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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-6.8/] [sim/] [common/] [sim-fpu.c] - Blame information for rev 359

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1 24 jeremybenn
/* This is a software floating point library which can be used instead
2
   of the floating point routines in libgcc1.c for targets without
3
   hardware floating point.  */
4
 
5
/* Copyright 1994, 1997, 1998, 2003, 2007, 2008 Free Software Foundation, Inc.
6
 
7
This program is free software; you can redistribute it and/or modify
8
it under the terms of the GNU General Public License as published by
9
the Free Software Foundation; either version 3 of the License, or
10
(at your option) any later version.
11
 
12
This program is distributed in the hope that it will be useful,
13
but WITHOUT ANY WARRANTY; without even the implied warranty of
14
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15
GNU General Public License for more details.
16
 
17
You should have received a copy of the GNU General Public License
18
along with this program.  If not, see <http://www.gnu.org/licenses/>.  */
19
 
20
/* As a special exception, if you link this library with other files,
21
   some of which are compiled with GCC, to produce an executable,
22
   this library does not by itself cause the resulting executable
23
   to be covered by the GNU General Public License.
24
   This exception does not however invalidate any other reasons why
25
   the executable file might be covered by the GNU General Public License.  */
26
 
27
/* This implements IEEE 754 format arithmetic, but does not provide a
28
   mechanism for setting the rounding mode, or for generating or handling
29
   exceptions.
30
 
31
   The original code by Steve Chamberlain, hacked by Mark Eichin and Jim
32
   Wilson, all of Cygnus Support.  */
33
 
34
 
35
#ifndef SIM_FPU_C
36
#define SIM_FPU_C
37
 
38
#include "sim-basics.h"
39
#include "sim-fpu.h"
40
 
41
#include "sim-io.h"
42
#include "sim-assert.h"
43
 
44
 
45
/* Debugging support.
46
   If digits is -1, then print all digits.  */
47
 
48
static void
49
print_bits (unsigned64 x,
50
            int msbit,
51
            int digits,
52
            sim_fpu_print_func print,
53
            void *arg)
54
{
55
  unsigned64 bit = LSBIT64 (msbit);
56
  int i = 4;
57
  while (bit && digits)
58
    {
59
      if (i == 0)
60
        print (arg, ",");
61
 
62
      if ((x & bit))
63
        print (arg, "1");
64
      else
65
        print (arg, "0");
66
      bit >>= 1;
67
 
68
      if (digits > 0) digits--;
69
      i = (i + 1) % 4;
70
    }
71
}
72
 
73
 
74
 
75
/* Quick and dirty conversion between a host double and host 64bit int */
76
 
77
typedef union {
78
  double d;
79
  unsigned64 i;
80
} sim_fpu_map;
81
 
82
 
83
/* A packed IEEE floating point number.
84
 
85
   Form is <SIGN:1><BIASEDEXP:NR_EXPBITS><FRAC:NR_FRACBITS> for both
86
   32 and 64 bit numbers.  This number is interpreted as:
87
 
88
   Normalized (0 < BIASEDEXP && BIASEDEXP < EXPMAX):
89
   (sign ? '-' : '+') 1.<FRAC> x 2 ^ (BIASEDEXP - EXPBIAS)
90
 
91
   Denormalized (0 == BIASEDEXP && FRAC != 0):
92
   (sign ? "-" : "+") 0.<FRAC> x 2 ^ (- EXPBIAS)
93
 
94
   Zero (0 == BIASEDEXP && FRAC == 0):
95
   (sign ? "-" : "+") 0.0
96
 
97
   Infinity (BIASEDEXP == EXPMAX && FRAC == 0):
98
   (sign ? "-" : "+") "infinity"
99
 
100
   SignalingNaN (BIASEDEXP == EXPMAX && FRAC > 0 && FRAC < QUIET_NAN):
101
   SNaN.FRAC
102
 
103
   QuietNaN (BIASEDEXP == EXPMAX && FRAC > 0 && FRAC > QUIET_NAN):
104
   QNaN.FRAC
105
 
106
   */
107
 
108
#define NR_EXPBITS  (is_double ?   11 :   8)
109
#define NR_FRACBITS (is_double ?   52 : 23)
110
#define SIGNBIT     (is_double ? MSBIT64 (0) : MSBIT64 (32))
111
 
112
#define EXPMAX32    (255)
113
#define EXMPAX64    (2047)
114
#define EXPMAX      ((unsigned) (is_double ? EXMPAX64 : EXPMAX32))
115
 
116
#define EXPBIAS32   (127)
117
#define EXPBIAS64   (1023)
118
#define EXPBIAS     (is_double ? EXPBIAS64 : EXPBIAS32)
119
 
120
#define QUIET_NAN   LSBIT64 (NR_FRACBITS - 1)
121
 
122
 
123
 
124
/* An unpacked floating point number.
125
 
126
   When unpacked, the fraction of both a 32 and 64 bit floating point
127
   number is stored using the same format:
128
 
129
   64 bit - <IMPLICIT_1:1><FRACBITS:52><GUARDS:8><PAD:00>
130
   32 bit - <IMPLICIT_1:1><FRACBITS:23><GUARDS:7><PAD:30> */
131
 
132
#define NR_PAD32    (30)
133
#define NR_PAD64    (0)
134
#define NR_PAD      (is_double ? NR_PAD64 : NR_PAD32)
135
#define PADMASK     (is_double ? 0 : LSMASK64 (NR_PAD32 - 1, 0))
136
 
137
#define NR_GUARDS32 (7 + NR_PAD32)
138
#define NR_GUARDS64 (8 + NR_PAD64)
139
#define NR_GUARDS  (is_double ? NR_GUARDS64 : NR_GUARDS32)
140
#define GUARDMASK  LSMASK64 (NR_GUARDS - 1, 0)
141
 
142
#define GUARDMSB   LSBIT64  (NR_GUARDS - 1)
143
#define GUARDLSB   LSBIT64  (NR_PAD)
144
#define GUARDROUND LSMASK64 (NR_GUARDS - 2, 0)
145
 
146
#define NR_FRAC_GUARD   (60)
147
#define IMPLICIT_1 LSBIT64 (NR_FRAC_GUARD)
148
#define IMPLICIT_2 LSBIT64 (NR_FRAC_GUARD + 1)
149
#define IMPLICIT_4 LSBIT64 (NR_FRAC_GUARD + 2)
150
#define NR_SPARE 2
151
 
152
#define FRAC32MASK LSMASK64 (63, NR_FRAC_GUARD - 32 + 1)
153
 
154
#define NORMAL_EXPMIN (-(EXPBIAS)+1)
155
 
156
#define NORMAL_EXPMAX32 (EXPBIAS32)
157
#define NORMAL_EXPMAX64 (EXPBIAS64)
158
#define NORMAL_EXPMAX (EXPBIAS)
159
 
160
 
161
/* Integer constants */
162
 
163
#define MAX_INT32  ((signed64) LSMASK64 (30, 0))
164
#define MAX_UINT32 LSMASK64 (31, 0)
165
#define MIN_INT32  ((signed64) LSMASK64 (63, 31))
166
 
167
#define MAX_INT64  ((signed64) LSMASK64 (62, 0))
168
#define MAX_UINT64 LSMASK64 (63, 0)
169
#define MIN_INT64  ((signed64) LSMASK64 (63, 63))
170
 
171
#define MAX_INT   (is_64bit ? MAX_INT64  : MAX_INT32)
172
#define MIN_INT   (is_64bit ? MIN_INT64  : MIN_INT32)
173
#define MAX_UINT  (is_64bit ? MAX_UINT64 : MAX_UINT32)
174
#define NR_INTBITS (is_64bit ? 64 : 32)
175
 
176
/* Squeese an unpacked sim_fpu struct into a 32/64 bit integer */
177
STATIC_INLINE_SIM_FPU (unsigned64)
178
pack_fpu (const sim_fpu *src,
179
          int is_double)
180
{
181
  int sign;
182
  unsigned64 exp;
183
  unsigned64 fraction;
184
  unsigned64 packed;
185
 
186
  switch (src->class)
187
    {
188
      /* create a NaN */
189
    case sim_fpu_class_qnan:
190
      sign = src->sign;
191
      exp = EXPMAX;
192
      /* force fraction to correct class */
193
      fraction = src->fraction;
194
      fraction >>= NR_GUARDS;
195
#ifdef SIM_QUIET_NAN_NEGATED
196
      fraction |= QUIET_NAN - 1;
197
#else
198
      fraction |= QUIET_NAN;
199
#endif
200
      break;
201
    case sim_fpu_class_snan:
202
      sign = src->sign;
203
      exp = EXPMAX;
204
      /* force fraction to correct class */
205
      fraction = src->fraction;
206
      fraction >>= NR_GUARDS;
207
#ifdef SIM_QUIET_NAN_NEGATED
208
      fraction |= QUIET_NAN;
209
#else
210
      fraction &= ~QUIET_NAN;
211
#endif
212
      break;
213
    case sim_fpu_class_infinity:
214
      sign = src->sign;
215
      exp = EXPMAX;
216
      fraction = 0;
217
      break;
218
    case sim_fpu_class_zero:
219
      sign = src->sign;
220
      exp = 0;
221
      fraction = 0;
222
      break;
223
    case sim_fpu_class_number:
224
    case sim_fpu_class_denorm:
225
      ASSERT (src->fraction >= IMPLICIT_1);
226
      ASSERT (src->fraction < IMPLICIT_2);
227
      if (src->normal_exp < NORMAL_EXPMIN)
228
        {
229
          /* This number's exponent is too low to fit into the bits
230
             available in the number We'll denormalize the number by
231
             storing zero in the exponent and shift the fraction to
232
             the right to make up for it. */
233
          int nr_shift = NORMAL_EXPMIN - src->normal_exp;
234
          if (nr_shift > NR_FRACBITS)
235
            {
236
              /* underflow, just make the number zero */
237
              sign = src->sign;
238
              exp = 0;
239
              fraction = 0;
240
            }
241
          else
242
            {
243
              sign = src->sign;
244
              exp = 0;
245
              /* Shift by the value */
246
              fraction = src->fraction;
247
              fraction >>= NR_GUARDS;
248
              fraction >>= nr_shift;
249
            }
250
        }
251
      else if (src->normal_exp > NORMAL_EXPMAX)
252
        {
253
          /* Infinity */
254
          sign = src->sign;
255
          exp = EXPMAX;
256
          fraction = 0;
257
        }
258
      else
259
        {
260
          exp = (src->normal_exp + EXPBIAS);
261
          sign = src->sign;
262
          fraction = src->fraction;
263
          /* FIXME: Need to round according to WITH_SIM_FPU_ROUNDING
264
             or some such */
265
          /* Round to nearest: If the guard bits are the all zero, but
266
             the first, then we're half way between two numbers,
267
             choose the one which makes the lsb of the answer 0.  */
268
          if ((fraction & GUARDMASK) == GUARDMSB)
269
            {
270
              if ((fraction & (GUARDMSB << 1)))
271
                fraction += (GUARDMSB << 1);
272
            }
273
          else
274
            {
275
              /* Add a one to the guards to force round to nearest */
276
              fraction += GUARDROUND;
277
            }
278
          if ((fraction & IMPLICIT_2)) /* rounding resulted in carry */
279
            {
280
              exp += 1;
281
              fraction >>= 1;
282
            }
283
          fraction >>= NR_GUARDS;
284
          /* When exp == EXPMAX (overflow from carry) fraction must
285
             have been made zero */
286
          ASSERT ((exp == EXPMAX) <= ((fraction & ~IMPLICIT_1) == 0));
287
        }
288
      break;
289
    default:
290
      abort ();
291
    }
292
 
293
  packed = ((sign ? SIGNBIT : 0)
294
             | (exp << NR_FRACBITS)
295
             | LSMASKED64 (fraction, NR_FRACBITS - 1, 0));
296
 
297
  /* trace operation */
298
#if 0
299
  if (is_double)
300
    {
301
    }
302
  else
303
    {
304
      printf ("pack_fpu: ");
305
      printf ("-> %c%0lX.%06lX\n",
306
              LSMASKED32 (packed, 31, 31) ? '8' : '0',
307
              (long) LSEXTRACTED32 (packed, 30, 23),
308
              (long) LSEXTRACTED32 (packed, 23 - 1, 0));
309
    }
310
#endif
311
 
312
  return packed;
313
}
314
 
315
 
316
/* Unpack a 32/64 bit integer into a sim_fpu structure */
317
STATIC_INLINE_SIM_FPU (void)
318
unpack_fpu (sim_fpu *dst, unsigned64 packed, int is_double)
319
{
320
  unsigned64 fraction = LSMASKED64 (packed, NR_FRACBITS - 1, 0);
321
  unsigned exp = LSEXTRACTED64 (packed, NR_EXPBITS + NR_FRACBITS - 1, NR_FRACBITS);
322
  int sign = (packed & SIGNBIT) != 0;
323
 
324
  if (exp == 0)
325
    {
326
      /* Hmm.  Looks like 0 */
327
      if (fraction == 0)
328
        {
329
          /* tastes like zero */
330
          dst->class = sim_fpu_class_zero;
331
          dst->sign = sign;
332
          dst->normal_exp = 0;
333
        }
334
      else
335
        {
336
          /* Zero exponent with non zero fraction - it's denormalized,
337
             so there isn't a leading implicit one - we'll shift it so
338
             it gets one.  */
339
          dst->normal_exp = exp - EXPBIAS + 1;
340
          dst->class = sim_fpu_class_denorm;
341
          dst->sign = sign;
342
          fraction <<= NR_GUARDS;
343
          while (fraction < IMPLICIT_1)
344
            {
345
              fraction <<= 1;
346
              dst->normal_exp--;
347
            }
348
          dst->fraction = fraction;
349
        }
350
    }
351
  else if (exp == EXPMAX)
352
    {
353
      /* Huge exponent*/
354
      if (fraction == 0)
355
        {
356
          /* Attached to a zero fraction - means infinity */
357
          dst->class = sim_fpu_class_infinity;
358
          dst->sign = sign;
359
          /* dst->normal_exp = EXPBIAS; */
360
          /* dst->fraction = 0; */
361
        }
362
      else
363
        {
364
          int qnan;
365
 
366
          /* Non zero fraction, means NaN */
367
          dst->sign = sign;
368
          dst->fraction = (fraction << NR_GUARDS);
369
#ifdef SIM_QUIET_NAN_NEGATED
370
          qnan = (fraction & QUIET_NAN) == 0;
371
#else
372
          qnan = fraction >= QUIET_NAN;
373
#endif
374
          if (qnan)
375
            dst->class = sim_fpu_class_qnan;
376
          else
377
            dst->class = sim_fpu_class_snan;
378
        }
379
    }
380
  else
381
    {
382
      /* Nothing strange about this number */
383
      dst->class = sim_fpu_class_number;
384
      dst->sign = sign;
385
      dst->fraction = ((fraction << NR_GUARDS) | IMPLICIT_1);
386
      dst->normal_exp = exp - EXPBIAS;
387
    }
388
 
389
  /* trace operation */
390
#if 0
391
  if (is_double)
392
    {
393
    }
394
  else
395
    {
396
      printf ("unpack_fpu: %c%02lX.%06lX ->\n",
397
              LSMASKED32 (packed, 31, 31) ? '8' : '0',
398
              (long) LSEXTRACTED32 (packed, 30, 23),
399
              (long) LSEXTRACTED32 (packed, 23 - 1, 0));
400
    }
401
#endif
402
 
403
  /* sanity checks */
404
  {
405
    sim_fpu_map val;
406
    val.i = pack_fpu (dst, 1);
407
    if (is_double)
408
      {
409
        ASSERT (val.i == packed);
410
      }
411
    else
412
      {
413
        unsigned32 val = pack_fpu (dst, 0);
414
        unsigned32 org = packed;
415
        ASSERT (val == org);
416
      }
417
  }
418
}
419
 
420
 
421
/* Convert a floating point into an integer */
422
STATIC_INLINE_SIM_FPU (int)
423
fpu2i (signed64 *i,
424
       const sim_fpu *s,
425
       int is_64bit,
426
       sim_fpu_round round)
427
{
428
  unsigned64 tmp;
429
  int shift;
430
  int status = 0;
431
  if (sim_fpu_is_zero (s))
432
    {
433
      *i = 0;
434
      return 0;
435
    }
436
  if (sim_fpu_is_snan (s))
437
    {
438
      *i = MIN_INT; /* FIXME */
439
      return sim_fpu_status_invalid_cvi;
440
    }
441
  if (sim_fpu_is_qnan (s))
442
    {
443
      *i = MIN_INT; /* FIXME */
444
      return sim_fpu_status_invalid_cvi;
445
    }
446
  /* map infinity onto MAX_INT... */
447
  if (sim_fpu_is_infinity (s))
448
    {
449
      *i = s->sign ? MIN_INT : MAX_INT;
450
      return sim_fpu_status_invalid_cvi;
451
    }
452
  /* it is a number, but a small one */
453
  if (s->normal_exp < 0)
454
    {
455
      *i = 0;
456
      return sim_fpu_status_inexact;
457
    }
458
  /* Is the floating point MIN_INT or just close? */
459
  if (s->sign && s->normal_exp == (NR_INTBITS - 1))
460
    {
461
      *i = MIN_INT;
462
      ASSERT (s->fraction >= IMPLICIT_1);
463
      if (s->fraction == IMPLICIT_1)
464
        return 0; /* exact */
465
      if (is_64bit) /* can't round */
466
        return sim_fpu_status_invalid_cvi; /* must be overflow */
467
      /* For a 32bit with MAX_INT, rounding is possible */
468
      switch (round)
469
        {
470
        case sim_fpu_round_default:
471
          abort ();
472
        case sim_fpu_round_zero:
473
          if ((s->fraction & FRAC32MASK) != IMPLICIT_1)
474
            return sim_fpu_status_invalid_cvi;
475
          else
476
            return sim_fpu_status_inexact;
477
          break;
478
        case sim_fpu_round_near:
479
          {
480
            if ((s->fraction & FRAC32MASK) != IMPLICIT_1)
481
              return sim_fpu_status_invalid_cvi;
482
            else if ((s->fraction & !FRAC32MASK) >= (~FRAC32MASK >> 1))
483
              return sim_fpu_status_invalid_cvi;
484
            else
485
              return sim_fpu_status_inexact;
486
          }
487
        case sim_fpu_round_up:
488
          if ((s->fraction & FRAC32MASK) == IMPLICIT_1)
489
            return sim_fpu_status_inexact;
490
          else
491
            return sim_fpu_status_invalid_cvi;
492
        case sim_fpu_round_down:
493
          return sim_fpu_status_invalid_cvi;
494
        }
495
    }
496
  /* Would right shifting result in the FRAC being shifted into
497
     (through) the integer's sign bit? */
498
  if (s->normal_exp > (NR_INTBITS - 2))
499
    {
500
      *i = s->sign ? MIN_INT : MAX_INT;
501
      return sim_fpu_status_invalid_cvi;
502
    }
503
  /* normal number shift it into place */
504
  tmp = s->fraction;
505
  shift = (s->normal_exp - (NR_FRAC_GUARD));
506
  if (shift > 0)
507
    {
508
      tmp <<= shift;
509
    }
510
  else
511
    {
512
      shift = -shift;
513
      if (tmp & ((SIGNED64 (1) << shift) - 1))
514
        status |= sim_fpu_status_inexact;
515
      tmp >>= shift;
516
    }
517
  *i = s->sign ? (-tmp) : (tmp);
518
  return status;
519
}
520
 
521
/* convert an integer into a floating point */
522
STATIC_INLINE_SIM_FPU (int)
523
i2fpu (sim_fpu *f, signed64 i, int is_64bit)
524
{
525
  int status = 0;
526
  if (i == 0)
527
    {
528
      f->class = sim_fpu_class_zero;
529
      f->sign = 0;
530
      f->normal_exp = 0;
531
    }
532
  else
533
    {
534
      f->class = sim_fpu_class_number;
535
      f->sign = (i < 0);
536
      f->normal_exp = NR_FRAC_GUARD;
537
 
538
      if (f->sign)
539
        {
540
          /* Special case for minint, since there is no corresponding
541
             +ve integer representation for it */
542
          if (i == MIN_INT)
543
            {
544
              f->fraction = IMPLICIT_1;
545
              f->normal_exp = NR_INTBITS - 1;
546
            }
547
          else
548
            f->fraction = (-i);
549
        }
550
      else
551
        f->fraction = i;
552
 
553
      if (f->fraction >= IMPLICIT_2)
554
        {
555
          do
556
            {
557
              f->fraction = (f->fraction >> 1) | (f->fraction & 1);
558
              f->normal_exp += 1;
559
            }
560
          while (f->fraction >= IMPLICIT_2);
561
        }
562
      else if (f->fraction < IMPLICIT_1)
563
        {
564
          do
565
            {
566
              f->fraction <<= 1;
567
              f->normal_exp -= 1;
568
            }
569
          while (f->fraction < IMPLICIT_1);
570
        }
571
    }
572
 
573
  /* trace operation */
574
#if 0
575
  {
576
    printf ("i2fpu: 0x%08lX ->\n", (long) i);
577
  }
578
#endif
579
 
580
  /* sanity check */
581
  {
582
    signed64 val;
583
    fpu2i (&val, f, is_64bit, sim_fpu_round_zero);
584
    if (i >= MIN_INT32 && i <= MAX_INT32)
585
      {
586
        ASSERT (val == i);
587
      }
588
  }
589
 
590
  return status;
591
}
592
 
593
 
594
/* Convert a floating point into an integer */
595
STATIC_INLINE_SIM_FPU (int)
596
fpu2u (unsigned64 *u, const sim_fpu *s, int is_64bit)
597
{
598
  const int is_double = 1;
599
  unsigned64 tmp;
600
  int shift;
601
  if (sim_fpu_is_zero (s))
602
    {
603
      *u = 0;
604
      return 0;
605
    }
606
  if (sim_fpu_is_nan (s))
607
    {
608
      *u = 0;
609
      return 0;
610
    }
611
  /* it is a negative number */
612
  if (s->sign)
613
    {
614
      *u = 0;
615
      return 0;
616
    }
617
  /* get reasonable MAX_USI_INT... */
618
  if (sim_fpu_is_infinity (s))
619
    {
620
      *u = MAX_UINT;
621
      return 0;
622
    }
623
  /* it is a number, but a small one */
624
  if (s->normal_exp < 0)
625
    {
626
      *u = 0;
627
      return 0;
628
    }
629
  /* overflow */
630
  if (s->normal_exp > (NR_INTBITS - 1))
631
    {
632
      *u = MAX_UINT;
633
      return 0;
634
    }
635
  /* normal number */
636
  tmp = (s->fraction & ~PADMASK);
637
  shift = (s->normal_exp - (NR_FRACBITS + NR_GUARDS));
638
  if (shift > 0)
639
    {
640
      tmp <<= shift;
641
    }
642
  else
643
    {
644
      shift = -shift;
645
      tmp >>= shift;
646
    }
647
  *u = tmp;
648
  return 0;
649
}
650
 
651
/* Convert an unsigned integer into a floating point */
652
STATIC_INLINE_SIM_FPU (int)
653
u2fpu (sim_fpu *f, unsigned64 u, int is_64bit)
654
{
655
  if (u == 0)
656
    {
657
      f->class = sim_fpu_class_zero;
658
      f->sign = 0;
659
      f->normal_exp = 0;
660
    }
661
  else
662
    {
663
      f->class = sim_fpu_class_number;
664
      f->sign = 0;
665
      f->normal_exp = NR_FRAC_GUARD;
666
      f->fraction = u;
667
 
668
      while (f->fraction < IMPLICIT_1)
669
        {
670
          f->fraction <<= 1;
671
          f->normal_exp -= 1;
672
        }
673
    }
674
  return 0;
675
}
676
 
677
 
678
/* register <-> sim_fpu */
679
 
680
INLINE_SIM_FPU (void)
681
sim_fpu_32to (sim_fpu *f, unsigned32 s)
682
{
683
  unpack_fpu (f, s, 0);
684
}
685
 
686
 
687
INLINE_SIM_FPU (void)
688
sim_fpu_232to (sim_fpu *f, unsigned32 h, unsigned32 l)
689
{
690
  unsigned64 s = h;
691
  s = (s << 32) | l;
692
  unpack_fpu (f, s, 1);
693
}
694
 
695
 
696
INLINE_SIM_FPU (void)
697
sim_fpu_64to (sim_fpu *f, unsigned64 s)
698
{
699
  unpack_fpu (f, s, 1);
700
}
701
 
702
 
703
INLINE_SIM_FPU (void)
704
sim_fpu_to32 (unsigned32 *s,
705
              const sim_fpu *f)
706
{
707
  *s = pack_fpu (f, 0);
708
}
709
 
710
 
711
INLINE_SIM_FPU (void)
712
sim_fpu_to232 (unsigned32 *h, unsigned32 *l,
713
               const sim_fpu *f)
714
{
715
  unsigned64 s = pack_fpu (f, 1);
716
  *l = s;
717
  *h = (s >> 32);
718
}
719
 
720
 
721
INLINE_SIM_FPU (void)
722
sim_fpu_to64 (unsigned64 *u,
723
              const sim_fpu *f)
724
{
725
  *u = pack_fpu (f, 1);
726
}
727
 
728
 
729
INLINE_SIM_FPU (void)
730
sim_fpu_fractionto (sim_fpu *f,
731
                    int sign,
732
                    int normal_exp,
733
                    unsigned64 fraction,
734
                    int precision)
735
{
736
  int shift = (NR_FRAC_GUARD - precision);
737
  f->class = sim_fpu_class_number;
738
  f->sign = sign;
739
  f->normal_exp = normal_exp;
740
  /* shift the fraction to where sim-fpu expects it */
741
  if (shift >= 0)
742
    f->fraction = (fraction << shift);
743
  else
744
    f->fraction = (fraction >> -shift);
745
  f->fraction |= IMPLICIT_1;
746
}
747
 
748
 
749
INLINE_SIM_FPU (unsigned64)
750
sim_fpu_tofraction (const sim_fpu *d,
751
                    int precision)
752
{
753
  /* we have NR_FRAC_GUARD bits, we want only PRECISION bits */
754
  int shift = (NR_FRAC_GUARD - precision);
755
  unsigned64 fraction = (d->fraction & ~IMPLICIT_1);
756
  if (shift >= 0)
757
    return fraction >> shift;
758
  else
759
    return fraction << -shift;
760
}
761
 
762
 
763
/* Rounding */
764
 
765
STATIC_INLINE_SIM_FPU (int)
766
do_normal_overflow (sim_fpu *f,
767
                    int is_double,
768
                    sim_fpu_round round)
769
{
770
  switch (round)
771
    {
772
    case sim_fpu_round_default:
773
      return 0;
774
    case sim_fpu_round_near:
775
      f->class = sim_fpu_class_infinity;
776
      break;
777
    case sim_fpu_round_up:
778
      if (!f->sign)
779
        f->class = sim_fpu_class_infinity;
780
      break;
781
    case sim_fpu_round_down:
782
      if (f->sign)
783
        f->class = sim_fpu_class_infinity;
784
      break;
785
    case sim_fpu_round_zero:
786
      break;
787
    }
788
  f->normal_exp = NORMAL_EXPMAX;
789
  f->fraction = LSMASK64 (NR_FRAC_GUARD, NR_GUARDS);
790
  return (sim_fpu_status_overflow | sim_fpu_status_inexact);
791
}
792
 
793
STATIC_INLINE_SIM_FPU (int)
794
do_normal_underflow (sim_fpu *f,
795
                     int is_double,
796
                     sim_fpu_round round)
797
{
798
  switch (round)
799
    {
800
    case sim_fpu_round_default:
801
      return 0;
802
    case sim_fpu_round_near:
803
      f->class = sim_fpu_class_zero;
804
      break;
805
    case sim_fpu_round_up:
806
      if (f->sign)
807
        f->class = sim_fpu_class_zero;
808
      break;
809
    case sim_fpu_round_down:
810
      if (!f->sign)
811
        f->class = sim_fpu_class_zero;
812
      break;
813
    case sim_fpu_round_zero:
814
      f->class = sim_fpu_class_zero;
815
      break;
816
    }
817
  f->normal_exp = NORMAL_EXPMIN - NR_FRACBITS;
818
  f->fraction = IMPLICIT_1;
819
  return (sim_fpu_status_inexact | sim_fpu_status_underflow);
820
}
821
 
822
 
823
 
824
/* Round a number using NR_GUARDS.
825
   Will return the rounded number or F->FRACTION == 0 when underflow */
826
 
827
STATIC_INLINE_SIM_FPU (int)
828
do_normal_round (sim_fpu *f,
829
                 int nr_guards,
830
                 sim_fpu_round round)
831
{
832
  unsigned64 guardmask = LSMASK64 (nr_guards - 1, 0);
833
  unsigned64 guardmsb = LSBIT64 (nr_guards - 1);
834
  unsigned64 fraclsb = guardmsb << 1;
835
  if ((f->fraction & guardmask))
836
    {
837
      int status = sim_fpu_status_inexact;
838
      switch (round)
839
        {
840
        case sim_fpu_round_default:
841
          return 0;
842
        case sim_fpu_round_near:
843
          if ((f->fraction & guardmsb))
844
            {
845
              if ((f->fraction & fraclsb))
846
                {
847
                  status |= sim_fpu_status_rounded;
848
                }
849
              else if ((f->fraction & (guardmask >> 1)))
850
                {
851
                  status |= sim_fpu_status_rounded;
852
                }
853
            }
854
          break;
855
        case sim_fpu_round_up:
856
          if (!f->sign)
857
            status |= sim_fpu_status_rounded;
858
          break;
859
        case sim_fpu_round_down:
860
          if (f->sign)
861
            status |= sim_fpu_status_rounded;
862
          break;
863
        case sim_fpu_round_zero:
864
          break;
865
        }
866
      f->fraction &= ~guardmask;
867
      /* round if needed, handle resulting overflow */
868
      if ((status & sim_fpu_status_rounded))
869
        {
870
          f->fraction += fraclsb;
871
          if ((f->fraction & IMPLICIT_2))
872
            {
873
              f->fraction >>= 1;
874
              f->normal_exp += 1;
875
            }
876
        }
877
      return status;
878
    }
879
  else
880
    return 0;
881
}
882
 
883
 
884
STATIC_INLINE_SIM_FPU (int)
885
do_round (sim_fpu *f,
886
          int is_double,
887
          sim_fpu_round round,
888
          sim_fpu_denorm denorm)
889
{
890
  switch (f->class)
891
    {
892
    case sim_fpu_class_qnan:
893
    case sim_fpu_class_zero:
894
    case sim_fpu_class_infinity:
895
      return 0;
896
      break;
897
    case sim_fpu_class_snan:
898
      /* Quieten a SignalingNaN */
899
      f->class = sim_fpu_class_qnan;
900
      return sim_fpu_status_invalid_snan;
901
      break;
902
    case sim_fpu_class_number:
903
    case sim_fpu_class_denorm:
904
      {
905
        int status;
906
        ASSERT (f->fraction < IMPLICIT_2);
907
        ASSERT (f->fraction >= IMPLICIT_1);
908
        if (f->normal_exp < NORMAL_EXPMIN)
909
          {
910
            /* This number's exponent is too low to fit into the bits
911
               available in the number.  Round off any bits that will be
912
               discarded as a result of denormalization.  Edge case is
913
               the implicit bit shifted to GUARD0 and then rounded
914
               up. */
915
            int shift = NORMAL_EXPMIN - f->normal_exp;
916
            if (shift + NR_GUARDS <= NR_FRAC_GUARD + 1
917
                && !(denorm & sim_fpu_denorm_zero))
918
              {
919
                status = do_normal_round (f, shift + NR_GUARDS, round);
920
                if (f->fraction == 0) /* rounding underflowed */
921
                  {
922
                    status |= do_normal_underflow (f, is_double, round);
923
                  }
924
                else if (f->normal_exp < NORMAL_EXPMIN) /* still underflow? */
925
                  {
926
                    status |= sim_fpu_status_denorm;
927
                    /* Any loss of precision when denormalizing is
928
                       underflow. Some processors check for underflow
929
                       before rounding, some after! */
930
                    if (status & sim_fpu_status_inexact)
931
                      status |= sim_fpu_status_underflow;
932
                    /* Flag that resultant value has been denormalized */
933
                    f->class = sim_fpu_class_denorm;
934
                  }
935
                else if ((denorm & sim_fpu_denorm_underflow_inexact))
936
                  {
937
                    if ((status & sim_fpu_status_inexact))
938
                      status |= sim_fpu_status_underflow;
939
                  }
940
              }
941
            else
942
              {
943
                status = do_normal_underflow (f, is_double, round);
944
              }
945
          }
946
        else if (f->normal_exp > NORMAL_EXPMAX)
947
          {
948
            /* Infinity */
949
            status = do_normal_overflow (f, is_double, round);
950
          }
951
        else
952
          {
953
            status = do_normal_round (f, NR_GUARDS, round);
954
            if (f->fraction == 0)
955
              /* f->class = sim_fpu_class_zero; */
956
              status |= do_normal_underflow (f, is_double, round);
957
            else if (f->normal_exp > NORMAL_EXPMAX)
958
              /* oops! rounding caused overflow */
959
              status |= do_normal_overflow (f, is_double, round);
960
          }
961
        ASSERT ((f->class == sim_fpu_class_number
962
                 || f->class == sim_fpu_class_denorm)
963
                <= (f->fraction < IMPLICIT_2 && f->fraction >= IMPLICIT_1));
964
        return status;
965
      }
966
    }
967
  return 0;
968
}
969
 
970
INLINE_SIM_FPU (int)
971
sim_fpu_round_32 (sim_fpu *f,
972
                  sim_fpu_round round,
973
                  sim_fpu_denorm denorm)
974
{
975
  return do_round (f, 0, round, denorm);
976
}
977
 
978
INLINE_SIM_FPU (int)
979
sim_fpu_round_64 (sim_fpu *f,
980
                  sim_fpu_round round,
981
                  sim_fpu_denorm denorm)
982
{
983
  return do_round (f, 1, round, denorm);
984
}
985
 
986
 
987
 
988
/* Arithmetic ops */
989
 
990
INLINE_SIM_FPU (int)
991
sim_fpu_add (sim_fpu *f,
992
             const sim_fpu *l,
993
             const sim_fpu *r)
994
{
995
  if (sim_fpu_is_snan (l))
996
    {
997
      *f = *l;
998
      f->class = sim_fpu_class_qnan;
999
      return sim_fpu_status_invalid_snan;
1000
    }
1001
  if (sim_fpu_is_snan (r))
1002
    {
1003
      *f = *r;
1004
      f->class = sim_fpu_class_qnan;
1005
      return sim_fpu_status_invalid_snan;
1006
    }
1007
  if (sim_fpu_is_qnan (l))
1008
    {
1009
      *f = *l;
1010
      return 0;
1011
    }
1012
  if (sim_fpu_is_qnan (r))
1013
    {
1014
      *f = *r;
1015
      return 0;
1016
    }
1017
  if (sim_fpu_is_infinity (l))
1018
    {
1019
      if (sim_fpu_is_infinity (r)
1020
          && l->sign != r->sign)
1021
        {
1022
          *f = sim_fpu_qnan;
1023
          return sim_fpu_status_invalid_isi;
1024
        }
1025
      *f = *l;
1026
      return 0;
1027
    }
1028
  if (sim_fpu_is_infinity (r))
1029
    {
1030
      *f = *r;
1031
      return 0;
1032
    }
1033
  if (sim_fpu_is_zero (l))
1034
    {
1035
      if (sim_fpu_is_zero (r))
1036
        {
1037
          *f = sim_fpu_zero;
1038
          f->sign = l->sign & r->sign;
1039
        }
1040
      else
1041
        *f = *r;
1042
      return 0;
1043
    }
1044
  if (sim_fpu_is_zero (r))
1045
    {
1046
      *f = *l;
1047
      return 0;
1048
    }
1049
  {
1050
    int status = 0;
1051
    int shift = l->normal_exp - r->normal_exp;
1052
    unsigned64 lfraction;
1053
    unsigned64 rfraction;
1054
    /* use exp of larger */
1055
    if (shift >= NR_FRAC_GUARD)
1056
      {
1057
        /* left has much bigger magnitute */
1058
        *f = *l;
1059
        return sim_fpu_status_inexact;
1060
      }
1061
    if (shift <= - NR_FRAC_GUARD)
1062
      {
1063
        /* right has much bigger magnitute */
1064
        *f = *r;
1065
        return sim_fpu_status_inexact;
1066
      }
1067
    lfraction = l->fraction;
1068
    rfraction = r->fraction;
1069
    if (shift > 0)
1070
      {
1071
        f->normal_exp = l->normal_exp;
1072
        if (rfraction & LSMASK64 (shift - 1, 0))
1073
          {
1074
            status |= sim_fpu_status_inexact;
1075
            rfraction |= LSBIT64 (shift); /* stick LSBit */
1076
          }
1077
        rfraction >>= shift;
1078
      }
1079
    else if (shift < 0)
1080
      {
1081
        f->normal_exp = r->normal_exp;
1082
        if (lfraction & LSMASK64 (- shift - 1, 0))
1083
          {
1084
            status |= sim_fpu_status_inexact;
1085
            lfraction |= LSBIT64 (- shift); /* stick LSBit */
1086
          }
1087
        lfraction >>= -shift;
1088
      }
1089
    else
1090
      {
1091
        f->normal_exp = r->normal_exp;
1092
      }
1093
 
1094
    /* perform the addition */
1095
    if (l->sign)
1096
      lfraction = - lfraction;
1097
    if (r->sign)
1098
      rfraction = - rfraction;
1099
    f->fraction = lfraction + rfraction;
1100
 
1101
    /* zero? */
1102
    if (f->fraction == 0)
1103
      {
1104
        *f = sim_fpu_zero;
1105
        return 0;
1106
      }
1107
 
1108
    /* sign? */
1109
    f->class = sim_fpu_class_number;
1110
    if ((signed64) f->fraction >= 0)
1111
      f->sign = 0;
1112
    else
1113
      {
1114
        f->sign = 1;
1115
        f->fraction = - f->fraction;
1116
      }
1117
 
1118
    /* normalize it */
1119
    if ((f->fraction & IMPLICIT_2))
1120
      {
1121
        f->fraction = (f->fraction >> 1) | (f->fraction & 1);
1122
        f->normal_exp ++;
1123
      }
1124
    else if (f->fraction < IMPLICIT_1)
1125
      {
1126
        do
1127
          {
1128
            f->fraction <<= 1;
1129
            f->normal_exp --;
1130
          }
1131
        while (f->fraction < IMPLICIT_1);
1132
      }
1133
    ASSERT (f->fraction >= IMPLICIT_1 && f->fraction < IMPLICIT_2);
1134
    return status;
1135
  }
1136
}
1137
 
1138
 
1139
INLINE_SIM_FPU (int)
1140
sim_fpu_sub (sim_fpu *f,
1141
             const sim_fpu *l,
1142
             const sim_fpu *r)
1143
{
1144
  if (sim_fpu_is_snan (l))
1145
    {
1146
      *f = *l;
1147
      f->class = sim_fpu_class_qnan;
1148
      return sim_fpu_status_invalid_snan;
1149
    }
1150
  if (sim_fpu_is_snan (r))
1151
    {
1152
      *f = *r;
1153
      f->class = sim_fpu_class_qnan;
1154
      return sim_fpu_status_invalid_snan;
1155
    }
1156
  if (sim_fpu_is_qnan (l))
1157
    {
1158
      *f = *l;
1159
      return 0;
1160
    }
1161
  if (sim_fpu_is_qnan (r))
1162
    {
1163
      *f = *r;
1164
      return 0;
1165
    }
1166
  if (sim_fpu_is_infinity (l))
1167
    {
1168
      if (sim_fpu_is_infinity (r)
1169
          && l->sign == r->sign)
1170
        {
1171
          *f = sim_fpu_qnan;
1172
          return sim_fpu_status_invalid_isi;
1173
        }
1174
      *f = *l;
1175
      return 0;
1176
    }
1177
  if (sim_fpu_is_infinity (r))
1178
    {
1179
      *f = *r;
1180
      f->sign = !r->sign;
1181
      return 0;
1182
    }
1183
  if (sim_fpu_is_zero (l))
1184
    {
1185
      if (sim_fpu_is_zero (r))
1186
        {
1187
          *f = sim_fpu_zero;
1188
          f->sign = l->sign & !r->sign;
1189
        }
1190
      else
1191
        {
1192
          *f = *r;
1193
          f->sign = !r->sign;
1194
        }
1195
      return 0;
1196
    }
1197
  if (sim_fpu_is_zero (r))
1198
    {
1199
      *f = *l;
1200
      return 0;
1201
    }
1202
  {
1203
    int status = 0;
1204
    int shift = l->normal_exp - r->normal_exp;
1205
    unsigned64 lfraction;
1206
    unsigned64 rfraction;
1207
    /* use exp of larger */
1208
    if (shift >= NR_FRAC_GUARD)
1209
      {
1210
        /* left has much bigger magnitute */
1211
        *f = *l;
1212
        return sim_fpu_status_inexact;
1213
      }
1214
    if (shift <= - NR_FRAC_GUARD)
1215
      {
1216
        /* right has much bigger magnitute */
1217
        *f = *r;
1218
        f->sign = !r->sign;
1219
        return sim_fpu_status_inexact;
1220
      }
1221
    lfraction = l->fraction;
1222
    rfraction = r->fraction;
1223
    if (shift > 0)
1224
      {
1225
        f->normal_exp = l->normal_exp;
1226
        if (rfraction & LSMASK64 (shift - 1, 0))
1227
          {
1228
            status |= sim_fpu_status_inexact;
1229
            rfraction |= LSBIT64 (shift); /* stick LSBit */
1230
          }
1231
        rfraction >>= shift;
1232
      }
1233
    else if (shift < 0)
1234
      {
1235
        f->normal_exp = r->normal_exp;
1236
        if (lfraction & LSMASK64 (- shift - 1, 0))
1237
          {
1238
            status |= sim_fpu_status_inexact;
1239
            lfraction |= LSBIT64 (- shift); /* stick LSBit */
1240
          }
1241
        lfraction >>= -shift;
1242
      }
1243
    else
1244
      {
1245
        f->normal_exp = r->normal_exp;
1246
      }
1247
 
1248
    /* perform the subtraction */
1249
    if (l->sign)
1250
      lfraction = - lfraction;
1251
    if (!r->sign)
1252
      rfraction = - rfraction;
1253
    f->fraction = lfraction + rfraction;
1254
 
1255
    /* zero? */
1256
    if (f->fraction == 0)
1257
      {
1258
        *f = sim_fpu_zero;
1259
        return 0;
1260
      }
1261
 
1262
    /* sign? */
1263
    f->class = sim_fpu_class_number;
1264
    if ((signed64) f->fraction >= 0)
1265
      f->sign = 0;
1266
    else
1267
      {
1268
        f->sign = 1;
1269
        f->fraction = - f->fraction;
1270
      }
1271
 
1272
    /* normalize it */
1273
    if ((f->fraction & IMPLICIT_2))
1274
      {
1275
        f->fraction = (f->fraction >> 1) | (f->fraction & 1);
1276
        f->normal_exp ++;
1277
      }
1278
    else if (f->fraction < IMPLICIT_1)
1279
      {
1280
        do
1281
          {
1282
            f->fraction <<= 1;
1283
            f->normal_exp --;
1284
          }
1285
        while (f->fraction < IMPLICIT_1);
1286
      }
1287
    ASSERT (f->fraction >= IMPLICIT_1 && f->fraction < IMPLICIT_2);
1288
    return status;
1289
  }
1290
}
1291
 
1292
 
1293
INLINE_SIM_FPU (int)
1294
sim_fpu_mul (sim_fpu *f,
1295
             const sim_fpu *l,
1296
             const sim_fpu *r)
1297
{
1298
  if (sim_fpu_is_snan (l))
1299
    {
1300
      *f = *l;
1301
      f->class = sim_fpu_class_qnan;
1302
      return sim_fpu_status_invalid_snan;
1303
    }
1304
  if (sim_fpu_is_snan (r))
1305
    {
1306
      *f = *r;
1307
      f->class = sim_fpu_class_qnan;
1308
      return sim_fpu_status_invalid_snan;
1309
    }
1310
  if (sim_fpu_is_qnan (l))
1311
    {
1312
      *f = *l;
1313
      return 0;
1314
    }
1315
  if (sim_fpu_is_qnan (r))
1316
    {
1317
      *f = *r;
1318
      return 0;
1319
    }
1320
  if (sim_fpu_is_infinity (l))
1321
    {
1322
      if (sim_fpu_is_zero (r))
1323
        {
1324
          *f = sim_fpu_qnan;
1325
          return sim_fpu_status_invalid_imz;
1326
        }
1327
      *f = *l;
1328
      f->sign = l->sign ^ r->sign;
1329
      return 0;
1330
    }
1331
  if (sim_fpu_is_infinity (r))
1332
    {
1333
      if (sim_fpu_is_zero (l))
1334
        {
1335
          *f = sim_fpu_qnan;
1336
          return sim_fpu_status_invalid_imz;
1337
        }
1338
      *f = *r;
1339
      f->sign = l->sign ^ r->sign;
1340
      return 0;
1341
    }
1342
  if (sim_fpu_is_zero (l) || sim_fpu_is_zero (r))
1343
    {
1344
      *f = sim_fpu_zero;
1345
      f->sign = l->sign ^ r->sign;
1346
      return 0;
1347
    }
1348
  /* Calculate the mantissa by multiplying both 64bit numbers to get a
1349
     128 bit number */
1350
  {
1351
    unsigned64 low;
1352
    unsigned64 high;
1353
    unsigned64 nl = l->fraction & 0xffffffff;
1354
    unsigned64 nh = l->fraction >> 32;
1355
    unsigned64 ml = r->fraction & 0xffffffff;
1356
    unsigned64 mh = r->fraction >>32;
1357
    unsigned64 pp_ll = ml * nl;
1358
    unsigned64 pp_hl = mh * nl;
1359
    unsigned64 pp_lh = ml * nh;
1360
    unsigned64 pp_hh = mh * nh;
1361
    unsigned64 res2 = 0;
1362
    unsigned64 res0 = 0;
1363
    unsigned64 ps_hh__ = pp_hl + pp_lh;
1364
    if (ps_hh__ < pp_hl)
1365
      res2 += UNSIGNED64 (0x100000000);
1366
    pp_hl = (ps_hh__ << 32) & UNSIGNED64 (0xffffffff00000000);
1367
    res0 = pp_ll + pp_hl;
1368
    if (res0 < pp_ll)
1369
      res2++;
1370
    res2 += ((ps_hh__ >> 32) & 0xffffffff) + pp_hh;
1371
    high = res2;
1372
    low = res0;
1373
 
1374
    f->normal_exp = l->normal_exp + r->normal_exp;
1375
    f->sign = l->sign ^ r->sign;
1376
    f->class = sim_fpu_class_number;
1377
 
1378
    /* Input is bounded by [1,2)   ;   [2^60,2^61)
1379
       Output is bounded by [1,4)  ;   [2^120,2^122) */
1380
 
1381
    /* Adjust the exponent according to where the decimal point ended
1382
       up in the high 64 bit word.  In the source the decimal point
1383
       was at NR_FRAC_GUARD. */
1384
    f->normal_exp += NR_FRAC_GUARD + 64 - (NR_FRAC_GUARD * 2);
1385
 
1386
    /* The high word is bounded according to the above.  Consequently
1387
       it has never overflowed into IMPLICIT_2. */
1388
    ASSERT (high < LSBIT64 (((NR_FRAC_GUARD + 1) * 2) - 64));
1389
    ASSERT (high >= LSBIT64 ((NR_FRAC_GUARD * 2) - 64));
1390
    ASSERT (LSBIT64 (((NR_FRAC_GUARD + 1) * 2) - 64) < IMPLICIT_1);
1391
 
1392
    /* normalize */
1393
    do
1394
      {
1395
        f->normal_exp--;
1396
        high <<= 1;
1397
        if (low & LSBIT64 (63))
1398
          high |= 1;
1399
        low <<= 1;
1400
      }
1401
    while (high < IMPLICIT_1);
1402
 
1403
    ASSERT (high >= IMPLICIT_1 && high < IMPLICIT_2);
1404
    if (low != 0)
1405
      {
1406
        f->fraction = (high | 1); /* sticky */
1407
        return sim_fpu_status_inexact;
1408
      }
1409
    else
1410
      {
1411
        f->fraction = high;
1412
        return 0;
1413
      }
1414
    return 0;
1415
  }
1416
}
1417
 
1418
INLINE_SIM_FPU (int)
1419
sim_fpu_div (sim_fpu *f,
1420
             const sim_fpu *l,
1421
             const sim_fpu *r)
1422
{
1423
  if (sim_fpu_is_snan (l))
1424
    {
1425
      *f = *l;
1426
      f->class = sim_fpu_class_qnan;
1427
      return sim_fpu_status_invalid_snan;
1428
    }
1429
  if (sim_fpu_is_snan (r))
1430
    {
1431
      *f = *r;
1432
      f->class = sim_fpu_class_qnan;
1433
      return sim_fpu_status_invalid_snan;
1434
    }
1435
  if (sim_fpu_is_qnan (l))
1436
    {
1437
      *f = *l;
1438
      f->class = sim_fpu_class_qnan;
1439
      return 0;
1440
    }
1441
  if (sim_fpu_is_qnan (r))
1442
    {
1443
      *f = *r;
1444
      f->class = sim_fpu_class_qnan;
1445
      return 0;
1446
    }
1447
  if (sim_fpu_is_infinity (l))
1448
    {
1449
      if (sim_fpu_is_infinity (r))
1450
        {
1451
          *f = sim_fpu_qnan;
1452
          return sim_fpu_status_invalid_idi;
1453
        }
1454
      else
1455
        {
1456
          *f = *l;
1457
          f->sign = l->sign ^ r->sign;
1458
          return 0;
1459
        }
1460
    }
1461
  if (sim_fpu_is_zero (l))
1462
    {
1463
      if (sim_fpu_is_zero (r))
1464
        {
1465
          *f = sim_fpu_qnan;
1466
          return sim_fpu_status_invalid_zdz;
1467
        }
1468
      else
1469
        {
1470
          *f = *l;
1471
          f->sign = l->sign ^ r->sign;
1472
          return 0;
1473
        }
1474
    }
1475
  if (sim_fpu_is_infinity (r))
1476
    {
1477
      *f = sim_fpu_zero;
1478
      f->sign = l->sign ^ r->sign;
1479
      return 0;
1480
    }
1481
  if (sim_fpu_is_zero (r))
1482
    {
1483
      f->class = sim_fpu_class_infinity;
1484
      f->sign = l->sign ^ r->sign;
1485
      return sim_fpu_status_invalid_div0;
1486
    }
1487
 
1488
  /* Calculate the mantissa by multiplying both 64bit numbers to get a
1489
     128 bit number */
1490
  {
1491
    /* quotient =  ( ( numerator / denominator)
1492
                      x 2^(numerator exponent -  denominator exponent)
1493
     */
1494
    unsigned64 numerator;
1495
    unsigned64 denominator;
1496
    unsigned64 quotient;
1497
    unsigned64 bit;
1498
 
1499
    f->class = sim_fpu_class_number;
1500
    f->sign = l->sign ^ r->sign;
1501
    f->normal_exp = l->normal_exp - r->normal_exp;
1502
 
1503
    numerator = l->fraction;
1504
    denominator = r->fraction;
1505
 
1506
    /* Fraction will be less than 1.0 */
1507
    if (numerator < denominator)
1508
      {
1509
        numerator <<= 1;
1510
        f->normal_exp--;
1511
      }
1512
    ASSERT (numerator >= denominator);
1513
 
1514
    /* Gain extra precision, already used one spare bit */
1515
    numerator <<=    NR_SPARE;
1516
    denominator <<=  NR_SPARE;
1517
 
1518
    /* Does divide one bit at a time.  Optimize???  */
1519
    quotient = 0;
1520
    bit = (IMPLICIT_1 << NR_SPARE);
1521
    while (bit)
1522
      {
1523
        if (numerator >= denominator)
1524
          {
1525
            quotient |= bit;
1526
            numerator -= denominator;
1527
          }
1528
        bit >>= 1;
1529
        numerator <<= 1;
1530
      }
1531
 
1532
    /* discard (but save) the extra bits */
1533
    if ((quotient & LSMASK64 (NR_SPARE -1, 0)))
1534
      quotient = (quotient >> NR_SPARE) | 1;
1535
    else
1536
      quotient = (quotient >> NR_SPARE);
1537
 
1538
    f->fraction = quotient;
1539
    ASSERT (f->fraction >= IMPLICIT_1 && f->fraction < IMPLICIT_2);
1540
    if (numerator != 0)
1541
      {
1542
        f->fraction |= 1; /* stick remaining bits */
1543
        return sim_fpu_status_inexact;
1544
      }
1545
    else
1546
      return 0;
1547
  }
1548
}
1549
 
1550
 
1551
INLINE_SIM_FPU (int)
1552
sim_fpu_max (sim_fpu *f,
1553
             const sim_fpu *l,
1554
             const sim_fpu *r)
1555
{
1556
  if (sim_fpu_is_snan (l))
1557
    {
1558
      *f = *l;
1559
      f->class = sim_fpu_class_qnan;
1560
      return sim_fpu_status_invalid_snan;
1561
    }
1562
  if (sim_fpu_is_snan (r))
1563
    {
1564
      *f = *r;
1565
      f->class = sim_fpu_class_qnan;
1566
      return sim_fpu_status_invalid_snan;
1567
    }
1568
  if (sim_fpu_is_qnan (l))
1569
    {
1570
      *f = *l;
1571
      return 0;
1572
    }
1573
  if (sim_fpu_is_qnan (r))
1574
    {
1575
      *f = *r;
1576
      return 0;
1577
    }
1578
  if (sim_fpu_is_infinity (l))
1579
    {
1580
      if (sim_fpu_is_infinity (r)
1581
          && l->sign == r->sign)
1582
        {
1583
          *f = sim_fpu_qnan;
1584
          return sim_fpu_status_invalid_isi;
1585
        }
1586
      if (l->sign)
1587
        *f = *r; /* -inf < anything */
1588
      else
1589
        *f = *l; /* +inf > anthing */
1590
      return 0;
1591
    }
1592
  if (sim_fpu_is_infinity (r))
1593
    {
1594
      if (r->sign)
1595
        *f = *l; /* anything > -inf */
1596
      else
1597
        *f = *r; /* anthing < +inf */
1598
      return 0;
1599
    }
1600
  if (l->sign > r->sign)
1601
    {
1602
      *f = *r; /* -ve < +ve */
1603
      return 0;
1604
    }
1605
  if (l->sign < r->sign)
1606
    {
1607
      *f = *l; /* +ve > -ve */
1608
      return 0;
1609
    }
1610
  ASSERT (l->sign == r->sign);
1611
  if (l->normal_exp > r->normal_exp
1612
      || (l->normal_exp == r->normal_exp &&
1613
          l->fraction > r->fraction))
1614
    {
1615
      /* |l| > |r| */
1616
      if (l->sign)
1617
        *f = *r; /* -ve < -ve */
1618
      else
1619
        *f = *l; /* +ve > +ve */
1620
      return 0;
1621
    }
1622
  else
1623
    {
1624
      /* |l| <= |r| */
1625
      if (l->sign)
1626
        *f = *l; /* -ve > -ve */
1627
      else
1628
        *f = *r; /* +ve < +ve */
1629
      return 0;
1630
    }
1631
}
1632
 
1633
 
1634
INLINE_SIM_FPU (int)
1635
sim_fpu_min (sim_fpu *f,
1636
             const sim_fpu *l,
1637
             const sim_fpu *r)
1638
{
1639
  if (sim_fpu_is_snan (l))
1640
    {
1641
      *f = *l;
1642
      f->class = sim_fpu_class_qnan;
1643
      return sim_fpu_status_invalid_snan;
1644
    }
1645
  if (sim_fpu_is_snan (r))
1646
    {
1647
      *f = *r;
1648
      f->class = sim_fpu_class_qnan;
1649
      return sim_fpu_status_invalid_snan;
1650
    }
1651
  if (sim_fpu_is_qnan (l))
1652
    {
1653
      *f = *l;
1654
      return 0;
1655
    }
1656
  if (sim_fpu_is_qnan (r))
1657
    {
1658
      *f = *r;
1659
      return 0;
1660
    }
1661
  if (sim_fpu_is_infinity (l))
1662
    {
1663
      if (sim_fpu_is_infinity (r)
1664
          && l->sign == r->sign)
1665
        {
1666
          *f = sim_fpu_qnan;
1667
          return sim_fpu_status_invalid_isi;
1668
        }
1669
      if (l->sign)
1670
        *f = *l; /* -inf < anything */
1671
      else
1672
        *f = *r; /* +inf > anthing */
1673
      return 0;
1674
    }
1675
  if (sim_fpu_is_infinity (r))
1676
    {
1677
      if (r->sign)
1678
        *f = *r; /* anything > -inf */
1679
      else
1680
        *f = *l; /* anything < +inf */
1681
      return 0;
1682
    }
1683
  if (l->sign > r->sign)
1684
    {
1685
      *f = *l; /* -ve < +ve */
1686
      return 0;
1687
    }
1688
  if (l->sign < r->sign)
1689
    {
1690
      *f = *r; /* +ve > -ve */
1691
      return 0;
1692
    }
1693
  ASSERT (l->sign == r->sign);
1694
  if (l->normal_exp > r->normal_exp
1695
      || (l->normal_exp == r->normal_exp &&
1696
          l->fraction > r->fraction))
1697
    {
1698
      /* |l| > |r| */
1699
      if (l->sign)
1700
        *f = *l; /* -ve < -ve */
1701
      else
1702
        *f = *r; /* +ve > +ve */
1703
      return 0;
1704
    }
1705
  else
1706
    {
1707
      /* |l| <= |r| */
1708
      if (l->sign)
1709
        *f = *r; /* -ve > -ve */
1710
      else
1711
        *f = *l; /* +ve < +ve */
1712
      return 0;
1713
    }
1714
}
1715
 
1716
 
1717
INLINE_SIM_FPU (int)
1718
sim_fpu_neg (sim_fpu *f,
1719
             const sim_fpu *r)
1720
{
1721
  if (sim_fpu_is_snan (r))
1722
    {
1723
      *f = *r;
1724
      f->class = sim_fpu_class_qnan;
1725
      return sim_fpu_status_invalid_snan;
1726
    }
1727
  if (sim_fpu_is_qnan (r))
1728
    {
1729
      *f = *r;
1730
      return 0;
1731
    }
1732
  *f = *r;
1733
  f->sign = !r->sign;
1734
  return 0;
1735
}
1736
 
1737
 
1738
INLINE_SIM_FPU (int)
1739
sim_fpu_abs (sim_fpu *f,
1740
             const sim_fpu *r)
1741
{
1742
  *f = *r;
1743
  f->sign = 0;
1744
  if (sim_fpu_is_snan (r))
1745
    {
1746
      f->class = sim_fpu_class_qnan;
1747
      return sim_fpu_status_invalid_snan;
1748
    }
1749
  return 0;
1750
}
1751
 
1752
 
1753
INLINE_SIM_FPU (int)
1754
sim_fpu_inv (sim_fpu *f,
1755
             const sim_fpu *r)
1756
{
1757
  return sim_fpu_div (f, &sim_fpu_one, r);
1758
}
1759
 
1760
 
1761
INLINE_SIM_FPU (int)
1762
sim_fpu_sqrt (sim_fpu *f,
1763
              const sim_fpu *r)
1764
{
1765
  if (sim_fpu_is_snan (r))
1766
    {
1767
      *f = sim_fpu_qnan;
1768
      return sim_fpu_status_invalid_snan;
1769
    }
1770
  if (sim_fpu_is_qnan (r))
1771
    {
1772
      *f = sim_fpu_qnan;
1773
      return 0;
1774
    }
1775
  if (sim_fpu_is_zero (r))
1776
    {
1777
      f->class = sim_fpu_class_zero;
1778
      f->sign = r->sign;
1779
      f->normal_exp = 0;
1780
      return 0;
1781
    }
1782
  if (sim_fpu_is_infinity (r))
1783
    {
1784
      if (r->sign)
1785
        {
1786
          *f = sim_fpu_qnan;
1787
          return sim_fpu_status_invalid_sqrt;
1788
        }
1789
      else
1790
        {
1791
          f->class = sim_fpu_class_infinity;
1792
          f->sign = 0;
1793
          f->sign = 0;
1794
          return 0;
1795
        }
1796
    }
1797
  if (r->sign)
1798
    {
1799
      *f = sim_fpu_qnan;
1800
      return sim_fpu_status_invalid_sqrt;
1801
    }
1802
 
1803
  /* @(#)e_sqrt.c 5.1 93/09/24 */
1804
  /*
1805
   * ====================================================
1806
   * Copyright (C) 1993 by Sun Microsystems, Inc. All rights reserved.
1807
   *
1808
   * Developed at SunPro, a Sun Microsystems, Inc. business.
1809
   * Permission to use, copy, modify, and distribute this
1810
   * software is freely granted, provided that this notice
1811
   * is preserved.
1812
   * ====================================================
1813
   */
1814
 
1815
  /* __ieee754_sqrt(x)
1816
   * Return correctly rounded sqrt.
1817
   *           ------------------------------------------
1818
   *           |  Use the hardware sqrt if you have one |
1819
   *           ------------------------------------------
1820
   * Method:
1821
   *   Bit by bit method using integer arithmetic. (Slow, but portable)
1822
   *   1. Normalization
1823
   *    Scale x to y in [1,4) with even powers of 2:
1824
   *    find an integer k such that  1 <= (y=x*2^(2k)) < 4, then
1825
   *            sqrt(x) = 2^k * sqrt(y)
1826
   -
1827
   - Since:
1828
   -   sqrt ( x*2^(2m) )     = sqrt(x).2^m    ; m even
1829
   -   sqrt ( x*2^(2m + 1) ) = sqrt(2.x).2^m  ; m odd
1830
   - Define:
1831
   -   y = ((m even) ? x : 2.x)
1832
   - Then:
1833
   -   y in [1, 4)                            ; [IMPLICIT_1,IMPLICIT_4)
1834
   - And:
1835
   -   sqrt (y) in [1, 2)                     ; [IMPLICIT_1,IMPLICIT_2)
1836
   -
1837
   *   2. Bit by bit computation
1838
   *    Let q  = sqrt(y) truncated to i bit after binary point (q = 1),
1839
   *         i                                                   0
1840
   *                                     i+1         2
1841
   *        s  = 2*q , and      y  =  2   * ( y - q  ).         (1)
1842
   *         i      i            i                 i
1843
   *
1844
   *    To compute q    from q , one checks whether
1845
   *                i+1       i
1846
   *
1847
   *                          -(i+1) 2
1848
   *                    (q + 2      ) <= y.                     (2)
1849
   *                              i
1850
   *                                                          -(i+1)
1851
   *    If (2) is false, then q   = q ; otherwise q   = q  + 2      .
1852
   *                           i+1   i             i+1   i
1853
   *
1854
   *    With some algebric manipulation, it is not difficult to see
1855
   *    that (2) is equivalent to
1856
   *                             -(i+1)
1857
   *                    s  +  2       <= y                      (3)
1858
   *                     i                i
1859
   *
1860
   *    The advantage of (3) is that s  and y  can be computed by
1861
   *                                  i      i
1862
   *    the following recurrence formula:
1863
   *        if (3) is false
1864
   *
1865
   *        s     =  s  ,       y    = y   ;                    (4)
1866
   *         i+1      i          i+1    i
1867
   *
1868
   -
1869
   -                      NOTE: y    = 2*y
1870
   -                             i+1      i
1871
   -
1872
   *        otherwise,
1873
   *                       -i                      -(i+1)
1874
   *        s     =  s  + 2  ,  y    = y  -  s  - 2             (5)
1875
   *         i+1      i          i+1    i     i
1876
   *
1877
   -
1878
   -                                                   -(i+1)
1879
   -                      NOTE: y    = 2 (y  -  s  -  2      )
1880
   -                             i+1       i     i
1881
   -
1882
   *    One may easily use induction to prove (4) and (5).
1883
   *    Note. Since the left hand side of (3) contain only i+2 bits,
1884
   *          it does not necessary to do a full (53-bit) comparison
1885
   *          in (3).
1886
   *   3. Final rounding
1887
   *    After generating the 53 bits result, we compute one more bit.
1888
   *    Together with the remainder, we can decide whether the
1889
   *    result is exact, bigger than 1/2ulp, or less than 1/2ulp
1890
   *    (it will never equal to 1/2ulp).
1891
   *    The rounding mode can be detected by checking whether
1892
   *    huge + tiny is equal to huge, and whether huge - tiny is
1893
   *    equal to huge for some floating point number "huge" and "tiny".
1894
   *
1895
   * Special cases:
1896
   *    sqrt(+-0) = +-0         ... exact
1897
   *    sqrt(inf) = inf
1898
   *    sqrt(-ve) = NaN         ... with invalid signal
1899
   *    sqrt(NaN) = NaN         ... with invalid signal for signaling NaN
1900
   *
1901
   * Other methods : see the appended file at the end of the program below.
1902
   *---------------
1903
   */
1904
 
1905
  {
1906
    /* generate sqrt(x) bit by bit */
1907
    unsigned64 y;
1908
    unsigned64 q;
1909
    unsigned64 s;
1910
    unsigned64 b;
1911
 
1912
    f->class = sim_fpu_class_number;
1913
    f->sign = 0;
1914
    y = r->fraction;
1915
    f->normal_exp = (r->normal_exp >> 1);       /* exp = [exp/2] */
1916
 
1917
    /* odd exp, double x to make it even */
1918
    ASSERT (y >= IMPLICIT_1 && y < IMPLICIT_4);
1919
    if ((r->normal_exp & 1))
1920
      {
1921
        y += y;
1922
      }
1923
    ASSERT (y >= IMPLICIT_1 && y < (IMPLICIT_2 << 1));
1924
 
1925
    /* Let loop determine first value of s (either 1 or 2) */
1926
    b = IMPLICIT_1;
1927
    q = 0;
1928
    s = 0;
1929
 
1930
    while (b)
1931
      {
1932
        unsigned64 t = s + b;
1933
        if (t <= y)
1934
          {
1935
            s |= (b << 1);
1936
            y -= t;
1937
            q |= b;
1938
          }
1939
        y <<= 1;
1940
        b >>= 1;
1941
      }
1942
 
1943
    ASSERT (q >= IMPLICIT_1 && q < IMPLICIT_2);
1944
    f->fraction = q;
1945
    if (y != 0)
1946
      {
1947
        f->fraction |= 1; /* stick remaining bits */
1948
        return sim_fpu_status_inexact;
1949
      }
1950
    else
1951
      return 0;
1952
  }
1953
}
1954
 
1955
 
1956
/* int/long <-> sim_fpu */
1957
 
1958
INLINE_SIM_FPU (int)
1959
sim_fpu_i32to (sim_fpu *f,
1960
               signed32 i,
1961
               sim_fpu_round round)
1962
{
1963
  i2fpu (f, i, 0);
1964
  return 0;
1965
}
1966
 
1967
INLINE_SIM_FPU (int)
1968
sim_fpu_u32to (sim_fpu *f,
1969
               unsigned32 u,
1970
               sim_fpu_round round)
1971
{
1972
  u2fpu (f, u, 0);
1973
  return 0;
1974
}
1975
 
1976
INLINE_SIM_FPU (int)
1977
sim_fpu_i64to (sim_fpu *f,
1978
               signed64 i,
1979
               sim_fpu_round round)
1980
{
1981
  i2fpu (f, i, 1);
1982
  return 0;
1983
}
1984
 
1985
INLINE_SIM_FPU (int)
1986
sim_fpu_u64to (sim_fpu *f,
1987
               unsigned64 u,
1988
               sim_fpu_round round)
1989
{
1990
  u2fpu (f, u, 1);
1991
  return 0;
1992
}
1993
 
1994
 
1995
INLINE_SIM_FPU (int)
1996
sim_fpu_to32i (signed32 *i,
1997
               const sim_fpu *f,
1998
               sim_fpu_round round)
1999
{
2000
  signed64 i64;
2001
  int status = fpu2i (&i64, f, 0, round);
2002
  *i = i64;
2003
  return status;
2004
}
2005
 
2006
INLINE_SIM_FPU (int)
2007
sim_fpu_to32u (unsigned32 *u,
2008
               const sim_fpu *f,
2009
               sim_fpu_round round)
2010
{
2011
  unsigned64 u64;
2012
  int status = fpu2u (&u64, f, 0);
2013
  *u = u64;
2014
  return status;
2015
}
2016
 
2017
INLINE_SIM_FPU (int)
2018
sim_fpu_to64i (signed64 *i,
2019
               const sim_fpu *f,
2020
               sim_fpu_round round)
2021
{
2022
  return fpu2i (i, f, 1, round);
2023
}
2024
 
2025
 
2026
INLINE_SIM_FPU (int)
2027
sim_fpu_to64u (unsigned64 *u,
2028
               const sim_fpu *f,
2029
               sim_fpu_round round)
2030
{
2031
  return fpu2u (u, f, 1);
2032
}
2033
 
2034
 
2035
 
2036
/* sim_fpu -> host format */
2037
 
2038
#if 0
2039
INLINE_SIM_FPU (float)
2040
sim_fpu_2f (const sim_fpu *f)
2041
{
2042
  return fval.d;
2043
}
2044
#endif
2045
 
2046
 
2047
INLINE_SIM_FPU (double)
2048
sim_fpu_2d (const sim_fpu *s)
2049
{
2050
  sim_fpu_map val;
2051
  if (sim_fpu_is_snan (s))
2052
    {
2053
      /* gag SNaN's */
2054
      sim_fpu n = *s;
2055
      n.class = sim_fpu_class_qnan;
2056
      val.i = pack_fpu (&n, 1);
2057
    }
2058
  else
2059
    {
2060
      val.i = pack_fpu (s, 1);
2061
    }
2062
  return val.d;
2063
}
2064
 
2065
 
2066
#if 0
2067
INLINE_SIM_FPU (void)
2068
sim_fpu_f2 (sim_fpu *f,
2069
            float s)
2070
{
2071
  sim_fpu_map val;
2072
  val.d = s;
2073
  unpack_fpu (f, val.i, 1);
2074
}
2075
#endif
2076
 
2077
 
2078
INLINE_SIM_FPU (void)
2079
sim_fpu_d2 (sim_fpu *f,
2080
            double d)
2081
{
2082
  sim_fpu_map val;
2083
  val.d = d;
2084
  unpack_fpu (f, val.i, 1);
2085
}
2086
 
2087
 
2088
/* General */
2089
 
2090
INLINE_SIM_FPU (int)
2091
sim_fpu_is_nan (const sim_fpu *d)
2092
{
2093
  switch (d->class)
2094
    {
2095
    case sim_fpu_class_qnan:
2096
    case sim_fpu_class_snan:
2097
      return 1;
2098
    default:
2099
      return 0;
2100
    }
2101
}
2102
 
2103
INLINE_SIM_FPU (int)
2104
sim_fpu_is_qnan (const sim_fpu *d)
2105
{
2106
  switch (d->class)
2107
    {
2108
    case sim_fpu_class_qnan:
2109
      return 1;
2110
    default:
2111
      return 0;
2112
    }
2113
}
2114
 
2115
INLINE_SIM_FPU (int)
2116
sim_fpu_is_snan (const sim_fpu *d)
2117
{
2118
  switch (d->class)
2119
    {
2120
    case sim_fpu_class_snan:
2121
      return 1;
2122
    default:
2123
      return 0;
2124
    }
2125
}
2126
 
2127
INLINE_SIM_FPU (int)
2128
sim_fpu_is_zero (const sim_fpu *d)
2129
{
2130
  switch (d->class)
2131
    {
2132
    case sim_fpu_class_zero:
2133
      return 1;
2134
    default:
2135
      return 0;
2136
    }
2137
}
2138
 
2139
INLINE_SIM_FPU (int)
2140
sim_fpu_is_infinity (const sim_fpu *d)
2141
{
2142
  switch (d->class)
2143
    {
2144
    case sim_fpu_class_infinity:
2145
      return 1;
2146
    default:
2147
      return 0;
2148
    }
2149
}
2150
 
2151
INLINE_SIM_FPU (int)
2152
sim_fpu_is_number (const sim_fpu *d)
2153
{
2154
  switch (d->class)
2155
    {
2156
    case sim_fpu_class_denorm:
2157
    case sim_fpu_class_number:
2158
      return 1;
2159
    default:
2160
      return 0;
2161
    }
2162
}
2163
 
2164
INLINE_SIM_FPU (int)
2165
sim_fpu_is_denorm (const sim_fpu *d)
2166
{
2167
  switch (d->class)
2168
    {
2169
    case sim_fpu_class_denorm:
2170
      return 1;
2171
    default:
2172
      return 0;
2173
    }
2174
}
2175
 
2176
 
2177
INLINE_SIM_FPU (int)
2178
sim_fpu_sign (const sim_fpu *d)
2179
{
2180
  return d->sign;
2181
}
2182
 
2183
 
2184
INLINE_SIM_FPU (int)
2185
sim_fpu_exp (const sim_fpu *d)
2186
{
2187
  return d->normal_exp;
2188
}
2189
 
2190
 
2191
INLINE_SIM_FPU (unsigned64)
2192
sim_fpu_fraction (const sim_fpu *d)
2193
{
2194
  return d->fraction;
2195
}
2196
 
2197
 
2198
INLINE_SIM_FPU (unsigned64)
2199
sim_fpu_guard (const sim_fpu *d, int is_double)
2200
{
2201
  unsigned64 rv;
2202
  unsigned64 guardmask = LSMASK64 (NR_GUARDS - 1, 0);
2203
  rv = (d->fraction & guardmask) >> NR_PAD;
2204
  return rv;
2205
}
2206
 
2207
 
2208
INLINE_SIM_FPU (int)
2209
sim_fpu_is (const sim_fpu *d)
2210
{
2211
  switch (d->class)
2212
    {
2213
    case sim_fpu_class_qnan:
2214
      return SIM_FPU_IS_QNAN;
2215
    case sim_fpu_class_snan:
2216
      return SIM_FPU_IS_SNAN;
2217
    case sim_fpu_class_infinity:
2218
      if (d->sign)
2219
        return SIM_FPU_IS_NINF;
2220
      else
2221
        return SIM_FPU_IS_PINF;
2222
    case sim_fpu_class_number:
2223
      if (d->sign)
2224
        return SIM_FPU_IS_NNUMBER;
2225
      else
2226
        return SIM_FPU_IS_PNUMBER;
2227
    case sim_fpu_class_denorm:
2228
      if (d->sign)
2229
        return SIM_FPU_IS_NDENORM;
2230
      else
2231
        return SIM_FPU_IS_PDENORM;
2232
    case sim_fpu_class_zero:
2233
      if (d->sign)
2234
        return SIM_FPU_IS_NZERO;
2235
      else
2236
        return SIM_FPU_IS_PZERO;
2237
    default:
2238
      return -1;
2239
      abort ();
2240
    }
2241
}
2242
 
2243
INLINE_SIM_FPU (int)
2244
sim_fpu_cmp (const sim_fpu *l, const sim_fpu *r)
2245
{
2246
  sim_fpu res;
2247
  sim_fpu_sub (&res, l, r);
2248
  return sim_fpu_is (&res);
2249
}
2250
 
2251
INLINE_SIM_FPU (int)
2252
sim_fpu_is_lt (const sim_fpu *l, const sim_fpu *r)
2253
{
2254
  int status;
2255
  sim_fpu_lt (&status, l, r);
2256
  return status;
2257
}
2258
 
2259
INLINE_SIM_FPU (int)
2260
sim_fpu_is_le (const sim_fpu *l, const sim_fpu *r)
2261
{
2262
  int is;
2263
  sim_fpu_le (&is, l, r);
2264
  return is;
2265
}
2266
 
2267
INLINE_SIM_FPU (int)
2268
sim_fpu_is_eq (const sim_fpu *l, const sim_fpu *r)
2269
{
2270
  int is;
2271
  sim_fpu_eq (&is, l, r);
2272
  return is;
2273
}
2274
 
2275
INLINE_SIM_FPU (int)
2276
sim_fpu_is_ne (const sim_fpu *l, const sim_fpu *r)
2277
{
2278
  int is;
2279
  sim_fpu_ne (&is, l, r);
2280
  return is;
2281
}
2282
 
2283
INLINE_SIM_FPU (int)
2284
sim_fpu_is_ge (const sim_fpu *l, const sim_fpu *r)
2285
{
2286
  int is;
2287
  sim_fpu_ge (&is, l, r);
2288
  return is;
2289
}
2290
 
2291
INLINE_SIM_FPU (int)
2292
sim_fpu_is_gt (const sim_fpu *l, const sim_fpu *r)
2293
{
2294
  int is;
2295
  sim_fpu_gt (&is, l, r);
2296
  return is;
2297
}
2298
 
2299
 
2300
/* Compare operators */
2301
 
2302
INLINE_SIM_FPU (int)
2303
sim_fpu_lt (int *is,
2304
            const sim_fpu *l,
2305
            const sim_fpu *r)
2306
{
2307
  if (!sim_fpu_is_nan (l) && !sim_fpu_is_nan (r))
2308
    {
2309
      sim_fpu_map lval;
2310
      sim_fpu_map rval;
2311
      lval.i = pack_fpu (l, 1);
2312
      rval.i = pack_fpu (r, 1);
2313
      (*is) = (lval.d < rval.d);
2314
      return 0;
2315
    }
2316
  else if (sim_fpu_is_snan (l) || sim_fpu_is_snan (r))
2317
    {
2318
      *is = 0;
2319
      return sim_fpu_status_invalid_snan;
2320
    }
2321
  else
2322
    {
2323
      *is = 0;
2324
      return sim_fpu_status_invalid_qnan;
2325
    }
2326
}
2327
 
2328
INLINE_SIM_FPU (int)
2329
sim_fpu_le (int *is,
2330
            const sim_fpu *l,
2331
            const sim_fpu *r)
2332
{
2333
  if (!sim_fpu_is_nan (l) && !sim_fpu_is_nan (r))
2334
    {
2335
      sim_fpu_map lval;
2336
      sim_fpu_map rval;
2337
      lval.i = pack_fpu (l, 1);
2338
      rval.i = pack_fpu (r, 1);
2339
      *is = (lval.d <= rval.d);
2340
      return 0;
2341
    }
2342
  else if (sim_fpu_is_snan (l) || sim_fpu_is_snan (r))
2343
    {
2344
      *is = 0;
2345
      return sim_fpu_status_invalid_snan;
2346
    }
2347
  else
2348
    {
2349
      *is = 0;
2350
      return sim_fpu_status_invalid_qnan;
2351
    }
2352
}
2353
 
2354
INLINE_SIM_FPU (int)
2355
sim_fpu_eq (int *is,
2356
            const sim_fpu *l,
2357
            const sim_fpu *r)
2358
{
2359
  if (!sim_fpu_is_nan (l) && !sim_fpu_is_nan (r))
2360
    {
2361
      sim_fpu_map lval;
2362
      sim_fpu_map rval;
2363
      lval.i = pack_fpu (l, 1);
2364
      rval.i = pack_fpu (r, 1);
2365
      (*is) = (lval.d == rval.d);
2366
      return 0;
2367
    }
2368
  else if (sim_fpu_is_snan (l) || sim_fpu_is_snan (r))
2369
    {
2370
      *is = 0;
2371
      return sim_fpu_status_invalid_snan;
2372
    }
2373
  else
2374
    {
2375
      *is = 0;
2376
      return sim_fpu_status_invalid_qnan;
2377
    }
2378
}
2379
 
2380
INLINE_SIM_FPU (int)
2381
sim_fpu_ne (int *is,
2382
            const sim_fpu *l,
2383
            const sim_fpu *r)
2384
{
2385
  if (!sim_fpu_is_nan (l) && !sim_fpu_is_nan (r))
2386
    {
2387
      sim_fpu_map lval;
2388
      sim_fpu_map rval;
2389
      lval.i = pack_fpu (l, 1);
2390
      rval.i = pack_fpu (r, 1);
2391
      (*is) = (lval.d != rval.d);
2392
      return 0;
2393
    }
2394
  else if (sim_fpu_is_snan (l) || sim_fpu_is_snan (r))
2395
    {
2396
      *is = 0;
2397
      return sim_fpu_status_invalid_snan;
2398
    }
2399
  else
2400
    {
2401
      *is = 0;
2402
      return sim_fpu_status_invalid_qnan;
2403
    }
2404
}
2405
 
2406
INLINE_SIM_FPU (int)
2407
sim_fpu_ge (int *is,
2408
            const sim_fpu *l,
2409
            const sim_fpu *r)
2410
{
2411
  return sim_fpu_le (is, r, l);
2412
}
2413
 
2414
INLINE_SIM_FPU (int)
2415
sim_fpu_gt (int *is,
2416
            const sim_fpu *l,
2417
            const sim_fpu *r)
2418
{
2419
  return sim_fpu_lt (is, r, l);
2420
}
2421
 
2422
 
2423
/* A number of useful constants */
2424
 
2425
#if EXTERN_SIM_FPU_P
2426
const sim_fpu sim_fpu_zero = {
2427
  sim_fpu_class_zero,
2428
};
2429
const sim_fpu sim_fpu_qnan = {
2430
  sim_fpu_class_qnan,
2431
};
2432
const sim_fpu sim_fpu_one = {
2433
  sim_fpu_class_number, 0, IMPLICIT_1, 0
2434
};
2435
const sim_fpu sim_fpu_two = {
2436
  sim_fpu_class_number, 0, IMPLICIT_1, 1
2437
};
2438
const sim_fpu sim_fpu_max32 = {
2439
  sim_fpu_class_number, 0, LSMASK64 (NR_FRAC_GUARD, NR_GUARDS32), NORMAL_EXPMAX32
2440
};
2441
const sim_fpu sim_fpu_max64 = {
2442
  sim_fpu_class_number, 0, LSMASK64 (NR_FRAC_GUARD, NR_GUARDS64), NORMAL_EXPMAX64
2443
};
2444
#endif
2445
 
2446
 
2447
/* For debugging */
2448
 
2449
INLINE_SIM_FPU (void)
2450
sim_fpu_print_fpu (const sim_fpu *f,
2451
                   sim_fpu_print_func *print,
2452
                   void *arg)
2453
{
2454
  sim_fpu_printn_fpu (f, print, -1, arg);
2455
}
2456
 
2457
INLINE_SIM_FPU (void)
2458
sim_fpu_printn_fpu (const sim_fpu *f,
2459
                   sim_fpu_print_func *print,
2460
                   int digits,
2461
                   void *arg)
2462
{
2463
  print (arg, "%s", f->sign ? "-" : "+");
2464
  switch (f->class)
2465
    {
2466
    case sim_fpu_class_qnan:
2467
      print (arg, "0.");
2468
      print_bits (f->fraction, NR_FRAC_GUARD - 1, digits, print, arg);
2469
      print (arg, "*QuietNaN");
2470
      break;
2471
    case sim_fpu_class_snan:
2472
      print (arg, "0.");
2473
      print_bits (f->fraction, NR_FRAC_GUARD - 1, digits, print, arg);
2474
      print (arg, "*SignalNaN");
2475
      break;
2476
    case sim_fpu_class_zero:
2477
      print (arg, "0.0");
2478
      break;
2479
    case sim_fpu_class_infinity:
2480
      print (arg, "INF");
2481
      break;
2482
    case sim_fpu_class_number:
2483
    case sim_fpu_class_denorm:
2484
      print (arg, "1.");
2485
      print_bits (f->fraction, NR_FRAC_GUARD - 1, digits, print, arg);
2486
      print (arg, "*2^%+d", f->normal_exp);
2487
      ASSERT (f->fraction >= IMPLICIT_1);
2488
      ASSERT (f->fraction < IMPLICIT_2);
2489
    }
2490
}
2491
 
2492
 
2493
INLINE_SIM_FPU (void)
2494
sim_fpu_print_status (int status,
2495
                      sim_fpu_print_func *print,
2496
                      void *arg)
2497
{
2498
  int i = 1;
2499
  char *prefix = "";
2500
  while (status >= i)
2501
    {
2502
      switch ((sim_fpu_status) (status & i))
2503
        {
2504
        case sim_fpu_status_denorm:
2505
          print (arg, "%sD", prefix);
2506
          break;
2507
        case sim_fpu_status_invalid_snan:
2508
          print (arg, "%sSNaN", prefix);
2509
          break;
2510
        case sim_fpu_status_invalid_qnan:
2511
          print (arg, "%sQNaN", prefix);
2512
          break;
2513
        case sim_fpu_status_invalid_isi:
2514
          print (arg, "%sISI", prefix);
2515
          break;
2516
        case sim_fpu_status_invalid_idi:
2517
          print (arg, "%sIDI", prefix);
2518
          break;
2519
        case sim_fpu_status_invalid_zdz:
2520
          print (arg, "%sZDZ", prefix);
2521
          break;
2522
        case sim_fpu_status_invalid_imz:
2523
          print (arg, "%sIMZ", prefix);
2524
          break;
2525
        case sim_fpu_status_invalid_cvi:
2526
          print (arg, "%sCVI", prefix);
2527
          break;
2528
        case sim_fpu_status_invalid_cmp:
2529
          print (arg, "%sCMP", prefix);
2530
          break;
2531
        case sim_fpu_status_invalid_sqrt:
2532
          print (arg, "%sSQRT", prefix);
2533
          break;
2534
          break;
2535
        case sim_fpu_status_inexact:
2536
          print (arg, "%sX", prefix);
2537
          break;
2538
          break;
2539
        case sim_fpu_status_overflow:
2540
          print (arg, "%sO", prefix);
2541
          break;
2542
          break;
2543
        case sim_fpu_status_underflow:
2544
          print (arg, "%sU", prefix);
2545
          break;
2546
          break;
2547
        case sim_fpu_status_invalid_div0:
2548
          print (arg, "%s/", prefix);
2549
          break;
2550
          break;
2551
        case sim_fpu_status_rounded:
2552
          print (arg, "%sR", prefix);
2553
          break;
2554
          break;
2555
        }
2556
      i <<= 1;
2557
      prefix = ",";
2558
    }
2559
}
2560
 
2561
#endif

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