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

Subversion Repositories openrisc_me

[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [sim/] [mips/] [mdmx.c] - Blame information for rev 227

Details | Compare with Previous | View Log

Line No. Rev Author Line
1 227 jeremybenn
/* Simulation code for the MIPS MDMX ASE.
2
   Copyright (C) 2002, 2007, 2008, 2009, 2010 Free Software Foundation, Inc.
3
   Contributed by Ed Satterthwaite and Chris Demetriou, of Broadcom
4
   Corporation (SiByte).
5
 
6
This file is part of GDB, the GNU debugger.
7
 
8
This program is free software; you can redistribute it and/or modify
9
it under the terms of the GNU General Public License as published by
10
the Free Software Foundation; either version 3 of the License, or
11
(at your option) any later version.
12
 
13
This program is distributed in the hope that it will be useful,
14
but WITHOUT ANY WARRANTY; without even the implied warranty of
15
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
16
GNU General Public License for more details.
17
 
18
You should have received a copy of the GNU General Public License
19
along with this program.  If not, see <http://www.gnu.org/licenses/>.  */
20
 
21
#include <stdio.h>
22
 
23
#include "sim-main.h"
24
 
25
/* Within mdmx.c we refer to the sim_cpu directly. */
26
#define CPU cpu
27
#define SD  (CPU_STATE(CPU))
28
 
29
/* XXX FIXME: temporary hack while the impact of making unpredictable()
30
   a "normal" (non-igen) function is evaluated.  */
31
#undef Unpredictable
32
#define Unpredictable() unpredictable_action (cpu, cia)
33
 
34
/* MDMX Representations
35
 
36
   An 8-bit packed byte element (OB) is always unsigned.
37
   The 24-bit accumulators are signed and are represented as 32-bit
38
   signed values, which are reduced to 24-bit signed values prior to
39
   Round and Clamp operations.
40
 
41
   A 16-bit packed halfword element (QH) is always signed.
42
   The 48-bit accumulators are signed and are represented as 64-bit
43
   signed values, which are reduced to 48-bit signed values prior to
44
   Round and Clamp operations.
45
 
46
   The code below assumes a 2's-complement representation of signed
47
   quantities.  Care is required to clear extended sign bits when
48
   repacking fields.
49
 
50
   The code (and the code for arithmetic shifts in mips.igen) also makes
51
   the (not guaranteed portable) assumption that right shifts of signed
52
   quantities in C do sign extension.  */
53
 
54
typedef unsigned64 unsigned48;
55
#define MASK48 (UNSIGNED64 (0xffffffffffff))
56
 
57
typedef unsigned32 unsigned24;
58
#define MASK24 (UNSIGNED32 (0xffffff))
59
 
60
typedef enum {
61
  mdmx_ob,          /* OB (octal byte) */
62
  mdmx_qh           /* QH (quad half-word) */
63
} MX_fmt;
64
 
65
typedef enum {
66
  sel_elem,         /* element select */
67
  sel_vect,         /* vector select */
68
  sel_imm           /* immediate select */
69
} VT_select;
70
 
71
#define OB_MAX  ((unsigned8)0xFF)
72
#define QH_MIN  ((signed16)0x8000)
73
#define QH_MAX  ((signed16)0x7FFF)
74
 
75
#define OB_CLAMP(x)  ((unsigned8)((x) > OB_MAX ? OB_MAX : (x)))
76
#define QH_CLAMP(x)  ((signed16)((x) < QH_MIN ? QH_MIN : \
77
                                ((x) > QH_MAX ? QH_MAX : (x))))
78
 
79
#define MX_FMT(fmtsel) (((fmtsel) & 0x1) == 0 ? mdmx_ob : mdmx_qh)
80
#define MX_VT(fmtsel)  (((fmtsel) & 0x10) == 0 ?    sel_elem : \
81
                       (((fmtsel) & 0x18) == 0x10 ? sel_vect : sel_imm))
82
 
83
#define QH_ELEM(v,fmtsel) \
84
        ((signed16)(((v) >> (((fmtsel) & 0xC) << 2)) & 0xFFFF))
85
#define OB_ELEM(v,fmtsel) \
86
        ((unsigned8)(((v) >> (((fmtsel) & 0xE) << 2)) & 0xFF))
87
 
88
 
89
typedef signed16 (*QH_FUNC)(signed16, signed16);
90
typedef unsigned8 (*OB_FUNC)(unsigned8, unsigned8);
91
 
92
/* vectorized logical operators */
93
 
94
static signed16
95
AndQH(signed16 ts, signed16 tt)
96
{
97
  return (signed16)((unsigned16)ts & (unsigned16)tt);
98
}
99
 
100
static unsigned8
101
AndOB(unsigned8 ts, unsigned8 tt)
102
{
103
  return ts & tt;
104
}
105
 
106
static signed16
107
NorQH(signed16 ts, signed16 tt)
108
{
109
  return (signed16)(((unsigned16)ts | (unsigned16)tt) ^ 0xFFFF);
110
}
111
 
112
static unsigned8
113
NorOB(unsigned8 ts, unsigned8 tt)
114
{
115
  return (ts | tt) ^ 0xFF;
116
}
117
 
118
static signed16
119
OrQH(signed16 ts, signed16 tt)
120
{
121
  return (signed16)((unsigned16)ts | (unsigned16)tt);
122
}
123
 
124
static unsigned8
125
OrOB(unsigned8 ts, unsigned8 tt)
126
{
127
  return ts | tt;
128
}
129
 
130
static signed16
131
XorQH(signed16 ts, signed16 tt)
132
{
133
  return (signed16)((unsigned16)ts ^ (unsigned16)tt);
134
}
135
 
136
static unsigned8
137
XorOB(unsigned8 ts, unsigned8 tt)
138
{
139
  return ts ^ tt;
140
}
141
 
142
static signed16
143
SLLQH(signed16 ts, signed16 tt)
144
{
145
  unsigned32 s = (unsigned32)tt & 0xF;
146
  return (signed16)(((unsigned32)ts << s) & 0xFFFF);
147
}
148
 
149
static unsigned8
150
SLLOB(unsigned8 ts, unsigned8 tt)
151
{
152
  unsigned32 s = tt & 0x7;
153
  return (ts << s) & 0xFF;
154
}
155
 
156
static signed16
157
SRLQH(signed16 ts, signed16 tt)
158
{
159
  unsigned32 s = (unsigned32)tt & 0xF;
160
  return (signed16)((unsigned16)ts >> s);
161
}
162
 
163
static unsigned8
164
SRLOB(unsigned8 ts, unsigned8 tt)
165
{
166
  unsigned32 s = tt & 0x7;
167
  return ts >> s;
168
}
169
 
170
 
171
/* Vectorized arithmetic operators.  */
172
 
173
static signed16
174
AddQH(signed16 ts, signed16 tt)
175
{
176
  signed32 t = (signed32)ts + (signed32)tt;
177
  return QH_CLAMP(t);
178
}
179
 
180
static unsigned8
181
AddOB(unsigned8 ts, unsigned8 tt)
182
{
183
  unsigned32 t = (unsigned32)ts + (unsigned32)tt;
184
  return OB_CLAMP(t);
185
}
186
 
187
static signed16
188
SubQH(signed16 ts, signed16 tt)
189
{
190
  signed32 t = (signed32)ts - (signed32)tt;
191
  return QH_CLAMP(t);
192
}
193
 
194
static unsigned8
195
SubOB(unsigned8 ts, unsigned8 tt)
196
{
197
  signed32 t;
198
  t = (signed32)ts - (signed32)tt;
199
  if (t < 0)
200
    t = 0;
201
  return (unsigned8)t;
202
}
203
 
204
static signed16
205
MinQH(signed16 ts, signed16 tt)
206
{
207
  return (ts < tt ? ts : tt);
208
}
209
 
210
static unsigned8
211
MinOB(unsigned8 ts, unsigned8 tt)
212
{
213
  return (ts < tt ? ts : tt);
214
}
215
 
216
static signed16
217
MaxQH(signed16 ts, signed16 tt)
218
{
219
  return (ts > tt ? ts : tt);
220
}
221
 
222
static unsigned8
223
MaxOB(unsigned8 ts, unsigned8 tt)
224
{
225
  return (ts > tt ? ts : tt);
226
}
227
 
228
static signed16
229
MulQH(signed16 ts, signed16 tt)
230
{
231
  signed32 t = (signed32)ts * (signed32)tt;
232
  return QH_CLAMP(t);
233
}
234
 
235
static unsigned8
236
MulOB(unsigned8 ts, unsigned8 tt)
237
{
238
  unsigned32 t = (unsigned32)ts * (unsigned32)tt;
239
  return OB_CLAMP(t);
240
}
241
 
242
/* "msgn" and "sra" are defined only for QH format.  */
243
 
244
static signed16
245
MsgnQH(signed16 ts, signed16 tt)
246
{
247
  signed16 t;
248
  if (ts < 0)
249
    t = (tt == QH_MIN ? QH_MAX : -tt);
250
  else if (ts == 0)
251
    t = 0;
252
  else
253
    t = tt;
254
  return t;
255
}
256
 
257
static signed16
258
SRAQH(signed16 ts, signed16 tt)
259
{
260
  unsigned32 s = (unsigned32)tt & 0xF;
261
  return (signed16)((signed32)ts >> s);
262
}
263
 
264
 
265
/* "pabsdiff" and "pavg" are defined only for OB format.  */
266
 
267
static unsigned8
268
AbsDiffOB(unsigned8 ts, unsigned8 tt)
269
{
270
  return (ts >= tt ? ts - tt : tt - ts);
271
}
272
 
273
static unsigned8
274
AvgOB(unsigned8 ts, unsigned8 tt)
275
{
276
  return ((unsigned32)ts + (unsigned32)tt + 1) >> 1;
277
}
278
 
279
 
280
/* Dispatch tables for operations that update a CPR.  */
281
 
282
static const QH_FUNC qh_func[] = {
283
  AndQH,  NorQH,  OrQH,   XorQH, SLLQH, SRLQH,
284
  AddQH,  SubQH,  MinQH,  MaxQH,
285
  MulQH,  MsgnQH, SRAQH,  NULL,  NULL
286
};
287
 
288
static const OB_FUNC ob_func[] = {
289
  AndOB,  NorOB,  OrOB,   XorOB, SLLOB, SRLOB,
290
  AddOB,  SubOB,  MinOB,  MaxOB,
291
  MulOB,  NULL,   NULL,   AbsDiffOB, AvgOB
292
};
293
 
294
/* Auxiliary functions for CPR updates.  */
295
 
296
/* Vector mapping for QH format.  */
297
static unsigned64
298
qh_vector_op(unsigned64 v1, unsigned64 v2, QH_FUNC func)
299
{
300
  unsigned64 result = 0;
301
  int  i;
302
  signed16 h, h1, h2;
303
 
304
  for (i = 0; i < 64; i += 16)
305
    {
306
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
307
      h2 = (signed16)(v2 & 0xFFFF);  v2 >>= 16;
308
      h = (*func)(h1, h2);
309
      result |= ((unsigned64)((unsigned16)h) << i);
310
    }
311
  return result;
312
}
313
 
314
static unsigned64
315
qh_map_op(unsigned64 v1, signed16 h2, QH_FUNC func)
316
{
317
  unsigned64 result = 0;
318
  int  i;
319
  signed16 h, h1;
320
 
321
  for (i = 0; i < 64; i += 16)
322
    {
323
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
324
      h = (*func)(h1, h2);
325
      result |= ((unsigned64)((unsigned16)h) << i);
326
    }
327
  return result;
328
}
329
 
330
 
331
/* Vector operations for OB format.  */
332
 
333
static unsigned64
334
ob_vector_op(unsigned64 v1, unsigned64 v2, OB_FUNC func)
335
{
336
  unsigned64 result = 0;
337
  int  i;
338
  unsigned8 b, b1, b2;
339
 
340
  for (i = 0; i < 64; i += 8)
341
    {
342
      b1 = v1 & 0xFF;  v1 >>= 8;
343
      b2 = v2 & 0xFF;  v2 >>= 8;
344
      b = (*func)(b1, b2);
345
      result |= ((unsigned64)b << i);
346
    }
347
  return result;
348
}
349
 
350
static unsigned64
351
ob_map_op(unsigned64 v1, unsigned8 b2, OB_FUNC func)
352
{
353
  unsigned64 result = 0;
354
  int  i;
355
  unsigned8 b, b1;
356
 
357
  for (i = 0; i < 64; i += 8)
358
    {
359
      b1 = v1 & 0xFF;  v1 >>= 8;
360
      b = (*func)(b1, b2);
361
      result |= ((unsigned64)b << i);
362
    }
363
  return result;
364
}
365
 
366
 
367
/* Primary entry for operations that update CPRs.  */
368
unsigned64
369
mdmx_cpr_op(sim_cpu *cpu,
370
            address_word cia,
371
            int op,
372
            unsigned64 op1,
373
            int vt,
374
            MX_fmtsel fmtsel)
375
{
376
  unsigned64 op2;
377
  unsigned64 result = 0;
378
 
379
  switch (MX_FMT (fmtsel))
380
    {
381
    case mdmx_qh:
382
      switch (MX_VT (fmtsel))
383
        {
384
        case sel_elem:
385
          op2 = ValueFPR(vt, fmt_mdmx);
386
          result = qh_map_op(op1, QH_ELEM(op2, fmtsel), qh_func[op]);
387
          break;
388
        case sel_vect:
389
          result = qh_vector_op(op1, ValueFPR(vt, fmt_mdmx), qh_func[op]);
390
          break;
391
        case sel_imm:
392
          result = qh_map_op(op1, vt, qh_func[op]);
393
          break;
394
        }
395
      break;
396
    case mdmx_ob:
397
      switch (MX_VT (fmtsel))
398
        {
399
        case sel_elem:
400
          op2 = ValueFPR(vt, fmt_mdmx);
401
          result = ob_map_op(op1, OB_ELEM(op2, fmtsel), ob_func[op]);
402
          break;
403
        case sel_vect:
404
          result = ob_vector_op(op1, ValueFPR(vt, fmt_mdmx), ob_func[op]);
405
          break;
406
        case sel_imm:
407
          result = ob_map_op(op1, vt, ob_func[op]);
408
          break;
409
        }
410
      break;
411
    default:
412
      Unpredictable ();
413
    }
414
 
415
  return result;
416
}
417
 
418
 
419
/* Operations that update CCs */
420
 
421
static void
422
qh_vector_test(sim_cpu *cpu, unsigned64 v1, unsigned64 v2, int cond)
423
{
424
  int  i;
425
  signed16 h1, h2;
426
  int  boolean;
427
 
428
  for (i = 0; i < 4; i++)
429
    {
430
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
431
      h2 = (signed16)(v2 & 0xFFFF);  v2 >>= 16;
432
      boolean = ((cond & MX_C_EQ) && (h1 == h2)) ||
433
        ((cond & MX_C_LT) && (h1 < h2));
434
      SETFCC(i, boolean);
435
    }
436
}
437
 
438
static void
439
qh_map_test(sim_cpu *cpu, unsigned64 v1, signed16 h2, int cond)
440
{
441
  int  i;
442
  signed16 h1;
443
  int  boolean;
444
 
445
  for (i = 0; i < 4; i++)
446
    {
447
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
448
      boolean = ((cond & MX_C_EQ) && (h1 == h2)) ||
449
        ((cond & MX_C_LT) && (h1 < h2));
450
      SETFCC(i, boolean);
451
    }
452
}
453
 
454
static void
455
ob_vector_test(sim_cpu *cpu, unsigned64 v1, unsigned64 v2, int cond)
456
{
457
  int  i;
458
  unsigned8 b1, b2;
459
  int  boolean;
460
 
461
  for (i = 0; i < 8; i++)
462
    {
463
      b1 = v1 & 0xFF;  v1 >>= 8;
464
      b2 = v2 & 0xFF;  v2 >>= 8;
465
      boolean = ((cond & MX_C_EQ) && (b1 == b2)) ||
466
        ((cond & MX_C_LT) && (b1 < b2));
467
      SETFCC(i, boolean);
468
    }
469
}
470
 
471
static void
472
ob_map_test(sim_cpu *cpu, unsigned64 v1, unsigned8 b2, int cond)
473
{
474
  int  i;
475
  unsigned8 b1;
476
  int  boolean;
477
 
478
  for (i = 0; i < 8; i++)
479
    {
480
      b1 = (unsigned8)(v1 & 0xFF);  v1 >>= 8;
481
      boolean = ((cond & MX_C_EQ) && (b1 == b2)) ||
482
        ((cond & MX_C_LT) && (b1 < b2));
483
      SETFCC(i, boolean);
484
    }
485
}
486
 
487
 
488
void
489
mdmx_cc_op(sim_cpu *cpu,
490
           address_word cia,
491
           int cond,
492
           unsigned64 v1,
493
           int vt,
494
           MX_fmtsel fmtsel)
495
{
496
  unsigned64 op2;
497
 
498
  switch (MX_FMT (fmtsel))
499
    {
500
    case mdmx_qh:
501
      switch (MX_VT (fmtsel))
502
        {
503
        case sel_elem:
504
          op2 = ValueFPR(vt, fmt_mdmx);
505
          qh_map_test(cpu, v1, QH_ELEM(op2, fmtsel), cond);
506
          break;
507
        case sel_vect:
508
          qh_vector_test(cpu, v1, ValueFPR(vt, fmt_mdmx), cond);
509
          break;
510
        case sel_imm:
511
          qh_map_test(cpu, v1, vt, cond);
512
          break;
513
        }
514
      break;
515
    case mdmx_ob:
516
      switch (MX_VT (fmtsel))
517
        {
518
        case sel_elem:
519
          op2 = ValueFPR(vt, fmt_mdmx);
520
          ob_map_test(cpu, v1, OB_ELEM(op2, fmtsel), cond);
521
          break;
522
        case sel_vect:
523
          ob_vector_test(cpu, v1, ValueFPR(vt, fmt_mdmx), cond);
524
          break;
525
        case sel_imm:
526
          ob_map_test(cpu, v1, vt, cond);
527
          break;
528
        }
529
      break;
530
    default:
531
      Unpredictable ();
532
    }
533
}
534
 
535
 
536
/* Pick operations.  */
537
 
538
static unsigned64
539
qh_vector_pick(sim_cpu *cpu, unsigned64 v1, unsigned64 v2, int tf)
540
{
541
  unsigned64 result = 0;
542
  int  i, s;
543
  unsigned16 h;
544
 
545
  s = 0;
546
  for (i = 0; i < 4; i++)
547
    {
548
      h = ((GETFCC(i) == tf) ? (v1 & 0xFFFF) : (v2 & 0xFFFF));
549
      v1 >>= 16;  v2 >>= 16;
550
      result |= ((unsigned64)h << s);
551
      s += 16;
552
    }
553
  return result;
554
}
555
 
556
static unsigned64
557
qh_map_pick(sim_cpu *cpu, unsigned64 v1, signed16 h2, int tf)
558
{
559
  unsigned64 result = 0;
560
  int  i, s;
561
  unsigned16 h;
562
 
563
  s = 0;
564
  for (i = 0; i < 4; i++)
565
    {
566
      h = (GETFCC(i) == tf) ? (v1 & 0xFFFF) : (unsigned16)h2;
567
      v1 >>= 16;
568
      result |= ((unsigned64)h << s);
569
      s += 16;
570
    }
571
  return result;
572
}
573
 
574
static unsigned64
575
ob_vector_pick(sim_cpu *cpu, unsigned64 v1, unsigned64 v2, int tf)
576
{
577
  unsigned64 result = 0;
578
  int  i, s;
579
  unsigned8 b;
580
 
581
  s = 0;
582
  for (i = 0; i < 8; i++)
583
    {
584
      b = (GETFCC(i) == tf) ? (v1 & 0xFF) : (v2 & 0xFF);
585
      v1 >>= 8;  v2 >>= 8;
586
      result |= ((unsigned64)b << s);
587
      s += 8;
588
    }
589
  return result;
590
}
591
 
592
static unsigned64
593
ob_map_pick(sim_cpu *cpu, unsigned64 v1, unsigned8 b2, int tf)
594
{
595
  unsigned64 result = 0;
596
  int  i, s;
597
  unsigned8 b;
598
 
599
  s = 0;
600
  for (i = 0; i < 8; i++)
601
    {
602
      b = (GETFCC(i) == tf) ? (v1 & 0xFF) : b2;
603
      v1 >>= 8;
604
      result |= ((unsigned64)b << s);
605
      s += 8;
606
    }
607
  return result;
608
}
609
 
610
 
611
unsigned64
612
mdmx_pick_op(sim_cpu *cpu,
613
             address_word cia,
614
             int tf,
615
             unsigned64 v1,
616
             int vt,
617
             MX_fmtsel fmtsel)
618
{
619
  unsigned64 result = 0;
620
  unsigned64 op2;
621
 
622
  switch (MX_FMT (fmtsel))
623
    {
624
    case mdmx_qh:
625
      switch (MX_VT (fmtsel))
626
        {
627
        case sel_elem:
628
          op2 = ValueFPR(vt, fmt_mdmx);
629
          result = qh_map_pick(cpu, v1, QH_ELEM(op2, fmtsel), tf);
630
          break;
631
        case sel_vect:
632
          result = qh_vector_pick(cpu, v1, ValueFPR(vt, fmt_mdmx), tf);
633
          break;
634
        case sel_imm:
635
          result = qh_map_pick(cpu, v1, vt, tf);
636
          break;
637
        }
638
      break;
639
    case mdmx_ob:
640
      switch (MX_VT (fmtsel))
641
        {
642
        case sel_elem:
643
          op2 = ValueFPR(vt, fmt_mdmx);
644
          result = ob_map_pick(cpu, v1, OB_ELEM(op2, fmtsel), tf);
645
          break;
646
        case sel_vect:
647
          result = ob_vector_pick(cpu, v1, ValueFPR(vt, fmt_mdmx), tf);
648
          break;
649
        case sel_imm:
650
          result = ob_map_pick(cpu, v1, vt, tf);
651
          break;
652
        }
653
      break;
654
    default:
655
      Unpredictable ();
656
    }
657
  return result;
658
}
659
 
660
 
661
/* Accumulators.  */
662
 
663
typedef void (*QH_ACC)(signed48 *a, signed16 ts, signed16 tt);
664
 
665
static void
666
AccAddAQH(signed48 *a, signed16 ts, signed16 tt)
667
{
668
  *a += (signed48)ts + (signed48)tt;
669
}
670
 
671
static void
672
AccAddLQH(signed48 *a, signed16 ts, signed16 tt)
673
{
674
  *a = (signed48)ts + (signed48)tt;
675
}
676
 
677
static void
678
AccMulAQH(signed48 *a, signed16 ts, signed16 tt)
679
{
680
  *a += (signed48)ts * (signed48)tt;
681
}
682
 
683
static void
684
AccMulLQH(signed48 *a, signed16 ts, signed16 tt)
685
{
686
  *a = (signed48)ts * (signed48)tt;
687
}
688
 
689
static void
690
SubMulAQH(signed48 *a, signed16 ts, signed16 tt)
691
{
692
  *a -= (signed48)ts * (signed48)tt;
693
}
694
 
695
static void
696
SubMulLQH(signed48 *a, signed16 ts, signed16 tt)
697
{
698
  *a = -((signed48)ts * (signed48)tt);
699
}
700
 
701
static void
702
AccSubAQH(signed48 *a, signed16 ts, signed16 tt)
703
{
704
  *a += (signed48)ts - (signed48)tt;
705
}
706
 
707
static void
708
AccSubLQH(signed48 *a, signed16 ts, signed16 tt)
709
{
710
  *a =  (signed48)ts - (signed48)tt;
711
}
712
 
713
 
714
typedef void (*OB_ACC)(signed24 *acc, unsigned8 ts, unsigned8 tt);
715
 
716
static void
717
AccAddAOB(signed24 *a, unsigned8 ts, unsigned8 tt)
718
{
719
  *a += (signed24)ts + (signed24)tt;
720
}
721
 
722
static void
723
AccAddLOB(signed24 *a, unsigned8 ts, unsigned8 tt)
724
{
725
  *a = (signed24)ts + (signed24)tt;
726
}
727
 
728
static void
729
AccMulAOB(signed24 *a, unsigned8 ts, unsigned8 tt)
730
{
731
  *a += (signed24)ts * (signed24)tt;
732
}
733
 
734
static void
735
AccMulLOB(signed24 *a, unsigned8 ts, unsigned8 tt)
736
{
737
  *a = (signed24)ts * (signed24)tt;
738
}
739
 
740
static void
741
SubMulAOB(signed24 *a, unsigned8 ts, unsigned8 tt)
742
{
743
  *a -= (signed24)ts * (signed24)tt;
744
}
745
 
746
static void
747
SubMulLOB(signed24 *a, unsigned8 ts, unsigned8 tt)
748
{
749
  *a = -((signed24)ts * (signed24)tt);
750
}
751
 
752
static void
753
AccSubAOB(signed24 *a, unsigned8 ts, unsigned8 tt)
754
{
755
  *a += (signed24)ts - (signed24)tt;
756
}
757
 
758
static void
759
AccSubLOB(signed24 *a, unsigned8 ts, unsigned8 tt)
760
{
761
  *a = (signed24)ts - (signed24)tt;
762
}
763
 
764
static void
765
AccAbsDiffOB(signed24 *a, unsigned8 ts, unsigned8 tt)
766
{
767
  unsigned8 t = (ts >= tt ? ts - tt : tt - ts);
768
  *a += (signed24)t;
769
}
770
 
771
 
772
/* Dispatch tables for operations that update a CPR.  */
773
 
774
static const QH_ACC qh_acc[] = {
775
  AccAddAQH, AccAddAQH, AccMulAQH, AccMulLQH,
776
  SubMulAQH, SubMulLQH, AccSubAQH, AccSubLQH,
777
  NULL
778
};
779
 
780
static const OB_ACC ob_acc[] = {
781
  AccAddAOB, AccAddLOB, AccMulAOB, AccMulLOB,
782
  SubMulAOB, SubMulLOB, AccSubAOB, AccSubLOB,
783
  AccAbsDiffOB
784
};
785
 
786
 
787
static void
788
qh_vector_acc(signed48 a[], unsigned64 v1, unsigned64 v2, QH_ACC acc)
789
{
790
  int  i;
791
  signed16 h1, h2;
792
 
793
  for (i = 0; i < 4; i++)
794
    {
795
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
796
      h2 = (signed16)(v2 & 0xFFFF);  v2 >>= 16;
797
      (*acc)(&a[i], h1, h2);
798
    }
799
}
800
 
801
static void
802
qh_map_acc(signed48 a[], unsigned64 v1, signed16 h2, QH_ACC acc)
803
{
804
  int  i;
805
  signed16 h1;
806
 
807
  for (i = 0; i < 4; i++)
808
    {
809
      h1 = (signed16)(v1 & 0xFFFF);  v1 >>= 16;
810
      (*acc)(&a[i], h1, h2);
811
    }
812
}
813
 
814
static void
815
ob_vector_acc(signed24 a[], unsigned64 v1, unsigned64 v2, OB_ACC acc)
816
{
817
  int  i;
818
  unsigned8  b1, b2;
819
 
820
  for (i = 0; i < 8; i++)
821
    {
822
      b1 = v1 & 0xFF;  v1 >>= 8;
823
      b2 = v2 & 0xFF;  v2 >>= 8;
824
      (*acc)(&a[i], b1, b2);
825
    }
826
}
827
 
828
static void
829
ob_map_acc(signed24 a[], unsigned64 v1, unsigned8 b2, OB_ACC acc)
830
{
831
  int  i;
832
  unsigned8 b1;
833
 
834
  for (i = 0; i < 8; i++)
835
    {
836
      b1 = v1 & 0xFF;  v1 >>= 8;
837
      (*acc)(&a[i], b1, b2);
838
    }
839
}
840
 
841
 
842
/* Primary entry for operations that accumulate */
843
void
844
mdmx_acc_op(sim_cpu *cpu,
845
            address_word cia,
846
            int op,
847
            unsigned64 op1,
848
            int vt,
849
            MX_fmtsel fmtsel)
850
{
851
  unsigned64 op2;
852
 
853
  switch (MX_FMT (fmtsel))
854
    {
855
    case mdmx_qh:
856
      switch (MX_VT (fmtsel))
857
        {
858
        case sel_elem:
859
          op2 = ValueFPR(vt, fmt_mdmx);
860
          qh_map_acc(ACC.qh, op1, QH_ELEM(op2, fmtsel), qh_acc[op]);
861
          break;
862
        case sel_vect:
863
          qh_vector_acc(ACC.qh, op1, ValueFPR(vt, fmt_mdmx), qh_acc[op]);
864
          break;
865
        case sel_imm:
866
          qh_map_acc(ACC.qh, op1, vt, qh_acc[op]);
867
          break;
868
        }
869
      break;
870
    case mdmx_ob:
871
      switch (MX_VT (fmtsel))
872
        {
873
        case sel_elem:
874
          op2 = ValueFPR(vt, fmt_mdmx);
875
          ob_map_acc(ACC.ob, op1, OB_ELEM(op2, fmtsel), ob_acc[op]);
876
          break;
877
        case sel_vect:
878
          ob_vector_acc(ACC.ob, op1, ValueFPR(vt, fmt_mdmx), ob_acc[op]);
879
          break;
880
        case sel_imm:
881
          ob_map_acc(ACC.ob, op1, vt, ob_acc[op]);
882
          break;
883
        }
884
      break;
885
    default:
886
      Unpredictable ();
887
    }
888
}
889
 
890
 
891
/* Reading and writing accumulator (no conversion).  */
892
 
893
unsigned64
894
mdmx_rac_op(sim_cpu *cpu,
895
            address_word cia,
896
            int op,
897
            int fmt)
898
{
899
  unsigned64    result;
900
  unsigned int  shift;
901
  int           i;
902
 
903
  shift = op;          /* L = 00, M = 01, H = 10.  */
904
  result = 0;
905
 
906
  switch (fmt)
907
    {
908
    case MX_FMT_QH:
909
      shift <<= 4;              /* 16 bits per element.  */
910
      for (i = 3; i >= 0; --i)
911
        {
912
          result <<= 16;
913
          result |= ((ACC.qh[i] >> shift) & 0xFFFF);
914
        }
915
      break;
916
    case MX_FMT_OB:
917
      shift <<= 3;              /*  8 bits per element.  */
918
      for (i = 7; i >= 0; --i)
919
        {
920
          result <<= 8;
921
          result |= ((ACC.ob[i] >> shift) & 0xFF);
922
        }
923
      break;
924
    default:
925
      Unpredictable ();
926
    }
927
  return result;
928
}
929
 
930
void
931
mdmx_wacl(sim_cpu *cpu,
932
          address_word cia,
933
          int fmt,
934
          unsigned64 vs,
935
          unsigned64 vt)
936
{
937
  int           i;
938
 
939
  switch (fmt)
940
    {
941
    case MX_FMT_QH:
942
      for (i = 0; i < 4; i++)
943
        {
944
          signed32  s = (signed16)(vs & 0xFFFF);
945
          ACC.qh[i] = ((signed48)s << 16) | (vt & 0xFFFF);
946
          vs >>= 16;  vt >>= 16;
947
        }
948
      break;
949
    case MX_FMT_OB:
950
      for (i = 0; i < 8; i++)
951
        {
952
          signed16  s = (signed8)(vs & 0xFF);
953
          ACC.ob[i] = ((signed24)s << 8) | (vt & 0xFF);
954
          vs >>= 8;   vt >>= 8;
955
        }
956
      break;
957
    default:
958
      Unpredictable ();
959
    }
960
}
961
 
962
void
963
mdmx_wach(sim_cpu *cpu,
964
          address_word cia,
965
          int fmt,
966
          unsigned64 vs)
967
{
968
  int           i;
969
 
970
  switch (fmt)
971
    {
972
    case MX_FMT_QH:
973
      for (i = 0; i < 4; i++)
974
        {
975
          signed32  s = (signed16)(vs & 0xFFFF);
976
          ACC.qh[i] &= ~((signed48)0xFFFF << 32);
977
          ACC.qh[i] |=  ((signed48)s << 32);
978
          vs >>= 16;
979
        }
980
      break;
981
    case MX_FMT_OB:
982
      for (i = 0; i < 8; i++)
983
        {
984
          ACC.ob[i] &= ~((signed24)0xFF << 16);
985
          ACC.ob[i] |=  ((signed24)(vs & 0xFF) << 16);
986
          vs >>= 8;
987
        }
988
      break;
989
    default:
990
      Unpredictable ();
991
    }
992
}
993
 
994
 
995
/* Reading and writing accumulator (rounding conversions).
996
   Enumerating function guarantees s >= 0 for QH ops.  */
997
 
998
typedef signed16 (*QH_ROUND)(signed48 a, signed16 s);
999
 
1000
#define QH_BIT(n)  ((unsigned48)1 << (n))
1001
#define QH_ONES(n) (((unsigned48)1 << (n))-1)
1002
 
1003
static signed16
1004
RNASQH(signed48 a, signed16 s)
1005
{
1006
  signed48 t;
1007
  signed16 result = 0;
1008
 
1009
  if (s > 48)
1010
    result = 0;
1011
  else
1012
    {
1013
      t = (a >> s);
1014
      if ((a & QH_BIT(47)) == 0)
1015
        {
1016
          if (s > 0 && ((a >> (s-1)) & 1) == 1)
1017
            t++;
1018
          if (t > QH_MAX)
1019
            t = QH_MAX;
1020
        }
1021
      else
1022
        {
1023
          if (s > 0 && ((a >> (s-1)) & 1) == 1)
1024
            {
1025
              if (s > 1 && ((unsigned48)a & QH_ONES(s-1)) != 0)
1026
                t++;
1027
            }
1028
          if (t < QH_MIN)
1029
            t = QH_MIN;
1030
        }
1031
      result = (signed16)t;
1032
    }
1033
  return result;
1034
}
1035
 
1036
static signed16
1037
RNAUQH(signed48 a, signed16 s)
1038
{
1039
  unsigned48 t;
1040
  signed16 result;
1041
 
1042
  if (s > 48)
1043
    result = 0;
1044
  else if (s == 48)
1045
    result = ((unsigned48)a & MASK48) >> 47;
1046
  else
1047
    {
1048
      t = ((unsigned48)a & MASK48) >> s;
1049
      if (s > 0 && ((a >> (s-1)) & 1) == 1)
1050
        t++;
1051
      if (t > 0xFFFF)
1052
        t = 0xFFFF;
1053
      result = (signed16)t;
1054
    }
1055
  return result;
1056
}
1057
 
1058
static signed16
1059
RNESQH(signed48 a, signed16 s)
1060
{
1061
  signed48 t;
1062
  signed16 result = 0;
1063
 
1064
  if (s > 47)
1065
    result = 0;
1066
  else
1067
    {
1068
      t = (a >> s);
1069
      if (s > 0 && ((a >> (s-1)) & 1) == 1)
1070
        {
1071
          if (s == 1 || (a & QH_ONES(s-1)) == 0)
1072
            t += t & 1;
1073
          else
1074
            t += 1;
1075
        }
1076
      if ((a & QH_BIT(47)) == 0)
1077
        {
1078
          if (t > QH_MAX)
1079
            t = QH_MAX;
1080
        }
1081
      else
1082
        {
1083
          if (t < QH_MIN)
1084
            t = QH_MIN;
1085
        }
1086
      result = (signed16)t;
1087
    }
1088
  return result;
1089
}
1090
 
1091
static signed16
1092
RNEUQH(signed48 a, signed16 s)
1093
{
1094
  unsigned48 t;
1095
  signed16 result;
1096
 
1097
  if (s > 48)
1098
    result = 0;
1099
  else if (s == 48)
1100
    result = ((unsigned48)a > QH_BIT(47) ? 1 : 0);
1101
  else
1102
    {
1103
      t = ((unsigned48)a & MASK48) >> s;
1104
      if (s > 0 && ((a >> (s-1)) & 1) == 1)
1105
        {
1106
          if (s > 1 && (a & QH_ONES(s-1)) != 0)
1107
            t++;
1108
          else
1109
            t += t & 1;
1110
        }
1111
      if (t > 0xFFFF)
1112
        t = 0xFFFF;
1113
      result = (signed16)t;
1114
    }
1115
  return result;
1116
}
1117
 
1118
static signed16
1119
RZSQH(signed48 a, signed16 s)
1120
{
1121
  signed48 t;
1122
  signed16 result = 0;
1123
 
1124
  if (s > 47)
1125
    result = 0;
1126
  else
1127
    {
1128
      t = (a >> s);
1129
      if ((a & QH_BIT(47)) == 0)
1130
        {
1131
          if (t > QH_MAX)
1132
            t = QH_MAX;
1133
        }
1134
      else
1135
        {
1136
          if (t < QH_MIN)
1137
            t = QH_MIN;
1138
        }
1139
      result = (signed16)t;
1140
    }
1141
  return result;
1142
}
1143
 
1144
static signed16
1145
RZUQH(signed48 a, signed16 s)
1146
{
1147
  unsigned48 t;
1148
  signed16 result = 0;
1149
 
1150
  if (s > 48)
1151
    result = 0;
1152
  else if (s == 48)
1153
    result = ((unsigned48)a > QH_BIT(47) ? 1 : 0);
1154
  else
1155
    {
1156
      t = ((unsigned48)a & MASK48) >> s;
1157
      if (t > 0xFFFF)
1158
        t = 0xFFFF;
1159
      result = (signed16)t;
1160
    }
1161
  return result;
1162
}
1163
 
1164
 
1165
typedef unsigned8 (*OB_ROUND)(signed24 a, unsigned8 s);
1166
 
1167
#define OB_BIT(n)  ((unsigned24)1 << (n))
1168
#define OB_ONES(n) (((unsigned24)1 << (n))-1)
1169
 
1170
static unsigned8
1171
RNAUOB(signed24 a, unsigned8 s)
1172
{
1173
  unsigned8 result;
1174
  unsigned24 t;
1175
 
1176
  if (s > 24)
1177
    result = 0;
1178
  else if (s == 24)
1179
    result = ((unsigned24)a & MASK24) >> 23;
1180
  else
1181
    {
1182
      t = ((unsigned24)a & MASK24) >> s;
1183
      if (s > 0 && ((a >> (s-1)) & 1) == 1)
1184
        t ++;
1185
      result = OB_CLAMP(t);
1186
    }
1187
  return result;
1188
}
1189
 
1190
static unsigned8
1191
RNEUOB(signed24 a, unsigned8 s)
1192
{
1193
  unsigned8 result;
1194
  unsigned24 t;
1195
 
1196
  if (s > 24)
1197
    result = 0;
1198
  else if (s == 24)
1199
    result = (((unsigned24)a & MASK24) > OB_BIT(23) ? 1 : 0);
1200
  else
1201
    {
1202
      t = ((unsigned24)a & MASK24) >> s;
1203
      if (s > 0 && ((a >> (s-1)) & 1) == 1)
1204
        {
1205
          if (s > 1 && (a & OB_ONES(s-1)) != 0)
1206
            t++;
1207
          else
1208
            t += t & 1;
1209
        }
1210
      result = OB_CLAMP(t);
1211
    }
1212
  return result;
1213
}
1214
 
1215
static unsigned8
1216
RZUOB(signed24 a, unsigned8 s)
1217
{
1218
  unsigned8 result;
1219
  unsigned24 t;
1220
 
1221
  if (s >= 24)
1222
    result = 0;
1223
  else
1224
    {
1225
      t = ((unsigned24)a & MASK24) >> s;
1226
      result = OB_CLAMP(t);
1227
    }
1228
  return result;
1229
}
1230
 
1231
 
1232
static const QH_ROUND qh_round[] = {
1233
  RNASQH, RNAUQH, RNESQH, RNEUQH, RZSQH,  RZUQH
1234
};
1235
 
1236
static const OB_ROUND ob_round[] = {
1237
  NULL,   RNAUOB, NULL,   RNEUOB, NULL,   RZUOB
1238
};
1239
 
1240
 
1241
static unsigned64
1242
qh_vector_round(sim_cpu *cpu, address_word cia, unsigned64 v2, QH_ROUND round)
1243
{
1244
  unsigned64 result = 0;
1245
  int  i, s;
1246
  signed16 h, h2;
1247
 
1248
  s = 0;
1249
  for (i = 0; i < 4; i++)
1250
    {
1251
      h2 = (signed16)(v2 & 0xFFFF);
1252
      if (h2 >= 0)
1253
        h = (*round)(ACC.qh[i], h2);
1254
      else
1255
        {
1256
          UnpredictableResult ();
1257
          h = 0xdead;
1258
        }
1259
      v2 >>= 16;
1260
      result |= ((unsigned64)((unsigned16)h) << s);
1261
      s += 16;
1262
    }
1263
  return result;
1264
}
1265
 
1266
static unsigned64
1267
qh_map_round(sim_cpu *cpu, address_word cia, signed16 h2, QH_ROUND round)
1268
{
1269
  unsigned64 result = 0;
1270
  int  i, s;
1271
  signed16  h;
1272
 
1273
  s = 0;
1274
  for (i = 0; i < 4; i++)
1275
    {
1276
      if (h2 >= 0)
1277
        h = (*round)(ACC.qh[i], h2);
1278
      else
1279
        {
1280
          UnpredictableResult ();
1281
          h = 0xdead;
1282
        }
1283
      result |= ((unsigned64)((unsigned16)h) << s);
1284
      s += 16;
1285
    }
1286
  return result;
1287
}
1288
 
1289
static unsigned64
1290
ob_vector_round(sim_cpu *cpu, address_word cia, unsigned64 v2, OB_ROUND round)
1291
{
1292
  unsigned64 result = 0;
1293
  int  i, s;
1294
  unsigned8 b, b2;
1295
 
1296
  s = 0;
1297
  for (i = 0; i < 8; i++)
1298
    {
1299
      b2 = v2 & 0xFF;  v2 >>= 8;
1300
      b = (*round)(ACC.ob[i], b2);
1301
      result |= ((unsigned64)b << s);
1302
      s += 8;
1303
    }
1304
  return result;
1305
}
1306
 
1307
static unsigned64
1308
ob_map_round(sim_cpu *cpu, address_word cia, unsigned8 b2, OB_ROUND round)
1309
{
1310
  unsigned64 result = 0;
1311
  int  i, s;
1312
  unsigned8 b;
1313
 
1314
  s = 0;
1315
  for (i = 0; i < 8; i++)
1316
    {
1317
      b = (*round)(ACC.ob[i], b2);
1318
      result |= ((unsigned64)b << s);
1319
      s += 8;
1320
    }
1321
  return result;
1322
}
1323
 
1324
 
1325
unsigned64
1326
mdmx_round_op(sim_cpu *cpu,
1327
              address_word cia,
1328
              int rm,
1329
              int vt,
1330
              MX_fmtsel fmtsel)
1331
{
1332
  unsigned64 op2;
1333
  unsigned64 result = 0;
1334
 
1335
  switch (MX_FMT (fmtsel))
1336
    {
1337
    case mdmx_qh:
1338
      switch (MX_VT (fmtsel))
1339
        {
1340
        case sel_elem:
1341
          op2 = ValueFPR(vt, fmt_mdmx);
1342
          result = qh_map_round(cpu, cia, QH_ELEM(op2, fmtsel), qh_round[rm]);
1343
          break;
1344
        case sel_vect:
1345
          op2 = ValueFPR(vt, fmt_mdmx);
1346
          result = qh_vector_round(cpu, cia, op2, qh_round[rm]);
1347
          break;
1348
        case sel_imm:
1349
          result = qh_map_round(cpu, cia, vt, qh_round[rm]);
1350
          break;
1351
        }
1352
      break;
1353
    case mdmx_ob:
1354
      switch (MX_VT (fmtsel))
1355
        {
1356
        case sel_elem:
1357
          op2 = ValueFPR(vt, fmt_mdmx);
1358
          result = ob_map_round(cpu, cia, OB_ELEM(op2, fmtsel), ob_round[rm]);
1359
          break;
1360
        case sel_vect:
1361
          op2 = ValueFPR(vt, fmt_mdmx);
1362
          result = ob_vector_round(cpu, cia, op2, ob_round[rm]);
1363
          break;
1364
        case sel_imm:
1365
          result = ob_map_round(cpu, cia, vt, ob_round[rm]);
1366
          break;
1367
        }
1368
      break;
1369
    default:
1370
      Unpredictable ();
1371
    }
1372
 
1373
  return result;
1374
}
1375
 
1376
 
1377
/* Shuffle operation.  */
1378
 
1379
typedef struct {
1380
  enum {vs, ss, vt} source;
1381
  unsigned int      index;
1382
} sh_map;
1383
 
1384
static const sh_map ob_shuffle[][8] = {
1385
  /* MDMX 2.0 encodings (3-4, 6-7).  */
1386
  /* vr5400   encoding  (5), otherwise.  */
1387
  {                                                              }, /* RSVD */
1388
  {{vt,4}, {vs,4}, {vt,5}, {vs,5}, {vt,6}, {vs,6}, {vt,7}, {vs,7}}, /* RSVD */
1389
  {{vt,0}, {vs,0}, {vt,1}, {vs,1}, {vt,2}, {vs,2}, {vt,3}, {vs,3}}, /* RSVD */
1390
  {{vs,0}, {ss,0}, {vs,1}, {ss,1}, {vs,2}, {ss,2}, {vs,3}, {ss,3}}, /* upsl */
1391
  {{vt,1}, {vt,3}, {vt,5}, {vt,7}, {vs,1}, {vs,3}, {vs,5}, {vs,7}}, /* pach */
1392
  {{vt,0}, {vt,2}, {vt,4}, {vt,6}, {vs,0}, {vs,2}, {vs,4}, {vs,6}}, /* pacl */
1393
  {{vt,4}, {vs,4}, {vt,5}, {vs,5}, {vt,6}, {vs,6}, {vt,7}, {vs,7}}, /* mixh */
1394
  {{vt,0}, {vs,0}, {vt,1}, {vs,1}, {vt,2}, {vs,2}, {vt,3}, {vs,3}}  /* mixl */
1395
};
1396
 
1397
static const sh_map qh_shuffle[][4] = {
1398
  {{vt,2}, {vs,2}, {vt,3}, {vs,3}},  /* mixh */
1399
  {{vt,0}, {vs,0}, {vt,1}, {vs,1}},  /* mixl */
1400
  {{vt,1}, {vt,3}, {vs,1}, {vs,3}},  /* pach */
1401
  {                              },  /* RSVD */
1402
  {{vt,1}, {vs,0}, {vt,3}, {vs,2}},  /* bfla */
1403
  {                              },  /* RSVD */
1404
  {{vt,2}, {vt,3}, {vs,2}, {vs,3}},  /* repa */
1405
  {{vt,0}, {vt,1}, {vs,0}, {vs,1}}   /* repb */
1406
};
1407
 
1408
 
1409
unsigned64
1410
mdmx_shuffle(sim_cpu *cpu,
1411
             address_word cia,
1412
             int shop,
1413
             unsigned64 op1,
1414
             unsigned64 op2)
1415
{
1416
  unsigned64 result = 0;
1417
  int  i, s;
1418
  int  op;
1419
 
1420
  if ((shop & 0x3) == 0x1)       /* QH format.  */
1421
    {
1422
      op = shop >> 2;
1423
      s = 0;
1424
      for (i = 0; i < 4; i++)
1425
        {
1426
          unsigned64 v;
1427
 
1428
          switch (qh_shuffle[op][i].source)
1429
            {
1430
            case vs:
1431
              v = op1;
1432
              break;
1433
            case vt:
1434
              v = op2;
1435
              break;
1436
            default:
1437
              Unpredictable ();
1438
              v = 0;
1439
            }
1440
          result |= (((v >> 16*qh_shuffle[op][i].index) & 0xFFFF) << s);
1441
          s += 16;
1442
        }
1443
    }
1444
  else if ((shop & 0x1) == 0x0)  /* OB format.  */
1445
    {
1446
      op = shop >> 1;
1447
      s = 0;
1448
      for (i = 0; i < 8; i++)
1449
        {
1450
          unsigned8 b;
1451
          unsigned int ishift = 8*ob_shuffle[op][i].index;
1452
 
1453
          switch (ob_shuffle[op][i].source)
1454
            {
1455
            case vs:
1456
              b = (op1 >> ishift) & 0xFF;
1457
              break;
1458
            case ss:
1459
              b = ((op1 >> ishift) & 0x80) ? 0xFF : 0;
1460
              break;
1461
            case vt:
1462
              b = (op2 >> ishift) & 0xFF;
1463
              break;
1464
            default:
1465
              Unpredictable ();
1466
              b = 0;
1467
            }
1468
          result |= ((unsigned64)b << s);
1469
          s += 8;
1470
        }
1471
    }
1472
  else
1473
    Unpredictable ();
1474
 
1475
  return result;
1476
}

powered by: WebSVN 2.1.0

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