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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-6.8/] [sim/] [mips/] [mips.igen] - Blame information for rev 225

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1 24 jeremybenn
// -*- C -*-
2
//
3
//     ::=
4
//         { "+"  }
5
//        ":" 
6
//        ":" 
7
//        ":" 
8
//        ":" 
9
//        
10
//        {  }
11
//        {  }
12
//        
13
//
14
 
15
 
16
// IGEN config - mips16
17
// :option:16::insn-bit-size:16
18
// :option:16::hi-bit-nr:15
19
:option:16::insn-specifying-widths:true
20
:option:16::gen-delayed-branch:false
21
 
22
// IGEN config - mips32/64..
23
// :option:32::insn-bit-size:32
24
// :option:32::hi-bit-nr:31
25
:option:32::insn-specifying-widths:true
26
:option:32::gen-delayed-branch:false
27
 
28
 
29
// Generate separate simulators for each target
30
// :option:::multi-sim:true
31
 
32
 
33
// Models known by this simulator are defined below.
34
//
35
// When placing models in the instruction descriptions, please place
36
// them one per line, in the order given here.
37
 
38
//  MIPS ISAs:
39
//
40
//  Instructions and related functions for these models are included in
41
//  this file.
42
:model:::mipsI:mips3000:
43
:model:::mipsII:mips6000:
44
:model:::mipsIII:mips4000:
45
:model:::mipsIV:mips8000:
46
:model:::mipsV:mipsisaV:
47
:model:::mips32:mipsisa32:
48
:model:::mips32r2:mipsisa32r2:
49
:model:::mips64:mipsisa64:
50
:model:::mips64r2:mipsisa64r2:
51
 
52
//  Vendor ISAs:
53
//
54
//  Standard MIPS ISA instructions used for these models are listed here,
55
//  as are functions needed by those standard instructions.  Instructions
56
//  which are model-dependent and which are not in the standard MIPS ISAs
57
//  (or which pre-date or use different encodings than the standard
58
//  instructions) are (for the most part) in separate .igen files.
59
:model:::vr4100:mips4100:               // vr.igen
60
:model:::vr4120:mips4120:
61
:model:::vr5000:mips5000:
62
:model:::vr5400:mips5400:
63
:model:::vr5500:mips5500:
64
:model:::r3900:mips3900:                // tx.igen
65
 
66
//  MIPS Application Specific Extensions (ASEs)
67
//
68
//  Instructions for the ASEs are in separate .igen files.
69
//  ASEs add instructions on to a base ISA.
70
:model:::mips16:mips16:                 // m16.igen (and m16.dc)
71
:model:::mips16e:mips16e:               // m16e.igen
72
:model:::mips3d:mips3d:                 // mips3d.igen
73
:model:::mdmx:mdmx:                     // mdmx.igen
74
:model:::dsp:dsp:                       // dsp.igen
75
:model:::dsp2:dsp2:                     // dsp2.igen
76
:model:::smartmips:smartmips:           // smartmips.igen
77
 
78
//  Vendor Extensions
79
//
80
//  Instructions specific to these extensions are in separate .igen files.
81
//  Extensions add instructions on to a base ISA.
82
:model:::sb1:sb1:                       // sb1.igen
83
 
84
 
85
// Pseudo instructions known by IGEN
86
:internal::::illegal:
87
{
88
  SignalException (ReservedInstruction, 0);
89
}
90
 
91
 
92
// Pseudo instructions known by interp.c
93
// For grep - RSVD_INSTRUCTION, RSVD_INSTRUCTION_MASK
94
000000,5.*,5.*,5.*,5.OP,000101:SPECIAL:32::RSVD
95
"rsvd "
96
{
97
  SignalException (ReservedInstruction, instruction_0);
98
}
99
 
100
 
101
 
102
// Helper:
103
//
104
// Simulate a 32 bit delayslot instruction
105
//
106
 
107
:function:::address_word:delayslot32:address_word target
108
{
109
  instruction_word delay_insn;
110
  sim_events_slip (SD, 1);
111
  DSPC = CIA;
112
  CIA = CIA + 4; /* NOTE not mips16 */
113
  STATE |= simDELAYSLOT;
114
  delay_insn = IMEM32 (CIA); /* NOTE not mips16 */
115
  ENGINE_ISSUE_PREFIX_HOOK();
116
  idecode_issue (CPU_, delay_insn, (CIA));
117
  STATE &= ~simDELAYSLOT;
118
  return target;
119
}
120
 
121
:function:::address_word:nullify_next_insn32:
122
{
123
  sim_events_slip (SD, 1);
124
  dotrace (SD, CPU, tracefh, 2, CIA + 4, 4, "load instruction");
125
  return CIA + 8;
126
}
127
 
128
 
129
// Helper:
130
//
131
// Calculate an effective address given a base and an offset.
132
//
133
 
134
:function:::address_word:loadstore_ea:address_word base, address_word offset
135
*mipsI:
136
*mipsII:
137
*mipsIII:
138
*mipsIV:
139
*mipsV:
140
*mips32:
141
*mips32r2:
142
*vr4100:
143
*vr5000:
144
*r3900:
145
{
146
  return base + offset;
147
}
148
 
149
:function:::address_word:loadstore_ea:address_word base, address_word offset
150
*mips64:
151
*mips64r2:
152
{
153
#if 0 /* XXX FIXME: enable this only after some additional testing.  */
154
  /* If in user mode and UX is not set, use 32-bit compatibility effective
155
     address computations as defined in the MIPS64 Architecture for
156
     Programmers Volume III, Revision 0.95, section 4.9.  */
157
  if ((SR & (status_KSU_mask|status_EXL|status_ERL|status_UX))
158
      == (ksu_user << status_KSU_shift))
159
    return (address_word)((signed32)base + (signed32)offset);
160
#endif
161
  return base + offset;
162
}
163
 
164
 
165
// Helper:
166
//
167
// Check that a 32-bit register value is properly sign-extended.
168
// (See NotWordValue in ISA spec.)
169
//
170
 
171
:function:::int:not_word_value:unsigned_word value
172
*mipsI:
173
*mipsII:
174
*mipsIII:
175
*mipsIV:
176
*mipsV:
177
*vr4100:
178
*vr5000:
179
*r3900:
180
*mips32:
181
*mips32r2:
182
*mips64:
183
*mips64r2:
184
{
185
#if WITH_TARGET_WORD_BITSIZE == 64
186
  return value != (((value & 0xffffffff) ^ 0x80000000) - 0x80000000);
187
#else
188
  return 0;
189
#endif
190
}
191
 
192
// Helper:
193
//
194
// Handle UNPREDICTABLE operation behaviour.  The goal here is to prevent
195
// theoretically portable code which invokes non-portable behaviour from
196
// running with no indication of the portability issue.
197
// (See definition of UNPREDICTABLE in ISA spec.)
198
//
199
 
200
:function:::void:unpredictable:
201
*mipsI:
202
*mipsII:
203
*mipsIII:
204
*mipsIV:
205
*mipsV:
206
*vr4100:
207
*vr5000:
208
*r3900:
209
{
210
}
211
 
212
:function:::void:unpredictable:
213
*mips32:
214
*mips32r2:
215
*mips64:
216
*mips64r2:
217
{
218
  unpredictable_action (CPU, CIA);
219
}
220
 
221
 
222
// Helpers:
223
//
224
// Check that an access to a HI/LO register meets timing requirements
225
//
226
// In all MIPS ISAs,
227
//
228
//      OP {HI and LO} followed by MT{LO or HI} (and not MT{HI or LO})
229
//      makes subsequent MF{HI or LO} UNPREDICTABLE. (1)
230
//
231
// The following restrictions exist for MIPS I - MIPS III:
232
//
233
//      MF{HI or LO} followed by MT{HI or LO} w/ less than 2 instructions
234
//      in between makes MF UNPREDICTABLE. (2)
235
//
236
//      MF{HI or LO} followed by OP {HI and LO} w/ less than 2 instructions
237
//      in between makes MF UNPREDICTABLE. (3)
238
//
239
// On the r3900, restriction (2) is not present, and restriction (3) is not
240
// present for multiplication.
241
//
242
// Unfortunately, there seems to be some confusion about whether the last
243
// two restrictions should apply to "MIPS IV" as well.  One edition of
244
// the MIPS IV ISA says they do, but references in later ISA documents
245
// suggest they don't.
246
//
247
// In reality, some MIPS IV parts, such as the VR5000 and VR5400, do have
248
// these restrictions, while others, like the VR5500, don't.  To accomodate
249
// such differences, the MIPS IV and MIPS V version of these helper functions
250
// use auxillary routines to determine whether the restriction applies.
251
 
252
// check_mf_cycles:
253
//
254
// Helper used by check_mt_hilo, check_mult_hilo, and check_div_hilo
255
// to check for restrictions (2) and (3) above.
256
//
257
:function:::int:check_mf_cycles:hilo_history *history, signed64 time, const char *new
258
{
259
  if (history->mf.timestamp + 3 > time)
260
    {
261
      sim_engine_abort (SD, CPU, CIA, "HILO: %s: %s at 0x%08lx too close to MF at 0x%08lx\n",
262
                        itable[MY_INDEX].name,
263
                        new, (long) CIA,
264
                        (long) history->mf.cia);
265
      return 0;
266
    }
267
  return 1;
268
}
269
 
270
 
271
// check_mt_hilo:
272
//
273
// Check for restriction (2) above (for ISAs/processors that have it),
274
// and record timestamps for restriction (1) above.
275
//
276
:function:::int:check_mt_hilo:hilo_history *history
277
*mipsI:
278
*mipsII:
279
*mipsIII:
280
*vr4100:
281
*vr5000:
282
{
283
  signed64 time = sim_events_time (SD);
284
  int ok = check_mf_cycles (SD_, history, time, "MT");
285
  history->mt.timestamp = time;
286
  history->mt.cia = CIA;
287
  return ok;
288
}
289
 
290
:function:::int:check_mt_hilo:hilo_history *history
291
*mipsIV:
292
*mipsV:
293
{
294
  signed64 time = sim_events_time (SD);
295
  int ok = (! MIPS_MACH_HAS_MT_HILO_HAZARD (SD)
296
            || check_mf_cycles (SD_, history, time, "MT"));
297
  history->mt.timestamp = time;
298
  history->mt.cia = CIA;
299
  return ok;
300
}
301
 
302
:function:::int:check_mt_hilo:hilo_history *history
303
*mips32:
304
*mips32r2:
305
*mips64:
306
*mips64r2:
307
*r3900:
308
{
309
  signed64 time = sim_events_time (SD);
310
  history->mt.timestamp = time;
311
  history->mt.cia = CIA;
312
  return 1;
313
}
314
 
315
 
316
// check_mf_hilo:
317
//
318
// Check for restriction (1) above, and record timestamps for
319
// restriction (2) and (3) above.
320
//
321
:function:::int:check_mf_hilo:hilo_history *history, hilo_history *peer
322
*mipsI:
323
*mipsII:
324
*mipsIII:
325
*mipsIV:
326
*mipsV:
327
*mips32:
328
*mips32r2:
329
*mips64:
330
*mips64r2:
331
*vr4100:
332
*vr5000:
333
*r3900:
334
{
335
  signed64 time = sim_events_time (SD);
336
  int ok = 1;
337
  if (peer != NULL
338
      && peer->mt.timestamp > history->op.timestamp
339
      && history->mt.timestamp < history->op.timestamp
340
      && ! (history->mf.timestamp > history->op.timestamp
341
            && history->mf.timestamp < peer->mt.timestamp)
342
      && ! (peer->mf.timestamp > history->op.timestamp
343
            && peer->mf.timestamp < peer->mt.timestamp))
344
    {
345
      /* The peer has been written to since the last OP yet we have
346
         not */
347
      sim_engine_abort (SD, CPU, CIA, "HILO: %s: MF at 0x%08lx following OP at 0x%08lx corrupted by MT at 0x%08lx\n",
348
                        itable[MY_INDEX].name,
349
                        (long) CIA,
350
                        (long) history->op.cia,
351
                        (long) peer->mt.cia);
352
      ok = 0;
353
    }
354
  history->mf.timestamp = time;
355
  history->mf.cia = CIA;
356
  return ok;
357
}
358
 
359
 
360
 
361
// check_mult_hilo:
362
//
363
// Check for restriction (3) above (for ISAs/processors that have it)
364
// for MULT ops, and record timestamps for restriction (1) above.
365
//
366
:function:::int:check_mult_hilo:hilo_history *hi, hilo_history *lo
367
*mipsI:
368
*mipsII:
369
*mipsIII:
370
*vr4100:
371
*vr5000:
372
{
373
  signed64 time = sim_events_time (SD);
374
  int ok = (check_mf_cycles (SD_, hi, time, "OP")
375
            && check_mf_cycles (SD_, lo, time, "OP"));
376
  hi->op.timestamp = time;
377
  lo->op.timestamp = time;
378
  hi->op.cia = CIA;
379
  lo->op.cia = CIA;
380
  return ok;
381
}
382
 
383
:function:::int:check_mult_hilo:hilo_history *hi, hilo_history *lo
384
*mipsIV:
385
*mipsV:
386
{
387
  signed64 time = sim_events_time (SD);
388
  int ok = (! MIPS_MACH_HAS_MULT_HILO_HAZARD (SD)
389
            || (check_mf_cycles (SD_, hi, time, "OP")
390
                && check_mf_cycles (SD_, lo, time, "OP")));
391
  hi->op.timestamp = time;
392
  lo->op.timestamp = time;
393
  hi->op.cia = CIA;
394
  lo->op.cia = CIA;
395
  return ok;
396
}
397
 
398
:function:::int:check_mult_hilo:hilo_history *hi, hilo_history *lo
399
*mips32:
400
*mips32r2:
401
*mips64:
402
*mips64r2:
403
*r3900:
404
{
405
  /* FIXME: could record the fact that a stall occured if we want */
406
  signed64 time = sim_events_time (SD);
407
  hi->op.timestamp = time;
408
  lo->op.timestamp = time;
409
  hi->op.cia = CIA;
410
  lo->op.cia = CIA;
411
  return 1;
412
}
413
 
414
 
415
// check_div_hilo:
416
//
417
// Check for restriction (3) above (for ISAs/processors that have it)
418
// for DIV ops, and record timestamps for restriction (1) above.
419
//
420
:function:::int:check_div_hilo:hilo_history *hi, hilo_history *lo
421
*mipsI:
422
*mipsII:
423
*mipsIII:
424
*vr4100:
425
*vr5000:
426
*r3900:
427
{
428
  signed64 time = sim_events_time (SD);
429
  int ok = (check_mf_cycles (SD_, hi, time, "OP")
430
            && check_mf_cycles (SD_, lo, time, "OP"));
431
  hi->op.timestamp = time;
432
  lo->op.timestamp = time;
433
  hi->op.cia = CIA;
434
  lo->op.cia = CIA;
435
  return ok;
436
}
437
 
438
:function:::int:check_div_hilo:hilo_history *hi, hilo_history *lo
439
*mipsIV:
440
*mipsV:
441
{
442
  signed64 time = sim_events_time (SD);
443
  int ok = (! MIPS_MACH_HAS_DIV_HILO_HAZARD (SD)
444
            || (check_mf_cycles (SD_, hi, time, "OP")
445
                && check_mf_cycles (SD_, lo, time, "OP")));
446
  hi->op.timestamp = time;
447
  lo->op.timestamp = time;
448
  hi->op.cia = CIA;
449
  lo->op.cia = CIA;
450
  return ok;
451
}
452
 
453
:function:::int:check_div_hilo:hilo_history *hi, hilo_history *lo
454
*mips32:
455
*mips32r2:
456
*mips64:
457
*mips64r2:
458
{
459
  signed64 time = sim_events_time (SD);
460
  hi->op.timestamp = time;
461
  lo->op.timestamp = time;
462
  hi->op.cia = CIA;
463
  lo->op.cia = CIA;
464
  return 1;
465
}
466
 
467
 
468
// Helper:
469
//
470
// Check that the 64-bit instruction can currently be used, and signal
471
// a ReservedInstruction exception if not.
472
//
473
 
474
:function:::void:check_u64:instruction_word insn
475
*mipsIII:
476
*mipsIV:
477
*mipsV:
478
*vr4100:
479
*vr5000:
480
*vr5400:
481
*vr5500:
482
{
483
  // The check should be similar to mips64 for any with PX/UX bit equivalents.
484
}
485
 
486
:function:::void:check_u64:instruction_word insn
487
*mips16e:
488
*mips64:
489
*mips64r2:
490
{
491
#if 0 /* XXX FIXME: enable this only after some additional testing.  */
492
  if (UserMode && (SR & (status_UX|status_PX)) == 0)
493
    SignalException (ReservedInstruction, insn);
494
#endif
495
}
496
 
497
 
498
 
499
//
500
// MIPS Architecture:
501
//
502
//        CPU Instruction Set (mipsI - mipsV, mips32/r2, mips64/r2)
503
//
504
 
505
 
506
 
507
000000,5.RS,5.RT,5.RD,00000,100000:SPECIAL:32::ADD
508
"add r, r, r"
509
*mipsI:
510
*mipsII:
511
*mipsIII:
512
*mipsIV:
513
*mipsV:
514
*mips32:
515
*mips32r2:
516
*mips64:
517
*mips64r2:
518
*vr4100:
519
*vr5000:
520
*r3900:
521
{
522
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
523
    Unpredictable ();
524
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
525
  {
526
    ALU32_BEGIN (GPR[RS]);
527
    ALU32_ADD (GPR[RT]);
528
    ALU32_END (GPR[RD]);   /* This checks for overflow.  */
529
  }
530
  TRACE_ALU_RESULT (GPR[RD]);
531
}
532
 
533
 
534
 
535
001000,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::ADDI
536
"addi r, r, "
537
*mipsI:
538
*mipsII:
539
*mipsIII:
540
*mipsIV:
541
*mipsV:
542
*mips32:
543
*mips32r2:
544
*mips64:
545
*mips64r2:
546
*vr4100:
547
*vr5000:
548
*r3900:
549
{
550
  if (NotWordValue (GPR[RS]))
551
    Unpredictable ();
552
  TRACE_ALU_INPUT2 (GPR[RS], EXTEND16 (IMMEDIATE));
553
  {
554
    ALU32_BEGIN (GPR[RS]);
555
    ALU32_ADD (EXTEND16 (IMMEDIATE));
556
    ALU32_END (GPR[RT]);   /* This checks for overflow.  */
557
  }
558
  TRACE_ALU_RESULT (GPR[RT]);
559
}
560
 
561
 
562
 
563
:function:::void:do_addiu:int rs, int rt, unsigned16 immediate
564
{
565
  if (NotWordValue (GPR[rs]))
566
    Unpredictable ();
567
  TRACE_ALU_INPUT2 (GPR[rs], EXTEND16 (immediate));
568
  GPR[rt] = EXTEND32 (GPR[rs] + EXTEND16 (immediate));
569
  TRACE_ALU_RESULT (GPR[rt]);
570
}
571
 
572
001001,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::ADDIU
573
"addiu r, r, "
574
*mipsI:
575
*mipsII:
576
*mipsIII:
577
*mipsIV:
578
*mipsV:
579
*mips32:
580
*mips32r2:
581
*mips64:
582
*mips64r2:
583
*vr4100:
584
*vr5000:
585
*r3900:
586
{
587
  do_addiu (SD_, RS, RT, IMMEDIATE);
588
}
589
 
590
 
591
 
592
:function:::void:do_addu:int rs, int rt, int rd
593
{
594
  if (NotWordValue (GPR[rs]) || NotWordValue (GPR[rt]))
595
    Unpredictable ();
596
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
597
  GPR[rd] = EXTEND32 (GPR[rs] + GPR[rt]);
598
  TRACE_ALU_RESULT (GPR[rd]);
599
}
600
 
601
000000,5.RS,5.RT,5.RD,00000,100001:SPECIAL:32::ADDU
602
"addu r, r, r"
603
*mipsI:
604
*mipsII:
605
*mipsIII:
606
*mipsIV:
607
*mipsV:
608
*mips32:
609
*mips32r2:
610
*mips64:
611
*mips64r2:
612
*vr4100:
613
*vr5000:
614
*r3900:
615
{
616
  do_addu (SD_, RS, RT, RD);
617
}
618
 
619
 
620
 
621
:function:::void:do_and:int rs, int rt, int rd
622
{
623
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
624
  GPR[rd] = GPR[rs] & GPR[rt];
625
  TRACE_ALU_RESULT (GPR[rd]);
626
}
627
 
628
000000,5.RS,5.RT,5.RD,00000,100100:SPECIAL:32::AND
629
"and r, r, r"
630
*mipsI:
631
*mipsII:
632
*mipsIII:
633
*mipsIV:
634
*mipsV:
635
*mips32:
636
*mips32r2:
637
*mips64:
638
*mips64r2:
639
*vr4100:
640
*vr5000:
641
*r3900:
642
{
643
  do_and (SD_, RS, RT, RD);
644
}
645
 
646
 
647
 
648
001100,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::ANDI
649
"andi r, r, %#lx"
650
*mipsI:
651
*mipsII:
652
*mipsIII:
653
*mipsIV:
654
*mipsV:
655
*mips32:
656
*mips32r2:
657
*mips64:
658
*mips64r2:
659
*vr4100:
660
*vr5000:
661
*r3900:
662
{
663
  TRACE_ALU_INPUT2 (GPR[RS], IMMEDIATE);
664
  GPR[RT] = GPR[RS] & IMMEDIATE;
665
  TRACE_ALU_RESULT (GPR[RT]);
666
}
667
 
668
 
669
 
670
000100,5.RS,5.RT,16.OFFSET:NORMAL:32::BEQ
671
"beq r, r, "
672
*mipsI:
673
*mipsII:
674
*mipsIII:
675
*mipsIV:
676
*mipsV:
677
*mips32:
678
*mips32r2:
679
*mips64:
680
*mips64r2:
681
*vr4100:
682
*vr5000:
683
*r3900:
684
{
685
  address_word offset = EXTEND16 (OFFSET) << 2;
686
  if ((signed_word) GPR[RS] == (signed_word) GPR[RT])
687
    {
688
      DELAY_SLOT (NIA + offset);
689
    }
690
}
691
 
692
 
693
 
694
010100,5.RS,5.RT,16.OFFSET:NORMAL:32::BEQL
695
"beql r, r, "
696
*mipsII:
697
*mipsIII:
698
*mipsIV:
699
*mipsV:
700
*mips32:
701
*mips32r2:
702
*mips64:
703
*mips64r2:
704
*vr4100:
705
*vr5000:
706
*r3900:
707
{
708
  address_word offset = EXTEND16 (OFFSET) << 2;
709
  if ((signed_word) GPR[RS] == (signed_word) GPR[RT])
710
    {
711
      DELAY_SLOT (NIA + offset);
712
    }
713
  else
714
    NULLIFY_NEXT_INSTRUCTION ();
715
}
716
 
717
 
718
 
719
000001,5.RS,00001,16.OFFSET:REGIMM:32::BGEZ
720
"bgez r, "
721
*mipsI:
722
*mipsII:
723
*mipsIII:
724
*mipsIV:
725
*mipsV:
726
*mips32:
727
*mips32r2:
728
*mips64:
729
*mips64r2:
730
*vr4100:
731
*vr5000:
732
*r3900:
733
{
734
  address_word offset = EXTEND16 (OFFSET) << 2;
735
  if ((signed_word) GPR[RS] >= 0)
736
    {
737
      DELAY_SLOT (NIA + offset);
738
    }
739
}
740
 
741
 
742
 
743
000001,5.RS!31,10001,16.OFFSET:REGIMM:32::BGEZAL
744
"bgezal r, "
745
*mipsI:
746
*mipsII:
747
*mipsIII:
748
*mipsIV:
749
*mipsV:
750
*mips32:
751
*mips32r2:
752
*mips64:
753
*mips64r2:
754
*vr4100:
755
*vr5000:
756
*r3900:
757
{
758
  address_word offset = EXTEND16 (OFFSET) << 2;
759
  if (RS == 31)
760
    Unpredictable ();
761
  RA = (CIA + 8);
762
  if ((signed_word) GPR[RS] >= 0)
763
    {
764
      DELAY_SLOT (NIA + offset);
765
    }
766
}
767
 
768
 
769
 
770
000001,5.RS!31,10011,16.OFFSET:REGIMM:32::BGEZALL
771
"bgezall r, "
772
*mipsII:
773
*mipsIII:
774
*mipsIV:
775
*mipsV:
776
*mips32:
777
*mips32r2:
778
*mips64:
779
*mips64r2:
780
*vr4100:
781
*vr5000:
782
*r3900:
783
{
784
  address_word offset = EXTEND16 (OFFSET) << 2;
785
  if (RS == 31)
786
    Unpredictable ();
787
  RA = (CIA + 8);
788
  /* NOTE: The branch occurs AFTER the next instruction has been
789
     executed */
790
  if ((signed_word) GPR[RS] >= 0)
791
    {
792
      DELAY_SLOT (NIA + offset);
793
    }
794
  else
795
    NULLIFY_NEXT_INSTRUCTION ();
796
}
797
 
798
 
799
 
800
000001,5.RS,00011,16.OFFSET:REGIMM:32::BGEZL
801
"bgezl r, "
802
*mipsII:
803
*mipsIII:
804
*mipsIV:
805
*mipsV:
806
*mips32:
807
*mips32r2:
808
*mips64:
809
*mips64r2:
810
*vr4100:
811
*vr5000:
812
*r3900:
813
{
814
  address_word offset = EXTEND16 (OFFSET) << 2;
815
  if ((signed_word) GPR[RS] >= 0)
816
    {
817
      DELAY_SLOT (NIA + offset);
818
    }
819
  else
820
    NULLIFY_NEXT_INSTRUCTION ();
821
}
822
 
823
 
824
 
825
000111,5.RS,00000,16.OFFSET:NORMAL:32::BGTZ
826
"bgtz r, "
827
*mipsI:
828
*mipsII:
829
*mipsIII:
830
*mipsIV:
831
*mipsV:
832
*mips32:
833
*mips32r2:
834
*mips64:
835
*mips64r2:
836
*vr4100:
837
*vr5000:
838
*r3900:
839
{
840
  address_word offset = EXTEND16 (OFFSET) << 2;
841
  if ((signed_word) GPR[RS] > 0)
842
    {
843
      DELAY_SLOT (NIA + offset);
844
    }
845
}
846
 
847
 
848
 
849
010111,5.RS,00000,16.OFFSET:NORMAL:32::BGTZL
850
"bgtzl r, "
851
*mipsII:
852
*mipsIII:
853
*mipsIV:
854
*mipsV:
855
*mips32:
856
*mips32r2:
857
*mips64:
858
*mips64r2:
859
*vr4100:
860
*vr5000:
861
*r3900:
862
{
863
  address_word offset = EXTEND16 (OFFSET) << 2;
864
  /* NOTE: The branch occurs AFTER the next instruction has been
865
     executed */
866
  if ((signed_word) GPR[RS] > 0)
867
    {
868
      DELAY_SLOT (NIA + offset);
869
    }
870
  else
871
    NULLIFY_NEXT_INSTRUCTION ();
872
}
873
 
874
 
875
 
876
000110,5.RS,00000,16.OFFSET:NORMAL:32::BLEZ
877
"blez r, "
878
*mipsI:
879
*mipsII:
880
*mipsIII:
881
*mipsIV:
882
*mipsV:
883
*mips32:
884
*mips32r2:
885
*mips64:
886
*mips64r2:
887
*vr4100:
888
*vr5000:
889
*r3900:
890
{
891
  address_word offset = EXTEND16 (OFFSET) << 2;
892
  /* NOTE: The branch occurs AFTER the next instruction has been
893
     executed */
894
  if ((signed_word) GPR[RS] <= 0)
895
    {
896
      DELAY_SLOT (NIA + offset);
897
    }
898
}
899
 
900
 
901
 
902
010110,5.RS,00000,16.OFFSET:NORMAL:32::BLEZL
903
"bgezl r, "
904
*mipsII:
905
*mipsIII:
906
*mipsIV:
907
*mipsV:
908
*mips32:
909
*mips32r2:
910
*mips64:
911
*mips64r2:
912
*vr4100:
913
*vr5000:
914
*r3900:
915
{
916
  address_word offset = EXTEND16 (OFFSET) << 2;
917
  if ((signed_word) GPR[RS] <= 0)
918
    {
919
      DELAY_SLOT (NIA + offset);
920
    }
921
  else
922
    NULLIFY_NEXT_INSTRUCTION ();
923
}
924
 
925
 
926
 
927
000001,5.RS,00000,16.OFFSET:REGIMM:32::BLTZ
928
"bltz r, "
929
*mipsI:
930
*mipsII:
931
*mipsIII:
932
*mipsIV:
933
*mipsV:
934
*mips32:
935
*mips32r2:
936
*mips64:
937
*mips64r2:
938
*vr4100:
939
*vr5000:
940
*r3900:
941
{
942
  address_word offset = EXTEND16 (OFFSET) << 2;
943
  if ((signed_word) GPR[RS] < 0)
944
    {
945
      DELAY_SLOT (NIA + offset);
946
    }
947
}
948
 
949
 
950
 
951
000001,5.RS!31,10000,16.OFFSET:REGIMM:32::BLTZAL
952
"bltzal r, "
953
*mipsI:
954
*mipsII:
955
*mipsIII:
956
*mipsIV:
957
*mipsV:
958
*mips32:
959
*mips32r2:
960
*mips64:
961
*mips64r2:
962
*vr4100:
963
*vr5000:
964
*r3900:
965
{
966
  address_word offset = EXTEND16 (OFFSET) << 2;
967
  if (RS == 31)
968
    Unpredictable ();
969
  RA = (CIA + 8);
970
  /* NOTE: The branch occurs AFTER the next instruction has been
971
     executed */
972
  if ((signed_word) GPR[RS] < 0)
973
    {
974
      DELAY_SLOT (NIA + offset);
975
    }
976
}
977
 
978
 
979
 
980
000001,5.RS!31,10010,16.OFFSET:REGIMM:32::BLTZALL
981
"bltzall r, "
982
*mipsII:
983
*mipsIII:
984
*mipsIV:
985
*mipsV:
986
*mips32:
987
*mips32r2:
988
*mips64:
989
*mips64r2:
990
*vr4100:
991
*vr5000:
992
*r3900:
993
{
994
  address_word offset = EXTEND16 (OFFSET) << 2;
995
  if (RS == 31)
996
    Unpredictable ();
997
  RA = (CIA + 8);
998
  if ((signed_word) GPR[RS] < 0)
999
    {
1000
      DELAY_SLOT (NIA + offset);
1001
    }
1002
  else
1003
    NULLIFY_NEXT_INSTRUCTION ();
1004
}
1005
 
1006
 
1007
 
1008
000001,5.RS,00010,16.OFFSET:REGIMM:32::BLTZL
1009
"bltzl r, "
1010
*mipsII:
1011
*mipsIII:
1012
*mipsIV:
1013
*mipsV:
1014
*mips32:
1015
*mips32r2:
1016
*mips64:
1017
*mips64r2:
1018
*vr4100:
1019
*vr5000:
1020
*r3900:
1021
{
1022
  address_word offset = EXTEND16 (OFFSET) << 2;
1023
  /* NOTE: The branch occurs AFTER the next instruction has been
1024
     executed */
1025
  if ((signed_word) GPR[RS] < 0)
1026
    {
1027
      DELAY_SLOT (NIA + offset);
1028
    }
1029
  else
1030
    NULLIFY_NEXT_INSTRUCTION ();
1031
}
1032
 
1033
 
1034
 
1035
000101,5.RS,5.RT,16.OFFSET:NORMAL:32::BNE
1036
"bne r, r, "
1037
*mipsI:
1038
*mipsII:
1039
*mipsIII:
1040
*mipsIV:
1041
*mipsV:
1042
*mips32:
1043
*mips32r2:
1044
*mips64:
1045
*mips64r2:
1046
*vr4100:
1047
*vr5000:
1048
*r3900:
1049
{
1050
  address_word offset = EXTEND16 (OFFSET) << 2;
1051
  if ((signed_word) GPR[RS] != (signed_word) GPR[RT])
1052
    {
1053
      DELAY_SLOT (NIA + offset);
1054
    }
1055
}
1056
 
1057
 
1058
 
1059
010101,5.RS,5.RT,16.OFFSET:NORMAL:32::BNEL
1060
"bnel r, r, "
1061
*mipsII:
1062
*mipsIII:
1063
*mipsIV:
1064
*mipsV:
1065
*mips32:
1066
*mips32r2:
1067
*mips64:
1068
*mips64r2:
1069
*vr4100:
1070
*vr5000:
1071
*r3900:
1072
{
1073
  address_word offset = EXTEND16 (OFFSET) << 2;
1074
  if ((signed_word) GPR[RS] != (signed_word) GPR[RT])
1075
    {
1076
      DELAY_SLOT (NIA + offset);
1077
    }
1078
  else
1079
    NULLIFY_NEXT_INSTRUCTION ();
1080
}
1081
 
1082
 
1083
 
1084
000000,20.CODE,001101:SPECIAL:32::BREAK
1085
"break %#lx"
1086
*mipsI:
1087
*mipsII:
1088
*mipsIII:
1089
*mipsIV:
1090
*mipsV:
1091
*mips32:
1092
*mips32r2:
1093
*mips64:
1094
*mips64r2:
1095
*vr4100:
1096
*vr5000:
1097
*r3900:
1098
{
1099
  /* Check for some break instruction which are reserved for use by the simulator.  */
1100
  unsigned int break_code = instruction_0 & HALT_INSTRUCTION_MASK;
1101
  if (break_code == (HALT_INSTRUCTION  & HALT_INSTRUCTION_MASK) ||
1102
      break_code == (HALT_INSTRUCTION2 & HALT_INSTRUCTION_MASK))
1103
    {
1104
      sim_engine_halt (SD, CPU, NULL, cia,
1105
                       sim_exited, (unsigned int)(A0 & 0xFFFFFFFF));
1106
    }
1107
  else if (break_code == (BREAKPOINT_INSTRUCTION  & HALT_INSTRUCTION_MASK) ||
1108
           break_code == (BREAKPOINT_INSTRUCTION2 & HALT_INSTRUCTION_MASK))
1109
    {
1110
      if (STATE & simDELAYSLOT)
1111
        PC = cia - 4; /* reference the branch instruction */
1112
      else
1113
        PC = cia;
1114
      SignalException (BreakPoint, instruction_0);
1115
    }
1116
 
1117
  else
1118
    {
1119
      /* If we get this far, we're not an instruction reserved by the sim.  Raise
1120
         the exception. */
1121
      SignalException (BreakPoint, instruction_0);
1122
    }
1123
}
1124
 
1125
 
1126
 
1127
011100,5.RS,5.RT,5.RD,00000,100001:SPECIAL2:32::CLO
1128
"clo r, r"
1129
*mips32:
1130
*mips32r2:
1131
*mips64:
1132
*mips64r2:
1133
*vr5500:
1134
{
1135
  unsigned32 temp = GPR[RS];
1136
  unsigned32 i, mask;
1137
  if (RT != RD)
1138
    Unpredictable ();
1139
  if (NotWordValue (GPR[RS]))
1140
    Unpredictable ();
1141
  TRACE_ALU_INPUT1 (GPR[RS]);
1142
  for (mask = ((unsigned32)1<<31), i = 0; i < 32; ++i)
1143
    {
1144
      if ((temp & mask) == 0)
1145
        break;
1146
      mask >>= 1;
1147
    }
1148
  GPR[RD] = EXTEND32 (i);
1149
  TRACE_ALU_RESULT (GPR[RD]);
1150
}
1151
 
1152
 
1153
 
1154
011100,5.RS,5.RT,5.RD,00000,100000:SPECIAL2:32::CLZ
1155
"clz r, r"
1156
*mips32:
1157
*mips32r2:
1158
*mips64:
1159
*mips64r2:
1160
*vr5500:
1161
{
1162
  unsigned32 temp = GPR[RS];
1163
  unsigned32 i, mask;
1164
  if (RT != RD)
1165
    Unpredictable ();
1166
  if (NotWordValue (GPR[RS]))
1167
    Unpredictable ();
1168
  TRACE_ALU_INPUT1 (GPR[RS]);
1169
  for (mask = ((unsigned32)1<<31), i = 0; i < 32; ++i)
1170
    {
1171
      if ((temp & mask) != 0)
1172
        break;
1173
      mask >>= 1;
1174
    }
1175
  GPR[RD] = EXTEND32 (i);
1176
  TRACE_ALU_RESULT (GPR[RD]);
1177
}
1178
 
1179
 
1180
 
1181
000000,5.RS,5.RT,5.RD,00000,101100:SPECIAL:64::DADD
1182
"dadd r, r, r"
1183
*mipsIII:
1184
*mipsIV:
1185
*mipsV:
1186
*mips64:
1187
*mips64r2:
1188
*vr4100:
1189
*vr5000:
1190
{
1191
  check_u64 (SD_, instruction_0);
1192
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
1193
  {
1194
    ALU64_BEGIN (GPR[RS]);
1195
    ALU64_ADD (GPR[RT]);
1196
    ALU64_END (GPR[RD]);   /* This checks for overflow.  */
1197
  }
1198
  TRACE_ALU_RESULT (GPR[RD]);
1199
}
1200
 
1201
 
1202
 
1203
011000,5.RS,5.RT,16.IMMEDIATE:NORMAL:64::DADDI
1204
"daddi r, r, "
1205
*mipsIII:
1206
*mipsIV:
1207
*mipsV:
1208
*mips64:
1209
*mips64r2:
1210
*vr4100:
1211
*vr5000:
1212
{
1213
  check_u64 (SD_, instruction_0);
1214
  TRACE_ALU_INPUT2 (GPR[RS], EXTEND16 (IMMEDIATE));
1215
  {
1216
    ALU64_BEGIN (GPR[RS]);
1217
    ALU64_ADD (EXTEND16 (IMMEDIATE));
1218
    ALU64_END (GPR[RT]);   /* This checks for overflow.  */
1219
  }
1220
  TRACE_ALU_RESULT (GPR[RT]);
1221
}
1222
 
1223
 
1224
 
1225
:function:::void:do_daddiu:int rs, int rt, unsigned16 immediate
1226
{
1227
  TRACE_ALU_INPUT2 (GPR[rs], EXTEND16 (immediate));
1228
  GPR[rt] = GPR[rs] + EXTEND16 (immediate);
1229
  TRACE_ALU_RESULT (GPR[rt]);
1230
}
1231
 
1232
011001,5.RS,5.RT,16.IMMEDIATE:NORMAL:64::DADDIU
1233
"daddiu r, r, "
1234
*mipsIII:
1235
*mipsIV:
1236
*mipsV:
1237
*mips64:
1238
*mips64r2:
1239
*vr4100:
1240
*vr5000:
1241
{
1242
  check_u64 (SD_, instruction_0);
1243
  do_daddiu (SD_, RS, RT, IMMEDIATE);
1244
}
1245
 
1246
 
1247
 
1248
:function:::void:do_daddu:int rs, int rt, int rd
1249
{
1250
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1251
  GPR[rd] = GPR[rs] + GPR[rt];
1252
  TRACE_ALU_RESULT (GPR[rd]);
1253
}
1254
 
1255
000000,5.RS,5.RT,5.RD,00000,101101:SPECIAL:64::DADDU
1256
"daddu r, r, r"
1257
*mipsIII:
1258
*mipsIV:
1259
*mipsV:
1260
*mips64:
1261
*mips64r2:
1262
*vr4100:
1263
*vr5000:
1264
{
1265
  check_u64 (SD_, instruction_0);
1266
  do_daddu (SD_, RS, RT, RD);
1267
}
1268
 
1269
 
1270
 
1271
011100,5.RS,5.RT,5.RD,00000,100101:SPECIAL2:64::DCLO
1272
"dclo r, r"
1273
*mips64:
1274
*mips64r2:
1275
*vr5500:
1276
{
1277
  unsigned64 temp = GPR[RS];
1278
  unsigned32 i;
1279
  unsigned64 mask;
1280
  check_u64 (SD_, instruction_0);
1281
  if (RT != RD)
1282
    Unpredictable ();
1283
  TRACE_ALU_INPUT1 (GPR[RS]);
1284
  for (mask = ((unsigned64)1<<63), i = 0; i < 64; ++i)
1285
    {
1286
      if ((temp & mask) == 0)
1287
        break;
1288
      mask >>= 1;
1289
    }
1290
  GPR[RD] = EXTEND32 (i);
1291
  TRACE_ALU_RESULT (GPR[RD]);
1292
}
1293
 
1294
 
1295
 
1296
011100,5.RS,5.RT,5.RD,00000,100100:SPECIAL2:64::DCLZ
1297
"dclz r, r"
1298
*mips64:
1299
*mips64r2:
1300
*vr5500:
1301
{
1302
  unsigned64 temp = GPR[RS];
1303
  unsigned32 i;
1304
  unsigned64 mask;
1305
  check_u64 (SD_, instruction_0);
1306
  if (RT != RD)
1307
    Unpredictable ();
1308
  TRACE_ALU_INPUT1 (GPR[RS]);
1309
  for (mask = ((unsigned64)1<<63), i = 0; i < 64; ++i)
1310
    {
1311
      if ((temp & mask) != 0)
1312
        break;
1313
      mask >>= 1;
1314
    }
1315
  GPR[RD] = EXTEND32 (i);
1316
  TRACE_ALU_RESULT (GPR[RD]);
1317
}
1318
 
1319
 
1320
 
1321
:function:::void:do_ddiv:int rs, int rt
1322
{
1323
  check_div_hilo (SD_, HIHISTORY, LOHISTORY);
1324
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1325
  {
1326
    signed64 n = GPR[rs];
1327
    signed64 d = GPR[rt];
1328
    signed64 hi;
1329
    signed64 lo;
1330
    if (d == 0)
1331
      {
1332
        lo = SIGNED64 (0x8000000000000000);
1333
        hi = 0;
1334
      }
1335
    else if (d == -1 && n == SIGNED64 (0x8000000000000000))
1336
      {
1337
        lo = SIGNED64 (0x8000000000000000);
1338
        hi = 0;
1339
      }
1340
    else
1341
      {
1342
        lo = (n / d);
1343
        hi = (n % d);
1344
      }
1345
    HI = hi;
1346
    LO = lo;
1347
  }
1348
  TRACE_ALU_RESULT2 (HI, LO);
1349
}
1350
 
1351
000000,5.RS,5.RT,0000000000,011110:SPECIAL:64::DDIV
1352
"ddiv r, r"
1353
*mipsIII:
1354
*mipsIV:
1355
*mipsV:
1356
*mips64:
1357
*mips64r2:
1358
*vr4100:
1359
*vr5000:
1360
{
1361
  check_u64 (SD_, instruction_0);
1362
  do_ddiv (SD_, RS, RT);
1363
}
1364
 
1365
 
1366
 
1367
:function:::void:do_ddivu:int rs, int rt
1368
{
1369
  check_div_hilo (SD_, HIHISTORY, LOHISTORY);
1370
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1371
  {
1372
    unsigned64 n = GPR[rs];
1373
    unsigned64 d = GPR[rt];
1374
    unsigned64 hi;
1375
    unsigned64 lo;
1376
    if (d == 0)
1377
      {
1378
        lo = SIGNED64 (0x8000000000000000);
1379
        hi = 0;
1380
      }
1381
    else
1382
      {
1383
        lo = (n / d);
1384
        hi = (n % d);
1385
      }
1386
    HI = hi;
1387
    LO = lo;
1388
  }
1389
  TRACE_ALU_RESULT2 (HI, LO);
1390
}
1391
 
1392
000000,5.RS,5.RT,0000000000,011111:SPECIAL:64::DDIVU
1393
"ddivu r, r"
1394
*mipsIII:
1395
*mipsIV:
1396
*mipsV:
1397
*mips64:
1398
*mips64r2:
1399
*vr4100:
1400
*vr5000:
1401
{
1402
  check_u64 (SD_, instruction_0);
1403
  do_ddivu (SD_, RS, RT);
1404
}
1405
 
1406
:function:::void:do_div:int rs, int rt
1407
{
1408
  check_div_hilo (SD_, HIHISTORY, LOHISTORY);
1409
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1410
  {
1411
    signed32 n = GPR[rs];
1412
    signed32 d = GPR[rt];
1413
    if (d == 0)
1414
      {
1415
        LO = EXTEND32 (0x80000000);
1416
        HI = EXTEND32 (0);
1417
      }
1418
    else if (n == SIGNED32 (0x80000000) && d == -1)
1419
      {
1420
        LO = EXTEND32 (0x80000000);
1421
        HI = EXTEND32 (0);
1422
      }
1423
    else
1424
      {
1425
        LO = EXTEND32 (n / d);
1426
        HI = EXTEND32 (n % d);
1427
      }
1428
  }
1429
  TRACE_ALU_RESULT2 (HI, LO);
1430
}
1431
 
1432
000000,5.RS,5.RT,0000000000,011010:SPECIAL:32::DIV
1433
"div r, r"
1434
*mipsI:
1435
*mipsII:
1436
*mipsIII:
1437
*mipsIV:
1438
*mipsV:
1439
*mips32:
1440
*mips32r2:
1441
*mips64:
1442
*mips64r2:
1443
*vr4100:
1444
*vr5000:
1445
*r3900:
1446
{
1447
  do_div (SD_, RS, RT);
1448
}
1449
 
1450
 
1451
 
1452
:function:::void:do_divu:int rs, int rt
1453
{
1454
  check_div_hilo (SD_, HIHISTORY, LOHISTORY);
1455
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1456
  {
1457
    unsigned32 n = GPR[rs];
1458
    unsigned32 d = GPR[rt];
1459
    if (d == 0)
1460
      {
1461
        LO = EXTEND32 (0x80000000);
1462
        HI = EXTEND32 (0);
1463
      }
1464
    else
1465
      {
1466
        LO = EXTEND32 (n / d);
1467
        HI = EXTEND32 (n % d);
1468
      }
1469
  }
1470
  TRACE_ALU_RESULT2 (HI, LO);
1471
}
1472
 
1473
000000,5.RS,5.RT,0000000000,011011:SPECIAL:32::DIVU
1474
"divu r, r"
1475
*mipsI:
1476
*mipsII:
1477
*mipsIII:
1478
*mipsIV:
1479
*mipsV:
1480
*mips32:
1481
*mips32r2:
1482
*mips64:
1483
*mips64r2:
1484
*vr4100:
1485
*vr5000:
1486
*r3900:
1487
{
1488
  do_divu (SD_, RS, RT);
1489
}
1490
 
1491
 
1492
:function:::void:do_dmultx:int rs, int rt, int rd, int signed_p
1493
{
1494
  unsigned64 lo;
1495
  unsigned64 hi;
1496
  unsigned64 m00;
1497
  unsigned64 m01;
1498
  unsigned64 m10;
1499
  unsigned64 m11;
1500
  unsigned64 mid;
1501
  int sign;
1502
  unsigned64 op1 = GPR[rs];
1503
  unsigned64 op2 = GPR[rt];
1504
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
1505
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1506
  /* make signed multiply unsigned */
1507
  sign = 0;
1508
  if (signed_p)
1509
    {
1510
      if ((signed64) op1 < 0)
1511
        {
1512
          op1 = - op1;
1513
          ++sign;
1514
        }
1515
      if ((signed64) op2 < 0)
1516
        {
1517
          op2 = - op2;
1518
          ++sign;
1519
        }
1520
    }
1521
  /* multiply out the 4 sub products */
1522
  m00 = ((unsigned64) VL4_8 (op1) * (unsigned64) VL4_8 (op2));
1523
  m10 = ((unsigned64) VH4_8 (op1) * (unsigned64) VL4_8 (op2));
1524
  m01 = ((unsigned64) VL4_8 (op1) * (unsigned64) VH4_8 (op2));
1525
  m11 = ((unsigned64) VH4_8 (op1) * (unsigned64) VH4_8 (op2));
1526
  /* add the products */
1527
  mid = ((unsigned64) VH4_8 (m00)
1528
         + (unsigned64) VL4_8 (m10)
1529
         + (unsigned64) VL4_8 (m01));
1530
  lo = U8_4 (mid, m00);
1531
  hi = (m11
1532
        + (unsigned64) VH4_8 (mid)
1533
        + (unsigned64) VH4_8 (m01)
1534
        + (unsigned64) VH4_8 (m10));
1535
  /* fix the sign */
1536
  if (sign & 1)
1537
    {
1538
      lo = -lo;
1539
      if (lo == 0)
1540
        hi = -hi;
1541
      else
1542
        hi = -hi - 1;
1543
    }
1544
  /* save the result HI/LO (and a gpr) */
1545
  LO = lo;
1546
  HI = hi;
1547
  if (rd != 0)
1548
    GPR[rd] = lo;
1549
  TRACE_ALU_RESULT2 (HI, LO);
1550
}
1551
 
1552
:function:::void:do_dmult:int rs, int rt, int rd
1553
{
1554
  do_dmultx (SD_, rs, rt, rd, 1);
1555
}
1556
 
1557
000000,5.RS,5.RT,0000000000,011100:SPECIAL:64::DMULT
1558
"dmult r, r"
1559
*mipsIII:
1560
*mipsIV:
1561
*mipsV:
1562
*mips64:
1563
*mips64r2:
1564
*vr4100:
1565
{
1566
  check_u64 (SD_, instruction_0);
1567
  do_dmult (SD_, RS, RT, 0);
1568
}
1569
 
1570
000000,5.RS,5.RT,5.RD,00000,011100:SPECIAL:64::DMULT
1571
"dmult r, r":RD == 0
1572
"dmult r, r, r"
1573
*vr5000:
1574
{
1575
  check_u64 (SD_, instruction_0);
1576
  do_dmult (SD_, RS, RT, RD);
1577
}
1578
 
1579
 
1580
 
1581
:function:::void:do_dmultu:int rs, int rt, int rd
1582
{
1583
  do_dmultx (SD_, rs, rt, rd, 0);
1584
}
1585
 
1586
000000,5.RS,5.RT,0000000000,011101:SPECIAL:64::DMULTU
1587
"dmultu r, r"
1588
*mipsIII:
1589
*mipsIV:
1590
*mipsV:
1591
*mips64:
1592
*mips64r2:
1593
*vr4100:
1594
{
1595
  check_u64 (SD_, instruction_0);
1596
  do_dmultu (SD_, RS, RT, 0);
1597
}
1598
 
1599
000000,5.RS,5.RT,5.RD,00000,011101:SPECIAL:64::DMULTU
1600
"dmultu r, r, r":RD == 0
1601
"dmultu r, r"
1602
*vr5000:
1603
{
1604
  check_u64 (SD_, instruction_0);
1605
  do_dmultu (SD_, RS, RT, RD);
1606
}
1607
 
1608
 
1609
:function:::unsigned64:do_dror:unsigned64 x,unsigned64 y
1610
{
1611
  unsigned64 result;
1612
 
1613
  y &= 63;
1614
  TRACE_ALU_INPUT2 (x, y);
1615
  result = ROTR64 (x, y);
1616
  TRACE_ALU_RESULT (result);
1617
  return result;
1618
}
1619
 
1620
000000,00001,5.RT,5.RD,5.SHIFT,111010::64::DROR
1621
"dror r, r, "
1622
*mips64r2:
1623
*vr5400:
1624
*vr5500:
1625
{
1626
  check_u64 (SD_, instruction_0);
1627
  GPR[RD] = do_dror (SD_, GPR[RT], SHIFT);
1628
}
1629
 
1630
000000,00001,5.RT,5.RD,5.SHIFT,111110::64::DROR32
1631
"dror32 r, r, "
1632
*mips64r2:
1633
*vr5400:
1634
*vr5500:
1635
{
1636
  check_u64 (SD_, instruction_0);
1637
  GPR[RD] = do_dror (SD_, GPR[RT], SHIFT + 32);
1638
}
1639
 
1640
000000,5.RS,5.RT,5.RD,00001,010110::64::DRORV
1641
"drorv r, r, r"
1642
*mips64r2:
1643
*vr5400:
1644
*vr5500:
1645
{
1646
  check_u64 (SD_, instruction_0);
1647
  GPR[RD] = do_dror (SD_, GPR[RT], GPR[RS]);
1648
}
1649
 
1650
 
1651
:function:::void:do_dsll:int rt, int rd, int shift
1652
{
1653
  TRACE_ALU_INPUT2 (GPR[rt], shift);
1654
  GPR[rd] = GPR[rt] << shift;
1655
  TRACE_ALU_RESULT (GPR[rd]);
1656
}
1657
 
1658
000000,00000,5.RT,5.RD,5.SHIFT,111000:SPECIAL:64::DSLL
1659
"dsll r, r, "
1660
*mipsIII:
1661
*mipsIV:
1662
*mipsV:
1663
*mips64:
1664
*mips64r2:
1665
*vr4100:
1666
*vr5000:
1667
{
1668
  check_u64 (SD_, instruction_0);
1669
  do_dsll (SD_, RT, RD, SHIFT);
1670
}
1671
 
1672
 
1673
000000,00000,5.RT,5.RD,5.SHIFT,111100:SPECIAL:64::DSLL32
1674
"dsll32 r, r, "
1675
*mipsIII:
1676
*mipsIV:
1677
*mipsV:
1678
*mips64:
1679
*mips64r2:
1680
*vr4100:
1681
*vr5000:
1682
{
1683
  int s = 32 + SHIFT;
1684
  check_u64 (SD_, instruction_0);
1685
  TRACE_ALU_INPUT2 (GPR[RT], s);
1686
  GPR[RD] = GPR[RT] << s;
1687
  TRACE_ALU_RESULT (GPR[RD]);
1688
}
1689
 
1690
:function:::void:do_dsllv:int rs, int rt, int rd
1691
{
1692
  int s = MASKED64 (GPR[rs], 5, 0);
1693
  TRACE_ALU_INPUT2 (GPR[rt], s);
1694
  GPR[rd] = GPR[rt] << s;
1695
  TRACE_ALU_RESULT (GPR[rd]);
1696
}
1697
 
1698
000000,5.RS,5.RT,5.RD,00000,010100:SPECIAL:64::DSLLV
1699
"dsllv r, r, r"
1700
*mipsIII:
1701
*mipsIV:
1702
*mipsV:
1703
*mips64:
1704
*mips64r2:
1705
*vr4100:
1706
*vr5000:
1707
{
1708
  check_u64 (SD_, instruction_0);
1709
  do_dsllv (SD_, RS, RT, RD);
1710
}
1711
 
1712
:function:::void:do_dsra:int rt, int rd, int shift
1713
{
1714
  TRACE_ALU_INPUT2 (GPR[rt], shift);
1715
  GPR[rd] = ((signed64) GPR[rt]) >> shift;
1716
  TRACE_ALU_RESULT (GPR[rd]);
1717
}
1718
 
1719
 
1720
000000,00000,5.RT,5.RD,5.SHIFT,111011:SPECIAL:64::DSRA
1721
"dsra r, r, "
1722
*mipsIII:
1723
*mipsIV:
1724
*mipsV:
1725
*mips64:
1726
*mips64r2:
1727
*vr4100:
1728
*vr5000:
1729
{
1730
  check_u64 (SD_, instruction_0);
1731
  do_dsra (SD_, RT, RD, SHIFT);
1732
}
1733
 
1734
 
1735
000000,00000,5.RT,5.RD,5.SHIFT,111111:SPECIAL:64::DSRA32
1736
"dsra32 r, r, "
1737
*mipsIII:
1738
*mipsIV:
1739
*mipsV:
1740
*mips64:
1741
*mips64r2:
1742
*vr4100:
1743
*vr5000:
1744
{
1745
  int s = 32 + SHIFT;
1746
  check_u64 (SD_, instruction_0);
1747
  TRACE_ALU_INPUT2 (GPR[RT], s);
1748
  GPR[RD] = ((signed64) GPR[RT]) >> s;
1749
  TRACE_ALU_RESULT (GPR[RD]);
1750
}
1751
 
1752
 
1753
:function:::void:do_dsrav:int rs, int rt, int rd
1754
{
1755
  int s = MASKED64 (GPR[rs], 5, 0);
1756
  TRACE_ALU_INPUT2 (GPR[rt], s);
1757
  GPR[rd] = ((signed64) GPR[rt]) >> s;
1758
  TRACE_ALU_RESULT (GPR[rd]);
1759
}
1760
 
1761
000000,5.RS,5.RT,5.RD,00000,010111:SPECIAL:64::DSRAV
1762
"dsrav r, r, r"
1763
*mipsIII:
1764
*mipsIV:
1765
*mipsV:
1766
*mips64:
1767
*mips64r2:
1768
*vr4100:
1769
*vr5000:
1770
{
1771
  check_u64 (SD_, instruction_0);
1772
  do_dsrav (SD_, RS, RT, RD);
1773
}
1774
 
1775
:function:::void:do_dsrl:int rt, int rd, int shift
1776
{
1777
  TRACE_ALU_INPUT2 (GPR[rt], shift);
1778
  GPR[rd] = (unsigned64) GPR[rt] >> shift;
1779
  TRACE_ALU_RESULT (GPR[rd]);
1780
}
1781
 
1782
 
1783
000000,00000,5.RT,5.RD,5.SHIFT,111010:SPECIAL:64::DSRL
1784
"dsrl r, r, "
1785
*mipsIII:
1786
*mipsIV:
1787
*mipsV:
1788
*mips64:
1789
*mips64r2:
1790
*vr4100:
1791
*vr5000:
1792
{
1793
  check_u64 (SD_, instruction_0);
1794
  do_dsrl (SD_, RT, RD, SHIFT);
1795
}
1796
 
1797
 
1798
000000,00000,5.RT,5.RD,5.SHIFT,111110:SPECIAL:64::DSRL32
1799
"dsrl32 r, r, "
1800
*mipsIII:
1801
*mipsIV:
1802
*mipsV:
1803
*mips64:
1804
*mips64r2:
1805
*vr4100:
1806
*vr5000:
1807
{
1808
  int s = 32 + SHIFT;
1809
  check_u64 (SD_, instruction_0);
1810
  TRACE_ALU_INPUT2 (GPR[RT], s);
1811
  GPR[RD] = (unsigned64) GPR[RT] >> s;
1812
  TRACE_ALU_RESULT (GPR[RD]);
1813
}
1814
 
1815
 
1816
:function:::void:do_dsrlv:int rs, int rt, int rd
1817
{
1818
  int s = MASKED64 (GPR[rs], 5, 0);
1819
  TRACE_ALU_INPUT2 (GPR[rt], s);
1820
  GPR[rd] = (unsigned64) GPR[rt] >> s;
1821
  TRACE_ALU_RESULT (GPR[rd]);
1822
}
1823
 
1824
 
1825
 
1826
000000,5.RS,5.RT,5.RD,00000,010110:SPECIAL:64::DSRLV
1827
"dsrlv r, r, r"
1828
*mipsIII:
1829
*mipsIV:
1830
*mipsV:
1831
*mips64:
1832
*mips64r2:
1833
*vr4100:
1834
*vr5000:
1835
{
1836
  check_u64 (SD_, instruction_0);
1837
  do_dsrlv (SD_, RS, RT, RD);
1838
}
1839
 
1840
 
1841
000000,5.RS,5.RT,5.RD,00000,101110:SPECIAL:64::DSUB
1842
"dsub r, r, r"
1843
*mipsIII:
1844
*mipsIV:
1845
*mipsV:
1846
*mips64:
1847
*mips64r2:
1848
*vr4100:
1849
*vr5000:
1850
{
1851
  check_u64 (SD_, instruction_0);
1852
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
1853
  {
1854
    ALU64_BEGIN (GPR[RS]);
1855
    ALU64_SUB (GPR[RT]);
1856
    ALU64_END (GPR[RD]);   /* This checks for overflow.  */
1857
  }
1858
  TRACE_ALU_RESULT (GPR[RD]);
1859
}
1860
 
1861
 
1862
:function:::void:do_dsubu:int rs, int rt, int rd
1863
{
1864
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
1865
  GPR[rd] = GPR[rs] - GPR[rt];
1866
  TRACE_ALU_RESULT (GPR[rd]);
1867
}
1868
 
1869
000000,5.RS,5.RT,5.RD,00000,101111:SPECIAL:64::DSUBU
1870
"dsubu r, r, r"
1871
*mipsIII:
1872
*mipsIV:
1873
*mipsV:
1874
*mips64:
1875
*mips64r2:
1876
*vr4100:
1877
*vr5000:
1878
{
1879
  check_u64 (SD_, instruction_0);
1880
  do_dsubu (SD_, RS, RT, RD);
1881
}
1882
 
1883
 
1884
000010,26.INSTR_INDEX:NORMAL:32::J
1885
"j "
1886
*mipsI:
1887
*mipsII:
1888
*mipsIII:
1889
*mipsIV:
1890
*mipsV:
1891
*mips32:
1892
*mips32r2:
1893
*mips64:
1894
*mips64r2:
1895
*vr4100:
1896
*vr5000:
1897
*r3900:
1898
{
1899
  /* NOTE: The region used is that of the delay slot NIA and NOT the
1900
     current instruction */
1901
  address_word region = (NIA & MASK (63, 28));
1902
  DELAY_SLOT (region | (INSTR_INDEX << 2));
1903
}
1904
 
1905
 
1906
000011,26.INSTR_INDEX:NORMAL:32::JAL
1907
"jal "
1908
*mipsI:
1909
*mipsII:
1910
*mipsIII:
1911
*mipsIV:
1912
*mipsV:
1913
*mips32:
1914
*mips32r2:
1915
*mips64:
1916
*mips64r2:
1917
*vr4100:
1918
*vr5000:
1919
*r3900:
1920
{
1921
  /* NOTE: The region used is that of the delay slot and NOT the
1922
     current instruction */
1923
  address_word region = (NIA & MASK (63, 28));
1924
  GPR[31] = CIA + 8;
1925
  DELAY_SLOT (region | (INSTR_INDEX << 2));
1926
}
1927
 
1928
000000,5.RS,00000,5.RD,00000,001001:SPECIAL:32::JALR
1929
"jalr r":RD == 31
1930
"jalr r, r"
1931
*mipsI:
1932
*mipsII:
1933
*mipsIII:
1934
*mipsIV:
1935
*mipsV:
1936
*mips32:
1937
*mips32r2:
1938
*mips64:
1939
*mips64r2:
1940
*vr4100:
1941
*vr5000:
1942
*r3900:
1943
{
1944
  address_word temp = GPR[RS];
1945
  GPR[RD] = CIA + 8;
1946
  DELAY_SLOT (temp);
1947
}
1948
 
1949
000000,5.RS,00000,5.RD,10000,001001:SPECIAL:32::JALR_HB
1950
"jalr.hb r":RD == 31
1951
"jalr.hb r, r"
1952
*mips32r2:
1953
*mips64r2:
1954
{
1955
  address_word temp = GPR[RS];
1956
  GPR[RD] = CIA + 8;
1957
  DELAY_SLOT (temp);
1958
}
1959
 
1960
000000,5.RS,0000000000,00000,001000:SPECIAL:32::JR
1961
"jr r"
1962
*mipsI:
1963
*mipsII:
1964
*mipsIII:
1965
*mipsIV:
1966
*mipsV:
1967
*mips32:
1968
*mips32r2:
1969
*mips64:
1970
*mips64r2:
1971
*vr4100:
1972
*vr5000:
1973
*r3900:
1974
{
1975
  DELAY_SLOT (GPR[RS]);
1976
}
1977
 
1978
000000,5.RS,0000000000,10000,001000:SPECIAL:32::JR_HB
1979
"jr.hb r"
1980
*mips32r2:
1981
*mips64r2:
1982
{
1983
  DELAY_SLOT (GPR[RS]);
1984
}
1985
 
1986
:function:::unsigned_word:do_load:unsigned access, address_word base, address_word offset
1987
{
1988
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
1989
  address_word reverseendian = (ReverseEndian ? (mask ^ access) : 0);
1990
  address_word bigendiancpu = (BigEndianCPU ? (mask ^ access) : 0);
1991
  unsigned int byte;
1992
  address_word paddr;
1993
  int uncached;
1994
  unsigned64 memval;
1995
  address_word vaddr;
1996
 
1997
  vaddr = loadstore_ea (SD_, base, offset);
1998
  if ((vaddr & access) != 0)
1999
    {
2000
      SIM_CORE_SIGNAL (SD, STATE_CPU (SD, 0), cia, read_map, access+1, vaddr, read_transfer, sim_core_unaligned_signal);
2001
    }
2002
  AddressTranslation (vaddr, isDATA, isLOAD, &paddr, &uncached, isTARGET, isREAL);
2003
  paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
2004
  LoadMemory (&memval, NULL, uncached, access, paddr, vaddr, isDATA, isREAL);
2005
  byte = ((vaddr & mask) ^ bigendiancpu);
2006
  return (memval >> (8 * byte));
2007
}
2008
 
2009
:function:::unsigned_word:do_load_left:unsigned access, address_word base, address_word offset, unsigned_word rt
2010
{
2011
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
2012
  address_word reverseendian = (ReverseEndian ? -1 : 0);
2013
  address_word bigendiancpu = (BigEndianCPU ? -1 : 0);
2014
  unsigned int byte;
2015
  unsigned int word;
2016
  address_word paddr;
2017
  int uncached;
2018
  unsigned64 memval;
2019
  address_word vaddr;
2020
  int nr_lhs_bits;
2021
  int nr_rhs_bits;
2022
  unsigned_word lhs_mask;
2023
  unsigned_word temp;
2024
 
2025
  vaddr = loadstore_ea (SD_, base, offset);
2026
  AddressTranslation (vaddr, isDATA, isLOAD, &paddr, &uncached, isTARGET, isREAL);
2027
  paddr = (paddr ^ (reverseendian & mask));
2028
  if (BigEndianMem == 0)
2029
    paddr = paddr & ~access;
2030
 
2031
  /* compute where within the word/mem we are */
2032
  byte = ((vaddr ^ bigendiancpu) & access); /* 0..access */
2033
  word = ((vaddr ^ bigendiancpu) & (mask & ~access)) / (access + 1); /* 0..1 */
2034
  nr_lhs_bits = 8 * byte + 8;
2035
  nr_rhs_bits = 8 * access - 8 * byte;
2036
  /* nr_lhs_bits + nr_rhs_bits == 8 * (accesss + 1) */
2037
 
2038
  /* fprintf (stderr, "l[wd]l: 0x%08lx%08lx 0x%08lx%08lx %d:%d %d+%d\n",
2039
           (long) ((unsigned64) vaddr >> 32), (long) vaddr,
2040
           (long) ((unsigned64) paddr >> 32), (long) paddr,
2041
           word, byte, nr_lhs_bits, nr_rhs_bits); */
2042
 
2043
  LoadMemory (&memval, NULL, uncached, byte, paddr, vaddr, isDATA, isREAL);
2044
  if (word == 0)
2045
    {
2046
      /* GPR{31..32-NR_LHS_BITS} = memval{NR_LHS_BITS-1..0} */
2047
      temp = (memval << nr_rhs_bits);
2048
    }
2049
  else
2050
    {
2051
      /* GPR{31..32-NR_LHS_BITS = memval{32+NR_LHS_BITS..32} */
2052
      temp = (memval >> nr_lhs_bits);
2053
    }
2054
  lhs_mask = LSMASK (nr_lhs_bits + nr_rhs_bits - 1, nr_rhs_bits);
2055
  rt = (rt & ~lhs_mask) | (temp & lhs_mask);
2056
 
2057
  /* fprintf (stderr, "l[wd]l: 0x%08lx%08lx -> 0x%08lx%08lx & 0x%08lx%08lx -> 0x%08lx%08lx\n",
2058
           (long) ((unsigned64) memval >> 32), (long) memval,
2059
           (long) ((unsigned64) temp >> 32), (long) temp,
2060
           (long) ((unsigned64) lhs_mask >> 32), (long) lhs_mask,
2061
           (long) (rt >> 32), (long) rt); */
2062
  return rt;
2063
}
2064
 
2065
:function:::unsigned_word:do_load_right:unsigned access, address_word base, address_word offset, unsigned_word rt
2066
{
2067
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
2068
  address_word reverseendian = (ReverseEndian ? -1 : 0);
2069
  address_word bigendiancpu = (BigEndianCPU ? -1 : 0);
2070
  unsigned int byte;
2071
  address_word paddr;
2072
  int uncached;
2073
  unsigned64 memval;
2074
  address_word vaddr;
2075
 
2076
  vaddr = loadstore_ea (SD_, base, offset);
2077
  AddressTranslation (vaddr, isDATA, isLOAD, &paddr, &uncached, isTARGET, isREAL);
2078
  /* NOTE: SPEC is wrong, has `BigEndianMem == 0' not `BigEndianMem != 0' */
2079
  paddr = (paddr ^ (reverseendian & mask));
2080
  if (BigEndianMem != 0)
2081
    paddr = paddr & ~access;
2082
  byte = ((vaddr & mask) ^ (bigendiancpu & mask));
2083
  /* NOTE: SPEC is wrong, had `byte' not `access - byte'.  See SW. */
2084
  LoadMemory (&memval, NULL, uncached, access - (access & byte), paddr, vaddr, isDATA, isREAL);
2085
  /* printf ("lr: 0x%08lx %d@0x%08lx 0x%08lx\n",
2086
     (long) paddr, byte, (long) paddr, (long) memval); */
2087
  {
2088
    unsigned_word screen = LSMASK (8 * (access - (byte & access) + 1) - 1, 0);
2089
    rt &= ~screen;
2090
    rt |= (memval >> (8 * byte)) & screen;
2091
  }
2092
  return rt;
2093
}
2094
 
2095
 
2096
100000,5.BASE,5.RT,16.OFFSET:NORMAL:32::LB
2097
"lb r, (r)"
2098
*mipsI:
2099
*mipsII:
2100
*mipsIII:
2101
*mipsIV:
2102
*mipsV:
2103
*mips32:
2104
*mips32r2:
2105
*mips64:
2106
*mips64r2:
2107
*vr4100:
2108
*vr5000:
2109
*r3900:
2110
{
2111
  GPR[RT] = EXTEND8 (do_load (SD_, AccessLength_BYTE, GPR[BASE], EXTEND16 (OFFSET)));
2112
}
2113
 
2114
 
2115
100100,5.BASE,5.RT,16.OFFSET:NORMAL:32::LBU
2116
"lbu r, (r)"
2117
*mipsI:
2118
*mipsII:
2119
*mipsIII:
2120
*mipsIV:
2121
*mipsV:
2122
*mips32:
2123
*mips32r2:
2124
*mips64:
2125
*mips64r2:
2126
*vr4100:
2127
*vr5000:
2128
*r3900:
2129
{
2130
  GPR[RT] = do_load (SD_, AccessLength_BYTE, GPR[BASE], EXTEND16 (OFFSET));
2131
}
2132
 
2133
 
2134
110111,5.BASE,5.RT,16.OFFSET:NORMAL:64::LD
2135
"ld r, (r)"
2136
*mipsIII:
2137
*mipsIV:
2138
*mipsV:
2139
*mips64:
2140
*mips64r2:
2141
*vr4100:
2142
*vr5000:
2143
{
2144
  check_u64 (SD_, instruction_0);
2145
  GPR[RT] = EXTEND64 (do_load (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET)));
2146
}
2147
 
2148
 
2149
1101,ZZ!0!1!3,5.BASE,5.RT,16.OFFSET:NORMAL:64::LDCz
2150
"ldc r, (r)"
2151
*mipsII:
2152
*mipsIII:
2153
*mipsIV:
2154
*mipsV:
2155
*mips32:
2156
*mips32r2:
2157
*mips64:
2158
*mips64r2:
2159
*vr4100:
2160
*vr5000:
2161
*r3900:
2162
{
2163
  COP_LD (ZZ, RT, do_load (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET)));
2164
}
2165
 
2166
 
2167
 
2168
 
2169
011010,5.BASE,5.RT,16.OFFSET:NORMAL:64::LDL
2170
"ldl r, (r)"
2171
*mipsIII:
2172
*mipsIV:
2173
*mipsV:
2174
*mips64:
2175
*mips64r2:
2176
*vr4100:
2177
*vr5000:
2178
{
2179
  check_u64 (SD_, instruction_0);
2180
  GPR[RT] = do_load_left (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
2181
}
2182
 
2183
 
2184
011011,5.BASE,5.RT,16.OFFSET:NORMAL:64::LDR
2185
"ldr r, (r)"
2186
*mipsIII:
2187
*mipsIV:
2188
*mipsV:
2189
*mips64:
2190
*mips64r2:
2191
*vr4100:
2192
*vr5000:
2193
{
2194
  check_u64 (SD_, instruction_0);
2195
  GPR[RT] = do_load_right (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
2196
}
2197
 
2198
 
2199
100001,5.BASE,5.RT,16.OFFSET:NORMAL:32::LH
2200
"lh r, (r)"
2201
*mipsI:
2202
*mipsII:
2203
*mipsIII:
2204
*mipsIV:
2205
*mipsV:
2206
*mips32:
2207
*mips32r2:
2208
*mips64:
2209
*mips64r2:
2210
*vr4100:
2211
*vr5000:
2212
*r3900:
2213
{
2214
  GPR[RT] = EXTEND16 (do_load (SD_, AccessLength_HALFWORD, GPR[BASE], EXTEND16 (OFFSET)));
2215
}
2216
 
2217
 
2218
100101,5.BASE,5.RT,16.OFFSET:NORMAL:32::LHU
2219
"lhu r, (r)"
2220
*mipsI:
2221
*mipsII:
2222
*mipsIII:
2223
*mipsIV:
2224
*mipsV:
2225
*mips32:
2226
*mips32r2:
2227
*mips64:
2228
*mips64r2:
2229
*vr4100:
2230
*vr5000:
2231
*r3900:
2232
{
2233
  GPR[RT] = do_load (SD_, AccessLength_HALFWORD, GPR[BASE], EXTEND16 (OFFSET));
2234
}
2235
 
2236
 
2237
110000,5.BASE,5.RT,16.OFFSET:NORMAL:32::LL
2238
"ll r, (r)"
2239
*mipsII:
2240
*mipsIII:
2241
*mipsIV:
2242
*mipsV:
2243
*mips32:
2244
*mips32r2:
2245
*mips64:
2246
*mips64r2:
2247
*vr4100:
2248
*vr5000:
2249
{
2250
  address_word base = GPR[BASE];
2251
  address_word offset = EXTEND16 (OFFSET);
2252
  {
2253
    address_word vaddr = loadstore_ea (SD_, base, offset);
2254
    address_word paddr;
2255
    int uncached;
2256
    if ((vaddr & 3) != 0)
2257
      {
2258
        SIM_CORE_SIGNAL (SD, CPU, cia, read_map, 4, vaddr, read_transfer, sim_core_unaligned_signal);
2259
      }
2260
    else
2261
      {
2262
        if (AddressTranslation(vaddr,isDATA,isLOAD,&paddr,&uncached,isTARGET,isREAL))
2263
          {
2264
            unsigned64 memval = 0;
2265
            unsigned64 memval1 = 0;
2266
            unsigned64 mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
2267
            unsigned int shift = 2;
2268
            unsigned int reverse = (ReverseEndian ? (mask >> shift) : 0);
2269
            unsigned int bigend = (BigEndianCPU ? (mask >> shift) : 0);
2270
            unsigned int byte;
2271
            paddr = ((paddr & ~mask) | ((paddr & mask) ^ (reverse << shift)));
2272
            LoadMemory(&memval,&memval1,uncached,AccessLength_WORD,paddr,vaddr,isDATA,isREAL);
2273
            byte = ((vaddr & mask) ^ (bigend << shift));
2274
            GPR[RT] = EXTEND32 (memval >> (8 * byte));
2275
            LLBIT = 1;
2276
          }
2277
      }
2278
  }
2279
}
2280
 
2281
 
2282
110100,5.BASE,5.RT,16.OFFSET:NORMAL:64::LLD
2283
"lld r, (r)"
2284
*mipsIII:
2285
*mipsIV:
2286
*mipsV:
2287
*mips64:
2288
*mips64r2:
2289
*vr4100:
2290
*vr5000:
2291
{
2292
  address_word base = GPR[BASE];
2293
  address_word offset = EXTEND16 (OFFSET);
2294
  check_u64 (SD_, instruction_0);
2295
  {
2296
    address_word vaddr = loadstore_ea (SD_, base, offset);
2297
    address_word paddr;
2298
    int uncached;
2299
    if ((vaddr & 7) != 0)
2300
      {
2301
        SIM_CORE_SIGNAL (SD, CPU, cia, read_map, 8, vaddr, read_transfer, sim_core_unaligned_signal);
2302
      }
2303
    else
2304
      {
2305
        if (AddressTranslation(vaddr,isDATA,isLOAD,&paddr,&uncached,isTARGET,isREAL))
2306
          {
2307
            unsigned64 memval = 0;
2308
            unsigned64 memval1 = 0;
2309
            LoadMemory(&memval,&memval1,uncached,AccessLength_DOUBLEWORD,paddr,vaddr,isDATA,isREAL);
2310
            GPR[RT] = memval;
2311
            LLBIT = 1;
2312
          }
2313
      }
2314
  }
2315
}
2316
 
2317
 
2318
001111,00000,5.RT,16.IMMEDIATE:NORMAL:32::LUI
2319
"lui r, %#lx"
2320
*mipsI:
2321
*mipsII:
2322
*mipsIII:
2323
*mipsIV:
2324
*mipsV:
2325
*mips32:
2326
*mips32r2:
2327
*mips64:
2328
*mips64r2:
2329
*vr4100:
2330
*vr5000:
2331
*r3900:
2332
{
2333
  TRACE_ALU_INPUT1 (IMMEDIATE);
2334
  GPR[RT] = EXTEND32 (IMMEDIATE << 16);
2335
  TRACE_ALU_RESULT (GPR[RT]);
2336
}
2337
 
2338
 
2339
100011,5.BASE,5.RT,16.OFFSET:NORMAL:32::LW
2340
"lw r, (r)"
2341
*mipsI:
2342
*mipsII:
2343
*mipsIII:
2344
*mipsIV:
2345
*mipsV:
2346
*mips32:
2347
*mips32r2:
2348
*mips64:
2349
*mips64r2:
2350
*vr4100:
2351
*vr5000:
2352
*r3900:
2353
{
2354
  GPR[RT] = EXTEND32 (do_load (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET)));
2355
}
2356
 
2357
 
2358
1100,ZZ!0!1!3,5.BASE,5.RT,16.OFFSET:NORMAL:32::LWCz
2359
"lwc r, (r)"
2360
*mipsI:
2361
*mipsII:
2362
*mipsIII:
2363
*mipsIV:
2364
*mipsV:
2365
*mips32:
2366
*mips32r2:
2367
*mips64:
2368
*mips64r2:
2369
*vr4100:
2370
*vr5000:
2371
*r3900:
2372
{
2373
  COP_LW (ZZ, RT, do_load (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET)));
2374
}
2375
 
2376
 
2377
100010,5.BASE,5.RT,16.OFFSET:NORMAL:32::LWL
2378
"lwl r, (r)"
2379
*mipsI:
2380
*mipsII:
2381
*mipsIII:
2382
*mipsIV:
2383
*mipsV:
2384
*mips32:
2385
*mips32r2:
2386
*mips64:
2387
*mips64r2:
2388
*vr4100:
2389
*vr5000:
2390
*r3900:
2391
{
2392
  GPR[RT] = EXTEND32 (do_load_left (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]));
2393
}
2394
 
2395
 
2396
100110,5.BASE,5.RT,16.OFFSET:NORMAL:32::LWR
2397
"lwr r, (r)"
2398
*mipsI:
2399
*mipsII:
2400
*mipsIII:
2401
*mipsIV:
2402
*mipsV:
2403
*mips32:
2404
*mips32r2:
2405
*mips64:
2406
*mips64r2:
2407
*vr4100:
2408
*vr5000:
2409
*r3900:
2410
{
2411
  GPR[RT] = EXTEND32 (do_load_right (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]));
2412
}
2413
 
2414
 
2415
100111,5.BASE,5.RT,16.OFFSET:NORMAL:64::LWU
2416
"lwu r, (r)"
2417
*mipsIII:
2418
*mipsIV:
2419
*mipsV:
2420
*mips64:
2421
*mips64r2:
2422
*vr4100:
2423
*vr5000:
2424
{
2425
  check_u64 (SD_, instruction_0);
2426
  GPR[RT] = do_load (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET));
2427
}
2428
 
2429
 
2430
 
2431
011100,5.RS,5.RT,00000,00000,000000:SPECIAL2:32::MADD
2432
"madd r, r"
2433
*mips32:
2434
*mips64:
2435
*vr5500:
2436
{
2437
  signed64 temp;
2438
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2439
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2440
    Unpredictable ();
2441
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2442
  temp = (U8_4 (VL4_8 (HI), VL4_8 (LO))
2443
          + ((signed64) EXTEND32 (GPR[RT]) * (signed64) EXTEND32 (GPR[RS])));
2444
  LO = EXTEND32 (temp);
2445
  HI = EXTEND32 (VH4_8 (temp));
2446
  TRACE_ALU_RESULT2 (HI, LO);
2447
}
2448
 
2449
 
2450
011100,5.RS,5.RT,000,2.AC,00000,000000:SPECIAL2:32::MADD
2451
"madd r, r":AC == 0
2452
"madd ac, r, r"
2453
*mips32r2:
2454
*mips64r2:
2455
*dsp2:
2456
{
2457
  signed64 temp;
2458
  if (AC == 0)
2459
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2460
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2461
    Unpredictable ();
2462
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2463
  temp = (U8_4 (VL4_8 (DSPHI(AC)), VL4_8 (DSPLO(AC)))
2464
          + ((signed64) EXTEND32 (GPR[RT]) * (signed64) EXTEND32 (GPR[RS])));
2465
  DSPLO(AC) = EXTEND32 (temp);
2466
  DSPHI(AC) = EXTEND32 (VH4_8 (temp));
2467
  if (AC == 0)
2468
    TRACE_ALU_RESULT2 (HI, LO);
2469
}
2470
 
2471
 
2472
011100,5.RS,5.RT,00000,00000,000001:SPECIAL2:32::MADDU
2473
"maddu r, r"
2474
*mips32:
2475
*mips64:
2476
*vr5500:
2477
{
2478
  unsigned64 temp;
2479
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2480
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2481
    Unpredictable ();
2482
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2483
  temp = (U8_4 (VL4_8 (HI), VL4_8 (LO))
2484
          + ((unsigned64) VL4_8 (GPR[RS]) * (unsigned64) VL4_8 (GPR[RT])));
2485
  ACX += U8_4 (VL4_8 (HI), VL4_8 (LO)) < temp;  /* SmartMIPS */
2486
  LO = EXTEND32 (temp);
2487
  HI = EXTEND32 (VH4_8 (temp));
2488
  TRACE_ALU_RESULT2 (HI, LO);
2489
}
2490
 
2491
 
2492
011100,5.RS,5.RT,000,2.AC,00000,000001:SPECIAL2:32::MADDU
2493
"maddu r, r":AC == 0
2494
"maddu ac, r, r"
2495
*mips32r2:
2496
*mips64r2:
2497
*dsp2:
2498
{
2499
  unsigned64 temp;
2500
  if (AC == 0)
2501
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2502
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2503
    Unpredictable ();
2504
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2505
  temp = (U8_4 (VL4_8 (DSPHI(AC)), VL4_8 (DSPLO(AC)))
2506
          + ((unsigned64) VL4_8 (GPR[RS]) * (unsigned64) VL4_8 (GPR[RT])));
2507
  if (AC == 0)
2508
    ACX += U8_4 (VL4_8 (HI), VL4_8 (LO)) < temp;  /* SmartMIPS */
2509
  DSPLO(AC) = EXTEND32 (temp);
2510
  DSPHI(AC) = EXTEND32 (VH4_8 (temp));
2511
  if (AC == 0)
2512
    TRACE_ALU_RESULT2 (HI, LO);
2513
}
2514
 
2515
 
2516
:function:::void:do_mfhi:int rd
2517
{
2518
  check_mf_hilo (SD_, HIHISTORY, LOHISTORY);
2519
  TRACE_ALU_INPUT1 (HI);
2520
  GPR[rd] = HI;
2521
  TRACE_ALU_RESULT (GPR[rd]);
2522
}
2523
 
2524
000000,0000000000,5.RD,00000,010000:SPECIAL:32::MFHI
2525
"mfhi r"
2526
*mipsI:
2527
*mipsII:
2528
*mipsIII:
2529
*mipsIV:
2530
*mipsV:
2531
*vr4100:
2532
*vr5000:
2533
*r3900:
2534
*mips32:
2535
*mips64:
2536
{
2537
  do_mfhi (SD_, RD);
2538
}
2539
 
2540
 
2541
000000,000,2.AC,00000,5.RD,00000,010000:SPECIAL:32::MFHI
2542
"mfhi r":AC == 0
2543
"mfhi r, ac"
2544
*mips32r2:
2545
*mips64r2:
2546
*dsp:
2547
{
2548
  if (AC == 0)
2549
    do_mfhi (SD_, RD);
2550
  else
2551
    GPR[RD] = DSPHI(AC);
2552
}
2553
 
2554
 
2555
:function:::void:do_mflo:int rd
2556
{
2557
  check_mf_hilo (SD_, LOHISTORY, HIHISTORY);
2558
  TRACE_ALU_INPUT1 (LO);
2559
  GPR[rd] = LO;
2560
  TRACE_ALU_RESULT (GPR[rd]);
2561
}
2562
 
2563
000000,0000000000,5.RD,00000,010010:SPECIAL:32::MFLO
2564
"mflo r"
2565
*mipsI:
2566
*mipsII:
2567
*mipsIII:
2568
*mipsIV:
2569
*mipsV:
2570
*vr4100:
2571
*vr5000:
2572
*r3900:
2573
*mips32:
2574
*mips64:
2575
{
2576
  do_mflo (SD_, RD);
2577
}
2578
 
2579
 
2580
000000,000,2.AC,00000,5.RD,00000,010010:SPECIAL:32::MFLO
2581
"mflo r":AC == 0
2582
"mflo r, ac"
2583
*mips32r2:
2584
*mips64r2:
2585
*dsp:
2586
{
2587
  if (AC == 0)
2588
    do_mflo (SD_, RD);
2589
  else
2590
    GPR[RD] = DSPLO(AC);
2591
}
2592
 
2593
 
2594
000000,5.RS,5.RT,5.RD,00000,001011:SPECIAL:32::MOVN
2595
"movn r, r, r"
2596
*mipsIV:
2597
*mipsV:
2598
*mips32:
2599
*mips32r2:
2600
*mips64:
2601
*mips64r2:
2602
*vr5000:
2603
{
2604
  if (GPR[RT] != 0)
2605
    {
2606
      GPR[RD] = GPR[RS];
2607
      TRACE_ALU_RESULT (GPR[RD]);
2608
    }
2609
}
2610
 
2611
 
2612
 
2613
000000,5.RS,5.RT,5.RD,00000,001010:SPECIAL:32::MOVZ
2614
"movz r, r, r"
2615
*mipsIV:
2616
*mipsV:
2617
*mips32:
2618
*mips32r2:
2619
*mips64:
2620
*mips64r2:
2621
*vr5000:
2622
{
2623
  if (GPR[RT] == 0)
2624
    {
2625
      GPR[RD] = GPR[RS];
2626
      TRACE_ALU_RESULT (GPR[RD]);
2627
    }
2628
}
2629
 
2630
 
2631
 
2632
011100,5.RS,5.RT,00000,00000,000100:SPECIAL2:32::MSUB
2633
"msub r, r"
2634
*mips32:
2635
*mips64:
2636
*vr5500:
2637
{
2638
  signed64 temp;
2639
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2640
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2641
    Unpredictable ();
2642
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2643
  temp = (U8_4 (VL4_8 (HI), VL4_8 (LO))
2644
          - ((signed64) EXTEND32 (GPR[RT]) * (signed64) EXTEND32 (GPR[RS])));
2645
  LO = EXTEND32 (temp);
2646
  HI = EXTEND32 (VH4_8 (temp));
2647
  TRACE_ALU_RESULT2 (HI, LO);
2648
}
2649
 
2650
 
2651
011100,5.RS,5.RT,000,2.AC,00000,000100:SPECIAL2:32::MSUB
2652
"msub r, r":AC == 0
2653
"msub ac, r, r"
2654
*mips32r2:
2655
*mips64r2:
2656
*dsp2:
2657
{
2658
  signed64 temp;
2659
  if (AC == 0)
2660
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2661
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2662
    Unpredictable ();
2663
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2664
  temp = (U8_4 (VL4_8 (DSPHI(AC)), VL4_8 (DSPLO(AC)))
2665
          - ((signed64) EXTEND32 (GPR[RT]) * (signed64) EXTEND32 (GPR[RS])));
2666
  DSPLO(AC) = EXTEND32 (temp);
2667
  DSPHI(AC) = EXTEND32 (VH4_8 (temp));
2668
  if (AC == 0)
2669
    TRACE_ALU_RESULT2 (HI, LO);
2670
}
2671
 
2672
 
2673
011100,5.RS,5.RT,00000,00000,000101:SPECIAL2:32::MSUBU
2674
"msubu r, r"
2675
*mips32:
2676
*mips64:
2677
*vr5500:
2678
{
2679
  unsigned64 temp;
2680
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2681
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2682
    Unpredictable ();
2683
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2684
  temp = (U8_4 (VL4_8 (HI), VL4_8 (LO))
2685
          - ((unsigned64) VL4_8 (GPR[RS]) * (unsigned64) VL4_8 (GPR[RT])));
2686
  LO = EXTEND32 (temp);
2687
  HI = EXTEND32 (VH4_8 (temp));
2688
  TRACE_ALU_RESULT2 (HI, LO);
2689
}
2690
 
2691
 
2692
011100,5.RS,5.RT,000,2.AC,00000,000101:SPECIAL2:32::MSUBU
2693
"msubu r, r":AC == 0
2694
"msubu ac, r, r"
2695
*mips32r2:
2696
*mips64r2:
2697
*dsp2:
2698
{
2699
  unsigned64 temp;
2700
  if (AC == 0)
2701
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2702
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2703
    Unpredictable ();
2704
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2705
  temp = (U8_4 (VL4_8 (DSPHI(AC)), VL4_8 (DSPLO(AC)))
2706
          - ((unsigned64) VL4_8 (GPR[RS]) * (unsigned64) VL4_8 (GPR[RT])));
2707
  DSPLO(AC) = EXTEND32 (temp);
2708
  DSPHI(AC) = EXTEND32 (VH4_8 (temp));
2709
  if (AC == 0)
2710
    TRACE_ALU_RESULT2 (HI, LO);
2711
}
2712
 
2713
 
2714
000000,5.RS,000000000000000,010001:SPECIAL:32::MTHI
2715
"mthi r"
2716
*mipsI:
2717
*mipsII:
2718
*mipsIII:
2719
*mipsIV:
2720
*mipsV:
2721
*vr4100:
2722
*vr5000:
2723
*r3900:
2724
*mips32:
2725
*mips64:
2726
{
2727
  check_mt_hilo (SD_, HIHISTORY);
2728
  HI = GPR[RS];
2729
}
2730
 
2731
 
2732
000000,5.RS,00000,000,2.AC,00000,010001:SPECIAL:32::MTHI
2733
"mthi r":AC == 0
2734
"mthi r, ac"
2735
*mips32r2:
2736
*mips64r2:
2737
*dsp:
2738
{
2739
  if (AC == 0)
2740
    check_mt_hilo (SD_, HIHISTORY);
2741
  DSPHI(AC) = GPR[RS];
2742
}
2743
 
2744
 
2745
000000,5.RS,000000000000000,010011:SPECIAL:32::MTLO
2746
"mtlo r"
2747
*mipsI:
2748
*mipsII:
2749
*mipsIII:
2750
*mipsIV:
2751
*mipsV:
2752
*vr4100:
2753
*vr5000:
2754
*r3900:
2755
*mips32:
2756
*mips64:
2757
{
2758
  check_mt_hilo (SD_, LOHISTORY);
2759
  LO = GPR[RS];
2760
}
2761
 
2762
 
2763
000000,5.RS,00000,000,2.AC,00000,010011:SPECIAL:32::MTLO
2764
"mtlo r":AC == 0
2765
"mtlo r, ac"
2766
*mips32r2:
2767
*mips64r2:
2768
*dsp:
2769
{
2770
  if (AC == 0)
2771
    check_mt_hilo (SD_, LOHISTORY);
2772
  DSPLO(AC) = GPR[RS];
2773
}
2774
 
2775
 
2776
011100,5.RS,5.RT,5.RD,00000,000010:SPECIAL2:32::MUL
2777
"mul r, r, r"
2778
*mips32:
2779
*mips32r2:
2780
*mips64:
2781
*mips64r2:
2782
*vr5500:
2783
{
2784
  signed64 prod;
2785
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2786
    Unpredictable ();
2787
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2788
  prod = (((signed64)(signed32) GPR[RS])
2789
          * ((signed64)(signed32) GPR[RT]));
2790
  GPR[RD] = EXTEND32 (VL4_8 (prod));
2791
  TRACE_ALU_RESULT (GPR[RD]);
2792
}
2793
 
2794
 
2795
 
2796
:function:::void:do_mult:int rs, int rt, int rd
2797
{
2798
  signed64 prod;
2799
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2800
  if (NotWordValue (GPR[rs]) || NotWordValue (GPR[rt]))
2801
    Unpredictable ();
2802
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
2803
  prod = (((signed64)(signed32) GPR[rs])
2804
          * ((signed64)(signed32) GPR[rt]));
2805
  LO = EXTEND32 (VL4_8 (prod));
2806
  HI = EXTEND32 (VH4_8 (prod));
2807
  ACX = 0;  /* SmartMIPS */
2808
  if (rd != 0)
2809
    GPR[rd] = LO;
2810
  TRACE_ALU_RESULT2 (HI, LO);
2811
}
2812
 
2813
000000,5.RS,5.RT,0000000000,011000:SPECIAL:32::MULT
2814
"mult r, r"
2815
*mipsI:
2816
*mipsII:
2817
*mipsIII:
2818
*mipsIV:
2819
*mipsV:
2820
*mips32:
2821
*mips64:
2822
*vr4100:
2823
{
2824
  do_mult (SD_, RS, RT, 0);
2825
}
2826
 
2827
 
2828
000000,5.RS,5.RT,000,2.AC,00000,011000:SPECIAL:32::MULT
2829
"mult r, r":AC == 0
2830
"mult ac, r, r"
2831
*mips32r2:
2832
*mips64r2:
2833
*dsp2:
2834
{
2835
  signed64 prod;
2836
  if (AC == 0)
2837
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2838
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2839
    Unpredictable ();
2840
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2841
  prod = ((signed64)(signed32) GPR[RS])
2842
          * ((signed64)(signed32) GPR[RT]);
2843
  DSPLO(AC) = EXTEND32 (VL4_8 (prod));
2844
  DSPHI(AC) = EXTEND32 (VH4_8 (prod));
2845
  if (AC == 0)
2846
    {
2847
      ACX = 0;  /* SmartMIPS */
2848
      TRACE_ALU_RESULT2 (HI, LO);
2849
    }
2850
}
2851
 
2852
 
2853
000000,5.RS,5.RT,5.RD,00000,011000:SPECIAL:32::MULT
2854
"mult r, r":RD == 0
2855
"mult r, r, r"
2856
*vr5000:
2857
*r3900:
2858
{
2859
  do_mult (SD_, RS, RT, RD);
2860
}
2861
 
2862
 
2863
:function:::void:do_multu:int rs, int rt, int rd
2864
{
2865
  unsigned64 prod;
2866
  check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2867
  if (NotWordValue (GPR[rs]) || NotWordValue (GPR[rt]))
2868
    Unpredictable ();
2869
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
2870
  prod = (((unsigned64)(unsigned32) GPR[rs])
2871
          * ((unsigned64)(unsigned32) GPR[rt]));
2872
  LO = EXTEND32 (VL4_8 (prod));
2873
  HI = EXTEND32 (VH4_8 (prod));
2874
  if (rd != 0)
2875
    GPR[rd] = LO;
2876
  TRACE_ALU_RESULT2 (HI, LO);
2877
}
2878
 
2879
000000,5.RS,5.RT,0000000000,011001:SPECIAL:32::MULTU
2880
"multu r, r"
2881
*mipsI:
2882
*mipsII:
2883
*mipsIII:
2884
*mipsIV:
2885
*mipsV:
2886
*mips32:
2887
*mips64:
2888
*vr4100:
2889
{
2890
  do_multu (SD_, RS, RT, 0);
2891
}
2892
 
2893
 
2894
000000,5.RS,5.RT,000,2.AC,00000,011001:SPECIAL:32::MULTU
2895
"multu r, r":AC == 0
2896
"multu r, r"
2897
*mips32r2:
2898
*mips64r2:
2899
*dsp2:
2900
{
2901
  unsigned64 prod;
2902
  if (AC == 0)
2903
    check_mult_hilo (SD_, HIHISTORY, LOHISTORY);
2904
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
2905
    Unpredictable ();
2906
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
2907
  prod = ((unsigned64)(unsigned32) GPR[RS])
2908
          * ((unsigned64)(unsigned32) GPR[RT]);
2909
  DSPLO(AC) = EXTEND32 (VL4_8 (prod));
2910
  DSPHI(AC) = EXTEND32 (VH4_8 (prod));
2911
  if (AC == 0)
2912
    TRACE_ALU_RESULT2 (HI, LO);
2913
}
2914
 
2915
 
2916
000000,5.RS,5.RT,5.RD,00000,011001:SPECIAL:32::MULTU
2917
"multu r, r":RD == 0
2918
"multu r, r, r"
2919
*vr5000:
2920
*r3900:
2921
{
2922
  do_multu (SD_, RS, RT, RD);
2923
}
2924
 
2925
 
2926
:function:::void:do_nor:int rs, int rt, int rd
2927
{
2928
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
2929
  GPR[rd] = ~ (GPR[rs] | GPR[rt]);
2930
  TRACE_ALU_RESULT (GPR[rd]);
2931
}
2932
 
2933
000000,5.RS,5.RT,5.RD,00000,100111:SPECIAL:32::NOR
2934
"nor r, r, r"
2935
*mipsI:
2936
*mipsII:
2937
*mipsIII:
2938
*mipsIV:
2939
*mipsV:
2940
*mips32:
2941
*mips32r2:
2942
*mips64:
2943
*mips64r2:
2944
*vr4100:
2945
*vr5000:
2946
*r3900:
2947
{
2948
  do_nor (SD_, RS, RT, RD);
2949
}
2950
 
2951
 
2952
:function:::void:do_or:int rs, int rt, int rd
2953
{
2954
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
2955
  GPR[rd] = (GPR[rs] | GPR[rt]);
2956
  TRACE_ALU_RESULT (GPR[rd]);
2957
}
2958
 
2959
000000,5.RS,5.RT,5.RD,00000,100101:SPECIAL:32::OR
2960
"or r, r, r"
2961
*mipsI:
2962
*mipsII:
2963
*mipsIII:
2964
*mipsIV:
2965
*mipsV:
2966
*mips32:
2967
*mips32r2:
2968
*mips64:
2969
*mips64r2:
2970
*vr4100:
2971
*vr5000:
2972
*r3900:
2973
{
2974
  do_or (SD_, RS, RT, RD);
2975
}
2976
 
2977
 
2978
 
2979
:function:::void:do_ori:int rs, int rt, unsigned immediate
2980
{
2981
  TRACE_ALU_INPUT2 (GPR[rs], immediate);
2982
  GPR[rt] = (GPR[rs] | immediate);
2983
  TRACE_ALU_RESULT (GPR[rt]);
2984
}
2985
 
2986
001101,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::ORI
2987
"ori r, r, %#lx"
2988
*mipsI:
2989
*mipsII:
2990
*mipsIII:
2991
*mipsIV:
2992
*mipsV:
2993
*mips32:
2994
*mips32r2:
2995
*mips64:
2996
*mips64r2:
2997
*vr4100:
2998
*vr5000:
2999
*r3900:
3000
{
3001
  do_ori (SD_, RS, RT, IMMEDIATE);
3002
}
3003
 
3004
 
3005
110011,5.BASE,5.HINT,16.OFFSET:NORMAL:32::PREF
3006
"pref , (r)"
3007
*mipsIV:
3008
*mipsV:
3009
*mips32:
3010
*mips32r2:
3011
*mips64:
3012
*mips64r2:
3013
*vr5000:
3014
{
3015
  address_word base = GPR[BASE];
3016
  address_word offset = EXTEND16 (OFFSET);
3017
  {
3018
    address_word vaddr = loadstore_ea (SD_, base, offset);
3019
    address_word paddr;
3020
    int uncached;
3021
    {
3022
      if (AddressTranslation(vaddr,isDATA,isLOAD,&paddr,&uncached,isTARGET,isREAL))
3023
        Prefetch(uncached,paddr,vaddr,isDATA,HINT);
3024
    }
3025
  }
3026
}
3027
 
3028
 
3029
:function:::unsigned64:do_ror:unsigned32 x,unsigned32 y
3030
{
3031
  unsigned64 result;
3032
 
3033
  y &= 31;
3034
  TRACE_ALU_INPUT2 (x, y);
3035
  result = EXTEND32 (ROTR32 (x, y));
3036
  TRACE_ALU_RESULT (result);
3037
  return result;
3038
}
3039
 
3040
000000,00001,5.RT,5.RD,5.SHIFT,000010::32::ROR
3041
"ror r, r, "
3042
*mips32r2:
3043
*mips64r2:
3044
*smartmips:
3045
*vr5400:
3046
*vr5500:
3047
{
3048
  GPR[RD] = do_ror (SD_, GPR[RT], SHIFT);
3049
}
3050
 
3051
000000,5.RS,5.RT,5.RD,00001,000110::32::RORV
3052
"rorv r, r, r"
3053
*mips32r2:
3054
*mips64r2:
3055
*smartmips:
3056
*vr5400:
3057
*vr5500:
3058
{
3059
  GPR[RD] = do_ror (SD_, GPR[RT], GPR[RS]);
3060
}
3061
 
3062
 
3063
:function:::void:do_store:unsigned access, address_word base, address_word offset, unsigned_word word
3064
{
3065
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
3066
  address_word reverseendian = (ReverseEndian ? (mask ^ access) : 0);
3067
  address_word bigendiancpu = (BigEndianCPU ? (mask ^ access) : 0);
3068
  unsigned int byte;
3069
  address_word paddr;
3070
  int uncached;
3071
  unsigned64 memval;
3072
  address_word vaddr;
3073
 
3074
  vaddr = loadstore_ea (SD_, base, offset);
3075
  if ((vaddr & access) != 0)
3076
    {
3077
      SIM_CORE_SIGNAL (SD, STATE_CPU(SD, 0), cia, read_map, access+1, vaddr, write_transfer, sim_core_unaligned_signal);
3078
    }
3079
  AddressTranslation (vaddr, isDATA, isSTORE, &paddr, &uncached, isTARGET, isREAL);
3080
  paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
3081
  byte = ((vaddr & mask) ^ bigendiancpu);
3082
  memval = (word << (8 * byte));
3083
  StoreMemory (uncached, access, memval, 0, paddr, vaddr, isREAL);
3084
}
3085
 
3086
:function:::void:do_store_left:unsigned access, address_word base, address_word offset, unsigned_word rt
3087
{
3088
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
3089
  address_word reverseendian = (ReverseEndian ? -1 : 0);
3090
  address_word bigendiancpu = (BigEndianCPU ? -1 : 0);
3091
  unsigned int byte;
3092
  unsigned int word;
3093
  address_word paddr;
3094
  int uncached;
3095
  unsigned64 memval;
3096
  address_word vaddr;
3097
  int nr_lhs_bits;
3098
  int nr_rhs_bits;
3099
 
3100
  vaddr = loadstore_ea (SD_, base, offset);
3101
  AddressTranslation (vaddr, isDATA, isSTORE, &paddr, &uncached, isTARGET, isREAL);
3102
  paddr = (paddr ^ (reverseendian & mask));
3103
  if (BigEndianMem == 0)
3104
    paddr = paddr & ~access;
3105
 
3106
  /* compute where within the word/mem we are */
3107
  byte = ((vaddr ^ bigendiancpu) & access); /* 0..access */
3108
  word = ((vaddr ^ bigendiancpu) & (mask & ~access)) / (access + 1); /* 0..1 */
3109
  nr_lhs_bits = 8 * byte + 8;
3110
  nr_rhs_bits = 8 * access - 8 * byte;
3111
  /* nr_lhs_bits + nr_rhs_bits == 8 * (accesss + 1) */
3112
  /* fprintf (stderr, "s[wd]l: 0x%08lx%08lx 0x%08lx%08lx %d:%d %d+%d\n",
3113
           (long) ((unsigned64) vaddr >> 32), (long) vaddr,
3114
           (long) ((unsigned64) paddr >> 32), (long) paddr,
3115
           word, byte, nr_lhs_bits, nr_rhs_bits); */
3116
 
3117
  if (word == 0)
3118
    {
3119
      memval = (rt >> nr_rhs_bits);
3120
    }
3121
  else
3122
    {
3123
      memval = (rt << nr_lhs_bits);
3124
    }
3125
  /* fprintf (stderr, "s[wd]l: 0x%08lx%08lx -> 0x%08lx%08lx\n",
3126
           (long) ((unsigned64) rt >> 32), (long) rt,
3127
           (long) ((unsigned64) memval >> 32), (long) memval); */
3128
  StoreMemory (uncached, byte, memval, 0, paddr, vaddr, isREAL);
3129
}
3130
 
3131
:function:::void:do_store_right:unsigned access, address_word base, address_word offset, unsigned_word rt
3132
{
3133
  address_word mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
3134
  address_word reverseendian = (ReverseEndian ? -1 : 0);
3135
  address_word bigendiancpu = (BigEndianCPU ? -1 : 0);
3136
  unsigned int byte;
3137
  address_word paddr;
3138
  int uncached;
3139
  unsigned64 memval;
3140
  address_word vaddr;
3141
 
3142
  vaddr = loadstore_ea (SD_, base, offset);
3143
  AddressTranslation (vaddr, isDATA, isSTORE, &paddr, &uncached, isTARGET, isREAL);
3144
  paddr = (paddr ^ (reverseendian & mask));
3145
  if (BigEndianMem != 0)
3146
    paddr &= ~access;
3147
  byte = ((vaddr & mask) ^ (bigendiancpu & mask));
3148
  memval = (rt << (byte * 8));
3149
  StoreMemory (uncached, access - (access & byte), memval, 0, paddr, vaddr, isREAL);
3150
}
3151
 
3152
 
3153
101000,5.BASE,5.RT,16.OFFSET:NORMAL:32::SB
3154
"sb r, (r)"
3155
*mipsI:
3156
*mipsII:
3157
*mipsIII:
3158
*mipsIV:
3159
*mipsV:
3160
*mips32:
3161
*mips32r2:
3162
*mips64:
3163
*mips64r2:
3164
*vr4100:
3165
*vr5000:
3166
*r3900:
3167
{
3168
  do_store (SD_, AccessLength_BYTE, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3169
}
3170
 
3171
 
3172
111000,5.BASE,5.RT,16.OFFSET:NORMAL:32::SC
3173
"sc r, (r)"
3174
*mipsII:
3175
*mipsIII:
3176
*mipsIV:
3177
*mipsV:
3178
*mips32:
3179
*mips32r2:
3180
*mips64:
3181
*mips64r2:
3182
*vr4100:
3183
*vr5000:
3184
{
3185
  unsigned32 instruction = instruction_0;
3186
  address_word base = GPR[BASE];
3187
  address_word offset = EXTEND16 (OFFSET);
3188
  {
3189
    address_word vaddr = loadstore_ea (SD_, base, offset);
3190
    address_word paddr;
3191
    int uncached;
3192
    if ((vaddr & 3) != 0)
3193
      {
3194
        SIM_CORE_SIGNAL (SD, CPU, cia, read_map, 4, vaddr, write_transfer, sim_core_unaligned_signal);
3195
      }
3196
    else
3197
      {
3198
        if (AddressTranslation(vaddr,isDATA,isSTORE,&paddr,&uncached,isTARGET,isREAL))
3199
          {
3200
            unsigned64 memval = 0;
3201
            unsigned64 memval1 = 0;
3202
            unsigned64 mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
3203
            address_word reverseendian = (ReverseEndian ? (mask ^ AccessLength_WORD) : 0);
3204
            address_word bigendiancpu = (BigEndianCPU ? (mask ^ AccessLength_WORD) : 0);
3205
            unsigned int byte;
3206
            paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
3207
            byte = ((vaddr & mask) ^ bigendiancpu);
3208
            memval = ((unsigned64) GPR[RT] << (8 * byte));
3209
            if (LLBIT)
3210
              {
3211
                StoreMemory(uncached,AccessLength_WORD,memval,memval1,paddr,vaddr,isREAL);
3212
              }
3213
            GPR[RT] = LLBIT;
3214
          }
3215
      }
3216
  }
3217
}
3218
 
3219
 
3220
111100,5.BASE,5.RT,16.OFFSET:NORMAL:64::SCD
3221
"scd r, (r)"
3222
*mipsIII:
3223
*mipsIV:
3224
*mipsV:
3225
*mips64:
3226
*mips64r2:
3227
*vr4100:
3228
*vr5000:
3229
{
3230
  address_word base = GPR[BASE];
3231
  address_word offset = EXTEND16 (OFFSET);
3232
  check_u64 (SD_, instruction_0);
3233
  {
3234
    address_word vaddr = loadstore_ea (SD_, base, offset);
3235
    address_word paddr;
3236
    int uncached;
3237
    if ((vaddr & 7) != 0)
3238
      {
3239
        SIM_CORE_SIGNAL (SD, CPU, cia, read_map, 8, vaddr, write_transfer, sim_core_unaligned_signal);
3240
      }
3241
    else
3242
      {
3243
        if (AddressTranslation(vaddr,isDATA,isSTORE,&paddr,&uncached,isTARGET,isREAL))
3244
          {
3245
            unsigned64 memval = 0;
3246
            unsigned64 memval1 = 0;
3247
            memval = GPR[RT];
3248
            if (LLBIT)
3249
              {
3250
                StoreMemory(uncached,AccessLength_DOUBLEWORD,memval,memval1,paddr,vaddr,isREAL);
3251
              }
3252
            GPR[RT] = LLBIT;
3253
          }
3254
      }
3255
  }
3256
}
3257
 
3258
 
3259
111111,5.BASE,5.RT,16.OFFSET:NORMAL:64::SD
3260
"sd r, (r)"
3261
*mipsIII:
3262
*mipsIV:
3263
*mipsV:
3264
*mips64:
3265
*mips64r2:
3266
*vr4100:
3267
*vr5000:
3268
{
3269
  check_u64 (SD_, instruction_0);
3270
  do_store (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3271
}
3272
 
3273
 
3274
1111,ZZ!0!1!3,5.BASE,5.RT,16.OFFSET:NORMAL:64::SDCz
3275
"sdc r, (r)"
3276
*mipsII:
3277
*mipsIII:
3278
*mipsIV:
3279
*mipsV:
3280
*mips32:
3281
*mips32r2:
3282
*mips64:
3283
*mips64r2:
3284
*vr4100:
3285
*vr5000:
3286
{
3287
  do_store (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), COP_SD (ZZ, RT));
3288
}
3289
 
3290
 
3291
101100,5.BASE,5.RT,16.OFFSET:NORMAL:64::SDL
3292
"sdl r, (r)"
3293
*mipsIII:
3294
*mipsIV:
3295
*mipsV:
3296
*mips64:
3297
*mips64r2:
3298
*vr4100:
3299
*vr5000:
3300
{
3301
  check_u64 (SD_, instruction_0);
3302
  do_store_left (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3303
}
3304
 
3305
 
3306
101101,5.BASE,5.RT,16.OFFSET:NORMAL:64::SDR
3307
"sdr r, (r)"
3308
*mipsIII:
3309
*mipsIV:
3310
*mipsV:
3311
*mips64:
3312
*mips64r2:
3313
*vr4100:
3314
*vr5000:
3315
{
3316
  check_u64 (SD_, instruction_0);
3317
  do_store_right (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3318
}
3319
 
3320
 
3321
 
3322
101001,5.BASE,5.RT,16.OFFSET:NORMAL:32::SH
3323
"sh r, (r)"
3324
*mipsI:
3325
*mipsII:
3326
*mipsIII:
3327
*mipsIV:
3328
*mipsV:
3329
*mips32:
3330
*mips32r2:
3331
*mips64:
3332
*mips64r2:
3333
*vr4100:
3334
*vr5000:
3335
*r3900:
3336
{
3337
  do_store (SD_, AccessLength_HALFWORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3338
}
3339
 
3340
 
3341
:function:::void:do_sll:int rt, int rd, int shift
3342
{
3343
  unsigned32 temp = (GPR[rt] << shift);
3344
  TRACE_ALU_INPUT2 (GPR[rt], shift);
3345
  GPR[rd] = EXTEND32 (temp);
3346
  TRACE_ALU_RESULT (GPR[rd]);
3347
}
3348
 
3349
000000,00000,5.RT,5.RD,5.SHIFT,000000:SPECIAL:32::SLLa
3350
"nop":RD == 0 && RT == 0 && SHIFT == 0
3351
"sll r, r, "
3352
*mipsI:
3353
*mipsII:
3354
*mipsIII:
3355
*mipsIV:
3356
*mipsV:
3357
*vr4100:
3358
*vr5000:
3359
*r3900:
3360
{
3361
  /* Skip shift for NOP, so that there won't be lots of extraneous
3362
     trace output.  */
3363
  if (RD != 0 || RT != 0 || SHIFT != 0)
3364
    do_sll (SD_, RT, RD, SHIFT);
3365
}
3366
 
3367
000000,00000,5.RT,5.RD,5.SHIFT,000000:SPECIAL:32::SLLb
3368
"nop":RD == 0 && RT == 0 && SHIFT == 0
3369
"ssnop":RD == 0 && RT == 0 && SHIFT == 1
3370
"sll r, r, "
3371
*mips32:
3372
*mips32r2:
3373
*mips64:
3374
*mips64r2:
3375
{
3376
  /* Skip shift for NOP and SSNOP, so that there won't be lots of
3377
     extraneous trace output.  */
3378
  if (RD != 0 || RT != 0 || (SHIFT != 0 && SHIFT != 1))
3379
    do_sll (SD_, RT, RD, SHIFT);
3380
}
3381
 
3382
 
3383
:function:::void:do_sllv:int rs, int rt, int rd
3384
{
3385
  int s = MASKED (GPR[rs], 4, 0);
3386
  unsigned32 temp = (GPR[rt] << s);
3387
  TRACE_ALU_INPUT2 (GPR[rt], s);
3388
  GPR[rd] = EXTEND32 (temp);
3389
  TRACE_ALU_RESULT (GPR[rd]);
3390
}
3391
 
3392
000000,5.RS,5.RT,5.RD,00000,000100:SPECIAL:32::SLLV
3393
"sllv r, r, r"
3394
*mipsI:
3395
*mipsII:
3396
*mipsIII:
3397
*mipsIV:
3398
*mipsV:
3399
*mips32:
3400
*mips32r2:
3401
*mips64:
3402
*mips64r2:
3403
*vr4100:
3404
*vr5000:
3405
*r3900:
3406
{
3407
  do_sllv (SD_, RS, RT, RD);
3408
}
3409
 
3410
 
3411
:function:::void:do_slt:int rs, int rt, int rd
3412
{
3413
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
3414
  GPR[rd] = ((signed_word) GPR[rs] < (signed_word) GPR[rt]);
3415
  TRACE_ALU_RESULT (GPR[rd]);
3416
}
3417
 
3418
000000,5.RS,5.RT,5.RD,00000,101010:SPECIAL:32::SLT
3419
"slt r, r, r"
3420
*mipsI:
3421
*mipsII:
3422
*mipsIII:
3423
*mipsIV:
3424
*mipsV:
3425
*mips32:
3426
*mips32r2:
3427
*mips64:
3428
*mips64r2:
3429
*vr4100:
3430
*vr5000:
3431
*r3900:
3432
{
3433
  do_slt (SD_, RS, RT, RD);
3434
}
3435
 
3436
 
3437
:function:::void:do_slti:int rs, int rt, unsigned16 immediate
3438
{
3439
  TRACE_ALU_INPUT2 (GPR[rs], EXTEND16 (immediate));
3440
  GPR[rt] = ((signed_word) GPR[rs] < (signed_word) EXTEND16 (immediate));
3441
  TRACE_ALU_RESULT (GPR[rt]);
3442
}
3443
 
3444
001010,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::SLTI
3445
"slti r, r, "
3446
*mipsI:
3447
*mipsII:
3448
*mipsIII:
3449
*mipsIV:
3450
*mipsV:
3451
*mips32:
3452
*mips32r2:
3453
*mips64:
3454
*mips64r2:
3455
*vr4100:
3456
*vr5000:
3457
*r3900:
3458
{
3459
  do_slti (SD_, RS, RT, IMMEDIATE);
3460
}
3461
 
3462
 
3463
:function:::void:do_sltiu:int rs, int rt, unsigned16 immediate
3464
{
3465
  TRACE_ALU_INPUT2 (GPR[rs], EXTEND16 (immediate));
3466
  GPR[rt] = ((unsigned_word) GPR[rs] < (unsigned_word) EXTEND16 (immediate));
3467
  TRACE_ALU_RESULT (GPR[rt]);
3468
}
3469
 
3470
001011,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::SLTIU
3471
"sltiu r, r, "
3472
*mipsI:
3473
*mipsII:
3474
*mipsIII:
3475
*mipsIV:
3476
*mipsV:
3477
*mips32:
3478
*mips32r2:
3479
*mips64:
3480
*mips64r2:
3481
*vr4100:
3482
*vr5000:
3483
*r3900:
3484
{
3485
  do_sltiu (SD_, RS, RT, IMMEDIATE);
3486
}
3487
 
3488
 
3489
 
3490
:function:::void:do_sltu:int rs, int rt, int rd
3491
{
3492
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
3493
  GPR[rd] = ((unsigned_word) GPR[rs] < (unsigned_word) GPR[rt]);
3494
  TRACE_ALU_RESULT (GPR[rd]);
3495
}
3496
 
3497
000000,5.RS,5.RT,5.RD,00000,101011:SPECIAL:32::SLTU
3498
"sltu r, r, r"
3499
*mipsI:
3500
*mipsII:
3501
*mipsIII:
3502
*mipsIV:
3503
*mipsV:
3504
*mips32:
3505
*mips32r2:
3506
*mips64:
3507
*mips64r2:
3508
*vr4100:
3509
*vr5000:
3510
*r3900:
3511
{
3512
  do_sltu (SD_, RS, RT, RD);
3513
}
3514
 
3515
 
3516
:function:::void:do_sra:int rt, int rd, int shift
3517
{
3518
  signed32 temp = (signed32) GPR[rt] >> shift;
3519
  if (NotWordValue (GPR[rt]))
3520
    Unpredictable ();
3521
  TRACE_ALU_INPUT2 (GPR[rt], shift);
3522
  GPR[rd] = EXTEND32 (temp);
3523
  TRACE_ALU_RESULT (GPR[rd]);
3524
}
3525
 
3526
000000,00000,5.RT,5.RD,5.SHIFT,000011:SPECIAL:32::SRA
3527
"sra r, r, "
3528
*mipsI:
3529
*mipsII:
3530
*mipsIII:
3531
*mipsIV:
3532
*mipsV:
3533
*mips32:
3534
*mips32r2:
3535
*mips64:
3536
*mips64r2:
3537
*vr4100:
3538
*vr5000:
3539
*r3900:
3540
{
3541
  do_sra (SD_, RT, RD, SHIFT);
3542
}
3543
 
3544
 
3545
 
3546
:function:::void:do_srav:int rs, int rt, int rd
3547
{
3548
  int s = MASKED (GPR[rs], 4, 0);
3549
  signed32 temp = (signed32) GPR[rt] >> s;
3550
  if (NotWordValue (GPR[rt]))
3551
    Unpredictable ();
3552
  TRACE_ALU_INPUT2 (GPR[rt], s);
3553
  GPR[rd] = EXTEND32 (temp);
3554
  TRACE_ALU_RESULT (GPR[rd]);
3555
}
3556
 
3557
000000,5.RS,5.RT,5.RD,00000,000111:SPECIAL:32::SRAV
3558
"srav r, r, r"
3559
*mipsI:
3560
*mipsII:
3561
*mipsIII:
3562
*mipsIV:
3563
*mipsV:
3564
*mips32:
3565
*mips32r2:
3566
*mips64:
3567
*mips64r2:
3568
*vr4100:
3569
*vr5000:
3570
*r3900:
3571
{
3572
  do_srav (SD_, RS, RT, RD);
3573
}
3574
 
3575
 
3576
 
3577
:function:::void:do_srl:int rt, int rd, int shift
3578
{
3579
  unsigned32 temp = (unsigned32) GPR[rt] >> shift;
3580
  if (NotWordValue (GPR[rt]))
3581
    Unpredictable ();
3582
  TRACE_ALU_INPUT2 (GPR[rt], shift);
3583
  GPR[rd] = EXTEND32 (temp);
3584
  TRACE_ALU_RESULT (GPR[rd]);
3585
}
3586
 
3587
000000,00000,5.RT,5.RD,5.SHIFT,000010:SPECIAL:32::SRL
3588
"srl r, r, "
3589
*mipsI:
3590
*mipsII:
3591
*mipsIII:
3592
*mipsIV:
3593
*mipsV:
3594
*mips32:
3595
*mips32r2:
3596
*mips64:
3597
*mips64r2:
3598
*vr4100:
3599
*vr5000:
3600
*r3900:
3601
{
3602
  do_srl (SD_, RT, RD, SHIFT);
3603
}
3604
 
3605
 
3606
:function:::void:do_srlv:int rs, int rt, int rd
3607
{
3608
  int s = MASKED (GPR[rs], 4, 0);
3609
  unsigned32 temp = (unsigned32) GPR[rt] >> s;
3610
  if (NotWordValue (GPR[rt]))
3611
    Unpredictable ();
3612
  TRACE_ALU_INPUT2 (GPR[rt], s);
3613
  GPR[rd] = EXTEND32 (temp);
3614
  TRACE_ALU_RESULT (GPR[rd]);
3615
}
3616
 
3617
000000,5.RS,5.RT,5.RD,00000,000110:SPECIAL:32::SRLV
3618
"srlv r, r, r"
3619
*mipsI:
3620
*mipsII:
3621
*mipsIII:
3622
*mipsIV:
3623
*mipsV:
3624
*mips32:
3625
*mips32r2:
3626
*mips64:
3627
*mips64r2:
3628
*vr4100:
3629
*vr5000:
3630
*r3900:
3631
{
3632
  do_srlv (SD_, RS, RT, RD);
3633
}
3634
 
3635
 
3636
000000,5.RS,5.RT,5.RD,00000,100010:SPECIAL:32::SUB
3637
"sub r, r, r"
3638
*mipsI:
3639
*mipsII:
3640
*mipsIII:
3641
*mipsIV:
3642
*mipsV:
3643
*mips32:
3644
*mips32r2:
3645
*mips64:
3646
*mips64r2:
3647
*vr4100:
3648
*vr5000:
3649
*r3900:
3650
{
3651
  if (NotWordValue (GPR[RS]) || NotWordValue (GPR[RT]))
3652
    Unpredictable ();
3653
  TRACE_ALU_INPUT2 (GPR[RS], GPR[RT]);
3654
  {
3655
    ALU32_BEGIN (GPR[RS]);
3656
    ALU32_SUB (GPR[RT]);
3657
    ALU32_END (GPR[RD]);   /* This checks for overflow.  */
3658
  }
3659
  TRACE_ALU_RESULT (GPR[RD]);
3660
}
3661
 
3662
 
3663
:function:::void:do_subu:int rs, int rt, int rd
3664
{
3665
  if (NotWordValue (GPR[rs]) || NotWordValue (GPR[rt]))
3666
    Unpredictable ();
3667
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
3668
  GPR[rd] = EXTEND32 (GPR[rs] - GPR[rt]);
3669
  TRACE_ALU_RESULT (GPR[rd]);
3670
}
3671
 
3672
000000,5.RS,5.RT,5.RD,00000,100011:SPECIAL:32::SUBU
3673
"subu r, r, r"
3674
*mipsI:
3675
*mipsII:
3676
*mipsIII:
3677
*mipsIV:
3678
*mipsV:
3679
*mips32:
3680
*mips32r2:
3681
*mips64:
3682
*mips64r2:
3683
*vr4100:
3684
*vr5000:
3685
*r3900:
3686
{
3687
  do_subu (SD_, RS, RT, RD);
3688
}
3689
 
3690
 
3691
101011,5.BASE,5.RT,16.OFFSET:NORMAL:32::SW
3692
"sw r, (r)"
3693
*mipsI:
3694
*mipsII:
3695
*mipsIII:
3696
*mipsIV:
3697
*mipsV:
3698
*mips32:
3699
*mips32r2:
3700
*mips64:
3701
*mips64r2:
3702
*vr4100:
3703
*r3900:
3704
*vr5000:
3705
{
3706
  do_store (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3707
}
3708
 
3709
 
3710
1110,ZZ!0!1!3,5.BASE,5.RT,16.OFFSET:NORMAL:32::SWCz
3711
"swc r, (r)"
3712
*mipsI:
3713
*mipsII:
3714
*mipsIII:
3715
*mipsIV:
3716
*mipsV:
3717
*mips32:
3718
*mips32r2:
3719
*mips64:
3720
*mips64r2:
3721
*vr4100:
3722
*vr5000:
3723
*r3900:
3724
{
3725
  do_store (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), COP_SW (ZZ, RT));
3726
}
3727
 
3728
 
3729
101010,5.BASE,5.RT,16.OFFSET:NORMAL:32::SWL
3730
"swl r, (r)"
3731
*mipsI:
3732
*mipsII:
3733
*mipsIII:
3734
*mipsIV:
3735
*mipsV:
3736
*mips32:
3737
*mips32r2:
3738
*mips64:
3739
*mips64r2:
3740
*vr4100:
3741
*vr5000:
3742
*r3900:
3743
{
3744
  do_store_left (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3745
}
3746
 
3747
 
3748
101110,5.BASE,5.RT,16.OFFSET:NORMAL:32::SWR
3749
"swr r, (r)"
3750
*mipsI:
3751
*mipsII:
3752
*mipsIII:
3753
*mipsIV:
3754
*mipsV:
3755
*mips32:
3756
*mips32r2:
3757
*mips64:
3758
*mips64r2:
3759
*vr4100:
3760
*vr5000:
3761
*r3900:
3762
{
3763
  do_store_right (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET), GPR[RT]);
3764
}
3765
 
3766
 
3767
000000,000000000000000,5.STYPE,001111:SPECIAL:32::SYNC
3768
"sync":STYPE == 0
3769
"sync "
3770
*mipsII:
3771
*mipsIII:
3772
*mipsIV:
3773
*mipsV:
3774
*mips32:
3775
*mips32r2:
3776
*mips64:
3777
*mips64r2:
3778
*vr4100:
3779
*vr5000:
3780
*r3900:
3781
{
3782
  SyncOperation (STYPE);
3783
}
3784
 
3785
 
3786
000000,20.CODE,001100:SPECIAL:32::SYSCALL
3787
"syscall %#lx"
3788
*mipsI:
3789
*mipsII:
3790
*mipsIII:
3791
*mipsIV:
3792
*mipsV:
3793
*mips32:
3794
*mips32r2:
3795
*mips64:
3796
*mips64r2:
3797
*vr4100:
3798
*vr5000:
3799
*r3900:
3800
{
3801
  SignalException (SystemCall, instruction_0);
3802
}
3803
 
3804
 
3805
000000,5.RS,5.RT,10.CODE,110100:SPECIAL:32::TEQ
3806
"teq r, r"
3807
*mipsII:
3808
*mipsIII:
3809
*mipsIV:
3810
*mipsV:
3811
*mips32:
3812
*mips32r2:
3813
*mips64:
3814
*mips64r2:
3815
*vr4100:
3816
*vr5000:
3817
{
3818
  if ((signed_word) GPR[RS] == (signed_word) GPR[RT])
3819
    SignalException (Trap, instruction_0);
3820
}
3821
 
3822
 
3823
000001,5.RS,01100,16.IMMEDIATE:REGIMM:32::TEQI
3824
"teqi r, "
3825
*mipsII:
3826
*mipsIII:
3827
*mipsIV:
3828
*mipsV:
3829
*mips32:
3830
*mips32r2:
3831
*mips64:
3832
*mips64r2:
3833
*vr4100:
3834
*vr5000:
3835
{
3836
  if ((signed_word) GPR[RS] == (signed_word) EXTEND16 (IMMEDIATE))
3837
    SignalException (Trap, instruction_0);
3838
}
3839
 
3840
 
3841
000000,5.RS,5.RT,10.CODE,110000:SPECIAL:32::TGE
3842
"tge r, r"
3843
*mipsII:
3844
*mipsIII:
3845
*mipsIV:
3846
*mipsV:
3847
*mips32:
3848
*mips32r2:
3849
*mips64:
3850
*mips64r2:
3851
*vr4100:
3852
*vr5000:
3853
{
3854
  if ((signed_word) GPR[RS] >= (signed_word) GPR[RT])
3855
    SignalException (Trap, instruction_0);
3856
}
3857
 
3858
 
3859
000001,5.RS,01000,16.IMMEDIATE:REGIMM:32::TGEI
3860
"tgei r, "
3861
*mipsII:
3862
*mipsIII:
3863
*mipsIV:
3864
*mipsV:
3865
*mips32:
3866
*mips32r2:
3867
*mips64:
3868
*mips64r2:
3869
*vr4100:
3870
*vr5000:
3871
{
3872
  if ((signed_word) GPR[RS] >= (signed_word) EXTEND16 (IMMEDIATE))
3873
    SignalException (Trap, instruction_0);
3874
}
3875
 
3876
 
3877
000001,5.RS,01001,16.IMMEDIATE:REGIMM:32::TGEIU
3878
"tgeiu r, "
3879
*mipsII:
3880
*mipsIII:
3881
*mipsIV:
3882
*mipsV:
3883
*mips32:
3884
*mips32r2:
3885
*mips64:
3886
*mips64r2:
3887
*vr4100:
3888
*vr5000:
3889
{
3890
  if ((unsigned_word) GPR[RS] >= (unsigned_word) EXTEND16 (IMMEDIATE))
3891
    SignalException (Trap, instruction_0);
3892
}
3893
 
3894
 
3895
000000,5.RS,5.RT,10.CODE,110001:SPECIAL:32::TGEU
3896
"tgeu r, r"
3897
*mipsII:
3898
*mipsIII:
3899
*mipsIV:
3900
*mipsV:
3901
*mips32:
3902
*mips32r2:
3903
*mips64:
3904
*mips64r2:
3905
*vr4100:
3906
*vr5000:
3907
{
3908
  if ((unsigned_word) GPR[RS] >= (unsigned_word) GPR[RT])
3909
    SignalException (Trap, instruction_0);
3910
}
3911
 
3912
 
3913
000000,5.RS,5.RT,10.CODE,110010:SPECIAL:32::TLT
3914
"tlt r, r"
3915
*mipsII:
3916
*mipsIII:
3917
*mipsIV:
3918
*mipsV:
3919
*mips32:
3920
*mips32r2:
3921
*mips64:
3922
*mips64r2:
3923
*vr4100:
3924
*vr5000:
3925
{
3926
  if ((signed_word) GPR[RS] < (signed_word) GPR[RT])
3927
    SignalException (Trap, instruction_0);
3928
}
3929
 
3930
 
3931
000001,5.RS,01010,16.IMMEDIATE:REGIMM:32::TLTI
3932
"tlti r, "
3933
*mipsII:
3934
*mipsIII:
3935
*mipsIV:
3936
*mipsV:
3937
*mips32:
3938
*mips32r2:
3939
*mips64:
3940
*mips64r2:
3941
*vr4100:
3942
*vr5000:
3943
{
3944
  if ((signed_word) GPR[RS] < (signed_word) EXTEND16 (IMMEDIATE))
3945
    SignalException (Trap, instruction_0);
3946
}
3947
 
3948
 
3949
000001,5.RS,01011,16.IMMEDIATE:REGIMM:32::TLTIU
3950
"tltiu r, "
3951
*mipsII:
3952
*mipsIII:
3953
*mipsIV:
3954
*mipsV:
3955
*mips32:
3956
*mips32r2:
3957
*mips64:
3958
*mips64r2:
3959
*vr4100:
3960
*vr5000:
3961
{
3962
  if ((unsigned_word) GPR[RS] < (unsigned_word) EXTEND16 (IMMEDIATE))
3963
    SignalException (Trap, instruction_0);
3964
}
3965
 
3966
 
3967
000000,5.RS,5.RT,10.CODE,110011:SPECIAL:32::TLTU
3968
"tltu r, r"
3969
*mipsII:
3970
*mipsIII:
3971
*mipsIV:
3972
*mipsV:
3973
*mips32:
3974
*mips32r2:
3975
*mips64:
3976
*mips64r2:
3977
*vr4100:
3978
*vr5000:
3979
{
3980
  if ((unsigned_word) GPR[RS] < (unsigned_word) GPR[RT])
3981
    SignalException (Trap, instruction_0);
3982
}
3983
 
3984
 
3985
000000,5.RS,5.RT,10.CODE,110110:SPECIAL:32::TNE
3986
"tne r, r"
3987
*mipsII:
3988
*mipsIII:
3989
*mipsIV:
3990
*mipsV:
3991
*mips32:
3992
*mips32r2:
3993
*mips64:
3994
*mips64r2:
3995
*vr4100:
3996
*vr5000:
3997
{
3998
  if ((signed_word) GPR[RS] != (signed_word) GPR[RT])
3999
    SignalException (Trap, instruction_0);
4000
}
4001
 
4002
 
4003
000001,5.RS,01110,16.IMMEDIATE:REGIMM:32::TNEI
4004
"tnei r, "
4005
*mipsII:
4006
*mipsIII:
4007
*mipsIV:
4008
*mipsV:
4009
*mips32:
4010
*mips32r2:
4011
*mips64:
4012
*mips64r2:
4013
*vr4100:
4014
*vr5000:
4015
{
4016
  if ((signed_word) GPR[RS] != (signed_word) EXTEND16 (IMMEDIATE))
4017
    SignalException (Trap, instruction_0);
4018
}
4019
 
4020
 
4021
:function:::void:do_xor:int rs, int rt, int rd
4022
{
4023
  TRACE_ALU_INPUT2 (GPR[rs], GPR[rt]);
4024
  GPR[rd] = GPR[rs] ^ GPR[rt];
4025
  TRACE_ALU_RESULT (GPR[rd]);
4026
}
4027
 
4028
000000,5.RS,5.RT,5.RD,00000,100110:SPECIAL:32::XOR
4029
"xor r, r, r"
4030
*mipsI:
4031
*mipsII:
4032
*mipsIII:
4033
*mipsIV:
4034
*mipsV:
4035
*mips32:
4036
*mips32r2:
4037
*mips64:
4038
*mips64r2:
4039
*vr4100:
4040
*vr5000:
4041
*r3900:
4042
{
4043
  do_xor (SD_, RS, RT, RD);
4044
}
4045
 
4046
 
4047
:function:::void:do_xori:int rs, int rt, unsigned16 immediate
4048
{
4049
  TRACE_ALU_INPUT2 (GPR[rs], immediate);
4050
  GPR[rt] = GPR[rs] ^ immediate;
4051
  TRACE_ALU_RESULT (GPR[rt]);
4052
}
4053
 
4054
001110,5.RS,5.RT,16.IMMEDIATE:NORMAL:32::XORI
4055
"xori r, r, %#lx"
4056
*mipsI:
4057
*mipsII:
4058
*mipsIII:
4059
*mipsIV:
4060
*mipsV:
4061
*mips32:
4062
*mips32r2:
4063
*mips64:
4064
*mips64r2:
4065
*vr4100:
4066
*vr5000:
4067
*r3900:
4068
{
4069
  do_xori (SD_, RS, RT, IMMEDIATE);
4070
}
4071
 
4072
 
4073
//
4074
// MIPS Architecture:
4075
//
4076
//        FPU Instruction Set (COP1 & COP1X)
4077
//
4078
 
4079
 
4080
:%s::::FMT:int fmt
4081
{
4082
  switch (fmt)
4083
    {
4084
    case fmt_single: return "s";
4085
    case fmt_double: return "d";
4086
    case fmt_word: return "w";
4087
    case fmt_long: return "l";
4088
    case fmt_ps: return "ps";
4089
    default: return "?";
4090
    }
4091
}
4092
 
4093
:%s::::TF:int tf
4094
{
4095
  if (tf)
4096
    return "t";
4097
  else
4098
    return "f";
4099
}
4100
 
4101
:%s::::ND:int nd
4102
{
4103
  if (nd)
4104
    return "l";
4105
  else
4106
    return "";
4107
}
4108
 
4109
:%s::::COND:int cond
4110
{
4111
  switch (cond)
4112
    {
4113
    case 00: return "f";
4114
    case 01: return "un";
4115
    case 02: return "eq";
4116
    case 03: return "ueq";
4117
    case 04: return "olt";
4118
    case 05: return "ult";
4119
    case 06: return "ole";
4120
    case 07: return "ule";
4121
    case 010: return "sf";
4122
    case 011: return "ngle";
4123
    case 012: return "seq";
4124
    case 013: return "ngl";
4125
    case 014: return "lt";
4126
    case 015: return "nge";
4127
    case 016: return "le";
4128
    case 017: return "ngt";
4129
    default: return "?";
4130
    }
4131
}
4132
 
4133
 
4134
// Helpers:
4135
//
4136
// Check that the given FPU format is usable, and signal a
4137
// ReservedInstruction exception if not.
4138
//
4139
 
4140
// check_fmt_p checks that the format is single, double, or paired single.
4141
:function:::void:check_fmt_p:int fmt, instruction_word insn
4142
*mipsI:
4143
*mipsII:
4144
*mipsIII:
4145
*mipsIV:
4146
*mips32:
4147
*vr4100:
4148
*vr5000:
4149
*r3900:
4150
{
4151
  /* None of these ISAs support Paired Single, so just fall back to
4152
     the single/double check.  */
4153
  if ((fmt != fmt_single) && (fmt != fmt_double))
4154
    SignalException (ReservedInstruction, insn);
4155
}
4156
 
4157
:function:::void:check_fmt_p:int fmt, instruction_word insn
4158
*mips32r2:
4159
{
4160
  if ((fmt != fmt_single) && (fmt != fmt_double) && (fmt != fmt_ps))
4161
    SignalException (ReservedInstruction, insn);
4162
}
4163
 
4164
:function:::void:check_fmt_p:int fmt, instruction_word insn
4165
*mipsV:
4166
*mips64:
4167
*mips64r2:
4168
{
4169
  if ((fmt != fmt_single) && (fmt != fmt_double)
4170
      && (fmt != fmt_ps || (UserMode && (SR & (status_UX|status_PX)) == 0)))
4171
    SignalException (ReservedInstruction, insn);
4172
}
4173
 
4174
 
4175
// Helper:
4176
//
4177
// Check that the FPU is currently usable, and signal a CoProcessorUnusable
4178
// exception if not.
4179
//
4180
 
4181
:function:::void:check_fpu:
4182
*mipsI:
4183
*mipsII:
4184
*mipsIII:
4185
*mipsIV:
4186
*mipsV:
4187
*mips32:
4188
*mips32r2:
4189
*mips64:
4190
*mips64r2:
4191
*vr4100:
4192
*vr5000:
4193
*r3900:
4194
{
4195
  if (! COP_Usable (1))
4196
    SignalExceptionCoProcessorUnusable (1);
4197
}
4198
 
4199
 
4200
// Helper:
4201
//
4202
// Load a double word FP value using 2 32-bit memory cycles a la MIPS II
4203
// or MIPS32.  do_load cannot be used instead because it returns an
4204
// unsigned_word, which is limited to the size of the machine's registers.
4205
//
4206
 
4207
:function:::unsigned64:do_load_double:address_word base, address_word offset
4208
*mipsII:
4209
*mips32:
4210
*mips32r2:
4211
{
4212
  int bigendian = (BigEndianCPU ? ! ReverseEndian : ReverseEndian);
4213
  address_word vaddr;
4214
  address_word paddr;
4215
  int uncached;
4216
  unsigned64 memval;
4217
  unsigned64 v;
4218
 
4219
  vaddr = loadstore_ea (SD_, base, offset);
4220
  if ((vaddr & AccessLength_DOUBLEWORD) != 0)
4221
    {
4222
      SIM_CORE_SIGNAL (SD, STATE_CPU (SD, 0), cia, read_map,
4223
                       AccessLength_DOUBLEWORD + 1, vaddr, read_transfer,
4224
                       sim_core_unaligned_signal);
4225
    }
4226
  AddressTranslation (vaddr, isDATA, isLOAD, &paddr, &uncached, isTARGET,
4227
                      isREAL);
4228
  LoadMemory (&memval, NULL, uncached, AccessLength_WORD, paddr, vaddr,
4229
              isDATA, isREAL);
4230
  v = (unsigned64)memval;
4231
  LoadMemory (&memval, NULL, uncached, AccessLength_WORD, paddr + 4, vaddr + 4,
4232
              isDATA, isREAL);
4233
  return (bigendian ? ((v << 32) | memval) : (v | (memval << 32)));
4234
}
4235
 
4236
 
4237
// Helper:
4238
//
4239
// Store a double word FP value using 2 32-bit memory cycles a la MIPS II
4240
// or MIPS32.  do_load cannot be used instead because it returns an
4241
// unsigned_word, which is limited to the size of the machine's registers.
4242
//
4243
 
4244
:function:::void:do_store_double:address_word base, address_word offset, unsigned64 v
4245
*mipsII:
4246
*mips32:
4247
*mips32r2:
4248
{
4249
  int bigendian = (BigEndianCPU ? ! ReverseEndian : ReverseEndian);
4250
  address_word vaddr;
4251
  address_word paddr;
4252
  int uncached;
4253
  unsigned64 memval;
4254
 
4255
  vaddr = loadstore_ea (SD_, base, offset);
4256
  if ((vaddr & AccessLength_DOUBLEWORD) != 0)
4257
    {
4258
      SIM_CORE_SIGNAL (SD, STATE_CPU(SD, 0), cia, read_map,
4259
                       AccessLength_DOUBLEWORD + 1, vaddr, write_transfer,
4260
                       sim_core_unaligned_signal);
4261
    }
4262
  AddressTranslation (vaddr, isDATA, isSTORE, &paddr, &uncached, isTARGET,
4263
                      isREAL);
4264
  memval = (bigendian ? (v >> 32) : (v & 0xFFFFFFFF));
4265
  StoreMemory (uncached, AccessLength_WORD, memval, 0, paddr, vaddr,
4266
               isREAL);
4267
  memval = (bigendian ? (v & 0xFFFFFFFF) : (v >> 32));
4268
  StoreMemory (uncached, AccessLength_WORD, memval, 0, paddr + 4, vaddr + 4,
4269
               isREAL);
4270
}
4271
 
4272
 
4273
010001,10,3.FMT!2!3!4!5!7,00000,5.FS,5.FD,000101:COP1:32,f::ABS.fmt
4274
"abs.%s f, f"
4275
*mipsI:
4276
*mipsII:
4277
*mipsIII:
4278
*mipsIV:
4279
*mipsV:
4280
*mips32:
4281
*mips32r2:
4282
*mips64:
4283
*mips64r2:
4284
*vr4100:
4285
*vr5000:
4286
*r3900:
4287
{
4288
  int fmt = FMT;
4289
  check_fpu (SD_);
4290
  check_fmt_p (SD_, fmt, instruction_0);
4291
  StoreFPR (FD, fmt, AbsoluteValue (ValueFPR (FS, fmt), fmt));
4292
}
4293
 
4294
 
4295
 
4296
010001,10,3.FMT!2!3!4!5!7,5.FT,5.FS,5.FD,000000:COP1:32,f::ADD.fmt
4297
"add.%s f, f, f"
4298
*mipsI:
4299
*mipsII:
4300
*mipsIII:
4301
*mipsIV:
4302
*mipsV:
4303
*mips32:
4304
*mips32r2:
4305
*mips64:
4306
*mips64r2:
4307
*vr4100:
4308
*vr5000:
4309
*r3900:
4310
{
4311
  int fmt = FMT;
4312
  check_fpu (SD_);
4313
  check_fmt_p (SD_, fmt, instruction_0);
4314
  StoreFPR (FD, fmt, Add (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt));
4315
}
4316
 
4317
 
4318
010011,5.RS,5.FT,5.FS,5.FD,011,110:COP1X:32,f::ALNV.PS
4319
"alnv.ps f, f, f, r"
4320
*mipsV:
4321
*mips32r2:
4322
*mips64:
4323
*mips64r2:
4324
{
4325
  unsigned64 fs;
4326
  unsigned64 ft;
4327
  unsigned64 fd;
4328
  check_fpu (SD_);
4329
  check_u64 (SD_, instruction_0);
4330
  fs = ValueFPR (FS, fmt_ps);
4331
  if ((GPR[RS] & 0x3) != 0)
4332
    Unpredictable ();
4333
  if ((GPR[RS] & 0x4) == 0)
4334
    fd = fs;
4335
  else
4336
    {
4337
      ft = ValueFPR (FT, fmt_ps);
4338
      if (BigEndianCPU)
4339
        fd = PackPS (PSLower (fs), PSUpper (ft));
4340
      else
4341
        fd = PackPS (PSLower (ft), PSUpper (fs));
4342
    }
4343
  StoreFPR (FD, fmt_ps, fd);
4344
}
4345
 
4346
 
4347
// BC1F
4348
// BC1FL
4349
// BC1T
4350
// BC1TL
4351
 
4352
010001,01000,3.0,1.ND,1.TF,16.OFFSET:COP1S:32,f::BC1a
4353
"bc1%s%s "
4354
*mipsI:
4355
*mipsII:
4356
*mipsIII:
4357
{
4358
  check_fpu (SD_);
4359
  TRACE_BRANCH_INPUT (PREVCOC1());
4360
  if (PREVCOC1() == TF)
4361
    {
4362
      address_word dest = NIA + (EXTEND16 (OFFSET) << 2);
4363
      TRACE_BRANCH_RESULT (dest);
4364
      DELAY_SLOT (dest);
4365
    }
4366
  else if (ND)
4367
    {
4368
      TRACE_BRANCH_RESULT (0);
4369
      NULLIFY_NEXT_INSTRUCTION ();
4370
    }
4371
  else
4372
    {
4373
      TRACE_BRANCH_RESULT (NIA);
4374
    }
4375
}
4376
 
4377
010001,01000,3.CC,1.ND,1.TF,16.OFFSET:COP1S:32,f::BC1b
4378
"bc1%s%s ":CC == 0
4379
"bc1%s%s , "
4380
*mipsIV:
4381
*mipsV:
4382
*mips32:
4383
*mips32r2:
4384
*mips64:
4385
*mips64r2:
4386
#*vr4100:
4387
*vr5000:
4388
*r3900:
4389
{
4390
  check_fpu (SD_);
4391
  if (GETFCC(CC) == TF)
4392
    {
4393
      address_word dest = NIA + (EXTEND16 (OFFSET) << 2);
4394
      DELAY_SLOT (dest);
4395
    }
4396
  else if (ND)
4397
    {
4398
      NULLIFY_NEXT_INSTRUCTION ();
4399
    }
4400
}
4401
 
4402
 
4403
010001,10,3.FMT!2!3!4!5!6!7,5.FT,5.FS,3.0,00,11,4.COND:COP1:32,f::C.cond.fmta
4404
"c.%s.%s f, f"
4405
*mipsI:
4406
*mipsII:
4407
*mipsIII:
4408
{
4409
  int fmt = FMT;
4410
  check_fpu (SD_);
4411
  Compare (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt, COND, 0);
4412
  TRACE_ALU_RESULT (ValueFCR (31));
4413
}
4414
 
4415
010001,10,3.FMT!2!3!4!5!7,5.FT,5.FS,3.CC,00,11,4.COND:COP1:32,f::C.cond.fmtb
4416
"c.%s.%s f, f":CC == 0
4417
"c.%s.%s , f, f"
4418
*mipsIV:
4419
*mipsV:
4420
*mips32:
4421
*mips32r2:
4422
*mips64:
4423
*mips64r2:
4424
*vr4100:
4425
*vr5000:
4426
*r3900:
4427
{
4428
  int fmt = FMT;
4429
  check_fpu (SD_);
4430
  check_fmt_p (SD_, fmt, instruction_0);
4431
  Compare (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt, COND, CC);
4432
  TRACE_ALU_RESULT (ValueFCR (31));
4433
}
4434
 
4435
 
4436
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001010:COP1:32,f::CEIL.L.fmt
4437
"ceil.l.%s f, f"
4438
*mipsIII:
4439
*mipsIV:
4440
*mipsV:
4441
*mips32r2:
4442
*mips64:
4443
*mips64r2:
4444
*vr4100:
4445
*vr5000:
4446
*r3900:
4447
{
4448
  int fmt = FMT;
4449
  check_fpu (SD_);
4450
  StoreFPR (FD, fmt_long, Convert (FP_RM_TOPINF, ValueFPR (FS, fmt), fmt,
4451
            fmt_long));
4452
}
4453
 
4454
 
4455
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001110:COP1:32,f::CEIL.W
4456
"ceil.w.%s f, f"
4457
*mipsII:
4458
*mipsIII:
4459
*mipsIV:
4460
*mipsV:
4461
*mips32:
4462
*mips32r2:
4463
*mips64:
4464
*mips64r2:
4465
*vr4100:
4466
*vr5000:
4467
*r3900:
4468
{
4469
  int fmt = FMT;
4470
  check_fpu (SD_);
4471
  StoreFPR (FD, fmt_word, Convert (FP_RM_TOPINF, ValueFPR (FS, fmt), fmt,
4472
            fmt_word));
4473
}
4474
 
4475
 
4476
010001,00010,5.RT,5.FS,00000000000:COP1:32,f::CFC1a
4477
"cfc1 r, f"
4478
*mipsI:
4479
*mipsII:
4480
*mipsIII:
4481
{
4482
  check_fpu (SD_);
4483
  if (FS == 0)
4484
    PENDING_FILL (RT, EXTEND32 (FCR0));
4485
  else if (FS == 31)
4486
    PENDING_FILL (RT, EXTEND32 (FCR31));
4487
  /* else NOP */
4488
}
4489
 
4490
010001,00010,5.RT,5.FS,00000000000:COP1:32,f::CFC1b
4491
"cfc1 r, f"
4492
*mipsIV:
4493
*vr4100:
4494
*vr5000:
4495
*r3900:
4496
{
4497
  check_fpu (SD_);
4498
  if (FS == 0 || FS == 31)
4499
    {
4500
      unsigned_word  fcr = ValueFCR (FS);
4501
      TRACE_ALU_INPUT1 (fcr);
4502
      GPR[RT] = fcr;
4503
    }
4504
  /* else NOP */
4505
  TRACE_ALU_RESULT (GPR[RT]);
4506
}
4507
 
4508
010001,00010,5.RT,5.FS,00000000000:COP1:32,f::CFC1c
4509
"cfc1 r, f"
4510
*mipsV:
4511
*mips32:
4512
*mips32r2:
4513
*mips64:
4514
*mips64r2:
4515
{
4516
  check_fpu (SD_);
4517
  if (FS == 0 || FS == 25 || FS == 26 || FS == 28 || FS == 31)
4518
    {
4519
      unsigned_word  fcr = ValueFCR (FS);
4520
      TRACE_ALU_INPUT1 (fcr);
4521
      GPR[RT] = fcr;
4522
    }
4523
  /* else NOP */
4524
  TRACE_ALU_RESULT (GPR[RT]);
4525
}
4526
 
4527
010001,00110,5.RT,5.FS,00000000000:COP1:32,f::CTC1a
4528
"ctc1 r, f"
4529
*mipsI:
4530
*mipsII:
4531
*mipsIII:
4532
{
4533
  check_fpu (SD_);
4534
  if (FS == 31)
4535
    PENDING_FILL (FCRCS_REGNUM, VL4_8 (GPR[RT]));
4536
  /* else NOP */
4537
}
4538
 
4539
010001,00110,5.RT,5.FS,00000000000:COP1:32,f::CTC1b
4540
"ctc1 r, f"
4541
*mipsIV:
4542
*vr4100:
4543
*vr5000:
4544
*r3900:
4545
{
4546
  check_fpu (SD_);
4547
  TRACE_ALU_INPUT1 (GPR[RT]);
4548
  if (FS == 31)
4549
    StoreFCR (FS, GPR[RT]);
4550
  /* else NOP */
4551
}
4552
 
4553
010001,00110,5.RT,5.FS,00000000000:COP1:32,f::CTC1c
4554
"ctc1 r, f"
4555
*mipsV:
4556
*mips32:
4557
*mips32r2:
4558
*mips64:
4559
*mips64r2:
4560
{
4561
  check_fpu (SD_);
4562
  TRACE_ALU_INPUT1 (GPR[RT]);
4563
  if (FS == 25 || FS == 26 || FS == 28 || FS == 31)
4564
      StoreFCR (FS, GPR[RT]);
4565
  /* else NOP */
4566
}
4567
 
4568
 
4569
//
4570
// FIXME: Does not correctly differentiate between mips*
4571
//
4572
010001,10,3.FMT!1!2!3!6!7,00000,5.FS,5.FD,100001:COP1:32,f::CVT.D.fmt
4573
"cvt.d.%s f, f"
4574
*mipsI:
4575
*mipsII:
4576
*mipsIII:
4577
*mipsIV:
4578
*mipsV:
4579
*mips32:
4580
*mips32r2:
4581
*mips64:
4582
*mips64r2:
4583
*vr4100:
4584
*vr5000:
4585
*r3900:
4586
{
4587
  int fmt = FMT;
4588
  check_fpu (SD_);
4589
  if ((fmt == fmt_double) | 0)
4590
    SignalException (ReservedInstruction, instruction_0);
4591
  StoreFPR (FD, fmt_double, Convert (GETRM (), ValueFPR (FS, fmt), fmt,
4592
            fmt_double));
4593
}
4594
 
4595
 
4596
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,100101:COP1:32,f::CVT.L.fmt
4597
"cvt.l.%s f, f"
4598
*mipsIII:
4599
*mipsIV:
4600
*mipsV:
4601
*mips32r2:
4602
*mips64:
4603
*mips64r2:
4604
*vr4100:
4605
*vr5000:
4606
*r3900:
4607
{
4608
  int fmt = FMT;
4609
  check_fpu (SD_);
4610
  if ((fmt == fmt_long) | ((fmt == fmt_long) || (fmt == fmt_word)))
4611
    SignalException (ReservedInstruction, instruction_0);
4612
  StoreFPR (FD, fmt_long, Convert (GETRM (), ValueFPR (FS, fmt), fmt,
4613
            fmt_long));
4614
}
4615
 
4616
 
4617
010001,10,000,5.FT,5.FS,5.FD,100110:COP1:32,f::CVT.PS.S
4618
"cvt.ps.s f, f, f"
4619
*mipsV:
4620
*mips32r2:
4621
*mips64:
4622
*mips64r2:
4623
{
4624
  check_fpu (SD_);
4625
  check_u64 (SD_, instruction_0);
4626
  StoreFPR (FD, fmt_ps, PackPS (ValueFPR (FS, fmt_single),
4627
                                ValueFPR (FT, fmt_single)));
4628
}
4629
 
4630
 
4631
//
4632
// FIXME: Does not correctly differentiate between mips*
4633
//
4634
010001,10,3.FMT!0!2!3!6!7,00000,5.FS,5.FD,100000:COP1:32,f::CVT.S.fmt
4635
"cvt.s.%s f, f"
4636
*mipsI:
4637
*mipsII:
4638
*mipsIII:
4639
*mipsIV:
4640
*mipsV:
4641
*mips32:
4642
*mips32r2:
4643
*mips64:
4644
*mips64r2:
4645
*vr4100:
4646
*vr5000:
4647
*r3900:
4648
{
4649
  int fmt = FMT;
4650
  check_fpu (SD_);
4651
  if ((fmt == fmt_single) | 0)
4652
    SignalException (ReservedInstruction, instruction_0);
4653
  StoreFPR (FD, fmt_single, Convert (GETRM (), ValueFPR (FS, fmt), fmt,
4654
            fmt_single));
4655
}
4656
 
4657
 
4658
010001,10,110,00000,5.FS,5.FD,101000:COP1:32,f::CVT.S.PL
4659
"cvt.s.pl f, f"
4660
*mipsV:
4661
*mips32r2:
4662
*mips64:
4663
*mips64r2:
4664
{
4665
  check_fpu (SD_);
4666
  check_u64 (SD_, instruction_0);
4667
  StoreFPR (FD, fmt_single, PSLower (ValueFPR (FS, fmt_ps)));
4668
}
4669
 
4670
 
4671
010001,10,110,00000,5.FS,5.FD,100000:COP1:32,f::CVT.S.PU
4672
"cvt.s.pu f, f"
4673
*mipsV:
4674
*mips32r2:
4675
*mips64:
4676
*mips64r2:
4677
{
4678
  check_fpu (SD_);
4679
  check_u64 (SD_, instruction_0);
4680
  StoreFPR (FD, fmt_single, PSUpper (ValueFPR (FS, fmt_ps)));
4681
}
4682
 
4683
 
4684
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,100100:COP1:32,f::CVT.W.fmt
4685
"cvt.w.%s f, f"
4686
*mipsI:
4687
*mipsII:
4688
*mipsIII:
4689
*mipsIV:
4690
*mipsV:
4691
*mips32:
4692
*mips32r2:
4693
*mips64:
4694
*mips64r2:
4695
*vr4100:
4696
*vr5000:
4697
*r3900:
4698
{
4699
  int fmt = FMT;
4700
  check_fpu (SD_);
4701
  if ((fmt == fmt_word) | ((fmt == fmt_long) || (fmt == fmt_word)))
4702
    SignalException (ReservedInstruction, instruction_0);
4703
  StoreFPR (FD, fmt_word, Convert (GETRM (), ValueFPR (FS, fmt), fmt,
4704
            fmt_word));
4705
}
4706
 
4707
 
4708
010001,10,3.FMT!2!3!4!5!6!7,5.FT,5.FS,5.FD,000011:COP1:32,f::DIV.fmt
4709
"div.%s f, f, f"
4710
*mipsI:
4711
*mipsII:
4712
*mipsIII:
4713
*mipsIV:
4714
*mipsV:
4715
*mips32:
4716
*mips32r2:
4717
*mips64:
4718
*mips64r2:
4719
*vr4100:
4720
*vr5000:
4721
*r3900:
4722
{
4723
  int fmt = FMT;
4724
  check_fpu (SD_);
4725
  StoreFPR (FD, fmt, Divide (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt));
4726
}
4727
 
4728
 
4729
010001,00001,5.RT,5.FS,00000000000:COP1:64,f::DMFC1a
4730
"dmfc1 r, f"
4731
*mipsIII:
4732
{
4733
  unsigned64 v;
4734
  check_fpu (SD_);
4735
  check_u64 (SD_, instruction_0);
4736
  if (SizeFGR () == 64)
4737
    v = FGR[FS];
4738
  else if ((FS & 0x1) == 0)
4739
    v = SET64HI (FGR[FS+1]) | FGR[FS];
4740
  else
4741
    v = SET64HI (0xDEADC0DE) | 0xBAD0BAD0;
4742
  PENDING_FILL (RT, v);
4743
  TRACE_ALU_RESULT (v);
4744
}
4745
 
4746
010001,00001,5.RT,5.FS,00000000000:COP1:64,f::DMFC1b
4747
"dmfc1 r, f"
4748
*mipsIV:
4749
*mipsV:
4750
*mips64:
4751
*mips64r2:
4752
*vr4100:
4753
*vr5000:
4754
*r3900:
4755
{
4756
  check_fpu (SD_);
4757
  check_u64 (SD_, instruction_0);
4758
  if (SizeFGR () == 64)
4759
    GPR[RT] = FGR[FS];
4760
  else if ((FS & 0x1) == 0)
4761
    GPR[RT] = SET64HI (FGR[FS+1]) | FGR[FS];
4762
  else
4763
    GPR[RT] = SET64HI (0xDEADC0DE) | 0xBAD0BAD0;
4764
  TRACE_ALU_RESULT (GPR[RT]);
4765
}
4766
 
4767
 
4768
010001,00101,5.RT,5.FS,00000000000:COP1:64,f::DMTC1a
4769
"dmtc1 r, f"
4770
*mipsIII:
4771
{
4772
  unsigned64 v;
4773
  check_fpu (SD_);
4774
  check_u64 (SD_, instruction_0);
4775
  if (SizeFGR () == 64)
4776
    PENDING_FILL ((FS + FGR_BASE), GPR[RT]);
4777
  else if ((FS & 0x1) == 0)
4778
    {
4779
      PENDING_FILL (((FS + 1) + FGR_BASE), VH4_8 (GPR[RT]));
4780
      PENDING_FILL ((FS + FGR_BASE), VL4_8 (GPR[RT]));
4781
    }
4782
  else
4783
    Unpredictable ();
4784
  TRACE_FP_RESULT (GPR[RT]);
4785
}
4786
 
4787
010001,00101,5.RT,5.FS,00000000000:COP1:64,f::DMTC1b
4788
"dmtc1 r, f"
4789
*mipsIV:
4790
*mipsV:
4791
*mips64:
4792
*mips64r2:
4793
*vr4100:
4794
*vr5000:
4795
*r3900:
4796
{
4797
  check_fpu (SD_);
4798
  check_u64 (SD_, instruction_0);
4799
  if (SizeFGR () == 64)
4800
    StoreFPR (FS, fmt_uninterpreted_64, GPR[RT]);
4801
  else if ((FS & 0x1) == 0)
4802
    StoreFPR (FS, fmt_uninterpreted_64, GPR[RT]);
4803
  else
4804
    Unpredictable ();
4805
}
4806
 
4807
 
4808
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001011:COP1:32,f::FLOOR.L.fmt
4809
"floor.l.%s f, f"
4810
*mipsIII:
4811
*mipsIV:
4812
*mipsV:
4813
*mips32r2:
4814
*mips64:
4815
*mips64r2:
4816
*vr4100:
4817
*vr5000:
4818
*r3900:
4819
{
4820
  int fmt = FMT;
4821
  check_fpu (SD_);
4822
  StoreFPR (FD, fmt_long, Convert (FP_RM_TOMINF, ValueFPR (FS, fmt), fmt,
4823
            fmt_long));
4824
}
4825
 
4826
 
4827
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001111:COP1:32,f::FLOOR.W.fmt
4828
"floor.w.%s f, f"
4829
*mipsII:
4830
*mipsIII:
4831
*mipsIV:
4832
*mipsV:
4833
*mips32:
4834
*mips32r2:
4835
*mips64:
4836
*mips64r2:
4837
*vr4100:
4838
*vr5000:
4839
*r3900:
4840
{
4841
  int fmt = FMT;
4842
  check_fpu (SD_);
4843
  StoreFPR (FD, fmt_word, Convert (FP_RM_TOMINF, ValueFPR (FS, fmt), fmt,
4844
            fmt_word));
4845
}
4846
 
4847
 
4848
110101,5.BASE,5.FT,16.OFFSET:COP1:32,f::LDC1a
4849
"ldc1 f, (r)"
4850
*mipsII:
4851
*mips32:
4852
*mips32r2:
4853
{
4854
  check_fpu (SD_);
4855
  COP_LD (1, FT, do_load_double (SD_, GPR[BASE], EXTEND16 (OFFSET)));
4856
}
4857
 
4858
 
4859
110101,5.BASE,5.FT,16.OFFSET:COP1:32,f::LDC1b
4860
"ldc1 f, (r)"
4861
*mipsIII:
4862
*mipsIV:
4863
*mipsV:
4864
*mips64:
4865
*mips64r2:
4866
*vr4100:
4867
*vr5000:
4868
*r3900:
4869
{
4870
  check_fpu (SD_);
4871
  COP_LD (1, FT, do_load (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET)));
4872
}
4873
 
4874
 
4875
010011,5.BASE,5.INDEX,5.0,5.FD,000001:COP1X:32,f::LDXC1
4876
"ldxc1 f, r(r)"
4877
*mips32r2:
4878
{
4879
  check_fpu (SD_);
4880
  COP_LD (1, FD, do_load_double (SD_, GPR[BASE], GPR[INDEX]));
4881
}
4882
 
4883
 
4884
010011,5.BASE,5.INDEX,5.0,5.FD,000001:COP1X:64,f::LDXC1
4885
"ldxc1 f, r(r)"
4886
*mipsIV:
4887
*mipsV:
4888
*mips64:
4889
*mips64r2:
4890
*vr5000:
4891
{
4892
  check_fpu (SD_);
4893
  check_u64 (SD_, instruction_0);
4894
  COP_LD (1, FD, do_load (SD_, AccessLength_DOUBLEWORD, GPR[BASE], GPR[INDEX]));
4895
}
4896
 
4897
 
4898
010011,5.BASE,5.INDEX,5.0,5.FD,000101:COP1X:32,f::LUXC1
4899
"luxc1 f, r(r)"
4900
*mips32r2:
4901
{
4902
  address_word base = GPR[BASE];
4903
  address_word index = GPR[INDEX];
4904
  address_word vaddr = base + index;
4905
  check_fpu (SD_);
4906
  if (SizeFGR () != 64)
4907
    Unpredictable ();
4908
  /* Arrange for the bottom 3 bits of (base + index) to be 0.  */
4909
  if ((vaddr & 0x7) != 0)
4910
    index -= (vaddr & 0x7);
4911
  COP_LD (1, FD, do_load_double (SD_, base, index));
4912
}
4913
 
4914
 
4915
010011,5.BASE,5.INDEX,5.0,5.FD,000101:COP1X:64,f::LUXC1
4916
"luxc1 f, r(r)"
4917
*mipsV:
4918
*mips64:
4919
*mips64r2:
4920
{
4921
  address_word base = GPR[BASE];
4922
  address_word index = GPR[INDEX];
4923
  address_word vaddr = base + index;
4924
  check_fpu (SD_);
4925
  check_u64 (SD_, instruction_0);
4926
  if (SizeFGR () != 64)
4927
    Unpredictable ();
4928
  /* Arrange for the bottom 3 bits of (base + index) to be 0.  */
4929
  if ((vaddr & 0x7) != 0)
4930
    index -= (vaddr & 0x7);
4931
  COP_LD (1, FD, do_load (SD_, AccessLength_DOUBLEWORD, base, index));
4932
}
4933
 
4934
 
4935
110001,5.BASE,5.FT,16.OFFSET:COP1:32,f::LWC1
4936
"lwc1 f, (r)"
4937
*mipsI:
4938
*mipsII:
4939
*mipsIII:
4940
*mipsIV:
4941
*mipsV:
4942
*mips32:
4943
*mips32r2:
4944
*mips64:
4945
*mips64r2:
4946
*vr4100:
4947
*vr5000:
4948
*r3900:
4949
{
4950
  check_fpu (SD_);
4951
  COP_LW (1, FT, do_load (SD_, AccessLength_WORD, GPR[BASE], EXTEND16 (OFFSET)));
4952
}
4953
 
4954
 
4955
010011,5.BASE,5.INDEX,5.0,5.FD,000000:COP1X:32,f::LWXC1
4956
"lwxc1 f, r(r)"
4957
*mipsIV:
4958
*mipsV:
4959
*mips32r2:
4960
*mips64:
4961
*mips64r2:
4962
*vr5000:
4963
{
4964
  check_fpu (SD_);
4965
  check_u64 (SD_, instruction_0);
4966
  COP_LW (1, FD, do_load (SD_, AccessLength_WORD, GPR[BASE], GPR[INDEX]));
4967
}
4968
 
4969
 
4970
 
4971
010011,5.FR,5.FT,5.FS,5.FD,100,3.FMT!2!3!4!5!7:COP1X:32,f::MADD.fmt
4972
"madd.%s f, f, f, f"
4973
*mipsIV:
4974
*mipsV:
4975
*mips32r2:
4976
*mips64:
4977
*mips64r2:
4978
*vr5000:
4979
{
4980
  int fmt = FMT;
4981
  check_fpu (SD_);
4982
  check_u64 (SD_, instruction_0);
4983
  check_fmt_p (SD_, fmt, instruction_0);
4984
  StoreFPR (FD, fmt, MultiplyAdd (ValueFPR (FS, fmt), ValueFPR (FT, fmt),
4985
                                  ValueFPR (FR, fmt), fmt));
4986
}
4987
 
4988
 
4989
010001,00000,5.RT,5.FS,00000000000:COP1:32,f::MFC1a
4990
"mfc1 r, f"
4991
*mipsI:
4992
*mipsII:
4993
*mipsIII:
4994
{
4995
  unsigned64 v;
4996
  check_fpu (SD_);
4997
  v = EXTEND32 (FGR[FS]);
4998
  PENDING_FILL (RT, v);
4999
  TRACE_ALU_RESULT (v);
5000
}
5001
 
5002
010001,00000,5.RT,5.FS,00000000000:COP1:32,f::MFC1b
5003
"mfc1 r, f"
5004
*mipsIV:
5005
*mipsV:
5006
*mips32:
5007
*mips32r2:
5008
*mips64:
5009
*mips64r2:
5010
*vr4100:
5011
*vr5000:
5012
*r3900:
5013
{
5014
  check_fpu (SD_);
5015
  GPR[RT] = EXTEND32 (FGR[FS]);
5016
  TRACE_ALU_RESULT (GPR[RT]);
5017
}
5018
 
5019
 
5020
010001,10,3.FMT!2!3!4!5!7,00000,5.FS,5.FD,000110:COP1:32,f::MOV.fmt
5021
"mov.%s f, f"
5022
*mipsI:
5023
*mipsII:
5024
*mipsIII:
5025
*mipsIV:
5026
*mipsV:
5027
*mips32:
5028
*mips32r2:
5029
*mips64:
5030
*mips64r2:
5031
*vr4100:
5032
*vr5000:
5033
*r3900:
5034
{
5035
  int fmt = FMT;
5036
  check_fpu (SD_);
5037
  check_fmt_p (SD_, fmt, instruction_0);
5038
  StoreFPR (FD, fmt, ValueFPR (FS, fmt));
5039
}
5040
 
5041
 
5042
// MOVF
5043
// MOVT
5044
000000,5.RS,3.CC,0,1.TF,5.RD,00000,000001:SPECIAL:32,f::MOVtf
5045
"mov%s r, r, "
5046
*mipsIV:
5047
*mipsV:
5048
*mips32:
5049
*mips32r2:
5050
*mips64:
5051
*mips64r2:
5052
*vr5000:
5053
{
5054
  check_fpu (SD_);
5055
  if (GETFCC(CC) == TF)
5056
    GPR[RD] = GPR[RS];
5057
}
5058
 
5059
 
5060
// MOVF.fmt
5061
// MOVT.fmt
5062
010001,10,3.FMT!2!3!4!5!7,3.CC,0,1.TF,5.FS,5.FD,010001:COP1:32,f::MOVtf.fmt
5063
"mov%s.%s f, f, "
5064
*mipsIV:
5065
*mipsV:
5066
*mips32:
5067
*mips32r2:
5068
*mips64:
5069
*mips64r2:
5070
*vr5000:
5071
{
5072
  int fmt = FMT;
5073
  check_fpu (SD_);
5074
  if (fmt != fmt_ps)
5075
    {
5076
      if (GETFCC(CC) == TF)
5077
        StoreFPR (FD, fmt, ValueFPR (FS, fmt));
5078
      else
5079
        StoreFPR (FD, fmt, ValueFPR (FD, fmt));   /* set fmt */
5080
    }
5081
  else
5082
    {
5083
      unsigned64 fd;
5084
      fd = PackPS (PSUpper (ValueFPR ((GETFCC (CC+1) == TF) ? FS : FD,
5085
                                      fmt_ps)),
5086
                   PSLower (ValueFPR ((GETFCC (CC+0) == TF) ? FS : FD,
5087
                                      fmt_ps)));
5088
      StoreFPR (FD, fmt_ps, fd);
5089
    }
5090
}
5091
 
5092
 
5093
010001,10,3.FMT!2!3!4!5!7,5.RT,5.FS,5.FD,010011:COP1:32,f::MOVN.fmt
5094
"movn.%s f, f, r"
5095
*mipsIV:
5096
*mipsV:
5097
*mips32:
5098
*mips32r2:
5099
*mips64:
5100
*mips64r2:
5101
*vr5000:
5102
{
5103
  check_fpu (SD_);
5104
  if (GPR[RT] != 0)
5105
    StoreFPR (FD, FMT, ValueFPR (FS, FMT));
5106
  else
5107
    StoreFPR (FD, FMT, ValueFPR (FD, FMT));
5108
}
5109
 
5110
 
5111
// MOVT see MOVtf
5112
 
5113
 
5114
// MOVT.fmt see MOVtf.fmt
5115
 
5116
 
5117
 
5118
010001,10,3.FMT!2!3!4!5!7,5.RT,5.FS,5.FD,010010:COP1:32,f::MOVZ.fmt
5119
"movz.%s f, f, r"
5120
*mipsIV:
5121
*mipsV:
5122
*mips32:
5123
*mips32r2:
5124
*mips64:
5125
*mips64r2:
5126
*vr5000:
5127
{
5128
  check_fpu (SD_);
5129
  if (GPR[RT] == 0)
5130
    StoreFPR (FD, FMT, ValueFPR (FS, FMT));
5131
  else
5132
    StoreFPR (FD, FMT, ValueFPR (FD, FMT));
5133
}
5134
 
5135
 
5136
010011,5.FR,5.FT,5.FS,5.FD,101,3.FMT!2!3!4!5!7:COP1X:32,f::MSUB.fmt
5137
"msub.%s f, f, f, f"
5138
*mipsIV:
5139
*mipsV:
5140
*mips32r2:
5141
*mips64:
5142
*mips64r2:
5143
*vr5000:
5144
{
5145
  int fmt = FMT;
5146
  check_fpu (SD_);
5147
  check_u64 (SD_, instruction_0);
5148
  check_fmt_p (SD_, fmt, instruction_0);
5149
  StoreFPR (FD, fmt, MultiplySub (ValueFPR (FS, fmt), ValueFPR (FT, fmt),
5150
                                  ValueFPR (FR, fmt), fmt));
5151
}
5152
 
5153
 
5154
010001,00100,5.RT,5.FS,00000000000:COP1:32,f::MTC1a
5155
"mtc1 r, f"
5156
*mipsI:
5157
*mipsII:
5158
*mipsIII:
5159
{
5160
  check_fpu (SD_);
5161
  if (SizeFGR () == 64)
5162
    PENDING_FILL ((FS + FGR_BASE), (SET64HI (0xDEADC0DE) | VL4_8 (GPR[RT])));
5163
  else
5164
    PENDING_FILL ((FS + FGR_BASE), VL4_8 (GPR[RT]));
5165
  TRACE_FP_RESULT (GPR[RT]);
5166
}
5167
 
5168
010001,00100,5.RT,5.FS,00000000000:COP1:32,f::MTC1b
5169
"mtc1 r, f"
5170
*mipsIV:
5171
*mipsV:
5172
*mips32:
5173
*mips32r2:
5174
*mips64:
5175
*mips64r2:
5176
*vr4100:
5177
*vr5000:
5178
*r3900:
5179
{
5180
  check_fpu (SD_);
5181
  StoreFPR (FS, fmt_uninterpreted_32, VL4_8 (GPR[RT]));
5182
}
5183
 
5184
 
5185
010001,10,3.FMT!2!3!4!5!7,5.FT,5.FS,5.FD,000010:COP1:32,f::MUL.fmt
5186
"mul.%s f, f, f"
5187
*mipsI:
5188
*mipsII:
5189
*mipsIII:
5190
*mipsIV:
5191
*mipsV:
5192
*mips32:
5193
*mips32r2:
5194
*mips64:
5195
*mips64r2:
5196
*vr4100:
5197
*vr5000:
5198
*r3900:
5199
{
5200
  int fmt = FMT;
5201
  check_fpu (SD_);
5202
  check_fmt_p (SD_, fmt, instruction_0);
5203
  StoreFPR (FD, fmt, Multiply (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt));
5204
}
5205
 
5206
 
5207
010001,10,3.FMT!2!3!4!5!7,00000,5.FS,5.FD,000111:COP1:32,f::NEG.fmt
5208
"neg.%s f, f"
5209
*mipsI:
5210
*mipsII:
5211
*mipsIII:
5212
*mipsIV:
5213
*mipsV:
5214
*mips32:
5215
*mips32r2:
5216
*mips64:
5217
*mips64r2:
5218
*vr4100:
5219
*vr5000:
5220
*r3900:
5221
{
5222
  int fmt = FMT;
5223
  check_fpu (SD_);
5224
  check_fmt_p (SD_, fmt, instruction_0);
5225
  StoreFPR (FD, fmt, Negate (ValueFPR (FS, fmt), fmt));
5226
}
5227
 
5228
 
5229
010011,5.FR,5.FT,5.FS,5.FD,110,3.FMT!2!3!4!5!7:COP1X:32,f::NMADD.fmt
5230
"nmadd.%s f, f, f, f"
5231
*mipsIV:
5232
*mipsV:
5233
*mips32r2:
5234
*mips64:
5235
*mips64r2:
5236
*vr5000:
5237
{
5238
  int fmt = FMT;
5239
  check_fpu (SD_);
5240
  check_u64 (SD_, instruction_0);
5241
  check_fmt_p (SD_, fmt, instruction_0);
5242
  StoreFPR (FD, fmt, NegMultiplyAdd (ValueFPR (FS, fmt), ValueFPR (FT, fmt),
5243
                                     ValueFPR (FR, fmt), fmt));
5244
}
5245
 
5246
 
5247
010011,5.FR,5.FT,5.FS,5.FD,111,3.FMT!2!3!4!5!7:COP1X:32,f::NMSUB.fmt
5248
"nmsub.%s f, f, f, f"
5249
*mipsIV:
5250
*mipsV:
5251
*mips32r2:
5252
*mips64:
5253
*mips64r2:
5254
*vr5000:
5255
{
5256
  int fmt = FMT;
5257
  check_fpu (SD_);
5258
  check_u64 (SD_, instruction_0);
5259
  check_fmt_p (SD_, fmt, instruction_0);
5260
  StoreFPR (FD, fmt, NegMultiplySub (ValueFPR (FS, fmt), ValueFPR (FT, fmt),
5261
                                     ValueFPR (FR, fmt), fmt));
5262
}
5263
 
5264
 
5265
010001,10,110,5.FT,5.FS,5.FD,101100:COP1:32,f::PLL.PS
5266
"pll.ps f, f, f"
5267
*mipsV:
5268
*mips32r2:
5269
*mips64:
5270
*mips64r2:
5271
{
5272
  check_fpu (SD_);
5273
  check_u64 (SD_, instruction_0);
5274
  StoreFPR (FD, fmt_ps, PackPS (PSLower (ValueFPR (FS, fmt_ps)),
5275
                                PSLower (ValueFPR (FT, fmt_ps))));
5276
}
5277
 
5278
 
5279
010001,10,110,5.FT,5.FS,5.FD,101101:COP1:32,f::PLU.PS
5280
"plu.ps f, f, f"
5281
*mipsV:
5282
*mips32r2:
5283
*mips64:
5284
*mips64r2:
5285
{
5286
  check_fpu (SD_);
5287
  check_u64 (SD_, instruction_0);
5288
  StoreFPR (FD, fmt_ps, PackPS (PSLower (ValueFPR (FS, fmt_ps)),
5289
                                PSUpper (ValueFPR (FT, fmt_ps))));
5290
}
5291
 
5292
 
5293
010011,5.BASE,5.INDEX,5.HINT,00000,001111:COP1X:32::PREFX
5294
"prefx , r(r)"
5295
*mipsIV:
5296
*mipsV:
5297
*mips32r2:
5298
*mips64:
5299
*mips64r2:
5300
*vr5000:
5301
{
5302
  address_word base = GPR[BASE];
5303
  address_word index = GPR[INDEX];
5304
  {
5305
    address_word vaddr = loadstore_ea (SD_, base, index);
5306
    address_word paddr;
5307
    int uncached;
5308
    if (AddressTranslation(vaddr,isDATA,isLOAD,&paddr,&uncached,isTARGET,isREAL))
5309
      Prefetch(uncached,paddr,vaddr,isDATA,HINT);
5310
  }
5311
}
5312
 
5313
 
5314
010001,10,110,5.FT,5.FS,5.FD,101110:COP1:32,f::PUL.PS
5315
"pul.ps f, f, f"
5316
*mipsV:
5317
*mips32r2:
5318
*mips64:
5319
*mips64r2:
5320
{
5321
  check_fpu (SD_);
5322
  check_u64 (SD_, instruction_0);
5323
  StoreFPR (FD, fmt_ps, PackPS (PSUpper (ValueFPR (FS, fmt_ps)),
5324
                                PSLower (ValueFPR (FT, fmt_ps))));
5325
}
5326
 
5327
 
5328
010001,10,110,5.FT,5.FS,5.FD,101111:COP1:32,f::PUU.PS
5329
"puu.ps f, f, f"
5330
*mipsV:
5331
*mips32r2:
5332
*mips64:
5333
*mips64r2:
5334
{
5335
  check_fpu (SD_);
5336
  check_u64 (SD_, instruction_0);
5337
  StoreFPR (FD, fmt_ps, PackPS (PSUpper (ValueFPR (FS, fmt_ps)),
5338
                                PSUpper (ValueFPR (FT, fmt_ps))));
5339
}
5340
 
5341
 
5342
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,010101:COP1:32,f::RECIP.fmt
5343
"recip.%s f, f"
5344
*mipsIV:
5345
*mipsV:
5346
*mips32r2:
5347
*mips64:
5348
*mips64r2:
5349
*vr5000:
5350
{
5351
  int fmt = FMT;
5352
  check_fpu (SD_);
5353
  StoreFPR (FD, fmt, Recip (ValueFPR (FS, fmt), fmt));
5354
}
5355
 
5356
 
5357
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001000:COP1:32,f::ROUND.L.fmt
5358
"round.l.%s f, f"
5359
*mipsIII:
5360
*mipsIV:
5361
*mipsV:
5362
*mips32r2:
5363
*mips64:
5364
*mips64r2:
5365
*vr4100:
5366
*vr5000:
5367
*r3900:
5368
{
5369
  int fmt = FMT;
5370
  check_fpu (SD_);
5371
  StoreFPR (FD, fmt_long, Convert (FP_RM_NEAREST, ValueFPR (FS, fmt), fmt,
5372
            fmt_long));
5373
}
5374
 
5375
 
5376
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001100:COP1:32,f::ROUND.W.fmt
5377
"round.w.%s f, f"
5378
*mipsII:
5379
*mipsIII:
5380
*mipsIV:
5381
*mipsV:
5382
*mips32:
5383
*mips32r2:
5384
*mips64:
5385
*mips64r2:
5386
*vr4100:
5387
*vr5000:
5388
*r3900:
5389
{
5390
  int fmt = FMT;
5391
  check_fpu (SD_);
5392
  StoreFPR (FD, fmt_word, Convert (FP_RM_NEAREST, ValueFPR (FS, fmt), fmt,
5393
            fmt_word));
5394
}
5395
 
5396
 
5397
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,010110:COP1:32,f::RSQRT.fmt
5398
"rsqrt.%s f, f"
5399
*mipsIV:
5400
*mipsV:
5401
*mips32r2:
5402
*mips64:
5403
*mips64r2:
5404
*vr5000:
5405
{
5406
  int fmt = FMT;
5407
  check_fpu (SD_);
5408
  StoreFPR (FD, fmt, RSquareRoot (ValueFPR (FS, fmt), fmt));
5409
}
5410
 
5411
 
5412
111101,5.BASE,5.FT,16.OFFSET:COP1:32,f::SDC1a
5413
"sdc1 f, (r)"
5414
*mipsII:
5415
*mips32:
5416
*mips32r2:
5417
{
5418
  check_fpu (SD_);
5419
  do_store_double (SD_, GPR[BASE], EXTEND16 (OFFSET), COP_SD (1, FT));
5420
}
5421
 
5422
 
5423
111101,5.BASE,5.FT,16.OFFSET:COP1:32,f::SDC1b
5424
"sdc1 f, (r)"
5425
*mipsIII:
5426
*mipsIV:
5427
*mipsV:
5428
*mips64:
5429
*mips64r2:
5430
*vr4100:
5431
*vr5000:
5432
*r3900:
5433
{
5434
  check_fpu (SD_);
5435
  do_store (SD_, AccessLength_DOUBLEWORD, GPR[BASE], EXTEND16 (OFFSET), COP_SD (1, FT));
5436
}
5437
 
5438
 
5439
010011,5.BASE,5.INDEX,5.FS,00000001001:COP1X:32,f::SDXC1
5440
"sdxc1 f, r(r)"
5441
*mips32r2
5442
{
5443
  check_fpu (SD_);
5444
  do_store_double (SD_, GPR[BASE], GPR[INDEX], COP_SD (1, FS));
5445
}
5446
 
5447
 
5448
010011,5.BASE,5.INDEX,5.FS,00000001001:COP1X:64,f::SDXC1
5449
"sdxc1 f, r(r)"
5450
*mipsIV:
5451
*mipsV:
5452
*mips64:
5453
*mips64r2:
5454
*vr5000:
5455
{
5456
  check_fpu (SD_);
5457
  check_u64 (SD_, instruction_0);
5458
  do_store (SD_, AccessLength_DOUBLEWORD, GPR[BASE], GPR[INDEX], COP_SD (1, FS));
5459
}
5460
 
5461
 
5462
010011,5.BASE,5.INDEX,5.FS,00000,001101:COP1X:32,f::SUXC1
5463
"suxc1 f, r(r)"
5464
*mips32r2:
5465
{
5466
  address_word base = GPR[BASE];
5467
  address_word index = GPR[INDEX];
5468
  address_word vaddr = base + index;
5469
  check_fpu (SD_);
5470
  if (SizeFGR () != 64)
5471
    Unpredictable ();
5472
  /* Arrange for the bottom 3 bits of (base + index) to be 0.  */
5473
  if ((vaddr & 0x7) != 0)
5474
    index -= (vaddr & 0x7);
5475
  do_store_double (SD_, base, index, COP_SD (1, FS));
5476
}
5477
 
5478
 
5479
010011,5.BASE,5.INDEX,5.FS,00000,001101:COP1X:64,f::SUXC1
5480
"suxc1 f, r(r)"
5481
*mipsV:
5482
*mips64:
5483
*mips64r2:
5484
{
5485
  address_word base = GPR[BASE];
5486
  address_word index = GPR[INDEX];
5487
  address_word vaddr = base + index;
5488
  check_fpu (SD_);
5489
  check_u64 (SD_, instruction_0);
5490
  if (SizeFGR () != 64)
5491
    Unpredictable ();
5492
  /* Arrange for the bottom 3 bits of (base + index) to be 0.  */
5493
  if ((vaddr & 0x7) != 0)
5494
    index -= (vaddr & 0x7);
5495
  do_store (SD_, AccessLength_DOUBLEWORD, base, index, COP_SD (1, FS));
5496
}
5497
 
5498
 
5499
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,000100:COP1:32,f::SQRT.fmt
5500
"sqrt.%s f, f"
5501
*mipsII:
5502
*mipsIII:
5503
*mipsIV:
5504
*mipsV:
5505
*mips32:
5506
*mips32r2:
5507
*mips64:
5508
*mips64r2:
5509
*vr4100:
5510
*vr5000:
5511
*r3900:
5512
{
5513
  int fmt = FMT;
5514
  check_fpu (SD_);
5515
  StoreFPR (FD, fmt,  (SquareRoot (ValueFPR (FS, fmt), fmt)));
5516
}
5517
 
5518
 
5519
010001,10,3.FMT!2!3!4!5!7,5.FT,5.FS,5.FD,000001:COP1:32,f::SUB.fmt
5520
"sub.%s f, f, f"
5521
*mipsI:
5522
*mipsII:
5523
*mipsIII:
5524
*mipsIV:
5525
*mipsV:
5526
*mips32:
5527
*mips32r2:
5528
*mips64:
5529
*mips64r2:
5530
*vr4100:
5531
*vr5000:
5532
*r3900:
5533
{
5534
  int fmt = FMT;
5535
  check_fpu (SD_);
5536
  check_fmt_p (SD_, fmt, instruction_0);
5537
  StoreFPR (FD, fmt, Sub (ValueFPR (FS, fmt), ValueFPR (FT, fmt), fmt));
5538
}
5539
 
5540
 
5541
 
5542
111001,5.BASE,5.FT,16.OFFSET:COP1:32,f::SWC1
5543
"swc1 f, (r)"
5544
*mipsI:
5545
*mipsII:
5546
*mipsIII:
5547
*mipsIV:
5548
*mipsV:
5549
*mips32:
5550
*mips32r2:
5551
*mips64:
5552
*mips64r2:
5553
*vr4100:
5554
*vr5000:
5555
*r3900:
5556
{
5557
  address_word base = GPR[BASE];
5558
  address_word offset = EXTEND16 (OFFSET);
5559
  check_fpu (SD_);
5560
  {
5561
    address_word vaddr = loadstore_ea (SD_, base, offset);
5562
    address_word paddr;
5563
    int uncached;
5564
    if ((vaddr & 3) != 0)
5565
      {
5566
        SIM_CORE_SIGNAL (SD, CPU, cia, read_map, AccessLength_WORD+1, vaddr, write_transfer, sim_core_unaligned_signal);
5567
      }
5568
    else
5569
      {
5570
        if (AddressTranslation(vaddr,isDATA,isSTORE,&paddr,&uncached,isTARGET,isREAL))
5571
          {
5572
            uword64 memval = 0;
5573
            uword64 memval1 = 0;
5574
            uword64 mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
5575
            address_word reverseendian = (ReverseEndian ?(mask ^ AccessLength_WORD): 0);
5576
            address_word bigendiancpu = (BigEndianCPU ?(mask ^ AccessLength_WORD): 0);
5577
            unsigned int byte;
5578
            paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
5579
            byte = ((vaddr & mask) ^ bigendiancpu);
5580
            memval = (((uword64)COP_SW(((instruction_0 >> 26) & 0x3),FT)) << (8 * byte));
5581
            StoreMemory(uncached,AccessLength_WORD,memval,memval1,paddr,vaddr,isREAL);
5582
          }
5583
      }
5584
  }
5585
}
5586
 
5587
 
5588
010011,5.BASE,5.INDEX,5.FS,00000,001000:COP1X:32,f::SWXC1
5589
"swxc1 f, r(r)"
5590
*mipsIV:
5591
*mipsV:
5592
*mips32r2:
5593
*mips64:
5594
*mips64r2:
5595
*vr5000:
5596
{
5597
 
5598
  address_word base = GPR[BASE];
5599
  address_word index = GPR[INDEX];
5600
  check_fpu (SD_);
5601
  check_u64 (SD_, instruction_0);
5602
  {
5603
   address_word vaddr = loadstore_ea (SD_, base, index);
5604
   address_word paddr;
5605
   int uncached;
5606
   if ((vaddr & 3) != 0)
5607
     {
5608
       SIM_CORE_SIGNAL (SD, CPU, cia, read_map, 4, vaddr, write_transfer, sim_core_unaligned_signal);
5609
     }
5610
   else
5611
   {
5612
    if (AddressTranslation(vaddr,isDATA,isSTORE,&paddr,&uncached,isTARGET,isREAL))
5613
    {
5614
     unsigned64 memval = 0;
5615
     unsigned64 memval1 = 0;
5616
     unsigned64 mask = (WITH_TARGET_WORD_BITSIZE == 64 ? 0x7 : 0x3);
5617
     address_word reverseendian = (ReverseEndian ? (mask ^ AccessLength_WORD) : 0);
5618
     address_word bigendiancpu = (BigEndianCPU ? (mask ^ AccessLength_WORD) : 0);
5619
     unsigned int byte;
5620
     paddr = ((paddr & ~mask) | ((paddr & mask) ^ reverseendian));
5621
     byte = ((vaddr & mask) ^ bigendiancpu);
5622
     memval = (((unsigned64)COP_SW(1,FS)) << (8 * byte));
5623
      {
5624
       StoreMemory(uncached,AccessLength_WORD,memval,memval1,paddr,vaddr,isREAL);
5625
      }
5626
    }
5627
   }
5628
  }
5629
}
5630
 
5631
 
5632
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001001:COP1:32,f::TRUNC.L.fmt
5633
"trunc.l.%s f, f"
5634
*mipsIII:
5635
*mipsIV:
5636
*mipsV:
5637
*mips32r2:
5638
*mips64:
5639
*mips64r2:
5640
*vr4100:
5641
*vr5000:
5642
*r3900:
5643
{
5644
  int fmt = FMT;
5645
  check_fpu (SD_);
5646
  StoreFPR (FD, fmt_long, Convert (FP_RM_TOZERO, ValueFPR (FS, fmt), fmt,
5647
            fmt_long));
5648
}
5649
 
5650
 
5651
010001,10,3.FMT!2!3!4!5!6!7,00000,5.FS,5.FD,001101:COP1:32,f::TRUNC.W
5652
"trunc.w.%s f, f"
5653
*mipsII:
5654
*mipsIII:
5655
*mipsIV:
5656
*mipsV:
5657
*mips32:
5658
*mips32r2:
5659
*mips64:
5660
*mips64r2:
5661
*vr4100:
5662
*vr5000:
5663
*r3900:
5664
{
5665
  int fmt = FMT;
5666
  check_fpu (SD_);
5667
  StoreFPR (FD, fmt_word, Convert (FP_RM_TOZERO, ValueFPR (FS, fmt), fmt,
5668
            fmt_word));
5669
}
5670
 
5671
 
5672
//
5673
// MIPS Architecture:
5674
//
5675
//        System Control Instruction Set (COP0)
5676
//
5677
 
5678
 
5679
010000,01000,00000,16.OFFSET:COP0:32::BC0F
5680
"bc0f "
5681
*mipsI:
5682
*mipsII:
5683
*mipsIII:
5684
*mipsIV:
5685
*mipsV:
5686
*mips32:
5687
*mips32r2:
5688
*mips64:
5689
*mips64r2:
5690
*vr4100:
5691
*vr5000:
5692
 
5693
010000,01000,00000,16.OFFSET:COP0:32::BC0F
5694
"bc0f "
5695
// stub needed for eCos as tx39 hardware bug workaround
5696
*r3900:
5697
{
5698
  /* do nothing */
5699
}
5700
 
5701
 
5702
010000,01000,00010,16.OFFSET:COP0:32::BC0FL
5703
"bc0fl "
5704
*mipsI:
5705
*mipsII:
5706
*mipsIII:
5707
*mipsIV:
5708
*mipsV:
5709
*mips32:
5710
*mips32r2:
5711
*mips64:
5712
*mips64r2:
5713
*vr4100:
5714
*vr5000:
5715
 
5716
 
5717
010000,01000,00001,16.OFFSET:COP0:32::BC0T
5718
"bc0t "
5719
*mipsI:
5720
*mipsII:
5721
*mipsIII:
5722
*mipsIV:
5723
*mipsV:
5724
*mips32:
5725
*mips32r2:
5726
*mips64:
5727
*mips64r2:
5728
*vr4100:
5729
 
5730
 
5731
010000,01000,00011,16.OFFSET:COP0:32::BC0TL
5732
"bc0tl "
5733
*mipsI:
5734
*mipsII:
5735
*mipsIII:
5736
*mipsIV:
5737
*mipsV:
5738
*mips32:
5739
*mips32r2:
5740
*mips64:
5741
*mips64r2:
5742
*vr4100:
5743
*vr5000:
5744
 
5745
 
5746
101111,5.BASE,5.OP,16.OFFSET:NORMAL:32::CACHE
5747
"cache , (r)"
5748
*mipsIII:
5749
*mipsIV:
5750
*mipsV:
5751
*mips32:
5752
*mips32r2:
5753
*mips64:
5754
*mips64r2:
5755
*vr4100:
5756
*vr5000:
5757
*r3900:
5758
{
5759
  address_word base = GPR[BASE];
5760
  address_word offset = EXTEND16 (OFFSET);
5761
  {
5762
    address_word vaddr = loadstore_ea (SD_, base, offset);
5763
    address_word paddr;
5764
    int uncached;
5765
    if (AddressTranslation(vaddr,isDATA,isLOAD,&paddr,&uncached,isTARGET,isREAL))
5766
      CacheOp(OP,vaddr,paddr,instruction_0);
5767
  }
5768
}
5769
 
5770
 
5771
010000,00001,5.RT,5.RD,00000000000:COP0:64::DMFC0
5772
"dmfc0 r, r"
5773
*mipsIII:
5774
*mipsIV:
5775
*mipsV:
5776
*mips64:
5777
*mips64r2:
5778
{
5779
  check_u64 (SD_, instruction_0);
5780
  DecodeCoproc (instruction_0);
5781
}
5782
 
5783
 
5784
010000,00101,5.RT,5.RD,00000000000:COP0:64::DMTC0
5785
"dmtc0 r, r"
5786
*mipsIII:
5787
*mipsIV:
5788
*mipsV:
5789
*mips64:
5790
*mips64r2:
5791
{
5792
  check_u64 (SD_, instruction_0);
5793
  DecodeCoproc (instruction_0);
5794
}
5795
 
5796
 
5797
010000,1,0000000000000000000,011000:COP0:32::ERET
5798
"eret"
5799
*mipsIII:
5800
*mipsIV:
5801
*mipsV:
5802
*mips32:
5803
*mips32r2:
5804
*mips64:
5805
*mips64r2:
5806
*vr4100:
5807
*vr5000:
5808
{
5809
  if (SR & status_ERL)
5810
    {
5811
      /* Oops, not yet available */
5812
      sim_io_printf (SD, "Warning: ERET when SR[ERL] set not supported");
5813
      NIA = EPC;
5814
      SR &= ~status_ERL;
5815
    }
5816
  else
5817
    {
5818
      NIA = EPC;
5819
      SR &= ~status_EXL;
5820
    }
5821
}
5822
 
5823
 
5824
010000,00000,5.RT,5.RD,00000,6.REGX:COP0:32::MFC0
5825
"mfc0 r, r # "
5826
*mipsI:
5827
*mipsII:
5828
*mipsIII:
5829
*mipsIV:
5830
*mipsV:
5831
*mips32:
5832
*mips32r2:
5833
*mips64:
5834
*mips64r2:
5835
*vr4100:
5836
*vr5000:
5837
*r3900:
5838
{
5839
  TRACE_ALU_INPUT0 ();
5840
  DecodeCoproc (instruction_0);
5841
  TRACE_ALU_RESULT (GPR[RT]);
5842
}
5843
 
5844
010000,00100,5.RT,5.RD,00000,6.REGX:COP0:32::MTC0
5845
"mtc0 r, r # "
5846
*mipsI:
5847
*mipsII:
5848
*mipsIII:
5849
*mipsIV:
5850
*mipsV:
5851
*mips32:
5852
*mips32r2:
5853
*mips64:
5854
*mips64r2:
5855
*vr4100:
5856
*vr5000:
5857
*r3900:
5858
{
5859
  DecodeCoproc (instruction_0);
5860
}
5861
 
5862
 
5863
010000,1,0000000000000000000,010000:COP0:32::RFE
5864
"rfe"
5865
*mipsI:
5866
*mipsII:
5867
*mipsIII:
5868
*mipsIV:
5869
*mipsV:
5870
*vr4100:
5871
*vr5000:
5872
*r3900:
5873
{
5874
  DecodeCoproc (instruction_0);
5875
}
5876
 
5877
 
5878
0100,ZZ!0!1!3,5.COP_FUN0!8,5.COP_FUN1,16.COP_FUN2:NORMAL:32::COPz
5879
"cop "
5880
*mipsI:
5881
*mipsII:
5882
*mipsIII:
5883
*mipsIV:
5884
*mipsV:
5885
*mips32:
5886
*mips32r2:
5887
*mips64:
5888
*mips64r2:
5889
*vr4100:
5890
*r3900:
5891
{
5892
  DecodeCoproc (instruction_0);
5893
}
5894
 
5895
 
5896
 
5897
010000,1,0000000000000000000,001000:COP0:32::TLBP
5898
"tlbp"
5899
*mipsI:
5900
*mipsII:
5901
*mipsIII:
5902
*mipsIV:
5903
*mipsV:
5904
*mips32:
5905
*mips32r2:
5906
*mips64:
5907
*mips64r2:
5908
*vr4100:
5909
*vr5000:
5910
 
5911
 
5912
010000,1,0000000000000000000,000001:COP0:32::TLBR
5913
"tlbr"
5914
*mipsI:
5915
*mipsII:
5916
*mipsIII:
5917
*mipsIV:
5918
*mipsV:
5919
*mips32:
5920
*mips32r2:
5921
*mips64:
5922
*mips64r2:
5923
*vr4100:
5924
*vr5000:
5925
 
5926
 
5927
010000,1,0000000000000000000,000010:COP0:32::TLBWI
5928
"tlbwi"
5929
*mipsI:
5930
*mipsII:
5931
*mipsIII:
5932
*mipsIV:
5933
*mipsV:
5934
*mips32:
5935
*mips32r2:
5936
*mips64:
5937
*mips64r2:
5938
*vr4100:
5939
*vr5000:
5940
 
5941
 
5942
010000,1,0000000000000000000,000110:COP0:32::TLBWR
5943
"tlbwr"
5944
*mipsI:
5945
*mipsII:
5946
*mipsIII:
5947
*mipsIV:
5948
*mipsV:
5949
*mips32:
5950
*mips32r2:
5951
*mips64:
5952
*mips64r2:
5953
*vr4100:
5954
*vr5000:
5955
 
5956
 
5957
:include:::mips3264r2.igen
5958
:include:::m16.igen
5959
:include:::m16e.igen
5960
:include:::mdmx.igen
5961
:include:::mips3d.igen
5962
:include:::sb1.igen
5963
:include:::tx.igen
5964
:include:::vr.igen
5965
:include:::dsp.igen
5966
:include:::dsp2.igen
5967
:include:::smartmips.igen
5968
 

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