trace_values[1] = State.regs[OP[1]];
168
      trace_num_values = 2;
169
      break;
170
 
171
    case OP_UIMM16_REG_REG:
172
      trace_values[0] = (OP[2]) << size;
173
      trace_values[1] = State.regs[OP[1]];
174
      trace_num_values = 2;
175
      break;
176
 
177
    case OP_BIT:
178
      trace_num_values = 0;
179
      break;
180
 
181
    case OP_EX1:
182
      trace_values[0] = PSW;
183
      trace_num_values = 1;
184
      break;
185
 
186
    case OP_EX2:
187
      trace_num_values = 0;
188
      break;
189
 
190
    case OP_LDSR:
191
      trace_values[0] = State.regs[OP[0]];
192
      trace_num_values = 1;
193
      break;
194
 
195
    case OP_STSR:
196
      trace_values[0] = State.sregs[OP[1]];
197
      trace_num_values = 1;
198
    }
199
 
200
}
201
 
202
void
203
trace_result (int has_result, unsigned32 result)
204
{
205
  char buf[1000];
206
  char *chp;
207
 
208
  buf[0] = '\0';
209
  chp = buf;
210
 
211
  /* write out the values saved during the trace_input call */
212
  {
213
    int i;
214
    for (i = 0; i < trace_num_values; i++)
215
      {
216
        sprintf (chp, "%*s0x%.8lx", SIZE_VALUES - 10, "",
217
                 (long) trace_values[i]);
218
        chp = strchr (chp, '\0');
219
      }
220
    while (i++ < 3)
221
      {
222
        sprintf (chp, "%*s", SIZE_VALUES, "");
223
        chp = strchr (chp, '\0');
224
      }
225
  }
226
 
227
  /* append any result to the end of the buffer */
228
  if (has_result)
229
    sprintf (chp, " :: 0x%.8lx", (unsigned long)result);
230
 
231
  trace_generic (simulator, STATE_CPU (simulator, 0), trace_module, buf);
232
}
233
 
234
void
235
trace_output (result)
236
     enum op_types result;
237
{
238
  if (!TRACE_ALU_P (STATE_CPU (simulator, 0)))
239
    return;
240
 
241
  switch (result)
242
    {
243
    default:
244
    case OP_UNKNOWN:
245
    case OP_NONE:
246
    case OP_TRAP:
247
    case OP_REG:
248
    case OP_REG_REG_CMP:
249
    case OP_IMM_REG_CMP:
250
    case OP_COND_BR:
251
    case OP_STORE16:
252
    case OP_STORE32:
253
    case OP_BIT:
254
    case OP_EX2:
255
      trace_result (0, 0);
256
      break;
257
 
258
    case OP_LOAD16:
259
    case OP_STSR:
260
      trace_result (1, State.regs[OP[0]]);
261
      break;
262
 
263
    case OP_REG_REG:
264
    case OP_REG_REG_MOVE:
265
    case OP_IMM_REG:
266
    case OP_IMM_REG_MOVE:
267
    case OP_LOAD32:
268
    case OP_EX1:
269
      trace_result (1, State.regs[OP[1]]);
270
      break;
271
 
272
    case OP_IMM_REG_REG:
273
    case OP_UIMM_REG_REG:
274
    case OP_IMM16_REG_REG:
275
    case OP_UIMM16_REG_REG:
276
      trace_result (1, State.regs[OP[1]]);
277
      break;
278
 
279
    case OP_JUMP:
280
      if (OP[1] != 0)
281
        trace_result (1, State.regs[OP[1]]);
282
      else
283
        trace_result (0, 0);
284
      break;
285
 
286
    case OP_LDSR:
287
      trace_result (1, State.sregs[OP[1]]);
288
      break;
289
    }
290
}
291
#endif
292
 
293
 
294
/* Returns 1 if the specific condition is met, returns 0 otherwise.  */
295
int
296
condition_met (unsigned code)
297
{
298
  unsigned int psw = PSW;
299
 
300
  switch (code & 0xf)
301
    {
302
      case 0x0: return ((psw & PSW_OV) != 0);
303
      case 0x1: return ((psw & PSW_CY) != 0);
304
      case 0x2: return ((psw & PSW_Z) != 0);
305
      case 0x3: return ((((psw & PSW_CY) != 0) | ((psw & PSW_Z) != 0)) != 0);
306
      case 0x4: return ((psw & PSW_S) != 0);
307
    /*case 0x5: return 1;*/
308
      case 0x6: return ((((psw & PSW_S) != 0) ^ ((psw & PSW_OV) != 0)) != 0);
309
      case 0x7: return (((((psw & PSW_S) != 0) ^ ((psw & PSW_OV) != 0)) || ((psw & PSW_Z) != 0)) != 0);
310
      case 0x8: return ((psw & PSW_OV) == 0);
311
      case 0x9: return ((psw & PSW_CY) == 0);
312
      case 0xa: return ((psw & PSW_Z) == 0);
313
      case 0xb: return ((((psw & PSW_CY) != 0) | ((psw & PSW_Z) != 0)) == 0);
314
      case 0xc: return ((psw & PSW_S) == 0);
315
      case 0xd: return ((psw & PSW_SAT) != 0);
316
      case 0xe: return ((((psw & PSW_S) != 0) ^ ((psw & PSW_OV) != 0)) == 0);
317
      case 0xf: return (((((psw & PSW_S) != 0) ^ ((psw & PSW_OV) != 0)) || ((psw & PSW_Z) != 0)) == 0);
318
    }
319
 
320
  return 1;
321
}
322
 
323
static unsigned long
324
Add32 (unsigned long a1, unsigned long a2, int * carry)
325
{
326
  unsigned long result = (a1 + a2);
327
 
328
  * carry = (result < a1);
329
 
330
  return result;
331
}
332
 
333
static void
334
Multiply64 (int sign, unsigned long op0)
335
{
336
  unsigned long op1;
337
  unsigned long lo;
338
  unsigned long mid1;
339
  unsigned long mid2;
340
  unsigned long hi;
341
  unsigned long RdLo;
342
  unsigned long RdHi;
343
  int           carry;
344
 
345
  op1 = State.regs[ OP[1] ];
346
 
347
  if (sign)
348
    {
349
      /* Compute sign of result and adjust operands if necessary.  */
350
 
351
      sign = (op0 ^ op1) & 0x80000000;
352
 
353
      if (((signed long) op0) < 0)
354
        op0 = - op0;
355
 
356
      if (((signed long) op1) < 0)
357
        op1 = - op1;
358
    }
359
 
360
  /* We can split the 32x32 into four 16x16 operations. This ensures
361
     that we do not lose precision on 32bit only hosts: */
362
  lo   = ( (op0        & 0xFFFF) *  (op1        & 0xFFFF));
363
  mid1 = ( (op0        & 0xFFFF) * ((op1 >> 16) & 0xFFFF));
364
  mid2 = (((op0 >> 16) & 0xFFFF) *  (op1        & 0xFFFF));
365
  hi   = (((op0 >> 16) & 0xFFFF) * ((op1 >> 16) & 0xFFFF));
366
 
367
  /* We now need to add all of these results together, taking care
368
     to propogate the carries from the additions: */
369
  RdLo = Add32 (lo, (mid1 << 16), & carry);
370
  RdHi = carry;
371
  RdLo = Add32 (RdLo, (mid2 << 16), & carry);
372
  RdHi += (carry + ((mid1 >> 16) & 0xFFFF) + ((mid2 >> 16) & 0xFFFF) + hi);
373
 
374
  if (sign)
375
    {
376
      /* Negate result if necessary.  */
377
 
378
      RdLo = ~ RdLo;
379
      RdHi = ~ RdHi;
380
      if (RdLo == 0xFFFFFFFF)
381
        {
382
          RdLo = 0;
383
          RdHi += 1;
384
        }
385
      else
386
        RdLo += 1;
387
    }
388
 
389
  /* Don't store into register 0.  */
390
  if (OP[1])
391
    State.regs[ OP[1]       ] = RdLo;
392
  if (OP[2] >> 11)
393
    State.regs[ OP[2] >> 11 ] = RdHi;
394
 
395
  return;
396
}
397
 
398
 
399
/* Read a null terminated string from memory, return in a buffer */
400
static char *
401
fetch_str (sd, addr)
402
     SIM_DESC sd;
403
     address_word addr;
404
{
405
  char *buf;
406
  int nr = 0;
407
  while (sim_core_read_1 (STATE_CPU (sd, 0),
408
                          PC, read_map, addr + nr) != 0)
409
    nr++;
410
  buf = NZALLOC (char, nr + 1);
411
  sim_read (simulator, addr, buf, nr);
412
  return buf;
413
}
414
 
415
/* Read a null terminated argument vector from memory, return in a
416
   buffer */
417
static char **
418
fetch_argv (sd, addr)
419
     SIM_DESC sd;
420
     address_word addr;
421
{
422
  int max_nr = 64;
423
  int nr = 0;
424
  char **buf = xmalloc (max_nr * sizeof (char*));
425
  while (1)
426
    {
427
      unsigned32 a = sim_core_read_4 (STATE_CPU (sd, 0),
428
                                      PC, read_map, addr + nr * 4);
429
      if (a == 0) break;
430
      buf[nr] = fetch_str (sd, a);
431
      nr ++;
432
      if (nr == max_nr - 1)
433
        {
434
          max_nr += 50;
435
          buf = xrealloc (buf, max_nr * sizeof (char*));
436
        }
437
    }
438
  buf[nr] = 0;
439
  return buf;
440
}
441
 
442
 
443
/* sst.b */
444
int
445
OP_380 ()
446
{
447
  trace_input ("sst.b", OP_STORE16, 1);
448
 
449
  store_mem (State.regs[30] + (OP[3] & 0x7f), 1, State.regs[ OP[1] ]);
450
 
451
  trace_output (OP_STORE16);
452
 
453
  return 2;
454
}
455
 
456
/* sst.h */
457
int
458
OP_480 ()
459
{
460
  trace_input ("sst.h", OP_STORE16, 2);
461
 
462
  store_mem (State.regs[30] + ((OP[3] & 0x7f) << 1), 2, State.regs[ OP[1] ]);
463
 
464
  trace_output (OP_STORE16);
465
 
466
  return 2;
467
}
468
 
469
/* sst.w */
470
int
471
OP_501 ()
472
{
473
  trace_input ("sst.w", OP_STORE16, 4);
474
 
475
  store_mem (State.regs[30] + ((OP[3] & 0x7e) << 1), 4, State.regs[ OP[1] ]);
476
 
477
  trace_output (OP_STORE16);
478
 
479
  return 2;
480
}
481
 
482
/* ld.b */
483
int
484
OP_700 ()
485
{
486
  int adr;
487
 
488
  trace_input ("ld.b", OP_LOAD32, 1);
489
 
490
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2]);
491
 
492
  State.regs[ OP[1] ] = EXTEND8 (load_mem (adr, 1));
493
 
494
  trace_output (OP_LOAD32);
495
 
496
  return 4;
497
}
498
 
499
/* ld.h */
500
int
501
OP_720 ()
502
{
503
  int adr;
504
 
505
  trace_input ("ld.h", OP_LOAD32, 2);
506
 
507
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2]);
508
  adr &= ~0x1;
509
 
510
  State.regs[ OP[1] ] = EXTEND16 (load_mem (adr, 2));
511
 
512
  trace_output (OP_LOAD32);
513
 
514
  return 4;
515
}
516
 
517
/* ld.w */
518
int
519
OP_10720 ()
520
{
521
  int adr;
522
 
523
  trace_input ("ld.w", OP_LOAD32, 4);
524
 
525
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2] & ~1);
526
  adr &= ~0x3;
527
 
528
  State.regs[ OP[1] ] = load_mem (adr, 4);
529
 
530
  trace_output (OP_LOAD32);
531
 
532
  return 4;
533
}
534
 
535
/* st.b */
536
int
537
OP_740 ()
538
{
539
  trace_input ("st.b", OP_STORE32, 1);
540
 
541
  store_mem (State.regs[ OP[0] ] + EXTEND16 (OP[2]), 1, State.regs[ OP[1] ]);
542
 
543
  trace_output (OP_STORE32);
544
 
545
  return 4;
546
}
547
 
548
/* st.h */
549
int
550
OP_760 ()
551
{
552
  int adr;
553
 
554
  trace_input ("st.h", OP_STORE32, 2);
555
 
556
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2]);
557
  adr &= ~1;
558
 
559
  store_mem (adr, 2, State.regs[ OP[1] ]);
560
 
561
  trace_output (OP_STORE32);
562
 
563
  return 4;
564
}
565
 
566
/* st.w */
567
int
568
OP_10760 ()
569
{
570
  int adr;
571
 
572
  trace_input ("st.w", OP_STORE32, 4);
573
 
574
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2] & ~1);
575
  adr &= ~3;
576
 
577
  store_mem (adr, 4, State.regs[ OP[1] ]);
578
 
579
  trace_output (OP_STORE32);
580
 
581
  return 4;
582
}
583
 
584
/* add reg, reg */
585
int
586
OP_1C0 ()
587
{
588
  unsigned int op0, op1, result, z, s, cy, ov;
589
 
590
  trace_input ("add", OP_REG_REG, 0);
591
 
592
  /* Compute the result.  */
593
 
594
  op0 = State.regs[ OP[0] ];
595
  op1 = State.regs[ OP[1] ];
596
 
597
  result = op0 + op1;
598
 
599
  /* Compute the condition codes.  */
600
  z = (result == 0);
601
  s = (result & 0x80000000);
602
  cy = (result < op0 || result < op1);
603
  ov = ((op0 & 0x80000000) == (op1 & 0x80000000)
604
        && (op0 & 0x80000000) != (result & 0x80000000));
605
 
606
  /* Store the result and condition codes.  */
607
  State.regs[OP[1]] = result;
608
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
609
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
610
                     | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
611
  trace_output (OP_REG_REG);
612
 
613
  return 2;
614
}
615
 
616
/* add sign_extend(imm5), reg */
617
int
618
OP_240 ()
619
{
620
  unsigned int op0, op1, result, z, s, cy, ov;
621
  int temp;
622
 
623
  trace_input ("add", OP_IMM_REG, 0);
624
 
625
  /* Compute the result.  */
626
  temp = SEXT5 (OP[0]);
627
  op0 = temp;
628
  op1 = State.regs[OP[1]];
629
  result = op0 + op1;
630
 
631
  /* Compute the condition codes.  */
632
  z = (result == 0);
633
  s = (result & 0x80000000);
634
  cy = (result < op0 || result < op1);
635
  ov = ((op0 & 0x80000000) == (op1 & 0x80000000)
636
        && (op0 & 0x80000000) != (result & 0x80000000));
637
 
638
  /* Store the result and condition codes.  */
639
  State.regs[OP[1]] = result;
640
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
641
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
642
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
643
  trace_output (OP_IMM_REG);
644
 
645
  return 2;
646
}
647
 
648
/* addi sign_extend(imm16), reg, reg */
649
int
650
OP_600 ()
651
{
652
  unsigned int op0, op1, result, z, s, cy, ov;
653
 
654
  trace_input ("addi", OP_IMM16_REG_REG, 0);
655
 
656
  /* Compute the result.  */
657
 
658
  op0 = EXTEND16 (OP[2]);
659
  op1 = State.regs[ OP[0] ];
660
  result = op0 + op1;
661
 
662
  /* Compute the condition codes.  */
663
  z = (result == 0);
664
  s = (result & 0x80000000);
665
  cy = (result < op0 || result < op1);
666
  ov = ((op0 & 0x80000000) == (op1 & 0x80000000)
667
        && (op0 & 0x80000000) != (result & 0x80000000));
668
 
669
  /* Store the result and condition codes.  */
670
  State.regs[OP[1]] = result;
671
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
672
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
673
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
674
  trace_output (OP_IMM16_REG_REG);
675
 
676
  return 4;
677
}
678
 
679
/* sub reg1, reg2 */
680
int
681
OP_1A0 ()
682
{
683
  unsigned int op0, op1, result, z, s, cy, ov;
684
 
685
  trace_input ("sub", OP_REG_REG, 0);
686
  /* Compute the result.  */
687
  op0 = State.regs[ OP[0] ];
688
  op1 = State.regs[ OP[1] ];
689
  result = op1 - op0;
690
 
691
  /* Compute the condition codes.  */
692
  z = (result == 0);
693
  s = (result & 0x80000000);
694
  cy = (op1 < op0);
695
  ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
696
        && (op1 & 0x80000000) != (result & 0x80000000));
697
 
698
  /* Store the result and condition codes.  */
699
  State.regs[OP[1]] = result;
700
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
701
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
702
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
703
  trace_output (OP_REG_REG);
704
 
705
  return 2;
706
}
707
 
708
/* subr reg1, reg2 */
709
int
710
OP_180 ()
711
{
712
  unsigned int op0, op1, result, z, s, cy, ov;
713
 
714
  trace_input ("subr", OP_REG_REG, 0);
715
  /* Compute the result.  */
716
  op0 = State.regs[ OP[0] ];
717
  op1 = State.regs[ OP[1] ];
718
  result = op0 - op1;
719
 
720
  /* Compute the condition codes.  */
721
  z = (result == 0);
722
  s = (result & 0x80000000);
723
  cy = (op0 < op1);
724
  ov = ((op0 & 0x80000000) != (op1 & 0x80000000)
725
        && (op0 & 0x80000000) != (result & 0x80000000));
726
 
727
  /* Store the result and condition codes.  */
728
  State.regs[OP[1]] = result;
729
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
730
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
731
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
732
  trace_output (OP_REG_REG);
733
 
734
  return 2;
735
}
736
 
737
/* sxh reg1 */
738
int
739
OP_E0 ()
740
{
741
  trace_input ("mulh", OP_REG_REG, 0);
742
 
743
  State.regs[ OP[1] ] = (EXTEND16 (State.regs[ OP[1] ]) * EXTEND16 (State.regs[ OP[0] ]));
744
 
745
  trace_output (OP_REG_REG);
746
 
747
  return 2;
748
}
749
 
750
/* mulh sign_extend(imm5), reg2 */
751
int
752
OP_2E0 ()
753
{
754
  trace_input ("mulh", OP_IMM_REG, 0);
755
 
756
  State.regs[ OP[1] ] = EXTEND16 (State.regs[ OP[1] ]) * SEXT5 (OP[0]);
757
 
758
  trace_output (OP_IMM_REG);
759
 
760
  return 2;
761
}
762
 
763
/* mulhi imm16, reg1, reg2 */
764
int
765
OP_6E0 ()
766
{
767
  trace_input ("mulhi", OP_IMM16_REG_REG, 0);
768
 
769
  State.regs[ OP[1] ] = EXTEND16 (State.regs[ OP[0] ]) * EXTEND16 (OP[2]);
770
 
771
  trace_output (OP_IMM16_REG_REG);
772
 
773
  return 4;
774
}
775
 
776
/* cmp reg, reg */
777
int
778
OP_1E0 ()
779
{
780
  unsigned int op0, op1, result, z, s, cy, ov;
781
 
782
  trace_input ("cmp", OP_REG_REG_CMP, 0);
783
  /* Compute the result.  */
784
  op0 = State.regs[ OP[0] ];
785
  op1 = State.regs[ OP[1] ];
786
  result = op1 - op0;
787
 
788
  /* Compute the condition codes.  */
789
  z = (result == 0);
790
  s = (result & 0x80000000);
791
  cy = (op1 < op0);
792
  ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
793
        && (op1 & 0x80000000) != (result & 0x80000000));
794
 
795
  /* Set condition codes.  */
796
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
797
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
798
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
799
  trace_output (OP_REG_REG_CMP);
800
 
801
  return 2;
802
}
803
 
804
/* cmp sign_extend(imm5), reg */
805
int
806
OP_260 ()
807
{
808
  unsigned int op0, op1, result, z, s, cy, ov;
809
  int temp;
810
 
811
  /* Compute the result.  */
812
  trace_input ("cmp", OP_IMM_REG_CMP, 0);
813
  temp = SEXT5 (OP[0]);
814
  op0 = temp;
815
  op1 = State.regs[OP[1]];
816
  result = op1 - op0;
817
 
818
  /* Compute the condition codes.  */
819
  z = (result == 0);
820
  s = (result & 0x80000000);
821
  cy = (op1 < op0);
822
  ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
823
        && (op1 & 0x80000000) != (result & 0x80000000));
824
 
825
  /* Set condition codes.  */
826
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
827
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
828
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0));
829
  trace_output (OP_IMM_REG_CMP);
830
 
831
  return 2;
832
}
833
 
834
/* setf cccc,reg2 */
835
int
836
OP_7E0 ()
837
{
838
  trace_input ("setf", OP_EX1, 0);
839
 
840
  State.regs[ OP[1] ] = condition_met (OP[0]);
841
 
842
  trace_output (OP_EX1);
843
 
844
  return 4;
845
}
846
 
847
/* satadd reg,reg */
848
int
849
OP_C0 ()
850
{
851
  unsigned int op0, op1, result, z, s, cy, ov, sat;
852
 
853
  trace_input ("satadd", OP_REG_REG, 0);
854
  /* Compute the result.  */
855
  op0 = State.regs[ OP[0] ];
856
  op1 = State.regs[ OP[1] ];
857
  result = op0 + op1;
858
 
859
  /* Compute the condition codes.  */
860
  z = (result == 0);
861
  s = (result & 0x80000000);
862
  cy = (result < op0 || result < op1);
863
  ov = ((op0 & 0x80000000) == (op1 & 0x80000000)
864
        && (op0 & 0x80000000) != (result & 0x80000000));
865
  sat = ov;
866
 
867
  /* Handle saturated results.  */
868
  if (sat && s)
869
    {
870
      /* An overflow that results in a negative result implies that we
871
         became too positive.  */
872
      result = 0x7fffffff;
873
      s = 0;
874
    }
875
  else if (sat)
876
    {
877
      /* Any other overflow must have thus been too negative.  */
878
      result = 0x80000000;
879
      s = 1;
880
      z = 0;
881
    }
882
 
883
  /* Store the result and condition codes.  */
884
  State.regs[OP[1]] = result;
885
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
886
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
887
          | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
888
          | (sat ? PSW_SAT : 0));
889
 
890
  trace_output (OP_REG_REG);
891
 
892
  return 2;
893
}
894
 
895
/* satadd sign_extend(imm5), reg */
896
int
897
OP_220 ()
898
{
899
  unsigned int op0, op1, result, z, s, cy, ov, sat;
900
 
901
  int temp;
902
 
903
  trace_input ("satadd", OP_IMM_REG, 0);
904
 
905
  /* Compute the result.  */
906
  temp = SEXT5 (OP[0]);
907
  op0 = temp;
908
  op1 = State.regs[OP[1]];
909
  result = op0 + op1;
910
 
911
  /* Compute the condition codes.  */
912
  z = (result == 0);
913
  s = (result & 0x80000000);
914
  cy = (result < op0 || result < op1);
915
  ov = ((op0 & 0x80000000) == (op1 & 0x80000000)
916
        && (op0 & 0x80000000) != (result & 0x80000000));
917
  sat = ov;
918
 
919
  /* Handle saturated results.  */
920
  if (sat && s)
921
    {
922
      /* An overflow that results in a negative result implies that we
923
         became too positive.  */
924
      result = 0x7fffffff;
925
      s = 0;
926
    }
927
  else if (sat)
928
    {
929
      /* Any other overflow must have thus been too negative.  */
930
      result = 0x80000000;
931
      s = 1;
932
      z = 0;
933
    }
934
 
935
  /* Store the result and condition codes.  */
936
  State.regs[OP[1]] = result;
937
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
938
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
939
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
940
                | (sat ? PSW_SAT : 0));
941
  trace_output (OP_IMM_REG);
942
 
943
  return 2;
944
}
945
 
946
/* satsub reg1, reg2 */
947
int
948
OP_A0 ()
949
{
950
  unsigned int op0, op1, result, z, s, cy, ov, sat;
951
 
952
  trace_input ("satsub", OP_REG_REG, 0);
953
 
954
  /* Compute the result.  */
955
  op0 = State.regs[ OP[0] ];
956
  op1 = State.regs[ OP[1] ];
957
  result = op1 - op0;
958
 
959
  /* Compute the condition codes.  */
960
  z = (result == 0);
961
  s = (result & 0x80000000);
962
  cy = (op1 < op0);
963
  ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
964
        && (op1 & 0x80000000) != (result & 0x80000000));
965
  sat = ov;
966
 
967
  /* Handle saturated results.  */
968
  if (sat && s)
969
    {
970
      /* An overflow that results in a negative result implies that we
971
         became too positive.  */
972
      result = 0x7fffffff;
973
      s = 0;
974
    }
975
  else if (sat)
976
    {
977
      /* Any other overflow must have thus been too negative.  */
978
      result = 0x80000000;
979
      s = 1;
980
      z = 0;
981
    }
982
 
983
  /* Store the result and condition codes.  */
984
  State.regs[OP[1]] = result;
985
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
986
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
987
          | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
988
          | (sat ? PSW_SAT : 0));
989
 
990
  trace_output (OP_REG_REG);
991
  return 2;
992
}
993
 
994
/* satsubi sign_extend(imm16), reg */
995
int
996
OP_660 ()
997
{
998
  unsigned int op0, op1, result, z, s, cy, ov, sat;
999
  int temp;
1000
 
1001
  trace_input ("satsubi", OP_IMM_REG, 0);
1002
 
1003
  /* Compute the result.  */
1004
  temp = EXTEND16 (OP[2]);
1005
  op0 = temp;
1006
  op1 = State.regs[ OP[0] ];
1007
  result = op1 - op0;
1008
 
1009
  /* Compute the condition codes.  */
1010
  z = (result == 0);
1011
  s = (result & 0x80000000);
1012
  cy = (op1 < op0);
1013
  ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
1014
        && (op1 & 0x80000000) != (result & 0x80000000));
1015
  sat = ov;
1016
 
1017
  /* Handle saturated results.  */
1018
  if (sat && s)
1019
    {
1020
      /* An overflow that results in a negative result implies that we
1021
         became too positive.  */
1022
      result = 0x7fffffff;
1023
      s = 0;
1024
    }
1025
  else if (sat)
1026
    {
1027
      /* Any other overflow must have thus been too negative.  */
1028
      result = 0x80000000;
1029
      s = 1;
1030
      z = 0;
1031
    }
1032
 
1033
  /* Store the result and condition codes.  */
1034
  State.regs[OP[1]] = result;
1035
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
1036
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1037
                | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
1038
                | (sat ? PSW_SAT : 0));
1039
 
1040
  trace_output (OP_IMM_REG);
1041
 
1042
  return 4;
1043
}
1044
 
1045
/* satsubr reg,reg */
1046
int
1047
OP_80 ()
1048
{
1049
  unsigned int op0, op1, result, z, s, cy, ov, sat;
1050
 
1051
  trace_input ("satsubr", OP_REG_REG, 0);
1052
 
1053
  /* Compute the result.  */
1054
  op0 = State.regs[ OP[0] ];
1055
  op1 = State.regs[ OP[1] ];
1056
  result = op0 - op1;
1057
 
1058
  /* Compute the condition codes.  */
1059
  z = (result == 0);
1060
  s = (result & 0x80000000);
1061
  cy = (op0 < op1);
1062
  ov = ((op0 & 0x80000000) != (op1 & 0x80000000)
1063
        && (op0 & 0x80000000) != (result & 0x80000000));
1064
  sat = ov;
1065
 
1066
  /* Handle saturated results.  */
1067
  if (sat && s)
1068
    {
1069
      /* An overflow that results in a negative result implies that we
1070
         became too positive.  */
1071
      result = 0x7fffffff;
1072
      s = 0;
1073
    }
1074
  else if (sat)
1075
    {
1076
      /* Any other overflow must have thus been too negative.  */
1077
      result = 0x80000000;
1078
      s = 1;
1079
      z = 0;
1080
    }
1081
 
1082
  /* Store the result and condition codes.  */
1083
  State.regs[OP[1]] = result;
1084
  PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
1085
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1086
          | (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
1087
          | (sat ? PSW_SAT : 0));
1088
 
1089
  trace_output (OP_REG_REG);
1090
 
1091
  return 2;
1092
}
1093
 
1094
/* tst reg,reg */
1095
int
1096
OP_160 ()
1097
{
1098
  unsigned int op0, op1, result, z, s;
1099
 
1100
  trace_input ("tst", OP_REG_REG_CMP, 0);
1101
 
1102
  /* Compute the result.  */
1103
  op0 = State.regs[ OP[0] ];
1104
  op1 = State.regs[ OP[1] ];
1105
  result = op0 & op1;
1106
 
1107
  /* Compute the condition codes.  */
1108
  z = (result == 0);
1109
  s = (result & 0x80000000);
1110
 
1111
  /* Store the condition codes.  */
1112
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1113
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1114
  trace_output (OP_REG_REG_CMP);
1115
 
1116
  return 2;
1117
}
1118
 
1119
/* mov sign_extend(imm5), reg */
1120
int
1121
OP_200 ()
1122
{
1123
  int value = SEXT5 (OP[0]);
1124
 
1125
  trace_input ("mov", OP_IMM_REG_MOVE, 0);
1126
 
1127
  State.regs[ OP[1] ] = value;
1128
 
1129
  trace_output (OP_IMM_REG_MOVE);
1130
 
1131
  return 2;
1132
}
1133
 
1134
/* movhi imm16, reg, reg */
1135
int
1136
OP_640 ()
1137
{
1138
  trace_input ("movhi", OP_UIMM16_REG_REG, 16);
1139
 
1140
  State.regs[ OP[1] ] = State.regs[ OP[0] ] + (OP[2] << 16);
1141
 
1142
  trace_output (OP_UIMM16_REG_REG);
1143
 
1144
  return 4;
1145
}
1146
 
1147
/* sar zero_extend(imm5),reg1 */
1148
int
1149
OP_2A0 ()
1150
{
1151
  unsigned int op0, op1, result, z, s, cy;
1152
 
1153
  trace_input ("sar", OP_IMM_REG, 0);
1154
  op0 = OP[0];
1155
  op1 = State.regs[ OP[1] ];
1156
  result = (signed)op1 >> op0;
1157
 
1158
  /* Compute the condition codes.  */
1159
  z = (result == 0);
1160
  s = (result & 0x80000000);
1161
  cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
1162
 
1163
  /* Store the result and condition codes.  */
1164
  State.regs[ OP[1] ] = result;
1165
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1166
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1167
                | (cy ? PSW_CY : 0));
1168
  trace_output (OP_IMM_REG);
1169
 
1170
  return 2;
1171
}
1172
 
1173
/* sar reg1, reg2 */
1174
int
1175
OP_A007E0 ()
1176
{
1177
  unsigned int op0, op1, result, z, s, cy;
1178
 
1179
  trace_input ("sar", OP_REG_REG, 0);
1180
 
1181
  op0 = State.regs[ OP[0] ] & 0x1f;
1182
  op1 = State.regs[ OP[1] ];
1183
  result = (signed)op1 >> op0;
1184
 
1185
  /* Compute the condition codes.  */
1186
  z = (result == 0);
1187
  s = (result & 0x80000000);
1188
  cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
1189
 
1190
  /* Store the result and condition codes.  */
1191
  State.regs[OP[1]] = result;
1192
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1193
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1194
                | (cy ? PSW_CY : 0));
1195
  trace_output (OP_REG_REG);
1196
 
1197
  return 4;
1198
}
1199
 
1200
/* shl zero_extend(imm5),reg1 */
1201
int
1202
OP_2C0 ()
1203
{
1204
  unsigned int op0, op1, result, z, s, cy;
1205
 
1206
  trace_input ("shl", OP_IMM_REG, 0);
1207
  op0 = OP[0];
1208
  op1 = State.regs[ OP[1] ];
1209
  result = op1 << op0;
1210
 
1211
  /* Compute the condition codes.  */
1212
  z = (result == 0);
1213
  s = (result & 0x80000000);
1214
  cy = op0 ? (op1 & (1 << (32 - op0))) : 0;
1215
 
1216
  /* Store the result and condition codes.  */
1217
  State.regs[OP[1]] = result;
1218
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1219
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1220
                | (cy ? PSW_CY : 0));
1221
  trace_output (OP_IMM_REG);
1222
 
1223
  return 2;
1224
}
1225
 
1226
/* shl reg1, reg2 */
1227
int
1228
OP_C007E0 ()
1229
{
1230
  unsigned int op0, op1, result, z, s, cy;
1231
 
1232
  trace_input ("shl", OP_REG_REG, 0);
1233
  op0 = State.regs[ OP[0] ] & 0x1f;
1234
  op1 = State.regs[ OP[1] ];
1235
  result = op1 << op0;
1236
 
1237
  /* Compute the condition codes.  */
1238
  z = (result == 0);
1239
  s = (result & 0x80000000);
1240
  cy = op0 ? (op1 & (1 << (32 - op0))) : 0;
1241
 
1242
  /* Store the result and condition codes.  */
1243
  State.regs[OP[1]] = result;
1244
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1245
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1246
                | (cy ? PSW_CY : 0));
1247
  trace_output (OP_REG_REG);
1248
 
1249
  return 4;
1250
}
1251
 
1252
/* shr zero_extend(imm5),reg1 */
1253
int
1254
OP_280 ()
1255
{
1256
  unsigned int op0, op1, result, z, s, cy;
1257
 
1258
  trace_input ("shr", OP_IMM_REG, 0);
1259
  op0 = OP[0];
1260
  op1 = State.regs[ OP[1] ];
1261
  result = op1 >> op0;
1262
 
1263
  /* Compute the condition codes.  */
1264
  z = (result == 0);
1265
  s = (result & 0x80000000);
1266
  cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
1267
 
1268
  /* Store the result and condition codes.  */
1269
  State.regs[OP[1]] = result;
1270
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1271
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1272
                | (cy ? PSW_CY : 0));
1273
  trace_output (OP_IMM_REG);
1274
 
1275
  return 2;
1276
}
1277
 
1278
/* shr reg1, reg2 */
1279
int
1280
OP_8007E0 ()
1281
{
1282
  unsigned int op0, op1, result, z, s, cy;
1283
 
1284
  trace_input ("shr", OP_REG_REG, 0);
1285
  op0 = State.regs[ OP[0] ] & 0x1f;
1286
  op1 = State.regs[ OP[1] ];
1287
  result = op1 >> op0;
1288
 
1289
  /* Compute the condition codes.  */
1290
  z = (result == 0);
1291
  s = (result & 0x80000000);
1292
  cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
1293
 
1294
  /* Store the result and condition codes.  */
1295
  State.regs[OP[1]] = result;
1296
  PSW &= ~(PSW_Z | PSW_S | PSW_OV | PSW_CY);
1297
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
1298
                | (cy ? PSW_CY : 0));
1299
  trace_output (OP_REG_REG);
1300
 
1301
  return 4;
1302
}
1303
 
1304
/* or reg, reg */
1305
int
1306
OP_100 ()
1307
{
1308
  unsigned int op0, op1, result, z, s;
1309
 
1310
  trace_input ("or", OP_REG_REG, 0);
1311
 
1312
  /* Compute the result.  */
1313
  op0 = State.regs[ OP[0] ];
1314
  op1 = State.regs[ OP[1] ];
1315
  result = op0 | op1;
1316
 
1317
  /* Compute the condition codes.  */
1318
  z = (result == 0);
1319
  s = (result & 0x80000000);
1320
 
1321
  /* Store the result and condition codes.  */
1322
  State.regs[OP[1]] = result;
1323
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1324
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1325
  trace_output (OP_REG_REG);
1326
 
1327
  return 2;
1328
}
1329
 
1330
/* ori zero_extend(imm16), reg, reg */
1331
int
1332
OP_680 ()
1333
{
1334
  unsigned int op0, op1, result, z, s;
1335
 
1336
  trace_input ("ori", OP_UIMM16_REG_REG, 0);
1337
  op0 = OP[2];
1338
  op1 = State.regs[ OP[0] ];
1339
  result = op0 | op1;
1340
 
1341
  /* Compute the condition codes.  */
1342
  z = (result == 0);
1343
  s = (result & 0x80000000);
1344
 
1345
  /* Store the result and condition codes.  */
1346
  State.regs[OP[1]] = result;
1347
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1348
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1349
  trace_output (OP_UIMM16_REG_REG);
1350
 
1351
  return 4;
1352
}
1353
 
1354
/* and reg, reg */
1355
int
1356
OP_140 ()
1357
{
1358
  unsigned int op0, op1, result, z, s;
1359
 
1360
  trace_input ("and", OP_REG_REG, 0);
1361
 
1362
  /* Compute the result.  */
1363
  op0 = State.regs[ OP[0] ];
1364
  op1 = State.regs[ OP[1] ];
1365
  result = op0 & op1;
1366
 
1367
  /* Compute the condition codes.  */
1368
  z = (result == 0);
1369
  s = (result & 0x80000000);
1370
 
1371
  /* Store the result and condition codes.  */
1372
  State.regs[OP[1]] = result;
1373
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1374
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1375
  trace_output (OP_REG_REG);
1376
 
1377
  return 2;
1378
}
1379
 
1380
/* andi zero_extend(imm16), reg, reg */
1381
int
1382
OP_6C0 ()
1383
{
1384
  unsigned int result, z;
1385
 
1386
  trace_input ("andi", OP_UIMM16_REG_REG, 0);
1387
 
1388
  result = OP[2] & State.regs[ OP[0] ];
1389
 
1390
  /* Compute the condition codes.  */
1391
  z = (result == 0);
1392
 
1393
  /* Store the result and condition codes.  */
1394
  State.regs[ OP[1] ] = result;
1395
 
1396
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1397
  PSW |= (z ? PSW_Z : 0);
1398
 
1399
  trace_output (OP_UIMM16_REG_REG);
1400
 
1401
  return 4;
1402
}
1403
 
1404
/* xor reg, reg */
1405
int
1406
OP_120 ()
1407
{
1408
  unsigned int op0, op1, result, z, s;
1409
 
1410
  trace_input ("xor", OP_REG_REG, 0);
1411
 
1412
  /* Compute the result.  */
1413
  op0 = State.regs[ OP[0] ];
1414
  op1 = State.regs[ OP[1] ];
1415
  result = op0 ^ op1;
1416
 
1417
  /* Compute the condition codes.  */
1418
  z = (result == 0);
1419
  s = (result & 0x80000000);
1420
 
1421
  /* Store the result and condition codes.  */
1422
  State.regs[OP[1]] = result;
1423
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1424
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1425
  trace_output (OP_REG_REG);
1426
 
1427
  return 2;
1428
}
1429
 
1430
/* xori zero_extend(imm16), reg, reg */
1431
int
1432
OP_6A0 ()
1433
{
1434
  unsigned int op0, op1, result, z, s;
1435
 
1436
  trace_input ("xori", OP_UIMM16_REG_REG, 0);
1437
  op0 = OP[2];
1438
  op1 = State.regs[ OP[0] ];
1439
  result = op0 ^ op1;
1440
 
1441
  /* Compute the condition codes.  */
1442
  z = (result == 0);
1443
  s = (result & 0x80000000);
1444
 
1445
  /* Store the result and condition codes.  */
1446
  State.regs[OP[1]] = result;
1447
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1448
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1449
  trace_output (OP_UIMM16_REG_REG);
1450
 
1451
  return 4;
1452
}
1453
 
1454
/* not reg1, reg2 */
1455
int
1456
OP_20 ()
1457
{
1458
  unsigned int op0, result, z, s;
1459
 
1460
  trace_input ("not", OP_REG_REG_MOVE, 0);
1461
  /* Compute the result.  */
1462
  op0 = State.regs[ OP[0] ];
1463
  result = ~op0;
1464
 
1465
  /* Compute the condition codes.  */
1466
  z = (result == 0);
1467
  s = (result & 0x80000000);
1468
 
1469
  /* Store the result and condition codes.  */
1470
  State.regs[OP[1]] = result;
1471
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
1472
  PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0));
1473
  trace_output (OP_REG_REG_MOVE);
1474
 
1475
  return 2;
1476
}
1477
 
1478
/* set1 */
1479
int
1480
OP_7C0 ()
1481
{
1482
  unsigned int op0, op1, op2;
1483
  int temp;
1484
 
1485
  trace_input ("set1", OP_BIT, 0);
1486
  op0 = State.regs[ OP[0] ];
1487
  op1 = OP[1] & 0x7;
1488
  temp = EXTEND16 (OP[2]);
1489
  op2 = temp;
1490
  temp = load_mem (op0 + op2, 1);
1491
  PSW &= ~PSW_Z;
1492
  if ((temp & (1 << op1)) == 0)
1493
    PSW |= PSW_Z;
1494
  temp |= (1 << op1);
1495
  store_mem (op0 + op2, 1, temp);
1496
  trace_output (OP_BIT);
1497
 
1498
  return 4;
1499
}
1500
 
1501
/* not1 */
1502
int
1503
OP_47C0 ()
1504
{
1505
  unsigned int op0, op1, op2;
1506
  int temp;
1507
 
1508
  trace_input ("not1", OP_BIT, 0);
1509
  op0 = State.regs[ OP[0] ];
1510
  op1 = OP[1] & 0x7;
1511
  temp = EXTEND16 (OP[2]);
1512
  op2 = temp;
1513
  temp = load_mem (op0 + op2, 1);
1514
  PSW &= ~PSW_Z;
1515
  if ((temp & (1 << op1)) == 0)
1516
    PSW |= PSW_Z;
1517
  temp ^= (1 << op1);
1518
  store_mem (op0 + op2, 1, temp);
1519
  trace_output (OP_BIT);
1520
 
1521
  return 4;
1522
}
1523
 
1524
/* clr1 */
1525
int
1526
OP_87C0 ()
1527
{
1528
  unsigned int op0, op1, op2;
1529
  int temp;
1530
 
1531
  trace_input ("clr1", OP_BIT, 0);
1532
  op0 = State.regs[ OP[0] ];
1533
  op1 = OP[1] & 0x7;
1534
  temp = EXTEND16 (OP[2]);
1535
  op2 = temp;
1536
  temp = load_mem (op0 + op2, 1);
1537
  PSW &= ~PSW_Z;
1538
  if ((temp & (1 << op1)) == 0)
1539
    PSW |= PSW_Z;
1540
  temp &= ~(1 << op1);
1541
  store_mem (op0 + op2, 1, temp);
1542
  trace_output (OP_BIT);
1543
 
1544
  return 4;
1545
}
1546
 
1547
/* tst1 */
1548
int
1549
OP_C7C0 ()
1550
{
1551
  unsigned int op0, op1, op2;
1552
  int temp;
1553
 
1554
  trace_input ("tst1", OP_BIT, 0);
1555
  op0 = State.regs[ OP[0] ];
1556
  op1 = OP[1] & 0x7;
1557
  temp = EXTEND16 (OP[2]);
1558
  op2 = temp;
1559
  temp = load_mem (op0 + op2, 1);
1560
  PSW &= ~PSW_Z;
1561
  if ((temp & (1 << op1)) == 0)
1562
    PSW |= PSW_Z;
1563
  trace_output (OP_BIT);
1564
 
1565
  return 4;
1566
}
1567
 
1568
/* di */
1569
int
1570
OP_16007E0 ()
1571
{
1572
  trace_input ("di", OP_NONE, 0);
1573
  PSW |= PSW_ID;
1574
  trace_output (OP_NONE);
1575
 
1576
  return 4;
1577
}
1578
 
1579
/* ei */
1580
int
1581
OP_16087E0 ()
1582
{
1583
  trace_input ("ei", OP_NONE, 0);
1584
  PSW &= ~PSW_ID;
1585
  trace_output (OP_NONE);
1586
 
1587
  return 4;
1588
}
1589
 
1590
/* halt */
1591
int
1592
OP_12007E0 ()
1593
{
1594
  trace_input ("halt", OP_NONE, 0);
1595
  /* FIXME this should put processor into a mode where NMI still handled */
1596
  trace_output (OP_NONE);
1597
  sim_engine_halt (simulator, STATE_CPU (simulator, 0), NULL, PC,
1598
                   sim_stopped, SIM_SIGTRAP);
1599
  return 0;
1600
}
1601
 
1602
/* trap */
1603
int
1604
OP_10007E0 ()
1605
{
1606
  trace_input ("trap", OP_TRAP, 0);
1607
  trace_output (OP_TRAP);
1608
 
1609
  /* Trap 31 is used for simulating OS I/O functions */
1610
 
1611
  if (OP[0] == 31)
1612
    {
1613
      int save_errno = errno;
1614
      errno = 0;
1615
 
1616
/* Registers passed to trap 0 */
1617
 
1618
#define FUNC   State.regs[6]    /* function number, return value */
1619
#define PARM1  State.regs[7]    /* optional parm 1 */
1620
#define PARM2  State.regs[8]    /* optional parm 2 */
1621
#define PARM3  State.regs[9]    /* optional parm 3 */
1622
 
1623
/* Registers set by trap 0 */
1624
 
1625
#define RETVAL State.regs[10]   /* return value */
1626
#define RETERR State.regs[11]   /* return error code */
1627
 
1628
/* Turn a pointer in a register into a pointer into real memory. */
1629
 
1630
#define MEMPTR(x) (map (x))
1631
 
1632
      switch (FUNC)
1633
        {
1634
 
1635
#ifdef HAVE_FORK
1636
#ifdef TARGET_SYS_fork
1637
        case TARGET_SYS_fork:
1638
          RETVAL = fork ();
1639
          break;
1640
#endif
1641
#endif
1642
 
1643
#ifdef HAVE_EXECVE
1644
#ifdef TARGET_SYS_execv
1645
        case TARGET_SYS_execve:
1646
          {
1647
            char *path = fetch_str (simulator, PARM1);
1648
            char **argv = fetch_argv (simulator, PARM2);
1649
            char **envp = fetch_argv (simulator, PARM3);
1650
            RETVAL = execve (path, argv, envp);
1651
            zfree (path);
1652
            freeargv (argv);
1653
            freeargv (envp);
1654
            break;
1655
          }
1656
#endif
1657
#endif
1658
 
1659
#if HAVE_EXECV
1660
#ifdef TARGET_SYS_execv
1661
        case TARGET_SYS_execv:
1662
          {
1663
            char *path = fetch_str (simulator, PARM1);
1664
            char **argv = fetch_argv (simulator, PARM2);
1665
            RETVAL = execv (path, argv);
1666
            zfree (path);
1667
            freeargv (argv);
1668
            break;
1669
          }
1670
#endif
1671
#endif
1672
 
1673
#if 0
1674
#ifdef TARGET_SYS_pipe
1675
        case TARGET_SYS_pipe:
1676
          {
1677
            reg_t buf;
1678
            int host_fd[2];
1679
 
1680
            buf = PARM1;
1681
            RETVAL = pipe (host_fd);
1682
            SW (buf, host_fd[0]);
1683
            buf += sizeof(uint16);
1684
            SW (buf, host_fd[1]);
1685
          }
1686
          break;
1687
#endif
1688
#endif
1689
 
1690
#if 0
1691
#ifdef TARGET_SYS_wait
1692
        case TARGET_SYS_wait:
1693
          {
1694
            int status;
1695
 
1696
            RETVAL = wait (&status);
1697
            SW (PARM1, status);
1698
          }
1699
          break;
1700
#endif
1701
#endif
1702
 
1703
#ifdef TARGET_SYS_read
1704
        case TARGET_SYS_read:
1705
          {
1706
            char *buf = zalloc (PARM3);
1707
            RETVAL = sim_io_read (simulator, PARM1, buf, PARM3);
1708
            sim_write (simulator, PARM2, buf, PARM3);
1709
            zfree (buf);
1710
            break;
1711
          }
1712
#endif
1713
 
1714
#ifdef TARGET_SYS_write
1715
        case TARGET_SYS_write:
1716
          {
1717
            char *buf = zalloc (PARM3);
1718
            sim_read (simulator, PARM2, buf, PARM3);
1719
            if (PARM1 == 1)
1720
              RETVAL = sim_io_write_stdout (simulator, buf, PARM3);
1721
            else
1722
              RETVAL = sim_io_write (simulator, PARM1, buf, PARM3);
1723
            zfree (buf);
1724
            break;
1725
          }
1726
#endif
1727
 
1728
#ifdef TARGET_SYS_lseek
1729
        case TARGET_SYS_lseek:
1730
          RETVAL = sim_io_lseek (simulator, PARM1, PARM2, PARM3);
1731
          break;
1732
#endif
1733
 
1734
#ifdef TARGET_SYS_close
1735
        case TARGET_SYS_close:
1736
          RETVAL = sim_io_close (simulator, PARM1);
1737
          break;
1738
#endif
1739
 
1740
#ifdef TARGET_SYS_open
1741
        case TARGET_SYS_open:
1742
          {
1743
            char *buf = fetch_str (simulator, PARM1);
1744
            RETVAL = sim_io_open (simulator, buf, PARM2);
1745
            zfree (buf);
1746
            break;
1747
          }
1748
#endif
1749
 
1750
#ifdef TARGET_SYS_exit
1751
        case TARGET_SYS_exit:
1752
          if ((PARM1 & 0xffff0000) == 0xdead0000 && (PARM1 & 0xffff) != 0)
1753
            /* get signal encoded by kill */
1754
            sim_engine_halt (simulator, STATE_CPU (simulator, 0), NULL, PC,
1755
                             sim_signalled, PARM1 & 0xffff);
1756
          else if (PARM1 == 0xdead)
1757
            /* old libraries */
1758
            sim_engine_halt (simulator, STATE_CPU (simulator, 0), NULL, PC,
1759
                             sim_stopped, SIM_SIGABRT);
1760
          else
1761
            /* PARM1 has exit status */
1762
            sim_engine_halt (simulator, STATE_CPU (simulator, 0), NULL, PC,
1763
                             sim_exited, PARM1);
1764
          break;
1765
#endif
1766
 
1767
#if !defined(__GO32__) && !defined(_WIN32)
1768
#ifdef TARGET_SYS_stat
1769
        case TARGET_SYS_stat:   /* added at hmsi */
1770
          /* stat system call */
1771
          {
1772
            struct stat host_stat;
1773
            reg_t buf;
1774
            char *path = fetch_str (simulator, PARM1);
1775
 
1776
            RETVAL = stat (path, &host_stat);
1777
 
1778
            zfree (path);
1779
            buf = PARM2;
1780
 
1781
            /* Just wild-assed guesses.  */
1782
            store_mem (buf, 2, host_stat.st_dev);
1783
            store_mem (buf + 2, 2, host_stat.st_ino);
1784
            store_mem (buf + 4, 4, host_stat.st_mode);
1785
            store_mem (buf + 8, 2, host_stat.st_nlink);
1786
            store_mem (buf + 10, 2, host_stat.st_uid);
1787
            store_mem (buf + 12, 2, host_stat.st_gid);
1788
            store_mem (buf + 14, 2, host_stat.st_rdev);
1789
            store_mem (buf + 16, 4, host_stat.st_size);
1790
            store_mem (buf + 20, 4, host_stat.st_atime);
1791
            store_mem (buf + 28, 4, host_stat.st_mtime);
1792
            store_mem (buf + 36, 4, host_stat.st_ctime);
1793
          }
1794
          break;
1795
#endif
1796
#endif
1797
 
1798
#ifdef HAVE_CHOWN
1799
#ifdef TARGET_SYS_chown
1800
        case TARGET_SYS_chown:
1801
          {
1802
            char *path = fetch_str (simulator, PARM1);
1803
            RETVAL = chown (path, PARM2, PARM3);
1804
            zfree (path);
1805
          }
1806
          break;
1807
#endif
1808
#endif
1809
 
1810
#if HAVE_CHMOD
1811
#ifdef TARGET_SYS_chmod
1812
        case TARGET_SYS_chmod:
1813
          {
1814
            char *path = fetch_str (simulator, PARM1);
1815
            RETVAL = chmod (path, PARM2);
1816
            zfree (path);
1817
          }
1818
          break;
1819
#endif
1820
#endif
1821
 
1822
#ifdef TARGET_SYS_time
1823
#if HAVE_TIME
1824
        case TARGET_SYS_time:
1825
          {
1826
            time_t now;
1827
            RETVAL = time (&now);
1828
            store_mem (PARM1, 4, now);
1829
          }
1830
          break;
1831
#endif
1832
#endif
1833
 
1834
#if !defined(__GO32__) && !defined(_WIN32)
1835
#ifdef TARGET_SYS_times
1836
        case TARGET_SYS_times:
1837
          {
1838
            struct tms tms;
1839
            RETVAL = times (&tms);
1840
            store_mem (PARM1, 4, tms.tms_utime);
1841
            store_mem (PARM1 + 4, 4, tms.tms_stime);
1842
            store_mem (PARM1 + 8, 4, tms.tms_cutime);
1843
            store_mem (PARM1 + 12, 4, tms.tms_cstime);
1844
            break;
1845
          }
1846
#endif
1847
#endif
1848
 
1849
#ifdef TARGET_SYS_gettimeofday
1850
#if !defined(__GO32__) && !defined(_WIN32)
1851
        case TARGET_SYS_gettimeofday:
1852
          {
1853
            struct timeval t;
1854
            struct timezone tz;
1855
            RETVAL = gettimeofday (&t, &tz);
1856
            store_mem (PARM1, 4, t.tv_sec);
1857
            store_mem (PARM1 + 4, 4, t.tv_usec);
1858
            store_mem (PARM2, 4, tz.tz_minuteswest);
1859
            store_mem (PARM2 + 4, 4, tz.tz_dsttime);
1860
            break;
1861
          }
1862
#endif
1863
#endif
1864
 
1865
#ifdef TARGET_SYS_utime
1866
#if HAVE_UTIME
1867
        case TARGET_SYS_utime:
1868
          {
1869
            /* Cast the second argument to void *, to avoid type mismatch
1870
               if a prototype is present.  */
1871
            sim_io_error (simulator, "Utime not supported");
1872
            /* RETVAL = utime (path, (void *) MEMPTR (PARM2)); */
1873
          }
1874
          break;
1875
#endif
1876
#endif
1877
 
1878
        default:
1879
          abort ();
1880
        }
1881
      RETERR = errno;
1882
      errno = save_errno;
1883
 
1884
      return 4;
1885
    }
1886
  else
1887
    {                           /* Trap 0 -> 30 */
1888
      EIPC = PC + 4;
1889
      EIPSW = PSW;
1890
      /* Mask out EICC */
1891
      ECR &= 0xffff0000;
1892
      ECR |= 0x40 + OP[0];
1893
      /* Flag that we are now doing exception processing.  */
1894
      PSW |= PSW_EP | PSW_ID;
1895
      PC = (OP[0] < 0x10) ? 0x40 : 0x50;
1896
 
1897
      return 0;
1898
    }
1899
}
1900
 
1901
/* tst1 reg2, [reg1] */
1902
int
1903
OP_E607E0 (void)
1904
{
1905
  int temp;
1906
 
1907
  trace_input ("tst1", OP_BIT, 1);
1908
 
1909
  temp = load_mem (State.regs[ OP[0] ], 1);
1910
 
1911
  PSW &= ~PSW_Z;
1912
  if ((temp & (1 << (State.regs[ OP[1] ] & 0x7))) == 0)
1913
    PSW |= PSW_Z;
1914
 
1915
  trace_output (OP_BIT);
1916
 
1917
  return 4;
1918
}
1919
 
1920
/* mulu reg1, reg2, reg3 */
1921
int
1922
OP_22207E0 (void)
1923
{
1924
  trace_input ("mulu", OP_REG_REG_REG, 0);
1925
 
1926
  Multiply64 (0, State.regs[ OP[0] ]);
1927
 
1928
  trace_output (OP_REG_REG_REG);
1929
 
1930
  return 4;
1931
}
1932
 
1933
#define BIT_CHANGE_OP( name, binop )            \
1934
  unsigned int bit;                             \
1935
  unsigned int temp;                            \
1936
                                                \
1937
  trace_input (name, OP_BIT_CHANGE, 0);          \
1938
                                                \
1939
  bit  = 1 << (State.regs[ OP[1] ] & 0x7);      \
1940
  temp = load_mem (State.regs[ OP[0] ], 1);      \
1941
                                                \
1942
  PSW &= ~PSW_Z;                                \
1943
  if ((temp & bit) == 0)                 \
1944
    PSW |= PSW_Z;                               \
1945
  temp binop bit;                               \
1946
                                                \
1947
  store_mem (State.regs[ OP[0] ], 1, temp);      \
1948
                                                \
1949
  trace_output (OP_BIT_CHANGE);                 \
1950
                                                \
1951
  return 4;
1952
 
1953
/* clr1 reg2, [reg1] */
1954
int
1955
OP_E407E0 (void)
1956
{
1957
  BIT_CHANGE_OP ("clr1", &= ~ );
1958
}
1959
 
1960
/* not1 reg2, [reg1] */
1961
int
1962
OP_E207E0 (void)
1963
{
1964
  BIT_CHANGE_OP ("not1", ^= );
1965
}
1966
 
1967
/* set1 */
1968
int
1969
OP_E007E0 (void)
1970
{
1971
  BIT_CHANGE_OP ("set1", |= );
1972
}
1973
 
1974
/* sasf */
1975
int
1976
OP_20007E0 (void)
1977
{
1978
  trace_input ("sasf", OP_EX1, 0);
1979
 
1980
  State.regs[ OP[1] ] = (State.regs[ OP[1] ] << 1) | condition_met (OP[0]);
1981
 
1982
  trace_output (OP_EX1);
1983
 
1984
  return 4;
1985
}
1986
 
1987
/* This function is courtesy of Sugimoto at NEC, via Seow Tan
1988
   (Soew_Tan@el.nec.com) */
1989
void
1990
divun
1991
(
1992
  unsigned int       N,
1993
  unsigned long int  als,
1994
  unsigned long int  sfi,
1995
  unsigned32 /*unsigned long int*/ *  quotient_ptr,
1996
  unsigned32 /*unsigned long int*/ *  remainder_ptr,
1997
  int *          overflow_ptr
1998
)
1999
{
2000
  unsigned long   ald = sfi >> (N - 1);
2001
  unsigned long   alo = als;
2002
  unsigned int    Q   = 1;
2003
  unsigned int    C;
2004
  unsigned int    S   = 0;
2005
  unsigned int    i;
2006
  unsigned int    R1  = 1;
2007
  unsigned int    DBZ = (als == 0) ? 1 : 0;
2008
  unsigned long   alt = Q ? ~als : als;
2009
 
2010
  /* 1st Loop */
2011
  alo = ald + alt + Q;
2012
  C   = (((alt >> 31) & (ald >> 31))
2013
         | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2014
  C   = C ^ Q;
2015
  Q   = ~(C ^ S) & 1;
2016
  R1  = (alo == 0) ? 0 : (R1 & Q);
2017
  if ((S ^ (alo>>31)) && !C)
2018
    {
2019
      DBZ = 1;
2020
    }
2021
  S   = alo >> 31;
2022
  sfi = (sfi << (32-N+1)) | Q;
2023
  ald = (alo << 1) | (sfi >> 31);
2024
 
2025
  /* 2nd - N-1th Loop */
2026
  for (i = 2; i < N; i++)
2027
    {
2028
      alt = Q ? ~als : als;
2029
      alo = ald + alt + Q;
2030
      C   = (((alt >> 31) & (ald >> 31))
2031
             | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2032
      C   = C ^ Q;
2033
      Q   = ~(C ^ S) & 1;
2034
      R1  = (alo == 0) ? 0 : (R1 & Q);
2035
      if ((S ^ (alo>>31)) && !C && !DBZ)
2036
        {
2037
          DBZ = 1;
2038
        }
2039
      S   = alo >> 31;
2040
      sfi = (sfi << 1) | Q;
2041
      ald = (alo << 1) | (sfi >> 31);
2042
    }
2043
 
2044
  /* Nth Loop */
2045
  alt = Q ? ~als : als;
2046
  alo = ald + alt + Q;
2047
  C   = (((alt >> 31) & (ald >> 31))
2048
         | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2049
  C   = C ^ Q;
2050
  Q   = ~(C ^ S) & 1;
2051
  R1  = (alo == 0) ? 0 : (R1 & Q);
2052
  if ((S ^ (alo>>31)) && !C)
2053
    {
2054
      DBZ = 1;
2055
    }
2056
 
2057
  * quotient_ptr  = (sfi << 1) | Q;
2058
  * remainder_ptr = Q ? alo : (alo + als);
2059
  * overflow_ptr  = DBZ | R1;
2060
}
2061
 
2062
/* This function is courtesy of Sugimoto at NEC, via Seow Tan (Soew_Tan@el.nec.com) */
2063
void
2064
divn
2065
(
2066
  unsigned int       N,
2067
  unsigned long int  als,
2068
  unsigned long int  sfi,
2069
  signed32 /*signed long int*/ *  quotient_ptr,
2070
  signed32 /*signed long int*/ *  remainder_ptr,
2071
  int *          overflow_ptr
2072
)
2073
{
2074
  unsigned long   ald = (signed long) sfi >> (N - 1);
2075
  unsigned long   alo = als;
2076
  unsigned int    SS  = als >> 31;
2077
  unsigned int    SD  = sfi >> 31;
2078
  unsigned int    R1  = 1;
2079
  unsigned int    OV;
2080
  unsigned int    DBZ = als == 0 ? 1 : 0;
2081
  unsigned int    Q   = ~(SS ^ SD) & 1;
2082
  unsigned int    C;
2083
  unsigned int    S;
2084
  unsigned int    i;
2085
  unsigned long   alt = Q ? ~als : als;
2086
 
2087
 
2088
  /* 1st Loop */
2089
 
2090
  alo = ald + alt + Q;
2091
  C   = (((alt >> 31) & (ald >> 31))
2092
         | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2093
  Q   = C ^ SS;
2094
  R1  = (alo == 0) ? 0 : (R1 & (Q ^ (SS ^ SD)));
2095
  S   = alo >> 31;
2096
  sfi = (sfi << (32-N+1)) | Q;
2097
  ald = (alo << 1) | (sfi >> 31);
2098
  if ((alo >> 31) ^ (ald >> 31))
2099
    {
2100
      DBZ = 1;
2101
    }
2102
 
2103
  /* 2nd - N-1th Loop */
2104
 
2105
  for (i = 2; i < N; i++)
2106
    {
2107
      alt = Q ? ~als : als;
2108
      alo = ald + alt + Q;
2109
      C   = (((alt >> 31) & (ald >> 31))
2110
             | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2111
      Q   = C ^ SS;
2112
      R1  = (alo == 0) ? 0 : (R1 & (Q ^ (SS ^ SD)));
2113
      S   = alo >> 31;
2114
      sfi = (sfi << 1) | Q;
2115
      ald = (alo << 1) | (sfi >> 31);
2116
      if ((alo >> 31) ^ (ald >> 31))
2117
        {
2118
          DBZ = 1;
2119
        }
2120
    }
2121
 
2122
  /* Nth Loop */
2123
  alt = Q ? ~als : als;
2124
  alo = ald + alt + Q;
2125
  C   = (((alt >> 31) & (ald >> 31))
2126
         | (((alt >> 31) ^ (ald >> 31)) & (~alo >> 31)));
2127
  Q   = C ^ SS;
2128
  R1  = (alo == 0) ? 0 : (R1 & (Q ^ (SS ^ SD)));
2129
  sfi = (sfi << (32-N+1));
2130
  ald = alo;
2131
 
2132
  /* End */
2133
  if (alo != 0)
2134
    {
2135
      alt = Q ? ~als : als;
2136
      alo = ald + alt + Q;
2137
    }
2138
  R1  = R1 & ((~alo >> 31) ^ SD);
2139
  if ((alo != 0) && ((Q ^ (SS ^ SD)) ^ R1)) alo = ald;
2140
  if (N != 32)
2141
    ald = sfi = (long) ((sfi >> 1) | (SS ^ SD) << 31) >> (32-N-1) | Q;
2142
  else
2143
    ald = sfi = sfi | Q;
2144
 
2145
  OV = DBZ | ((alo == 0) ? 0 : R1);
2146
 
2147
  * remainder_ptr = alo;
2148
 
2149
  /* Adj */
2150
  if (((alo != 0) && ((SS ^ SD) ^ R1))
2151
      || ((alo == 0) && (SS ^ R1)))
2152
    alo = ald + 1;
2153
  else
2154
    alo = ald;
2155
 
2156
  OV  = (DBZ | R1) ? OV : ((alo >> 31) & (~ald >> 31));
2157
 
2158
  * quotient_ptr  = alo;
2159
  * overflow_ptr  = OV;
2160
}
2161
 
2162
/* sdivun imm5, reg1, reg2, reg3 */
2163
int
2164
OP_1C207E0 (void)
2165
{
2166
  unsigned32 /*unsigned long int*/  quotient;
2167
  unsigned32 /*unsigned long int*/  remainder;
2168
  unsigned long int  divide_by;
2169
  unsigned long int  divide_this;
2170
  int            overflow = 0;
2171
  unsigned int       imm5;
2172
 
2173
  trace_input ("sdivun", OP_IMM_REG_REG_REG, 0);
2174
 
2175
  imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
2176
 
2177
  divide_by   = State.regs[ OP[0] ];
2178
  divide_this = State.regs[ OP[1] ] << imm5;
2179
 
2180
  divun (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
2181
 
2182
  State.regs[ OP[1]       ] = quotient;
2183
  State.regs[ OP[2] >> 11 ] = remainder;
2184
 
2185
  /* Set condition codes.  */
2186
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2187
 
2188
  if (overflow)      PSW |= PSW_OV;
2189
  if (quotient == 0) PSW |= PSW_Z;
2190
  if (quotient & 0x80000000) PSW |= PSW_S;
2191
 
2192
  trace_output (OP_IMM_REG_REG_REG);
2193
 
2194
  return 4;
2195
}
2196
 
2197
/* sdivn imm5, reg1, reg2, reg3 */
2198
int
2199
OP_1C007E0 (void)
2200
{
2201
  signed32 /*signed long int*/  quotient;
2202
  signed32 /*signed long int*/  remainder;
2203
  signed long int  divide_by;
2204
  signed long int  divide_this;
2205
  int          overflow = 0;
2206
  unsigned int     imm5;
2207
 
2208
  trace_input ("sdivn", OP_IMM_REG_REG_REG, 0);
2209
 
2210
  imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
2211
 
2212
  divide_by   = (signed32) State.regs[ OP[0] ];
2213
  divide_this = (signed32) (State.regs[ OP[1] ] << imm5);
2214
 
2215
  divn (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
2216
 
2217
  State.regs[ OP[1]       ] = quotient;
2218
  State.regs[ OP[2] >> 11 ] = remainder;
2219
 
2220
  /* Set condition codes.  */
2221
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2222
 
2223
  if (overflow)      PSW |= PSW_OV;
2224
  if (quotient == 0) PSW |= PSW_Z;
2225
  if (quotient <  0) PSW |= PSW_S;
2226
 
2227
  trace_output (OP_IMM_REG_REG_REG);
2228
 
2229
  return 4;
2230
}
2231
 
2232
/* sdivhun imm5, reg1, reg2, reg3 */
2233
int
2234
OP_18207E0 (void)
2235
{
2236
  unsigned32 /*unsigned long int*/  quotient;
2237
  unsigned32 /*unsigned long int*/  remainder;
2238
  unsigned long int  divide_by;
2239
  unsigned long int  divide_this;
2240
  int            overflow = 0;
2241
  unsigned int       imm5;
2242
 
2243
  trace_input ("sdivhun", OP_IMM_REG_REG_REG, 0);
2244
 
2245
  imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
2246
 
2247
  divide_by   = State.regs[ OP[0] ] & 0xffff;
2248
  divide_this = State.regs[ OP[1] ] << imm5;
2249
 
2250
  divun (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
2251
 
2252
  State.regs[ OP[1]       ] = quotient;
2253
  State.regs[ OP[2] >> 11 ] = remainder;
2254
 
2255
  /* Set condition codes.  */
2256
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2257
 
2258
  if (overflow)      PSW |= PSW_OV;
2259
  if (quotient == 0) PSW |= PSW_Z;
2260
  if (quotient & 0x80000000) PSW |= PSW_S;
2261
 
2262
  trace_output (OP_IMM_REG_REG_REG);
2263
 
2264
  return 4;
2265
}
2266
 
2267
/* sdivhn imm5, reg1, reg2, reg3 */
2268
int
2269
OP_18007E0 (void)
2270
{
2271
  signed32 /*signed long int*/  quotient;
2272
  signed32 /*signed long int*/  remainder;
2273
  signed long int  divide_by;
2274
  signed long int  divide_this;
2275
  int          overflow = 0;
2276
  unsigned int     imm5;
2277
 
2278
  trace_input ("sdivhn", OP_IMM_REG_REG_REG, 0);
2279
 
2280
  imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
2281
 
2282
  divide_by   = EXTEND16 (State.regs[ OP[0] ]);
2283
  divide_this = (signed32) (State.regs[ OP[1] ] << imm5);
2284
 
2285
  divn (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
2286
 
2287
  State.regs[ OP[1]       ] = quotient;
2288
  State.regs[ OP[2] >> 11 ] = remainder;
2289
 
2290
  /* Set condition codes.  */
2291
  PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2292
 
2293
  if (overflow)      PSW |= PSW_OV;
2294
  if (quotient == 0) PSW |= PSW_Z;
2295
  if (quotient <  0) PSW |= PSW_S;
2296
 
2297
  trace_output (OP_IMM_REG_REG_REG);
2298
 
2299
  return 4;
2300
}
2301
 
2302
/* divu  reg1, reg2, reg3 */
2303
int
2304
OP_2C207E0 (void)
2305
{
2306
  unsigned long int quotient;
2307
  unsigned long int remainder;
2308
  unsigned long int divide_by;
2309
  unsigned long int divide_this;
2310
  int           overflow = 0;
2311
 
2312
  trace_input ("divu", OP_REG_REG_REG, 0);
2313
 
2314
  /* Compute the result.  */
2315
 
2316
  divide_by   = State.regs[ OP[0] ];
2317
  divide_this = State.regs[ OP[1] ];
2318
 
2319
  if (divide_by == 0)
2320
    {
2321
      PSW |= PSW_OV;
2322
    }
2323
  else
2324
    {
2325
      State.regs[ OP[1]       ] = quotient  = divide_this / divide_by;
2326
      State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
2327
 
2328
      /* Set condition codes.  */
2329
      PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2330
 
2331
      if (overflow)      PSW |= PSW_OV;
2332
      if (quotient == 0) PSW |= PSW_Z;
2333
      if (quotient & 0x80000000) PSW |= PSW_S;
2334
    }
2335
 
2336
  trace_output (OP_REG_REG_REG);
2337
 
2338
  return 4;
2339
}
2340
 
2341
/* div  reg1, reg2, reg3 */
2342
int
2343
OP_2C007E0 (void)
2344
{
2345
  signed long int quotient;
2346
  signed long int remainder;
2347
  signed long int divide_by;
2348
  signed long int divide_this;
2349
 
2350
  trace_input ("div", OP_REG_REG_REG, 0);
2351
 
2352
  /* Compute the result.  */
2353
 
2354
  divide_by   = (signed32) State.regs[ OP[0] ];
2355
  divide_this = State.regs[ OP[1] ];
2356
 
2357
  if (divide_by == 0)
2358
    {
2359
      PSW |= PSW_OV;
2360
    }
2361
  else if (divide_by == -1 && divide_this == (1L << 31))
2362
    {
2363
      PSW &= ~PSW_Z;
2364
      PSW |= PSW_OV | PSW_S;
2365
      State.regs[ OP[1] ] = (1 << 31);
2366
      State.regs[ OP[2] >> 11 ] = 0;
2367
    }
2368
  else
2369
    {
2370
      divide_this = (signed32) divide_this;
2371
      State.regs[ OP[1]       ] = quotient  = divide_this / divide_by;
2372
      State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
2373
 
2374
      /* Set condition codes.  */
2375
      PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2376
 
2377
      if (quotient == 0) PSW |= PSW_Z;
2378
      if (quotient <  0) PSW |= PSW_S;
2379
    }
2380
 
2381
  trace_output (OP_REG_REG_REG);
2382
 
2383
  return 4;
2384
}
2385
 
2386
/* divhu  reg1, reg2, reg3 */
2387
int
2388
OP_28207E0 (void)
2389
{
2390
  unsigned long int quotient;
2391
  unsigned long int remainder;
2392
  unsigned long int divide_by;
2393
  unsigned long int divide_this;
2394
  int           overflow = 0;
2395
 
2396
  trace_input ("divhu", OP_REG_REG_REG, 0);
2397
 
2398
  /* Compute the result.  */
2399
 
2400
  divide_by   = State.regs[ OP[0] ] & 0xffff;
2401
  divide_this = State.regs[ OP[1] ];
2402
 
2403
  if (divide_by == 0)
2404
    {
2405
      PSW |= PSW_OV;
2406
    }
2407
  else
2408
    {
2409
      State.regs[ OP[1]       ] = quotient  = divide_this / divide_by;
2410
      State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
2411
 
2412
      /* Set condition codes.  */
2413
      PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2414
 
2415
      if (overflow)      PSW |= PSW_OV;
2416
      if (quotient == 0) PSW |= PSW_Z;
2417
      if (quotient & 0x80000000) PSW |= PSW_S;
2418
    }
2419
 
2420
  trace_output (OP_REG_REG_REG);
2421
 
2422
  return 4;
2423
}
2424
 
2425
/* divh  reg1, reg2, reg3 */
2426
int
2427
OP_28007E0 (void)
2428
{
2429
  signed long int quotient;
2430
  signed long int remainder;
2431
  signed long int divide_by;
2432
  signed long int divide_this;
2433
  int         overflow = 0;
2434
 
2435
  trace_input ("divh", OP_REG_REG_REG, 0);
2436
 
2437
  /* Compute the result.  */
2438
 
2439
  divide_by  = EXTEND16 (State.regs[ OP[0] ]);
2440
  divide_this = State.regs[ OP[1] ];
2441
 
2442
  if (divide_by == 0)
2443
    {
2444
      PSW |= PSW_OV;
2445
    }
2446
  else if (divide_by == -1 && divide_this == (1L << 31))
2447
    {
2448
      PSW &= ~PSW_Z;
2449
      PSW |= PSW_OV | PSW_S;
2450
      State.regs[ OP[1] ] = (1 << 31);
2451
      State.regs[ OP[2] >> 11 ] = 0;
2452
    }
2453
  else
2454
    {
2455
      divide_this = (signed32) divide_this;
2456
      State.regs[ OP[1]       ] = quotient  = divide_this / divide_by;
2457
      State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
2458
 
2459
      /* Set condition codes.  */
2460
      PSW &= ~(PSW_Z | PSW_S | PSW_OV);
2461
 
2462
      if (quotient == 0) PSW |= PSW_Z;
2463
      if (quotient <  0) PSW |= PSW_S;
2464
    }
2465
 
2466
  trace_output (OP_REG_REG_REG);
2467
 
2468
  return 4;
2469
}
2470
 
2471
/* mulu imm9, reg2, reg3 */
2472
int
2473
OP_24207E0 (void)
2474
{
2475
  trace_input ("mulu", OP_IMM_REG_REG, 0);
2476
 
2477
  Multiply64 (0, (OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0));
2478
 
2479
  trace_output (OP_IMM_REG_REG);
2480
 
2481
  return 4;
2482
}
2483
 
2484
/* mul imm9, reg2, reg3 */
2485
int
2486
OP_24007E0 (void)
2487
{
2488
  trace_input ("mul", OP_IMM_REG_REG, 0);
2489
 
2490
  Multiply64 (1, SEXT9 ((OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0)));
2491
 
2492
  trace_output (OP_IMM_REG_REG);
2493
 
2494
  return 4;
2495
}
2496
 
2497
/* ld.hu */
2498
int
2499
OP_107E0 (void)
2500
{
2501
  int adr;
2502
 
2503
  trace_input ("ld.hu", OP_LOAD32, 2);
2504
 
2505
  adr = State.regs[ OP[0] ] + EXTEND16 (OP[2] & ~1);
2506
  adr &= ~0x1;
2507
 
2508
  State.regs[ OP[1] ] = load_mem (adr, 2);
2509
 
2510
  trace_output (OP_LOAD32);
2511
 
2512
  return 4;
2513
}
2514
 
2515
 
2516
/* ld.bu */
2517
int
2518
OP_10780 (void)
2519
{
2520
  int adr;
2521
 
2522
  trace_input ("ld.bu", OP_LOAD32, 1);
2523
 
2524
  adr = (State.regs[ OP[0] ]
2525
         + (EXTEND16 (OP[2] & ~1) | ((OP[3] >> 5) & 1)));
2526
 
2527
  State.regs[ OP[1] ] = load_mem (adr, 1);
2528
 
2529
  trace_output (OP_LOAD32);
2530
 
2531
  return 4;
2532
}
2533
 
2534
/* prepare list12, imm5, imm32 */
2535
int
2536
OP_1B0780 (void)
2537
{
2538
  int  i;
2539
 
2540
  trace_input ("prepare", OP_PUSHPOP1, 0);
2541
 
2542
  /* Store the registers with lower number registers being placed at higher addresses.  */
2543
  for (i = 0; i < 12; i++)
2544
    if ((OP[3] & (1 << type1_regs[ i ])))
2545
      {
2546
        SP -= 4;
2547
        store_mem (SP, 4, State.regs[ 20 + i ]);
2548
      }
2549
 
2550
  SP -= (OP[3] & 0x3e) << 1;
2551
 
2552
  EP = load_mem (PC + 4, 4);
2553
 
2554
  trace_output (OP_PUSHPOP1);
2555
 
2556
  return 8;
2557
}
2558
 
2559
/* prepare list12, imm5, imm16-32 */
2560
int
2561
OP_130780 (void)
2562
{
2563
  int  i;
2564
 
2565
  trace_input ("prepare", OP_PUSHPOP1, 0);
2566
 
2567
  /* Store the registers with lower number registers being placed at higher addresses.  */
2568
  for (i = 0; i < 12; i++)
2569
    if ((OP[3] & (1 << type1_regs[ i ])))
2570
      {
2571
        SP -= 4;
2572
        store_mem (SP, 4, State.regs[ 20 + i ]);
2573
      }
2574
 
2575
  SP -= (OP[3] & 0x3e) << 1;
2576
 
2577
  EP = load_mem (PC + 4, 2) << 16;
2578
 
2579
  trace_output (OP_PUSHPOP1);
2580
 
2581
  return 6;
2582
}
2583
 
2584
/* prepare list12, imm5, imm16 */
2585
int
2586
OP_B0780 (void)
2587
{
2588
  int  i;
2589
 
2590
  trace_input ("prepare", OP_PUSHPOP1, 0);
2591
 
2592
  /* Store the registers with lower number registers being placed at higher addresses.  */
2593
  for (i = 0; i < 12; i++)
2594
    if ((OP[3] & (1 << type1_regs[ i ])))
2595
      {
2596
        SP -= 4;
2597
        store_mem (SP, 4, State.regs[ 20 + i ]);
2598
      }
2599
 
2600
  SP -= (OP[3] & 0x3e) << 1;
2601
 
2602
  EP = EXTEND16 (load_mem (PC + 4, 2));
2603
 
2604
  trace_output (OP_PUSHPOP1);
2605
 
2606
  return 6;
2607
}
2608
 
2609
/* prepare list12, imm5, sp */
2610
int
2611
OP_30780 (void)
2612
{
2613
  int  i;
2614
 
2615
  trace_input ("prepare", OP_PUSHPOP1, 0);
2616
 
2617
  /* Store the registers with lower number registers being placed at higher addresses.  */
2618
  for (i = 0; i < 12; i++)
2619
    if ((OP[3] & (1 << type1_regs[ i ])))
2620
      {
2621
        SP -= 4;
2622
        store_mem (SP, 4, State.regs[ 20 + i ]);
2623
      }
2624
 
2625
  SP -= (OP[3] & 0x3e) << 1;
2626
 
2627
  EP = SP;
2628
 
2629
  trace_output (OP_PUSHPOP1);
2630
 
2631
  return 4;
2632
}
2633
 
2634
/* mul reg1, reg2, reg3 */
2635
int
2636
OP_22007E0 (void)
2637
{
2638
  trace_input ("mul", OP_REG_REG_REG, 0);
2639
 
2640
  Multiply64 (1, State.regs[ OP[0] ]);
2641
 
2642
  trace_output (OP_REG_REG_REG);
2643
 
2644
  return 4;
2645
}
2646
 
2647
/* popmh list18 */
2648
int
2649
OP_307F0 (void)
2650
{
2651
  int i;
2652
 
2653
  trace_input ("popmh", OP_PUSHPOP2, 0);
2654
 
2655
  if (OP[3] & (1 << 19))
2656
    {
2657
      if ((PSW & PSW_NP) && ((PSW & PSW_EP) == 0))
2658
        {
2659
          FEPSW = load_mem ( SP      & ~ 3, 4);
2660
          FEPC  = load_mem ((SP + 4) & ~ 3, 4);
2661
        }
2662
      else
2663
        {
2664
          EIPSW = load_mem ( SP      & ~ 3, 4);
2665
          EIPC  = load_mem ((SP + 4) & ~ 3, 4);
2666
        }
2667
 
2668
      SP += 8;
2669
    }
2670
 
2671
  /* Load the registers with lower number registers being retrieved from higher addresses.  */
2672
  for (i = 16; i--;)
2673
    if ((OP[3] & (1 << type2_regs[ i ])))
2674
      {
2675
        State.regs[ i + 16 ] = load_mem (SP & ~ 3, 4);
2676
        SP += 4;
2677
      }
2678
 
2679
  trace_output (OP_PUSHPOP2);
2680
 
2681
  return 4;
2682
}
2683
 
2684
/* popml lsit18 */
2685
int
2686
OP_107F0 (void)
2687
{
2688
  int i;
2689
 
2690
  trace_input ("popml", OP_PUSHPOP3, 0);
2691
 
2692
  if (OP[3] & (1 << 19))
2693
    {
2694
      if ((PSW & PSW_NP) && ((PSW & PSW_EP) == 0))
2695
        {
2696
          FEPSW = load_mem ( SP      & ~ 3, 4);
2697
          FEPC =  load_mem ((SP + 4) & ~ 3, 4);
2698
        }
2699
      else
2700
        {
2701
          EIPSW = load_mem ( SP      & ~ 3, 4);
2702
          EIPC  = load_mem ((SP + 4) & ~ 3, 4);
2703
        }
2704
 
2705
      SP += 8;
2706
    }
2707
 
2708
  if (OP[3] & (1 << 3))
2709
    {
2710
      PSW = load_mem (SP & ~ 3, 4);
2711
      SP += 4;
2712
    }
2713
 
2714
  /* Load the registers with lower number registers being retrieved from higher addresses.  */
2715
  for (i = 15; i--;)
2716
    if ((OP[3] & (1 << type3_regs[ i ])))
2717
      {
2718
        State.regs[ i + 1 ] = load_mem (SP & ~ 3, 4);
2719
        SP += 4;
2720
      }
2721
 
2722
  trace_output (OP_PUSHPOP2);
2723
 
2724
  return 4;
2725
}
2726
 
2727
/* pushmh list18 */
2728
int
2729
OP_307E0 (void)
2730
{
2731
  int i;
2732
 
2733
  trace_input ("pushmh", OP_PUSHPOP2, 0);
2734
 
2735
  /* Store the registers with lower number registers being placed at higher addresses.  */
2736
  for (i = 0; i < 16; i++)
2737
    if ((OP[3] & (1 << type2_regs[ i ])))
2738
      {
2739
        SP -= 4;
2740
        store_mem (SP & ~ 3, 4, State.regs[ i + 16 ]);
2741
      }
2742
 
2743
  if (OP[3] & (1 << 19))
2744
    {
2745
      SP -= 8;
2746
 
2747
      if ((PSW & PSW_NP) && ((PSW & PSW_EP) == 0))
2748
        {
2749
          store_mem ((SP + 4) & ~ 3, 4, FEPC);
2750
          store_mem ( SP      & ~ 3, 4, FEPSW);
2751
        }
2752
      else
2753
        {
2754
          store_mem ((SP + 4) & ~ 3, 4, EIPC);
2755
          store_mem ( SP      & ~ 3, 4, EIPSW);
2756
        }
2757
    }
2758
 
2759
  trace_output (OP_PUSHPOP2);
2760
 
2761
  return 4;
2762
}
2763
 

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