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[/] [openrisc/] [trunk/] [or1ksim/] [cpu/] [or32/] [insnset.c] - Blame information for rev 516

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Line No. Rev Author Line
1 19 jeremybenn
/* insnset.c -- Instruction specific functions.
2
 
3
   Copyright (C) 1999 Damjan Lampret, lampret@opencores.org
4
                 2000-2002 Marko Mlinar, markom@opencores.org
5
   Copyright (C) 2008 Embecosm Limited
6 100 julius
   Copyright (C) 2009 Jungsook yang, jungsook.yang@uci.edu
7 19 jeremybenn
 
8
   Contributor Jeremy Bennett <jeremy.bennett@embecosm.com>
9 100 julius
   Contributor Julius Baxter julius@orsoc.se
10
 
11 19 jeremybenn
   This file is part of OpenRISC 1000 Architectural Simulator.
12
 
13
   This program is free software; you can redistribute it and/or modify it
14
   under the terms of the GNU General Public License as published by the Free
15
   Software Foundation; either version 3 of the License, or (at your option)
16
   any later version.
17
 
18
   This program is distributed in the hope that it will be useful, but WITHOUT
19
   ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
20
   FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License for
21
   more details.
22
 
23
   You should have received a copy of the GNU General Public License along
24
   with this program.  If not, see <http://www.gnu.org/licenses/>. */
25
 
26
/* This program is commented throughout in a fashion suitable for processing
27
   with Doxygen. */
28
 
29
 
30
INSTRUCTION (l_add) {
31
  orreg_t temp1, temp2, temp3;
32
  int8_t temp4;
33
 
34
  temp2 = (orreg_t)PARAM2;
35
  temp3 = (orreg_t)PARAM1;
36
  temp1 = temp2 + temp3;
37 124 jeremybenn
  SET_PARAM0 (temp1);
38 112 jeremybenn
 
39
  /* Set overflow if two negative values gave a positive sum, or if two
40
     positive values gave a negative sum. Otherwise clear it */
41
  if ((((long int) temp2 <  0) &&
42
       ((long int) temp3 <  0) &&
43
       ((long int) temp1 >= 0)) ||
44
      (((long int) temp2 >= 0) &&
45
       ((long int) temp3 >= 0) &&
46
       ((long int) temp1 <  0)))
47
    {
48
      cpu_state.sprs[SPR_SR] |= SPR_SR_OV;
49
    }
50
  else
51
    {
52
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV;
53
    }
54
 
55
  /* Set the carry flag if (as unsigned values) the result is smaller than
56
     either operand (if it smaller than one, it will be smaller than both, so
57
     we need only test one). */
58 19 jeremybenn
  if ((uorreg_t) temp1 < (uorreg_t) temp2)
59 112 jeremybenn
    {
60
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
61
    }
62 19 jeremybenn
  else
63 112 jeremybenn
    {
64
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
65
    }
66 19 jeremybenn
 
67 112 jeremybenn
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
68
     is set. */
69
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
70
      ((cpu_state.sprs[SPR_SR] & SPR_SR_OV)  == SPR_SR_OV))
71
    {
72
      except_handle (EXCEPT_RANGE, cpu_state.pc);
73
    }
74
 
75 19 jeremybenn
  temp4 = temp1;
76
  if (temp4 == temp1)
77
    or1k_mstats.byteadd++;
78
}
79
INSTRUCTION (l_addc) {
80
  orreg_t temp1, temp2, temp3;
81
  int8_t temp4;
82 114 jeremybenn
  int    carry_in = (cpu_state.sprs[SPR_SR] & SPR_SR_CY) == SPR_SR_CY;
83
 
84 19 jeremybenn
  temp2 = (orreg_t)PARAM2;
85
  temp3 = (orreg_t)PARAM1;
86
  temp1 = temp2 + temp3;
87 114 jeremybenn
 
88
  if(carry_in)
89
    {
90
      temp1++;                          /* Add in the carry bit */
91
    }
92
 
93 19 jeremybenn
  SET_PARAM0(temp1);
94 114 jeremybenn
 
95
  /* Set overflow if two negative values gave a positive sum, or if two
96
     positive values gave a negative sum. Otherwise clear it. There are no
97
     corner cases with the extra bit carried in (unlike the carry flag - see
98
     below). */
99
  if ((((long int) temp2 <  0) &&
100
       ((long int) temp3 <  0) &&
101
       ((long int) temp1 >= 0)) ||
102
      (((long int) temp2 >= 0) &&
103
       ((long int) temp3 >= 0) &&
104
       ((long int) temp1 <  0)))
105
    {
106
      cpu_state.sprs[SPR_SR] |= SPR_SR_OV;
107
    }
108 19 jeremybenn
  else
109 114 jeremybenn
    {
110
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV;
111
    }
112 19 jeremybenn
 
113 114 jeremybenn
  /* Set the carry flag if (as unsigned values) the result is smaller than
114
     either operand (if it smaller than one, it will be smaller than both, so
115
     we need only test one). If there is a carry in, the test should be less
116
     than or equal, to deal with the 0 + 0xffffffff + c = 0 case (which
117
     generates a carry). */
118
  if ((carry_in && ((uorreg_t) temp1 <= (uorreg_t) temp2)) ||
119
      ((uorreg_t) temp1 < (uorreg_t) temp2))
120
    {
121
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
122
    }
123
  else
124
    {
125
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
126
    }
127
 
128
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
129
     is set. */
130
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
131
      ((cpu_state.sprs[SPR_SR] & SPR_SR_OV)  == SPR_SR_OV))
132
    {
133
      except_handle (EXCEPT_RANGE, cpu_state.pc);
134
    }
135
 
136 19 jeremybenn
  temp4 = temp1;
137
  if (temp4 == temp1)
138
    or1k_mstats.byteadd++;
139
}
140
INSTRUCTION (l_sw) {
141
  int old_cyc = 0;
142
  if (config.cpu.sbuf_len) old_cyc = runtime.sim.mem_cycles;
143
  set_mem32(PARAM0, PARAM1, &breakpoint);
144
  if (config.cpu.sbuf_len) {
145
    int t = runtime.sim.mem_cycles;
146
    runtime.sim.mem_cycles = old_cyc;
147
    sbuf_store (t - old_cyc);
148
  }
149
}
150
INSTRUCTION (l_sb) {
151
  int old_cyc = 0;
152
  if (config.cpu.sbuf_len) old_cyc = runtime.sim.mem_cycles;
153
  set_mem8(PARAM0, PARAM1, &breakpoint);
154
  if (config.cpu.sbuf_len) {
155
    int t = runtime.sim.mem_cycles;
156
    runtime.sim.mem_cycles = old_cyc;
157
    sbuf_store (t- old_cyc);
158
  }
159
}
160
INSTRUCTION (l_sh) {
161
  int old_cyc = 0;
162
  if (config.cpu.sbuf_len) old_cyc = runtime.sim.mem_cycles;
163
  set_mem16(PARAM0, PARAM1, &breakpoint);
164
  if (config.cpu.sbuf_len) {
165
    int t = runtime.sim.mem_cycles;
166
    runtime.sim.mem_cycles = old_cyc;
167
    sbuf_store (t - old_cyc);
168
  }
169
}
170 104 jeremybenn
INSTRUCTION (l_lws) {
171
  uint32_t val;
172
  if (config.cpu.sbuf_len) sbuf_load ();
173
  val = eval_mem32(PARAM1, &breakpoint);
174
  /* If eval operand produced exception don't set anything. JPB changed to
175
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
176
  if (!(except_pending || breakpoint))
177
    SET_PARAM0(val);
178
}
179 19 jeremybenn
INSTRUCTION (l_lwz) {
180
  uint32_t val;
181
  if (config.cpu.sbuf_len) sbuf_load ();
182
  val = eval_mem32(PARAM1, &breakpoint);
183
  /* If eval operand produced exception don't set anything. JPB changed to
184
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
185
  if (!(except_pending || breakpoint))
186
    SET_PARAM0(val);
187
}
188
INSTRUCTION (l_lbs) {
189
  int8_t val;
190
  if (config.cpu.sbuf_len) sbuf_load ();
191
  val = eval_mem8(PARAM1, &breakpoint);
192
  /* If eval operand produced exception don't set anything. JPB changed to
193
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
194
  if (!(except_pending || breakpoint))
195
    SET_PARAM0(val);
196
}
197
INSTRUCTION (l_lbz) {
198
  uint8_t val;
199
  if (config.cpu.sbuf_len) sbuf_load ();
200
  val = eval_mem8(PARAM1, &breakpoint);
201
  /* If eval operand produced exception don't set anything. JPB changed to
202
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
203
  if (!(except_pending || breakpoint))
204
    SET_PARAM0(val);
205
}
206
INSTRUCTION (l_lhs) {
207
  int16_t val;
208
  if (config.cpu.sbuf_len) sbuf_load ();
209
  val = eval_mem16(PARAM1, &breakpoint);
210
  /* If eval operand produced exception don't set anything. JPB changed to
211
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
212
  if (!(except_pending || breakpoint))
213
    SET_PARAM0(val);
214
}
215
INSTRUCTION (l_lhz) {
216
  uint16_t val;
217
  if (config.cpu.sbuf_len) sbuf_load ();
218
  val = eval_mem16(PARAM1, &breakpoint);
219
  /* If eval operand produced exception don't set anything. JPB changed to
220
     trigger on breakpoint, as well as except_pending (seemed to be a bug). */
221
  if (!(except_pending || breakpoint))
222
    SET_PARAM0(val);
223
}
224
INSTRUCTION (l_movhi) {
225
  SET_PARAM0(PARAM1 << 16);
226
}
227
INSTRUCTION (l_and) {
228
  uorreg_t temp1;
229
  temp1 = PARAM1 & PARAM2;
230
  SET_PARAM0(temp1);
231
}
232
INSTRUCTION (l_or) {
233
  uorreg_t temp1;
234
  temp1 = PARAM1 | PARAM2;
235
  SET_PARAM0(temp1);
236
}
237
INSTRUCTION (l_xor) {
238 127 jeremybenn
  /* The argument is now specified as unsigned, but historically OR1K has
239
     always treated the argument as signed (so l.xori rD,rA,-1 can be used in
240
     the absence of l.not). Use this as the default behavior. This is
241
     controlled from or32.c. */
242
  uorreg_t  temp1 = PARAM1 ^ PARAM2;
243 19 jeremybenn
  SET_PARAM0(temp1);
244
}
245
INSTRUCTION (l_sub) {
246 124 jeremybenn
  orreg_t temp1, temp2, temp3;
247
 
248
  temp3 = (orreg_t)PARAM2;
249
  temp2 = (orreg_t)PARAM1;
250
  temp1 = temp2 - temp3;
251
  SET_PARAM0 (temp1);
252
 
253
  /* Set overflow if a negative value minus a positive value gave a positive
254
     sum, or if a positive value minus a negative value gave a negative
255
     sum. Otherwise clear it */
256
  if ((((long int) temp2 <  0) &&
257
       ((long int) temp3 >= 0) &&
258
       ((long int) temp1 >= 0)) ||
259
      (((long int) temp2 >= 0) &&
260
       ((long int) temp3 <  0) &&
261
       ((long int) temp1 <  0)))
262
    {
263
      cpu_state.sprs[SPR_SR] |= SPR_SR_OV;
264
    }
265
  else
266
    {
267
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV;
268
    }
269
 
270
  /* Set the carry flag if (as unsigned values) the second operand is greater
271
     than the first. */
272
  if ((uorreg_t) temp3 > (uorreg_t) temp2)
273
    {
274
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
275
    }
276
  else
277
    {
278
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
279
    }
280
 
281
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
282
     is set. */
283
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
284
      ((cpu_state.sprs[SPR_SR] & SPR_SR_OV)  == SPR_SR_OV))
285
    {
286
      except_handle (EXCEPT_RANGE, cpu_state.pc);
287
    }
288 19 jeremybenn
}
289
/*int mcount = 0;*/
290
INSTRUCTION (l_mul) {
291 118 jeremybenn
  orreg_t   temp0, temp1, temp2;
292
  LONGEST   ltemp0, ltemp1, ltemp2;
293
  ULONGEST  ultemp0, ultemp1, ultemp2;
294
 
295
  /* Args in 32-bit */
296
  temp2 = (orreg_t) PARAM2;
297
  temp1 = (orreg_t) PARAM1;
298
 
299
  /* Compute initially in 64-bit */
300
  ltemp1 = (LONGEST) temp1;
301
  ltemp2 = (LONGEST) temp2;
302
  ltemp0 = ltemp1 * ltemp2;
303
 
304
  temp0  = (orreg_t) (ltemp0  & 0xffffffffLL);
305
  SET_PARAM0 (temp0);
306
 
307
  /* We have 2's complement overflow, if the result is less than the smallest
308
     possible 32-bit negative number, or greater than the largest possible
309
     32-bit positive number. */
310
  if ((ltemp0 < (LONGEST) INT32_MIN) || (ltemp0 > (LONGEST) INT32_MAX))
311
    {
312
      cpu_state.sprs[SPR_SR] |= SPR_SR_OV;
313
    }
314
  else
315
    {
316
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV;
317
    }
318
 
319
  /* We have 1's complement overflow, if, as an unsigned operation, the result
320
     is greater than the largest possible 32-bit unsigned number. This is
321
     probably quicker than unpicking the bits of the signed result. */
322
  ultemp1 = (ULONGEST) temp1 & 0xffffffffULL;
323
  ultemp2 = (ULONGEST) temp2 & 0xffffffffULL;
324
  ultemp0 = ultemp1 * ultemp2;
325
 
326
  if (ultemp0 > (ULONGEST) UINT32_MAX)
327
    {
328
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
329
    }
330
  else
331
    {
332
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
333
    }
334
 
335
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
336
     is set. */
337
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
338
      ((cpu_state.sprs[SPR_SR] & SPR_SR_OV)  == SPR_SR_OV))
339
    {
340
      except_handle (EXCEPT_RANGE, cpu_state.pc);
341
    }
342 19 jeremybenn
}
343 118 jeremybenn
INSTRUCTION (l_mulu) {
344
  uorreg_t   temp0, temp1, temp2;
345
  ULONGEST  ultemp0, ultemp1, ultemp2;
346
 
347
  /* Args in 32-bit */
348
  temp2 = (uorreg_t) PARAM2;
349
  temp1 = (uorreg_t) PARAM1;
350
 
351
  /* Compute initially in 64-bit */
352
  ultemp1 = (ULONGEST) temp1 & 0xffffffffULL;
353
  ultemp2 = (ULONGEST) temp2 & 0xffffffffULL;
354
  ultemp0 = ultemp1 * ultemp2;
355
 
356
  temp0  = (uorreg_t) (ultemp0  & 0xffffffffULL);
357
  SET_PARAM0 (temp0);
358
 
359
  /* We never have 2's complement overflow */
360
  cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV;
361
 
362
  /* We have 1's complement overflow, if the result is greater than the
363
     largest possible 32-bit unsigned number. */
364
  if (ultemp0 > (ULONGEST) UINT32_MAX)
365
    {
366
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
367
    }
368
  else
369
    {
370
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
371
    }
372
}
373 19 jeremybenn
INSTRUCTION (l_div) {
374 118 jeremybenn
  orreg_t  temp3, temp2, temp1;
375 19 jeremybenn
 
376 118 jeremybenn
  temp3 = (orreg_t) PARAM2;
377
  temp2 = (orreg_t) PARAM1;
378
 
379
 /* Check for divide by zero (sets carry) */
380
  if (0 == temp3)
381
    {
382
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
383
    }
384
  else
385
    {
386
      temp1 = temp2 / temp3;
387
      SET_PARAM0(temp1);
388
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
389
    }
390
 
391
  cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV; /* Never set */
392
 
393
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
394
     is set. */
395
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
396
      ((cpu_state.sprs[SPR_SR] & SPR_SR_CY)  == SPR_SR_CY))
397
    {
398
      except_handle (EXCEPT_RANGE, cpu_state.pc);
399
    }
400 19 jeremybenn
}
401
INSTRUCTION (l_divu) {
402
  uorreg_t temp3, temp2, temp1;
403
 
404 118 jeremybenn
  temp3 = (uorreg_t) PARAM2;
405
  temp2 = (uorreg_t) PARAM1;
406
 
407
 /* Check for divide by zero (sets carry) */
408
  if (0 == temp3)
409
    {
410
      cpu_state.sprs[SPR_SR] |= SPR_SR_CY;
411
    }
412
  else
413
    {
414
      temp1 = temp2 / temp3;
415
      SET_PARAM0(temp1);
416
      cpu_state.sprs[SPR_SR] &= ~SPR_SR_CY;
417
    }
418
 
419
  cpu_state.sprs[SPR_SR] &= ~SPR_SR_OV; /* Never set */
420
 
421
  /* Trigger a range exception if the overflow flag is set and the SR[OVE] bit
422
     is set. */
423
  if (((cpu_state.sprs[SPR_SR] & SPR_SR_OVE) == SPR_SR_OVE) &&
424
      ((cpu_state.sprs[SPR_SR] & SPR_SR_CY)  == SPR_SR_CY))
425
    {
426
      except_handle (EXCEPT_RANGE, cpu_state.pc);
427
    }
428 19 jeremybenn
}
429
INSTRUCTION (l_sll) {
430
  uorreg_t temp1;
431
 
432
  temp1 = PARAM1 << PARAM2;
433
  SET_PARAM0(temp1);
434
  /* runtime.sim.cycles += 2; */
435
}
436
INSTRUCTION (l_sra) {
437
  orreg_t temp1;
438
 
439
  temp1 = (orreg_t)PARAM1 >> PARAM2;
440
  SET_PARAM0(temp1);
441
  /* runtime.sim.cycles += 2; */
442
}
443
INSTRUCTION (l_srl) {
444
  uorreg_t temp1;
445
  temp1 = PARAM1 >> PARAM2;
446
  SET_PARAM0(temp1);
447
  /* runtime.sim.cycles += 2; */
448
}
449 122 jeremybenn
INSTRUCTION (l_ror) {
450
  uorreg_t temp1;
451
  temp1  = PARAM1 >> (PARAM2 & 0x1f);
452
  temp1 |= PARAM1 << (32 - (PARAM2 & 0x1f));
453
  SET_PARAM0(temp1);
454
}
455 19 jeremybenn
INSTRUCTION (l_bf) {
456
  if (config.bpb.enabled) {
457
    int fwd = (PARAM0 >= cpu_state.pc) ? 1 : 0;
458
    or1k_mstats.bf[cpu_state.sprs[SPR_SR] & SPR_SR_F ? 1 : 0][fwd]++;
459
    bpb_update(current->insn_addr, cpu_state.sprs[SPR_SR] & SPR_SR_F ? 1 : 0);
460
  }
461
  if(cpu_state.sprs[SPR_SR] & SPR_SR_F) {
462
    cpu_state.pc_delay = cpu_state.pc + (orreg_t)PARAM0 * 4;
463
    btic_update(pcnext);
464
    next_delay_insn = 1;
465
  } else {
466
    btic_update(cpu_state.pc);
467
  }
468
}
469
INSTRUCTION (l_bnf) {
470
  if (config.bpb.enabled) {
471
    int fwd = (PARAM0 >= cpu_state.pc) ? 1 : 0;
472
    or1k_mstats.bnf[cpu_state.sprs[SPR_SR] & SPR_SR_F ? 0 : 1][fwd]++;
473
    bpb_update(current->insn_addr, cpu_state.sprs[SPR_SR] & SPR_SR_F ? 0 : 1);
474
  }
475
  if (!(cpu_state.sprs[SPR_SR] & SPR_SR_F)) {
476
    cpu_state.pc_delay = cpu_state.pc + (orreg_t)PARAM0 * 4;
477
    btic_update(pcnext);
478
    next_delay_insn = 1;
479
  } else {
480
    btic_update(cpu_state.pc);
481
  }
482
}
483
INSTRUCTION (l_j) {
484
  cpu_state.pc_delay = cpu_state.pc + (orreg_t)PARAM0 * 4;
485
  next_delay_insn = 1;
486
}
487
INSTRUCTION (l_jal) {
488
  cpu_state.pc_delay = cpu_state.pc + (orreg_t)PARAM0 * 4;
489
 
490
  setsim_reg(LINK_REGNO, cpu_state.pc + 8);
491
  next_delay_insn = 1;
492
  if (config.sim.profile) {
493
    struct label_entry *tmp;
494
    if (verify_memoryarea(cpu_state.pc_delay) && (tmp = get_label (cpu_state.pc_delay)))
495
      fprintf (runtime.sim.fprof, "+%08llX %"PRIxADDR" %"PRIxADDR" %s\n",
496
               runtime.sim.cycles, cpu_state.pc + 8, cpu_state.pc_delay,
497
               tmp->name);
498
    else
499
      fprintf (runtime.sim.fprof, "+%08llX %"PRIxADDR" %"PRIxADDR" @%"PRIxADDR"\n",
500
               runtime.sim.cycles, cpu_state.pc + 8, cpu_state.pc_delay,
501
               cpu_state.pc_delay);
502
  }
503
}
504
INSTRUCTION (l_jalr) {
505 121 jeremybenn
  /* Badly aligned destination or use of link register triggers an exception */
506
  uorreg_t  temp1 = PARAM0;
507
 
508
  if (REG_PARAM0 == LINK_REGNO)
509
    {
510
      except_handle (EXCEPT_ILLEGAL, cpu_state.pc);
511
    }
512
  else if ((temp1 & 0x3) != 0)
513
    {
514
      except_handle (EXCEPT_ALIGN, cpu_state.pc);
515
    }
516
  else
517
    {
518
      cpu_state.pc_delay = temp1;
519
      setsim_reg(LINK_REGNO, cpu_state.pc + 8);
520
      next_delay_insn = 1;
521
    }
522 19 jeremybenn
}
523
INSTRUCTION (l_jr) {
524 121 jeremybenn
  /* Badly aligned destination triggers an exception */
525
  uorreg_t  temp1 = PARAM0;
526
 
527
  if ((temp1 & 0x3) != 0)
528
    {
529
      except_handle (EXCEPT_ALIGN, cpu_state.pc);
530
    }
531
  else
532
    {
533
      cpu_state.pc_delay = temp1;
534
      next_delay_insn = 1;
535
 
536
      if (config.sim.profile)
537
        {
538
          fprintf (runtime.sim.fprof, "-%08llX %"PRIxADDR"\n",
539
                   runtime.sim.cycles, cpu_state.pc_delay);
540
        }
541
    }
542 19 jeremybenn
}
543
INSTRUCTION (l_rfe) {
544
  pcnext = cpu_state.sprs[SPR_EPCR_BASE];
545
  mtspr(SPR_SR, cpu_state.sprs[SPR_ESR_BASE]);
546
}
547
INSTRUCTION (l_nop) {
548
  uint32_t k = PARAM0;
549 483 jeremybenn
  switch (k)
550
    {
551 19 jeremybenn
    case NOP_NOP:
552
      break;
553
    case NOP_EXIT:
554 220 jeremybenn
      PRINTFQ("exit(%"PRIdREG")\n", evalsim_reg (3));
555
      PRINTFQ("@reset : cycles %lld, insn #%lld\n",
556 19 jeremybenn
              runtime.sim.reset_cycles, runtime.cpu.reset_instructions);
557 220 jeremybenn
      PRINTFQ("@exit  : cycles %lld, insn #%lld\n", runtime.sim.cycles,
558 19 jeremybenn
              runtime.cpu.instructions);
559 220 jeremybenn
      PRINTFQ(" diff  : cycles %lld, insn #%lld\n",
560 19 jeremybenn
              runtime.sim.cycles - runtime.sim.reset_cycles,
561
              runtime.cpu.instructions - runtime.cpu.reset_instructions);
562 143 jeremybenn
      if (config.sim.is_library)
563
        {
564
          runtime.cpu.halted = 1;
565
          set_stall_state (1);
566
        }
567 19 jeremybenn
      else
568 143 jeremybenn
        {
569
          sim_done();
570
        }
571 19 jeremybenn
      break;
572 483 jeremybenn
    case NOP_REPORT:
573
      PRINTF("report(0x%"PRIxREG");\n", evalsim_reg(3));
574
      break;
575
    case NOP_PUTC:              /*JPB */
576
      printf( "%c", (char)(evalsim_reg( 3 ) & 0xff));
577
      fflush( stdout );
578
      break;
579 19 jeremybenn
    case NOP_CNT_RESET:
580
      PRINTF("****************** counters reset ******************\n");
581
      PRINTF("cycles %lld, insn #%lld\n", runtime.sim.cycles, runtime.cpu.instructions);
582
      PRINTF("****************** counters reset ******************\n");
583
      runtime.sim.reset_cycles = runtime.sim.cycles;
584
      runtime.cpu.reset_instructions = runtime.cpu.instructions;
585
      break;
586 82 jeremybenn
    case NOP_GET_TICKS:
587
      cpu_state.reg[11] = runtime.sim.cycles & 0xffffffff;
588
      cpu_state.reg[12] = runtime.sim.cycles >> 32;
589
      break;
590
    case NOP_GET_PS:
591
      cpu_state.reg[11] = config.sim.clkcycle_ps;
592
      break;
593 460 jeremybenn
    case NOP_TRACE_ON:
594
      runtime.sim.hush = 0;
595
      break;
596
    case NOP_TRACE_OFF:
597
      runtime.sim.hush = 1;
598
      break;
599 483 jeremybenn
    case NOP_RANDOM:
600
      cpu_state.reg[11] = (unsigned int) (random () & 0xffffffff);
601
      break;
602
    case NOP_OR1KSIM:
603
      cpu_state.reg[11] = 1;
604
      break;
605 19 jeremybenn
    default:
606
      break;
607
  }
608
}
609
INSTRUCTION (l_sfeq) {
610
  if(PARAM0 == PARAM1)
611
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
612
  else
613
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
614
}
615
INSTRUCTION (l_sfne) {
616
  if(PARAM0 != PARAM1)
617
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
618
  else
619
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
620
}
621
INSTRUCTION (l_sfgts) {
622
  if((orreg_t)PARAM0 > (orreg_t)PARAM1)
623
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
624
  else
625
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
626
}
627
INSTRUCTION (l_sfges) {
628
  if((orreg_t)PARAM0 >= (orreg_t)PARAM1)
629
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
630
  else
631
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
632
}
633
INSTRUCTION (l_sflts) {
634
  if((orreg_t)PARAM0 < (orreg_t)PARAM1)
635
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
636
  else
637
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
638
}
639
INSTRUCTION (l_sfles) {
640
  if((orreg_t)PARAM0 <= (orreg_t)PARAM1)
641
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
642
  else
643
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
644
}
645
INSTRUCTION (l_sfgtu) {
646
  if(PARAM0 > PARAM1)
647
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
648
  else
649
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
650
}
651
INSTRUCTION (l_sfgeu) {
652
  if(PARAM0 >= PARAM1)
653
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
654
  else
655
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
656
}
657
INSTRUCTION (l_sfltu) {
658
  if(PARAM0 < PARAM1)
659
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
660
  else
661
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
662
}
663
INSTRUCTION (l_sfleu) {
664
  if(PARAM0 <= PARAM1)
665
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
666
  else
667
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
668
}
669
INSTRUCTION (l_extbs) {
670
  int8_t x;
671
  x = PARAM1;
672
  SET_PARAM0((orreg_t)x);
673
}
674
INSTRUCTION (l_extbz) {
675
  uint8_t x;
676
  x = PARAM1;
677
  SET_PARAM0((uorreg_t)x);
678
}
679
INSTRUCTION (l_exths) {
680
  int16_t x;
681
  x = PARAM1;
682
  SET_PARAM0((orreg_t)x);
683
}
684
INSTRUCTION (l_exthz) {
685
  uint16_t x;
686
  x = PARAM1;
687
  SET_PARAM0((uorreg_t)x);
688
}
689
INSTRUCTION (l_extws) {
690
  int32_t x;
691
  x = PARAM1;
692
  SET_PARAM0((orreg_t)x);
693
}
694
INSTRUCTION (l_extwz) {
695
  uint32_t x;
696
  x = PARAM1;
697
  SET_PARAM0((uorreg_t)x);
698
}
699
INSTRUCTION (l_mtspr) {
700 123 jeremybenn
  uint16_t regno = PARAM0 | PARAM2;
701 19 jeremybenn
  uorreg_t value = PARAM1;
702
 
703
  if (cpu_state.sprs[SPR_SR] & SPR_SR_SM)
704
    mtspr(regno, value);
705
  else {
706
    PRINTF("WARNING: trying to write SPR while SR[SUPV] is cleared.\n");
707
    sim_done();
708
  }
709
}
710
INSTRUCTION (l_mfspr) {
711 123 jeremybenn
  uint16_t regno = PARAM1 | PARAM2;
712 19 jeremybenn
  uorreg_t value = mfspr(regno);
713
 
714
  if (cpu_state.sprs[SPR_SR] & SPR_SR_SM)
715
    SET_PARAM0(value);
716
  else {
717
    SET_PARAM0(0);
718
    PRINTF("WARNING: trying to read SPR while SR[SUPV] is cleared.\n");
719
    sim_done();
720
  }
721
}
722
INSTRUCTION (l_sys) {
723
  except_handle(EXCEPT_SYSCALL, cpu_state.sprs[SPR_EEAR_BASE]);
724
}
725
INSTRUCTION (l_trap) {
726
  /* TODO: some SR related code here! */
727
  except_handle(EXCEPT_TRAP, cpu_state.sprs[SPR_EEAR_BASE]);
728
}
729
INSTRUCTION (l_mac) {
730
  uorreg_t lo, hi;
731
  LONGEST l;
732 116 jeremybenn
  orreg_t x, y, t;
733 19 jeremybenn
 
734
  lo = cpu_state.sprs[SPR_MACLO];
735
  hi = cpu_state.sprs[SPR_MACHI];
736
  x = PARAM0;
737
  y = PARAM1;
738
/*   PRINTF ("[%"PRIxREG",%"PRIxREG"]\t", x, y); */
739 116 jeremybenn
 
740
  /* Compute the temporary as (signed) 32-bits, then sign-extend to 64 when
741
     adding in. */
742 19 jeremybenn
  l = (ULONGEST)lo | ((LONGEST)hi << 32);
743 116 jeremybenn
  t = x * y;
744
  l += (LONGEST) t;
745 19 jeremybenn
 
746
  /* This implementation is very fast - it needs only one cycle for mac.  */
747
  lo = ((ULONGEST)l) & 0xFFFFFFFF;
748
  hi = ((LONGEST)l) >> 32;
749
  cpu_state.sprs[SPR_MACLO] = lo;
750
  cpu_state.sprs[SPR_MACHI] = hi;
751
/*   PRINTF ("(%"PRIxREG",%"PRIxREG"\n", hi, lo); */
752
}
753
INSTRUCTION (l_msb) {
754
  uorreg_t lo, hi;
755
  LONGEST l;
756
  orreg_t x, y;
757
 
758
  lo = cpu_state.sprs[SPR_MACLO];
759
  hi = cpu_state.sprs[SPR_MACHI];
760
  x = PARAM0;
761
  y = PARAM1;
762
 
763
/*   PRINTF ("[%"PRIxREG",%"PRIxREG"]\t", x, y); */
764
 
765
  l = (ULONGEST)lo | ((LONGEST)hi << 32);
766
  l -= x * y;
767
 
768
  /* This implementation is very fast - it needs only one cycle for msb.  */
769
  lo = ((ULONGEST)l) & 0xFFFFFFFF;
770
  hi = ((LONGEST)l) >> 32;
771
  cpu_state.sprs[SPR_MACLO] = lo;
772
  cpu_state.sprs[SPR_MACHI] = hi;
773
/*   PRINTF ("(%"PRIxREG",%"PRIxREG")\n", hi, lo); */
774
}
775
INSTRUCTION (l_macrc) {
776 116 jeremybenn
  orreg_t lo;
777 19 jeremybenn
  /* No need for synchronization here -- all MAC instructions are 1 cycle long.  */
778
  lo =  cpu_state.sprs[SPR_MACLO];
779
  //PRINTF ("<%08x>\n", (unsigned long)l);
780 116 jeremybenn
  SET_PARAM0(lo);
781 19 jeremybenn
  cpu_state.sprs[SPR_MACLO] = 0;
782
  cpu_state.sprs[SPR_MACHI] = 0;
783
}
784
INSTRUCTION (l_cmov) {
785
  SET_PARAM0(cpu_state.sprs[SPR_SR] & SPR_SR_F ? PARAM1 : PARAM2);
786
}
787
INSTRUCTION (l_ff1) {
788
  SET_PARAM0(ffs(PARAM1));
789
}
790 115 jeremybenn
INSTRUCTION (l_fl1) {
791
  orreg_t t = (orreg_t)PARAM1;
792
 
793
  /* Reverse the word and use ffs */
794
  t = (((t & 0xaaaaaaaa) >> 1) | ((t & 0x55555555) << 1));
795
  t = (((t & 0xcccccccc) >> 2) | ((t & 0x33333333) << 2));
796
  t = (((t & 0xf0f0f0f0) >> 4) | ((t & 0x0f0f0f0f) << 4));
797
  t = (((t & 0xff00ff00) >> 8) | ((t & 0x00ff00ff) << 8));
798
  t = ffs ((t >> 16) | (t << 16));
799
 
800
  SET_PARAM0 (0 == t ? t : 33 - t);
801
}
802 19 jeremybenn
/******* Floating point instructions *******/
803 226 julius
/* Do calculation, and update FPCSR as required */
804 19 jeremybenn
/* Single precision */
805
INSTRUCTION (lf_add_s) {
806 233 julius
  if (config.cpu.hardfloat) {
807
  float_set_rm();
808
  SET_PARAM0(float32_add((unsigned int)PARAM1,(unsigned int)PARAM2));
809
  float_set_flags();
810 100 julius
  } else l_invalid();
811 19 jeremybenn
}
812
INSTRUCTION (lf_div_s) {
813 100 julius
  if (config.cpu.hardfloat) {
814 233 julius
  float_set_rm();
815
  SET_PARAM0(float32_div((unsigned int)PARAM1,(unsigned int)PARAM2));
816
  float_set_flags();
817 100 julius
  } else l_invalid();
818 19 jeremybenn
}
819
INSTRUCTION (lf_ftoi_s) {
820 100 julius
  if (config.cpu.hardfloat) {
821 233 julius
  float_set_rm();
822
  SET_PARAM0(float32_to_int32((unsigned int)PARAM1));
823
  float_set_flags();
824 100 julius
  } else l_invalid();
825 19 jeremybenn
}
826
INSTRUCTION (lf_itof_s) {
827 100 julius
  if (config.cpu.hardfloat) {
828 233 julius
  float_set_rm();
829
  SET_PARAM0(int32_to_float32((unsigned int)PARAM1));
830
  float_set_flags();
831 100 julius
  } else l_invalid();
832 19 jeremybenn
}
833
INSTRUCTION (lf_madd_s) {
834 100 julius
  if (config.cpu.hardfloat) {
835 233 julius
  float_set_rm();
836
  SET_PARAM0(float32_add((unsigned int)PARAM0, float32_mul((unsigned int)PARAM1,(unsigned int)PARAM2)));
837
  // Note: this ignores flags from the multiply!
838
  float_set_flags();
839 100 julius
  } else l_invalid();
840 19 jeremybenn
}
841
INSTRUCTION (lf_mul_s) {
842 100 julius
  if (config.cpu.hardfloat) {
843 233 julius
  float_set_rm();
844
  SET_PARAM0(float32_mul((unsigned int)PARAM1,(unsigned int)PARAM2));
845
  float_set_flags();
846 100 julius
  } else l_invalid();
847 19 jeremybenn
}
848
INSTRUCTION (lf_rem_s) {
849 100 julius
  if (config.cpu.hardfloat) {
850 233 julius
  float_set_rm();
851
  SET_PARAM0(float32_rem((unsigned int)PARAM1,(unsigned int)PARAM2));
852
  float_set_flags();
853 100 julius
  } else l_invalid();
854 19 jeremybenn
}
855
INSTRUCTION (lf_sfeq_s) {
856 100 julius
  if (config.cpu.hardfloat) {
857 233 julius
  float_set_rm();
858
  if(float32_eq((unsigned int)PARAM0, (unsigned int)PARAM1))
859 19 jeremybenn
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
860
  else
861
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
862 233 julius
  float_set_flags();
863 100 julius
  } else l_invalid();
864 19 jeremybenn
}
865
INSTRUCTION (lf_sfge_s) {
866 100 julius
  if (config.cpu.hardfloat) {
867 233 julius
  float_set_rm();
868
  if((!float32_lt((unsigned int)PARAM0, (unsigned int)PARAM1) &
869
      !float32_is_nan( (unsigned int)PARAM0) &
870
      !float32_is_nan( (unsigned int)PARAM1) ) )
871 226 julius
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
872 19 jeremybenn
  else
873
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
874 233 julius
  float_set_flags();
875 100 julius
  } else l_invalid();
876 19 jeremybenn
}
877
INSTRUCTION (lf_sfgt_s) {
878 100 julius
  if (config.cpu.hardfloat) {
879 233 julius
  float_set_rm();
880
  if((!float32_le((unsigned int)PARAM0, (unsigned int)PARAM1)  &
881
      !float32_is_nan( (unsigned int)PARAM0) &
882
      !float32_is_nan( (unsigned int)PARAM1) ) )
883 19 jeremybenn
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
884
  else
885
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
886 233 julius
  float_set_flags();
887 100 julius
  } else l_invalid();
888 19 jeremybenn
}
889
INSTRUCTION (lf_sfle_s) {
890 100 julius
  if (config.cpu.hardfloat) {
891 233 julius
  float_set_rm();
892
  if((float32_le((unsigned int)PARAM0, (unsigned int)PARAM1) &
893
      !float32_is_nan( (unsigned int)PARAM0) &
894
      !float32_is_nan( (unsigned int)PARAM1) ) )
895 19 jeremybenn
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
896
  else
897
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
898 233 julius
  float_set_flags();
899 100 julius
  } else l_invalid();
900 19 jeremybenn
}
901
INSTRUCTION (lf_sflt_s) {
902 100 julius
  if (config.cpu.hardfloat) {
903 233 julius
  float_set_rm();
904
  if(( float32_lt((unsigned int)PARAM0, (unsigned int)PARAM1) &
905
       !float32_is_nan( (unsigned int)PARAM0) &
906
       !float32_is_nan( (unsigned int)PARAM1) ) )
907 19 jeremybenn
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
908
  else
909
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
910 233 julius
  float_set_flags();
911 100 julius
  } else l_invalid();
912 19 jeremybenn
}
913
INSTRUCTION (lf_sfne_s) {
914 100 julius
  if (config.cpu.hardfloat) {
915 233 julius
  float_set_rm();
916
  if(!float32_eq((unsigned int)PARAM0, (unsigned int)PARAM1))
917 19 jeremybenn
    cpu_state.sprs[SPR_SR] |= SPR_SR_F;
918
  else
919
    cpu_state.sprs[SPR_SR] &= ~SPR_SR_F;
920 233 julius
  float_set_flags();
921 100 julius
  } else l_invalid();
922 19 jeremybenn
}
923
INSTRUCTION (lf_sub_s) {
924 100 julius
  if (config.cpu.hardfloat) {
925 233 julius
  float_set_rm();
926
  SET_PARAM0(float32_sub((unsigned int)PARAM1,(unsigned int)PARAM2));
927
  float_set_flags();
928 100 julius
  } else l_invalid();
929 19 jeremybenn
}
930
 
931
/******* Custom instructions *******/
932
INSTRUCTION (l_cust1) {
933
  /*int destr = current->insn >> 21;
934
    int src1r = current->insn >> 15;
935
    int src2r = current->insn >> 9;*/
936
}
937
INSTRUCTION (l_cust2) {
938
}
939
INSTRUCTION (l_cust3) {
940
}
941
INSTRUCTION (l_cust4) {
942
}
943 100 julius
INSTRUCTION (lf_cust1) {
944
}

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