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1 734 jeremybenn
/* This is a software floating point library which can be used
2
   for targets without hardware floating point.
3
   Copyright (C) 1994, 1995, 1996, 1997, 1998, 2000, 2001, 2002, 2003,
4
   2004, 2005, 2008, 2009, 2010, 2011 Free Software Foundation, Inc.
5
 
6
This file is part of GCC.
7
 
8
GCC is free software; you can redistribute it and/or modify it under
9
the terms of the GNU General Public License as published by the Free
10
Software Foundation; either version 3, or (at your option) any later
11
version.
12
 
13
GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14
WARRANTY; without even the implied warranty of MERCHANTABILITY or
15
FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
16
for more details.
17
 
18
Under Section 7 of GPL version 3, you are granted additional
19
permissions described in the GCC Runtime Library Exception, version
20
3.1, as published by the Free Software Foundation.
21
 
22
You should have received a copy of the GNU General Public License and
23
a copy of the GCC Runtime Library Exception along with this program;
24
see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
25
<http://www.gnu.org/licenses/>.  */
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
/* The intended way to use this file is to make two copies, add `#define FLOAT'
35
   to one copy, then compile both copies and add them to libgcc.a.  */
36
 
37
#include "tconfig.h"
38
#include "coretypes.h"
39
#include "tm.h"
40
#include "libgcc_tm.h"
41
#include "fp-bit.h"
42
 
43
/* The following macros can be defined to change the behavior of this file:
44
   FLOAT: Implement a `float', aka SFmode, fp library.  If this is not
45
     defined, then this file implements a `double', aka DFmode, fp library.
46
   FLOAT_ONLY: Used with FLOAT, to implement a `float' only library, i.e.
47
     don't include float->double conversion which requires the double library.
48
     This is useful only for machines which can't support doubles, e.g. some
49
     8-bit processors.
50
   CMPtype: Specify the type that floating point compares should return.
51
     This defaults to SItype, aka int.
52
   _DEBUG_BITFLOAT: This makes debugging the code a little easier, by adding
53
     two integers to the FLO_union_type.
54
   NO_DENORMALS: Disable handling of denormals.
55
   NO_NANS: Disable nan and infinity handling
56
   SMALL_MACHINE: Useful when operations on QIs and HIs are faster
57
     than on an SI */
58
 
59
/* We don't currently support extended floats (long doubles) on machines
60
   without hardware to deal with them.
61
 
62
   These stubs are just to keep the linker from complaining about unresolved
63
   references which can be pulled in from libio & libstdc++, even if the
64
   user isn't using long doubles.  However, they may generate an unresolved
65
   external to abort if abort is not used by the function, and the stubs
66
   are referenced from within libc, since libgcc goes before and after the
67
   system library.  */
68
 
69
#ifdef DECLARE_LIBRARY_RENAMES
70
  DECLARE_LIBRARY_RENAMES
71
#endif
72
 
73
#ifdef EXTENDED_FLOAT_STUBS
74
extern void abort (void);
75
void __extendsfxf2 (void) { abort(); }
76
void __extenddfxf2 (void) { abort(); }
77
void __truncxfdf2 (void) { abort(); }
78
void __truncxfsf2 (void) { abort(); }
79
void __fixxfsi (void) { abort(); }
80
void __floatsixf (void) { abort(); }
81
void __addxf3 (void) { abort(); }
82
void __subxf3 (void) { abort(); }
83
void __mulxf3 (void) { abort(); }
84
void __divxf3 (void) { abort(); }
85
void __negxf2 (void) { abort(); }
86
void __eqxf2 (void) { abort(); }
87
void __nexf2 (void) { abort(); }
88
void __gtxf2 (void) { abort(); }
89
void __gexf2 (void) { abort(); }
90
void __lexf2 (void) { abort(); }
91
void __ltxf2 (void) { abort(); }
92
 
93
void __extendsftf2 (void) { abort(); }
94
void __extenddftf2 (void) { abort(); }
95
void __trunctfdf2 (void) { abort(); }
96
void __trunctfsf2 (void) { abort(); }
97
void __fixtfsi (void) { abort(); }
98
void __floatsitf (void) { abort(); }
99
void __addtf3 (void) { abort(); }
100
void __subtf3 (void) { abort(); }
101
void __multf3 (void) { abort(); }
102
void __divtf3 (void) { abort(); }
103
void __negtf2 (void) { abort(); }
104
void __eqtf2 (void) { abort(); }
105
void __netf2 (void) { abort(); }
106
void __gttf2 (void) { abort(); }
107
void __getf2 (void) { abort(); }
108
void __letf2 (void) { abort(); }
109
void __lttf2 (void) { abort(); }
110
#else   /* !EXTENDED_FLOAT_STUBS, rest of file */
111
 
112
/* IEEE "special" number predicates */
113
 
114
#ifdef NO_NANS
115
 
116
#define nan() 0
117
#define isnan(x) 0
118
#define isinf(x) 0
119
#else
120
 
121
#if   defined L_thenan_sf
122
const fp_number_type __thenan_sf = { CLASS_SNAN, 0, 0, {(fractype) 0} };
123
#elif defined L_thenan_df
124
const fp_number_type __thenan_df = { CLASS_SNAN, 0, 0, {(fractype) 0} };
125
#elif defined L_thenan_tf
126
const fp_number_type __thenan_tf = { CLASS_SNAN, 0, 0, {(fractype) 0} };
127
#elif defined TFLOAT
128
extern const fp_number_type __thenan_tf;
129
#elif defined FLOAT
130
extern const fp_number_type __thenan_sf;
131
#else
132
extern const fp_number_type __thenan_df;
133
#endif
134
 
135
INLINE
136
static const fp_number_type *
137
makenan (void)
138
{
139
#ifdef TFLOAT
140
  return & __thenan_tf;
141
#elif defined FLOAT  
142
  return & __thenan_sf;
143
#else
144
  return & __thenan_df;
145
#endif
146
}
147
 
148
INLINE
149
static int
150
isnan (const fp_number_type *x)
151
{
152
  return __builtin_expect (x->class == CLASS_SNAN || x->class == CLASS_QNAN,
153
                           0);
154
}
155
 
156
INLINE
157
static int
158
isinf (const fp_number_type *  x)
159
{
160
  return __builtin_expect (x->class == CLASS_INFINITY, 0);
161
}
162
 
163
#endif /* NO_NANS */
164
 
165
INLINE
166
static int
167
iszero (const fp_number_type *  x)
168
{
169
  return x->class == CLASS_ZERO;
170
}
171
 
172
INLINE
173
static void
174
flip_sign ( fp_number_type *  x)
175
{
176
  x->sign = !x->sign;
177
}
178
 
179
/* Count leading zeroes in N.  */
180
INLINE
181
static int
182
clzusi (USItype n)
183
{
184
  extern int __clzsi2 (USItype);
185
  if (sizeof (USItype) == sizeof (unsigned int))
186
    return __builtin_clz (n);
187
  else if (sizeof (USItype) == sizeof (unsigned long))
188
    return __builtin_clzl (n);
189
  else if (sizeof (USItype) == sizeof (unsigned long long))
190
    return __builtin_clzll (n);
191
  else
192
    return __clzsi2 (n);
193
}
194
 
195
extern FLO_type pack_d (const fp_number_type * );
196
 
197
#if defined(L_pack_df) || defined(L_pack_sf) || defined(L_pack_tf)
198
FLO_type
199
pack_d (const fp_number_type *src)
200
{
201
  FLO_union_type dst;
202
  fractype fraction = src->fraction.ll; /* wasn't unsigned before? */
203
  int sign = src->sign;
204
  int exp = 0;
205
 
206
  if (LARGEST_EXPONENT_IS_NORMAL (FRAC_NBITS) && (isnan (src) || isinf (src)))
207
    {
208
      /* We can't represent these values accurately.  By using the
209
         largest possible magnitude, we guarantee that the conversion
210
         of infinity is at least as big as any finite number.  */
211
      exp = EXPMAX;
212
      fraction = ((fractype) 1 << FRACBITS) - 1;
213
    }
214
  else if (isnan (src))
215
    {
216
      exp = EXPMAX;
217
      if (src->class == CLASS_QNAN || 1)
218
        {
219
#ifdef QUIET_NAN_NEGATED
220
          fraction |= QUIET_NAN - 1;
221
#else
222
          fraction |= QUIET_NAN;
223
#endif
224
        }
225
    }
226
  else if (isinf (src))
227
    {
228
      exp = EXPMAX;
229
      fraction = 0;
230
    }
231
  else if (iszero (src))
232
    {
233
      exp = 0;
234
      fraction = 0;
235
    }
236
  else if (fraction == 0)
237
    {
238
      exp = 0;
239
    }
240
  else
241
    {
242
      if (__builtin_expect (src->normal_exp < NORMAL_EXPMIN, 0))
243
        {
244
#ifdef NO_DENORMALS
245
          /* Go straight to a zero representation if denormals are not
246
             supported.  The denormal handling would be harmless but
247
             isn't unnecessary.  */
248
          exp = 0;
249
          fraction = 0;
250
#else /* NO_DENORMALS */
251
          /* This number's exponent is too low to fit into the bits
252
             available in the number, so we'll store 0 in the exponent and
253
             shift the fraction to the right to make up for it.  */
254
 
255
          int shift = NORMAL_EXPMIN - src->normal_exp;
256
 
257
          exp = 0;
258
 
259
          if (shift > FRAC_NBITS - NGARDS)
260
            {
261
              /* No point shifting, since it's more that 64 out.  */
262
              fraction = 0;
263
            }
264
          else
265
            {
266
              int lowbit = (fraction & (((fractype)1 << shift) - 1)) ? 1 : 0;
267
              fraction = (fraction >> shift) | lowbit;
268
            }
269
          if ((fraction & GARDMASK) == GARDMSB)
270
            {
271
              if ((fraction & (1 << NGARDS)))
272
                fraction += GARDROUND + 1;
273
            }
274
          else
275
            {
276
              /* Add to the guards to round up.  */
277
              fraction += GARDROUND;
278
            }
279
          /* Perhaps the rounding means we now need to change the
280
             exponent, because the fraction is no longer denormal.  */
281
          if (fraction >= IMPLICIT_1)
282
            {
283
              exp += 1;
284
            }
285
          fraction >>= NGARDS;
286
#endif /* NO_DENORMALS */
287
        }
288
      else if (!LARGEST_EXPONENT_IS_NORMAL (FRAC_NBITS)
289
               && __builtin_expect (src->normal_exp > EXPBIAS, 0))
290
        {
291
          exp = EXPMAX;
292
          fraction = 0;
293
        }
294
      else
295
        {
296
          exp = src->normal_exp + EXPBIAS;
297
          if (!ROUND_TOWARDS_ZERO)
298
            {
299
              /* IF the gard bits are the all zero, but the first, then we're
300
                 half way between two numbers, choose the one which makes the
301
                 lsb of the answer 0.  */
302
              if ((fraction & GARDMASK) == GARDMSB)
303
                {
304
                  if (fraction & (1 << NGARDS))
305
                    fraction += GARDROUND + 1;
306
                }
307
              else
308
                {
309
                  /* Add a one to the guards to round up */
310
                  fraction += GARDROUND;
311
                }
312
              if (fraction >= IMPLICIT_2)
313
                {
314
                  fraction >>= 1;
315
                  exp += 1;
316
                }
317
            }
318
          fraction >>= NGARDS;
319
 
320
          if (LARGEST_EXPONENT_IS_NORMAL (FRAC_NBITS) && exp > EXPMAX)
321
            {
322
              /* Saturate on overflow.  */
323
              exp = EXPMAX;
324
              fraction = ((fractype) 1 << FRACBITS) - 1;
325
            }
326
        }
327
    }
328
 
329
  /* We previously used bitfields to store the number, but this doesn't
330
     handle little/big endian systems conveniently, so use shifts and
331
     masks */
332
#ifdef FLOAT_BIT_ORDER_MISMATCH
333
  dst.bits.fraction = fraction;
334
  dst.bits.exp = exp;
335
  dst.bits.sign = sign;
336
#else
337
# if defined TFLOAT && defined HALFFRACBITS
338
 {
339
   halffractype high, low, unity;
340
   int lowsign, lowexp;
341
 
342
   unity = (halffractype) 1 << HALFFRACBITS;
343
 
344
   /* Set HIGH to the high double's significand, masking out the implicit 1.
345
      Set LOW to the low double's full significand.  */
346
   high = (fraction >> (FRACBITS - HALFFRACBITS)) & (unity - 1);
347
   low = fraction & (unity * 2 - 1);
348
 
349
   /* Get the initial sign and exponent of the low double.  */
350
   lowexp = exp - HALFFRACBITS - 1;
351
   lowsign = sign;
352
 
353
   /* HIGH should be rounded like a normal double, making |LOW| <=
354
      0.5 ULP of HIGH.  Assume round-to-nearest.  */
355
   if (exp < EXPMAX)
356
     if (low > unity || (low == unity && (high & 1) == 1))
357
       {
358
         /* Round HIGH up and adjust LOW to match.  */
359
         high++;
360
         if (high == unity)
361
           {
362
             /* May make it infinite, but that's OK.  */
363
             high = 0;
364
             exp++;
365
           }
366
         low = unity * 2 - low;
367
         lowsign ^= 1;
368
       }
369
 
370
   high |= (halffractype) exp << HALFFRACBITS;
371
   high |= (halffractype) sign << (HALFFRACBITS + EXPBITS);
372
 
373
   if (exp == EXPMAX || exp == 0 || low == 0)
374
     low = 0;
375
   else
376
     {
377
       while (lowexp > 0 && low < unity)
378
         {
379
           low <<= 1;
380
           lowexp--;
381
         }
382
 
383
       if (lowexp <= 0)
384
         {
385
           halffractype roundmsb, round;
386
           int shift;
387
 
388
           shift = 1 - lowexp;
389
           roundmsb = (1 << (shift - 1));
390
           round = low & ((roundmsb << 1) - 1);
391
 
392
           low >>= shift;
393
           lowexp = 0;
394
 
395
           if (round > roundmsb || (round == roundmsb && (low & 1) == 1))
396
             {
397
               low++;
398
               if (low == unity)
399
                 /* LOW rounds up to the smallest normal number.  */
400
                 lowexp++;
401
             }
402
         }
403
 
404
       low &= unity - 1;
405
       low |= (halffractype) lowexp << HALFFRACBITS;
406
       low |= (halffractype) lowsign << (HALFFRACBITS + EXPBITS);
407
     }
408
   dst.value_raw = ((fractype) high << HALFSHIFT) | low;
409
 }
410
# else
411
  dst.value_raw = fraction & ((((fractype)1) << FRACBITS) - (fractype)1);
412
  dst.value_raw |= ((fractype) (exp & ((1 << EXPBITS) - 1))) << FRACBITS;
413
  dst.value_raw |= ((fractype) (sign & 1)) << (FRACBITS | EXPBITS);
414
# endif
415
#endif
416
 
417
#if defined(FLOAT_WORD_ORDER_MISMATCH) && !defined(FLOAT)
418
#ifdef TFLOAT
419
  {
420
    qrtrfractype tmp1 = dst.words[0];
421
    qrtrfractype tmp2 = dst.words[1];
422
    dst.words[0] = dst.words[3];
423
    dst.words[1] = dst.words[2];
424
    dst.words[2] = tmp2;
425
    dst.words[3] = tmp1;
426
  }
427
#else
428
  {
429
    halffractype tmp = dst.words[0];
430
    dst.words[0] = dst.words[1];
431
    dst.words[1] = tmp;
432
  }
433
#endif
434
#endif
435
 
436
  return dst.value;
437
}
438
#endif
439
 
440
#if defined(L_unpack_df) || defined(L_unpack_sf) || defined(L_unpack_tf)
441
void
442
unpack_d (FLO_union_type * src, fp_number_type * dst)
443
{
444
  /* We previously used bitfields to store the number, but this doesn't
445
     handle little/big endian systems conveniently, so use shifts and
446
     masks */
447
  fractype fraction;
448
  int exp;
449
  int sign;
450
 
451
#if defined(FLOAT_WORD_ORDER_MISMATCH) && !defined(FLOAT)
452
  FLO_union_type swapped;
453
 
454
#ifdef TFLOAT
455
  swapped.words[0] = src->words[3];
456
  swapped.words[1] = src->words[2];
457
  swapped.words[2] = src->words[1];
458
  swapped.words[3] = src->words[0];
459
#else
460
  swapped.words[0] = src->words[1];
461
  swapped.words[1] = src->words[0];
462
#endif
463
  src = &swapped;
464
#endif
465
 
466
#ifdef FLOAT_BIT_ORDER_MISMATCH
467
  fraction = src->bits.fraction;
468
  exp = src->bits.exp;
469
  sign = src->bits.sign;
470
#else
471
# if defined TFLOAT && defined HALFFRACBITS
472
 {
473
   halffractype high, low;
474
 
475
   high = src->value_raw >> HALFSHIFT;
476
   low = src->value_raw & (((fractype)1 << HALFSHIFT) - 1);
477
 
478
   fraction = high & ((((fractype)1) << HALFFRACBITS) - 1);
479
   fraction <<= FRACBITS - HALFFRACBITS;
480
   exp = ((int)(high >> HALFFRACBITS)) & ((1 << EXPBITS) - 1);
481
   sign = ((int)(high >> (((HALFFRACBITS + EXPBITS))))) & 1;
482
 
483
   if (exp != EXPMAX && exp != 0 && low != 0)
484
     {
485
       int lowexp = ((int)(low >> HALFFRACBITS)) & ((1 << EXPBITS) - 1);
486
       int lowsign = ((int)(low >> (((HALFFRACBITS + EXPBITS))))) & 1;
487
       int shift;
488
       fractype xlow;
489
 
490
       xlow = low & ((((fractype)1) << HALFFRACBITS) - 1);
491
       if (lowexp)
492
         xlow |= (((halffractype)1) << HALFFRACBITS);
493
       else
494
         lowexp = 1;
495
       shift = (FRACBITS - HALFFRACBITS) - (exp - lowexp);
496
       if (shift > 0)
497
         xlow <<= shift;
498
       else if (shift < 0)
499
         xlow >>= -shift;
500
       if (sign == lowsign)
501
         fraction += xlow;
502
       else if (fraction >= xlow)
503
         fraction -= xlow;
504
       else
505
         {
506
           /* The high part is a power of two but the full number is lower.
507
              This code will leave the implicit 1 in FRACTION, but we'd
508
              have added that below anyway.  */
509
           fraction = (((fractype) 1 << FRACBITS) - xlow) << 1;
510
           exp--;
511
         }
512
     }
513
 }
514
# else
515
  fraction = src->value_raw & ((((fractype)1) << FRACBITS) - 1);
516
  exp = ((int)(src->value_raw >> FRACBITS)) & ((1 << EXPBITS) - 1);
517
  sign = ((int)(src->value_raw >> (FRACBITS + EXPBITS))) & 1;
518
# endif
519
#endif
520
 
521
  dst->sign = sign;
522
  if (exp == 0)
523
    {
524
      /* Hmm.  Looks like 0 */
525
      if (fraction == 0
526
#ifdef NO_DENORMALS
527
          || 1
528
#endif
529
          )
530
        {
531
          /* tastes like zero */
532
          dst->class = CLASS_ZERO;
533
        }
534
      else
535
        {
536
          /* Zero exponent with nonzero fraction - it's denormalized,
537
             so there isn't a leading implicit one - we'll shift it so
538
             it gets one.  */
539
          dst->normal_exp = exp - EXPBIAS + 1;
540
          fraction <<= NGARDS;
541
 
542
          dst->class = CLASS_NUMBER;
543
#if 1
544
          while (fraction < IMPLICIT_1)
545
            {
546
              fraction <<= 1;
547
              dst->normal_exp--;
548
            }
549
#endif
550
          dst->fraction.ll = fraction;
551
        }
552
    }
553
  else if (!LARGEST_EXPONENT_IS_NORMAL (FRAC_NBITS)
554
           && __builtin_expect (exp == EXPMAX, 0))
555
    {
556
      /* Huge exponent*/
557
      if (fraction == 0)
558
        {
559
          /* Attached to a zero fraction - means infinity */
560
          dst->class = CLASS_INFINITY;
561
        }
562
      else
563
        {
564
          /* Nonzero fraction, means nan */
565
#ifdef QUIET_NAN_NEGATED
566
          if ((fraction & QUIET_NAN) == 0)
567
#else
568
          if (fraction & QUIET_NAN)
569
#endif
570
            {
571
              dst->class = CLASS_QNAN;
572
            }
573
          else
574
            {
575
              dst->class = CLASS_SNAN;
576
            }
577
          /* Keep the fraction part as the nan number */
578
          dst->fraction.ll = fraction;
579
        }
580
    }
581
  else
582
    {
583
      /* Nothing strange about this number */
584
      dst->normal_exp = exp - EXPBIAS;
585
      dst->class = CLASS_NUMBER;
586
      dst->fraction.ll = (fraction << NGARDS) | IMPLICIT_1;
587
    }
588
}
589
#endif /* L_unpack_df || L_unpack_sf */
590
 
591
#if defined(L_addsub_sf) || defined(L_addsub_df) || defined(L_addsub_tf)
592
static const fp_number_type *
593
_fpadd_parts (fp_number_type * a,
594
              fp_number_type * b,
595
              fp_number_type * tmp)
596
{
597
  intfrac tfraction;
598
 
599
  /* Put commonly used fields in local variables.  */
600
  int a_normal_exp;
601
  int b_normal_exp;
602
  fractype a_fraction;
603
  fractype b_fraction;
604
 
605
  if (isnan (a))
606
    {
607
      return a;
608
    }
609
  if (isnan (b))
610
    {
611
      return b;
612
    }
613
  if (isinf (a))
614
    {
615
      /* Adding infinities with opposite signs yields a NaN.  */
616
      if (isinf (b) && a->sign != b->sign)
617
        return makenan ();
618
      return a;
619
    }
620
  if (isinf (b))
621
    {
622
      return b;
623
    }
624
  if (iszero (b))
625
    {
626
      if (iszero (a))
627
        {
628
          *tmp = *a;
629
          tmp->sign = a->sign & b->sign;
630
          return tmp;
631
        }
632
      return a;
633
    }
634
  if (iszero (a))
635
    {
636
      return b;
637
    }
638
 
639
  /* Got two numbers. shift the smaller and increment the exponent till
640
     they're the same */
641
  {
642
    int diff;
643
    int sdiff;
644
 
645
    a_normal_exp = a->normal_exp;
646
    b_normal_exp = b->normal_exp;
647
    a_fraction = a->fraction.ll;
648
    b_fraction = b->fraction.ll;
649
 
650
    diff = a_normal_exp - b_normal_exp;
651
    sdiff = diff;
652
 
653
    if (diff < 0)
654
      diff = -diff;
655
    if (diff < FRAC_NBITS)
656
      {
657
        if (sdiff > 0)
658
          {
659
            b_normal_exp += diff;
660
            LSHIFT (b_fraction, diff);
661
          }
662
        else if (sdiff < 0)
663
          {
664
            a_normal_exp += diff;
665
            LSHIFT (a_fraction, diff);
666
          }
667
      }
668
    else
669
      {
670
        /* Somethings's up.. choose the biggest */
671
        if (a_normal_exp > b_normal_exp)
672
          {
673
            b_normal_exp = a_normal_exp;
674
            b_fraction = 0;
675
          }
676
        else
677
          {
678
            a_normal_exp = b_normal_exp;
679
            a_fraction = 0;
680
          }
681
      }
682
  }
683
 
684
  if (a->sign != b->sign)
685
    {
686
      if (a->sign)
687
        {
688
          tfraction = -a_fraction + b_fraction;
689
        }
690
      else
691
        {
692
          tfraction = a_fraction - b_fraction;
693
        }
694
      if (tfraction >= 0)
695
        {
696
          tmp->sign = 0;
697
          tmp->normal_exp = a_normal_exp;
698
          tmp->fraction.ll = tfraction;
699
        }
700
      else
701
        {
702
          tmp->sign = 1;
703
          tmp->normal_exp = a_normal_exp;
704
          tmp->fraction.ll = -tfraction;
705
        }
706
      /* and renormalize it */
707
 
708
      while (tmp->fraction.ll < IMPLICIT_1 && tmp->fraction.ll)
709
        {
710
          tmp->fraction.ll <<= 1;
711
          tmp->normal_exp--;
712
        }
713
    }
714
  else
715
    {
716
      tmp->sign = a->sign;
717
      tmp->normal_exp = a_normal_exp;
718
      tmp->fraction.ll = a_fraction + b_fraction;
719
    }
720
  tmp->class = CLASS_NUMBER;
721
  /* Now the fraction is added, we have to shift down to renormalize the
722
     number */
723
 
724
  if (tmp->fraction.ll >= IMPLICIT_2)
725
    {
726
      LSHIFT (tmp->fraction.ll, 1);
727
      tmp->normal_exp++;
728
    }
729
  return tmp;
730
}
731
 
732
FLO_type
733
add (FLO_type arg_a, FLO_type arg_b)
734
{
735
  fp_number_type a;
736
  fp_number_type b;
737
  fp_number_type tmp;
738
  const fp_number_type *res;
739
  FLO_union_type au, bu;
740
 
741
  au.value = arg_a;
742
  bu.value = arg_b;
743
 
744
  unpack_d (&au, &a);
745
  unpack_d (&bu, &b);
746
 
747
  res = _fpadd_parts (&a, &b, &tmp);
748
 
749
  return pack_d (res);
750
}
751
 
752
FLO_type
753
sub (FLO_type arg_a, FLO_type arg_b)
754
{
755
  fp_number_type a;
756
  fp_number_type b;
757
  fp_number_type tmp;
758
  const fp_number_type *res;
759
  FLO_union_type au, bu;
760
 
761
  au.value = arg_a;
762
  bu.value = arg_b;
763
 
764
  unpack_d (&au, &a);
765
  unpack_d (&bu, &b);
766
 
767
  b.sign ^= 1;
768
 
769
  res = _fpadd_parts (&a, &b, &tmp);
770
 
771
  return pack_d (res);
772
}
773
#endif /* L_addsub_sf || L_addsub_df */
774
 
775
#if defined(L_mul_sf) || defined(L_mul_df) || defined(L_mul_tf)
776
static inline __attribute__ ((__always_inline__)) const fp_number_type *
777
_fpmul_parts ( fp_number_type *  a,
778
               fp_number_type *  b,
779
               fp_number_type * tmp)
780
{
781
  fractype low = 0;
782
  fractype high = 0;
783
 
784
  if (isnan (a))
785
    {
786
      a->sign = a->sign != b->sign;
787
      return a;
788
    }
789
  if (isnan (b))
790
    {
791
      b->sign = a->sign != b->sign;
792
      return b;
793
    }
794
  if (isinf (a))
795
    {
796
      if (iszero (b))
797
        return makenan ();
798
      a->sign = a->sign != b->sign;
799
      return a;
800
    }
801
  if (isinf (b))
802
    {
803
      if (iszero (a))
804
        {
805
          return makenan ();
806
        }
807
      b->sign = a->sign != b->sign;
808
      return b;
809
    }
810
  if (iszero (a))
811
    {
812
      a->sign = a->sign != b->sign;
813
      return a;
814
    }
815
  if (iszero (b))
816
    {
817
      b->sign = a->sign != b->sign;
818
      return b;
819
    }
820
 
821
  /* Calculate the mantissa by multiplying both numbers to get a
822
     twice-as-wide number.  */
823
  {
824
#if defined(NO_DI_MODE) || defined(TFLOAT)
825
    {
826
      fractype x = a->fraction.ll;
827
      fractype ylow = b->fraction.ll;
828
      fractype yhigh = 0;
829
      int bit;
830
 
831
      /* ??? This does multiplies one bit at a time.  Optimize.  */
832
      for (bit = 0; bit < FRAC_NBITS; bit++)
833
        {
834
          int carry;
835
 
836
          if (x & 1)
837
            {
838
              carry = (low += ylow) < ylow;
839
              high += yhigh + carry;
840
            }
841
          yhigh <<= 1;
842
          if (ylow & FRACHIGH)
843
            {
844
              yhigh |= 1;
845
            }
846
          ylow <<= 1;
847
          x >>= 1;
848
        }
849
    }
850
#elif defined(FLOAT) 
851
    /* Multiplying two USIs to get a UDI, we're safe.  */
852
    {
853
      UDItype answer = (UDItype)a->fraction.ll * (UDItype)b->fraction.ll;
854
 
855
      high = answer >> BITS_PER_SI;
856
      low = answer;
857
    }
858
#else
859
    /* fractype is DImode, but we need the result to be twice as wide.
860
       Assuming a widening multiply from DImode to TImode is not
861
       available, build one by hand.  */
862
    {
863
      USItype nl = a->fraction.ll;
864
      USItype nh = a->fraction.ll >> BITS_PER_SI;
865
      USItype ml = b->fraction.ll;
866
      USItype mh = b->fraction.ll >> BITS_PER_SI;
867
      UDItype pp_ll = (UDItype) ml * nl;
868
      UDItype pp_hl = (UDItype) mh * nl;
869
      UDItype pp_lh = (UDItype) ml * nh;
870
      UDItype pp_hh = (UDItype) mh * nh;
871
      UDItype res2 = 0;
872
      UDItype res0 = 0;
873
      UDItype ps_hh__ = pp_hl + pp_lh;
874
      if (ps_hh__ < pp_hl)
875
        res2 += (UDItype)1 << BITS_PER_SI;
876
      pp_hl = (UDItype)(USItype)ps_hh__ << BITS_PER_SI;
877
      res0 = pp_ll + pp_hl;
878
      if (res0 < pp_ll)
879
        res2++;
880
      res2 += (ps_hh__ >> BITS_PER_SI) + pp_hh;
881
      high = res2;
882
      low = res0;
883
    }
884
#endif
885
  }
886
 
887
  tmp->normal_exp = a->normal_exp + b->normal_exp
888
    + FRAC_NBITS - (FRACBITS + NGARDS);
889
  tmp->sign = a->sign != b->sign;
890
  while (high >= IMPLICIT_2)
891
    {
892
      tmp->normal_exp++;
893
      if (high & 1)
894
        {
895
          low >>= 1;
896
          low |= FRACHIGH;
897
        }
898
      high >>= 1;
899
    }
900
  while (high < IMPLICIT_1)
901
    {
902
      tmp->normal_exp--;
903
 
904
      high <<= 1;
905
      if (low & FRACHIGH)
906
        high |= 1;
907
      low <<= 1;
908
    }
909
 
910
  if (!ROUND_TOWARDS_ZERO && (high & GARDMASK) == GARDMSB)
911
    {
912
      if (high & (1 << NGARDS))
913
        {
914
          /* Because we're half way, we would round to even by adding
915
             GARDROUND + 1, except that's also done in the packing
916
             function, and rounding twice will lose precision and cause
917
             the result to be too far off.  Example: 32-bit floats with
918
             bit patterns 0xfff * 0x3f800400 ~= 0xfff (less than 0.5ulp
919
             off), not 0x1000 (more than 0.5ulp off).  */
920
        }
921
      else if (low)
922
        {
923
          /* We're a further than half way by a small amount corresponding
924
             to the bits set in "low".  Knowing that, we round here and
925
             not in pack_d, because there we don't have "low" available
926
             anymore.  */
927
          high += GARDROUND + 1;
928
 
929
          /* Avoid further rounding in pack_d.  */
930
          high &= ~(fractype) GARDMASK;
931
        }
932
    }
933
  tmp->fraction.ll = high;
934
  tmp->class = CLASS_NUMBER;
935
  return tmp;
936
}
937
 
938
FLO_type
939
multiply (FLO_type arg_a, FLO_type arg_b)
940
{
941
  fp_number_type a;
942
  fp_number_type b;
943
  fp_number_type tmp;
944
  const fp_number_type *res;
945
  FLO_union_type au, bu;
946
 
947
  au.value = arg_a;
948
  bu.value = arg_b;
949
 
950
  unpack_d (&au, &a);
951
  unpack_d (&bu, &b);
952
 
953
  res = _fpmul_parts (&a, &b, &tmp);
954
 
955
  return pack_d (res);
956
}
957
#endif /* L_mul_sf || L_mul_df || L_mul_tf */
958
 
959
#if defined(L_div_sf) || defined(L_div_df) || defined(L_div_tf)
960
static inline __attribute__ ((__always_inline__)) const fp_number_type *
961
_fpdiv_parts (fp_number_type * a,
962
              fp_number_type * b)
963
{
964
  fractype bit;
965
  fractype numerator;
966
  fractype denominator;
967
  fractype quotient;
968
 
969
  if (isnan (a))
970
    {
971
      return a;
972
    }
973
  if (isnan (b))
974
    {
975
      return b;
976
    }
977
 
978
  a->sign = a->sign ^ b->sign;
979
 
980
  if (isinf (a) || iszero (a))
981
    {
982
      if (a->class == b->class)
983
        return makenan ();
984
      return a;
985
    }
986
 
987
  if (isinf (b))
988
    {
989
      a->fraction.ll = 0;
990
      a->normal_exp = 0;
991
      return a;
992
    }
993
  if (iszero (b))
994
    {
995
      a->class = CLASS_INFINITY;
996
      return a;
997
    }
998
 
999
  /* Calculate the mantissa by multiplying both 64bit numbers to get a
1000
     128 bit number */
1001
  {
1002
    /* quotient =
1003
       ( numerator / denominator) * 2^(numerator exponent -  denominator exponent)
1004
     */
1005
 
1006
    a->normal_exp = a->normal_exp - b->normal_exp;
1007
    numerator = a->fraction.ll;
1008
    denominator = b->fraction.ll;
1009
 
1010
    if (numerator < denominator)
1011
      {
1012
        /* Fraction will be less than 1.0 */
1013
        numerator *= 2;
1014
        a->normal_exp--;
1015
      }
1016
    bit = IMPLICIT_1;
1017
    quotient = 0;
1018
    /* ??? Does divide one bit at a time.  Optimize.  */
1019
    while (bit)
1020
      {
1021
        if (numerator >= denominator)
1022
          {
1023
            quotient |= bit;
1024
            numerator -= denominator;
1025
          }
1026
        bit >>= 1;
1027
        numerator *= 2;
1028
      }
1029
 
1030
    if (!ROUND_TOWARDS_ZERO && (quotient & GARDMASK) == GARDMSB)
1031
      {
1032
        if (quotient & (1 << NGARDS))
1033
          {
1034
            /* Because we're half way, we would round to even by adding
1035
               GARDROUND + 1, except that's also done in the packing
1036
               function, and rounding twice will lose precision and cause
1037
               the result to be too far off.  */
1038
          }
1039
        else if (numerator)
1040
          {
1041
            /* We're a further than half way by the small amount
1042
               corresponding to the bits set in "numerator".  Knowing
1043
               that, we round here and not in pack_d, because there we
1044
               don't have "numerator" available anymore.  */
1045
            quotient += GARDROUND + 1;
1046
 
1047
            /* Avoid further rounding in pack_d.  */
1048
            quotient &= ~(fractype) GARDMASK;
1049
          }
1050
      }
1051
 
1052
    a->fraction.ll = quotient;
1053
    return (a);
1054
  }
1055
}
1056
 
1057
FLO_type
1058
divide (FLO_type arg_a, FLO_type arg_b)
1059
{
1060
  fp_number_type a;
1061
  fp_number_type b;
1062
  const fp_number_type *res;
1063
  FLO_union_type au, bu;
1064
 
1065
  au.value = arg_a;
1066
  bu.value = arg_b;
1067
 
1068
  unpack_d (&au, &a);
1069
  unpack_d (&bu, &b);
1070
 
1071
  res = _fpdiv_parts (&a, &b);
1072
 
1073
  return pack_d (res);
1074
}
1075
#endif /* L_div_sf || L_div_df */
1076
 
1077
#if defined(L_fpcmp_parts_sf) || defined(L_fpcmp_parts_df) \
1078
    || defined(L_fpcmp_parts_tf)
1079
/* according to the demo, fpcmp returns a comparison with 0... thus
1080
   a<b -> -1
1081
   a==b -> 0
1082
   a>b -> +1
1083
 */
1084
 
1085
int
1086
__fpcmp_parts (fp_number_type * a, fp_number_type * b)
1087
{
1088
#if 0
1089
  /* either nan -> unordered. Must be checked outside of this routine.  */
1090
  if (isnan (a) && isnan (b))
1091
    {
1092
      return 1;                 /* still unordered! */
1093
    }
1094
#endif
1095
 
1096
  if (isnan (a) || isnan (b))
1097
    {
1098
      return 1;                 /* how to indicate unordered compare? */
1099
    }
1100
  if (isinf (a) && isinf (b))
1101
    {
1102
      /* +inf > -inf, but +inf != +inf */
1103
      /* b    \a| +inf(0)| -inf(1)
1104
       ______\+--------+--------
1105
       +inf(0)| a==b(0)| a<b(-1)
1106
       -------+--------+--------
1107
       -inf(1)| a>b(1) | a==b(0)
1108
       -------+--------+--------
1109
       So since unordered must be nonzero, just line up the columns...
1110
       */
1111
      return b->sign - a->sign;
1112
    }
1113
  /* but not both...  */
1114
  if (isinf (a))
1115
    {
1116
      return a->sign ? -1 : 1;
1117
    }
1118
  if (isinf (b))
1119
    {
1120
      return b->sign ? 1 : -1;
1121
    }
1122
  if (iszero (a) && iszero (b))
1123
    {
1124
      return 0;
1125
    }
1126
  if (iszero (a))
1127
    {
1128
      return b->sign ? 1 : -1;
1129
    }
1130
  if (iszero (b))
1131
    {
1132
      return a->sign ? -1 : 1;
1133
    }
1134
  /* now both are "normal".  */
1135
  if (a->sign != b->sign)
1136
    {
1137
      /* opposite signs */
1138
      return a->sign ? -1 : 1;
1139
    }
1140
  /* same sign; exponents? */
1141
  if (a->normal_exp > b->normal_exp)
1142
    {
1143
      return a->sign ? -1 : 1;
1144
    }
1145
  if (a->normal_exp < b->normal_exp)
1146
    {
1147
      return a->sign ? 1 : -1;
1148
    }
1149
  /* same exponents; check size.  */
1150
  if (a->fraction.ll > b->fraction.ll)
1151
    {
1152
      return a->sign ? -1 : 1;
1153
    }
1154
  if (a->fraction.ll < b->fraction.ll)
1155
    {
1156
      return a->sign ? 1 : -1;
1157
    }
1158
  /* after all that, they're equal.  */
1159
  return 0;
1160
}
1161
#endif
1162
 
1163
#if defined(L_compare_sf) || defined(L_compare_df) || defined(L_compoare_tf)
1164
CMPtype
1165
compare (FLO_type arg_a, FLO_type arg_b)
1166
{
1167
  fp_number_type a;
1168
  fp_number_type b;
1169
  FLO_union_type au, bu;
1170
 
1171
  au.value = arg_a;
1172
  bu.value = arg_b;
1173
 
1174
  unpack_d (&au, &a);
1175
  unpack_d (&bu, &b);
1176
 
1177
  return __fpcmp_parts (&a, &b);
1178
}
1179
#endif /* L_compare_sf || L_compare_df */
1180
 
1181
/* These should be optimized for their specific tasks someday.  */
1182
 
1183
#if defined(L_eq_sf) || defined(L_eq_df) || defined(L_eq_tf)
1184
CMPtype
1185
_eq_f2 (FLO_type arg_a, FLO_type arg_b)
1186
{
1187
  fp_number_type a;
1188
  fp_number_type b;
1189
  FLO_union_type au, bu;
1190
 
1191
  au.value = arg_a;
1192
  bu.value = arg_b;
1193
 
1194
  unpack_d (&au, &a);
1195
  unpack_d (&bu, &b);
1196
 
1197
  if (isnan (&a) || isnan (&b))
1198
    return 1;                   /* false, truth == 0 */
1199
 
1200
  return __fpcmp_parts (&a, &b) ;
1201
}
1202
#endif /* L_eq_sf || L_eq_df */
1203
 
1204
#if defined(L_ne_sf) || defined(L_ne_df) || defined(L_ne_tf)
1205
CMPtype
1206
_ne_f2 (FLO_type arg_a, FLO_type arg_b)
1207
{
1208
  fp_number_type a;
1209
  fp_number_type b;
1210
  FLO_union_type au, bu;
1211
 
1212
  au.value = arg_a;
1213
  bu.value = arg_b;
1214
 
1215
  unpack_d (&au, &a);
1216
  unpack_d (&bu, &b);
1217
 
1218
  if (isnan (&a) || isnan (&b))
1219
    return 1;                   /* true, truth != 0 */
1220
 
1221
  return  __fpcmp_parts (&a, &b) ;
1222
}
1223
#endif /* L_ne_sf || L_ne_df */
1224
 
1225
#if defined(L_gt_sf) || defined(L_gt_df) || defined(L_gt_tf)
1226
CMPtype
1227
_gt_f2 (FLO_type arg_a, FLO_type arg_b)
1228
{
1229
  fp_number_type a;
1230
  fp_number_type b;
1231
  FLO_union_type au, bu;
1232
 
1233
  au.value = arg_a;
1234
  bu.value = arg_b;
1235
 
1236
  unpack_d (&au, &a);
1237
  unpack_d (&bu, &b);
1238
 
1239
  if (isnan (&a) || isnan (&b))
1240
    return -1;                  /* false, truth > 0 */
1241
 
1242
  return __fpcmp_parts (&a, &b);
1243
}
1244
#endif /* L_gt_sf || L_gt_df */
1245
 
1246
#if defined(L_ge_sf) || defined(L_ge_df) || defined(L_ge_tf)
1247
CMPtype
1248
_ge_f2 (FLO_type arg_a, FLO_type arg_b)
1249
{
1250
  fp_number_type a;
1251
  fp_number_type b;
1252
  FLO_union_type au, bu;
1253
 
1254
  au.value = arg_a;
1255
  bu.value = arg_b;
1256
 
1257
  unpack_d (&au, &a);
1258
  unpack_d (&bu, &b);
1259
 
1260
  if (isnan (&a) || isnan (&b))
1261
    return -1;                  /* false, truth >= 0 */
1262
  return __fpcmp_parts (&a, &b) ;
1263
}
1264
#endif /* L_ge_sf || L_ge_df */
1265
 
1266
#if defined(L_lt_sf) || defined(L_lt_df) || defined(L_lt_tf)
1267
CMPtype
1268
_lt_f2 (FLO_type arg_a, FLO_type arg_b)
1269
{
1270
  fp_number_type a;
1271
  fp_number_type b;
1272
  FLO_union_type au, bu;
1273
 
1274
  au.value = arg_a;
1275
  bu.value = arg_b;
1276
 
1277
  unpack_d (&au, &a);
1278
  unpack_d (&bu, &b);
1279
 
1280
  if (isnan (&a) || isnan (&b))
1281
    return 1;                   /* false, truth < 0 */
1282
 
1283
  return __fpcmp_parts (&a, &b);
1284
}
1285
#endif /* L_lt_sf || L_lt_df */
1286
 
1287
#if defined(L_le_sf) || defined(L_le_df) || defined(L_le_tf)
1288
CMPtype
1289
_le_f2 (FLO_type arg_a, FLO_type arg_b)
1290
{
1291
  fp_number_type a;
1292
  fp_number_type b;
1293
  FLO_union_type au, bu;
1294
 
1295
  au.value = arg_a;
1296
  bu.value = arg_b;
1297
 
1298
  unpack_d (&au, &a);
1299
  unpack_d (&bu, &b);
1300
 
1301
  if (isnan (&a) || isnan (&b))
1302
    return 1;                   /* false, truth <= 0 */
1303
 
1304
  return __fpcmp_parts (&a, &b) ;
1305
}
1306
#endif /* L_le_sf || L_le_df */
1307
 
1308
#if defined(L_unord_sf) || defined(L_unord_df) || defined(L_unord_tf)
1309
CMPtype
1310
_unord_f2 (FLO_type arg_a, FLO_type arg_b)
1311
{
1312
  fp_number_type a;
1313
  fp_number_type b;
1314
  FLO_union_type au, bu;
1315
 
1316
  au.value = arg_a;
1317
  bu.value = arg_b;
1318
 
1319
  unpack_d (&au, &a);
1320
  unpack_d (&bu, &b);
1321
 
1322
  return (isnan (&a) || isnan (&b));
1323
}
1324
#endif /* L_unord_sf || L_unord_df */
1325
 
1326
#if defined(L_si_to_sf) || defined(L_si_to_df) || defined(L_si_to_tf)
1327
FLO_type
1328
si_to_float (SItype arg_a)
1329
{
1330
  fp_number_type in;
1331
 
1332
  in.class = CLASS_NUMBER;
1333
  in.sign = arg_a < 0;
1334
  if (!arg_a)
1335
    {
1336
      in.class = CLASS_ZERO;
1337
    }
1338
  else
1339
    {
1340
      USItype uarg;
1341
      int shift;
1342
      in.normal_exp = FRACBITS + NGARDS;
1343
      if (in.sign)
1344
        {
1345
          /* Special case for minint, since there is no +ve integer
1346
             representation for it */
1347
          if (arg_a == (- MAX_SI_INT - 1))
1348
            {
1349
              return (FLO_type)(- MAX_SI_INT - 1);
1350
            }
1351
          uarg = (-arg_a);
1352
        }
1353
      else
1354
        uarg = arg_a;
1355
 
1356
      in.fraction.ll = uarg;
1357
      shift = clzusi (uarg) - (BITS_PER_SI - 1 - FRACBITS - NGARDS);
1358
      if (shift > 0)
1359
        {
1360
          in.fraction.ll <<= shift;
1361
          in.normal_exp -= shift;
1362
        }
1363
    }
1364
  return pack_d (&in);
1365
}
1366
#endif /* L_si_to_sf || L_si_to_df */
1367
 
1368
#if defined(L_usi_to_sf) || defined(L_usi_to_df) || defined(L_usi_to_tf)
1369
FLO_type
1370
usi_to_float (USItype arg_a)
1371
{
1372
  fp_number_type in;
1373
 
1374
  in.sign = 0;
1375
  if (!arg_a)
1376
    {
1377
      in.class = CLASS_ZERO;
1378
    }
1379
  else
1380
    {
1381
      int shift;
1382
      in.class = CLASS_NUMBER;
1383
      in.normal_exp = FRACBITS + NGARDS;
1384
      in.fraction.ll = arg_a;
1385
 
1386
      shift = clzusi (arg_a) - (BITS_PER_SI - 1 - FRACBITS - NGARDS);
1387
      if (shift < 0)
1388
        {
1389
          fractype guard = in.fraction.ll & (((fractype)1 << -shift) - 1);
1390
          in.fraction.ll >>= -shift;
1391
          in.fraction.ll |= (guard != 0);
1392
          in.normal_exp -= shift;
1393
        }
1394
      else if (shift > 0)
1395
        {
1396
          in.fraction.ll <<= shift;
1397
          in.normal_exp -= shift;
1398
        }
1399
    }
1400
  return pack_d (&in);
1401
}
1402
#endif
1403
 
1404
#if defined(L_sf_to_si) || defined(L_df_to_si) || defined(L_tf_to_si)
1405
SItype
1406
float_to_si (FLO_type arg_a)
1407
{
1408
  fp_number_type a;
1409
  SItype tmp;
1410
  FLO_union_type au;
1411
 
1412
  au.value = arg_a;
1413
  unpack_d (&au, &a);
1414
 
1415
  if (iszero (&a))
1416
    return 0;
1417
  if (isnan (&a))
1418
    return 0;
1419
  /* get reasonable MAX_SI_INT...  */
1420
  if (isinf (&a))
1421
    return a.sign ? (-MAX_SI_INT)-1 : MAX_SI_INT;
1422
  /* it is a number, but a small one */
1423
  if (a.normal_exp < 0)
1424
    return 0;
1425
  if (a.normal_exp > BITS_PER_SI - 2)
1426
    return a.sign ? (-MAX_SI_INT)-1 : MAX_SI_INT;
1427
  tmp = a.fraction.ll >> ((FRACBITS + NGARDS) - a.normal_exp);
1428
  return a.sign ? (-tmp) : (tmp);
1429
}
1430
#endif /* L_sf_to_si || L_df_to_si */
1431
 
1432
#if defined(L_tf_to_usi)
1433
USItype
1434
float_to_usi (FLO_type arg_a)
1435
{
1436
  fp_number_type a;
1437
  FLO_union_type au;
1438
 
1439
  au.value = arg_a;
1440
  unpack_d (&au, &a);
1441
 
1442
  if (iszero (&a))
1443
    return 0;
1444
  if (isnan (&a))
1445
    return 0;
1446
  /* it is a negative number */
1447
  if (a.sign)
1448
    return 0;
1449
  /* get reasonable MAX_USI_INT...  */
1450
  if (isinf (&a))
1451
    return MAX_USI_INT;
1452
  /* it is a number, but a small one */
1453
  if (a.normal_exp < 0)
1454
    return 0;
1455
  if (a.normal_exp > BITS_PER_SI - 1)
1456
    return MAX_USI_INT;
1457
  else if (a.normal_exp > (FRACBITS + NGARDS))
1458
    return a.fraction.ll << (a.normal_exp - (FRACBITS + NGARDS));
1459
  else
1460
    return a.fraction.ll >> ((FRACBITS + NGARDS) - a.normal_exp);
1461
}
1462
#endif /* L_tf_to_usi */
1463
 
1464
#if defined(L_negate_sf) || defined(L_negate_df) || defined(L_negate_tf)
1465
FLO_type
1466
negate (FLO_type arg_a)
1467
{
1468
  fp_number_type a;
1469
  FLO_union_type au;
1470
 
1471
  au.value = arg_a;
1472
  unpack_d (&au, &a);
1473
 
1474
  flip_sign (&a);
1475
  return pack_d (&a);
1476
}
1477
#endif /* L_negate_sf || L_negate_df */
1478
 
1479
#ifdef FLOAT
1480
 
1481
#if defined(L_make_sf)
1482
SFtype
1483
__make_fp(fp_class_type class,
1484
             unsigned int sign,
1485
             int exp,
1486
             USItype frac)
1487
{
1488
  fp_number_type in;
1489
 
1490
  in.class = class;
1491
  in.sign = sign;
1492
  in.normal_exp = exp;
1493
  in.fraction.ll = frac;
1494
  return pack_d (&in);
1495
}
1496
#endif /* L_make_sf */
1497
 
1498
#ifndef FLOAT_ONLY
1499
 
1500
/* This enables one to build an fp library that supports float but not double.
1501
   Otherwise, we would get an undefined reference to __make_dp.
1502
   This is needed for some 8-bit ports that can't handle well values that
1503
   are 8-bytes in size, so we just don't support double for them at all.  */
1504
 
1505
#if defined(L_sf_to_df)
1506
DFtype
1507
sf_to_df (SFtype arg_a)
1508
{
1509
  fp_number_type in;
1510
  FLO_union_type au;
1511
 
1512
  au.value = arg_a;
1513
  unpack_d (&au, &in);
1514
 
1515
  return __make_dp (in.class, in.sign, in.normal_exp,
1516
                    ((UDItype) in.fraction.ll) << F_D_BITOFF);
1517
}
1518
#endif /* L_sf_to_df */
1519
 
1520
#if defined(L_sf_to_tf) && defined(TMODES)
1521
TFtype
1522
sf_to_tf (SFtype arg_a)
1523
{
1524
  fp_number_type in;
1525
  FLO_union_type au;
1526
 
1527
  au.value = arg_a;
1528
  unpack_d (&au, &in);
1529
 
1530
  return __make_tp (in.class, in.sign, in.normal_exp,
1531
                    ((UTItype) in.fraction.ll) << F_T_BITOFF);
1532
}
1533
#endif /* L_sf_to_df */
1534
 
1535
#endif /* ! FLOAT_ONLY */
1536
#endif /* FLOAT */
1537
 
1538
#ifndef FLOAT
1539
 
1540
extern SFtype __make_fp (fp_class_type, unsigned int, int, USItype);
1541
 
1542
#if defined(L_make_df)
1543
DFtype
1544
__make_dp (fp_class_type class, unsigned int sign, int exp, UDItype frac)
1545
{
1546
  fp_number_type in;
1547
 
1548
  in.class = class;
1549
  in.sign = sign;
1550
  in.normal_exp = exp;
1551
  in.fraction.ll = frac;
1552
  return pack_d (&in);
1553
}
1554
#endif /* L_make_df */
1555
 
1556
#if defined(L_df_to_sf)
1557
SFtype
1558
df_to_sf (DFtype arg_a)
1559
{
1560
  fp_number_type in;
1561
  USItype sffrac;
1562
  FLO_union_type au;
1563
 
1564
  au.value = arg_a;
1565
  unpack_d (&au, &in);
1566
 
1567
  sffrac = in.fraction.ll >> F_D_BITOFF;
1568
 
1569
  /* We set the lowest guard bit in SFFRAC if we discarded any non
1570
     zero bits.  */
1571
  if ((in.fraction.ll & (((USItype) 1 << F_D_BITOFF) - 1)) != 0)
1572
    sffrac |= 1;
1573
 
1574
  return __make_fp (in.class, in.sign, in.normal_exp, sffrac);
1575
}
1576
#endif /* L_df_to_sf */
1577
 
1578
#if defined(L_df_to_tf) && defined(TMODES) \
1579
    && !defined(FLOAT) && !defined(TFLOAT)
1580
TFtype
1581
df_to_tf (DFtype arg_a)
1582
{
1583
  fp_number_type in;
1584
  FLO_union_type au;
1585
 
1586
  au.value = arg_a;
1587
  unpack_d (&au, &in);
1588
 
1589
  return __make_tp (in.class, in.sign, in.normal_exp,
1590
                    ((UTItype) in.fraction.ll) << D_T_BITOFF);
1591
}
1592
#endif /* L_sf_to_df */
1593
 
1594
#ifdef TFLOAT
1595
#if defined(L_make_tf)
1596
TFtype
1597
__make_tp(fp_class_type class,
1598
             unsigned int sign,
1599
             int exp,
1600
             UTItype frac)
1601
{
1602
  fp_number_type in;
1603
 
1604
  in.class = class;
1605
  in.sign = sign;
1606
  in.normal_exp = exp;
1607
  in.fraction.ll = frac;
1608
  return pack_d (&in);
1609
}
1610
#endif /* L_make_tf */
1611
 
1612
#if defined(L_tf_to_df)
1613
DFtype
1614
tf_to_df (TFtype arg_a)
1615
{
1616
  fp_number_type in;
1617
  UDItype sffrac;
1618
  FLO_union_type au;
1619
 
1620
  au.value = arg_a;
1621
  unpack_d (&au, &in);
1622
 
1623
  sffrac = in.fraction.ll >> D_T_BITOFF;
1624
 
1625
  /* We set the lowest guard bit in SFFRAC if we discarded any non
1626
     zero bits.  */
1627
  if ((in.fraction.ll & (((UTItype) 1 << D_T_BITOFF) - 1)) != 0)
1628
    sffrac |= 1;
1629
 
1630
  return __make_dp (in.class, in.sign, in.normal_exp, sffrac);
1631
}
1632
#endif /* L_tf_to_df */
1633
 
1634
#if defined(L_tf_to_sf)
1635
SFtype
1636
tf_to_sf (TFtype arg_a)
1637
{
1638
  fp_number_type in;
1639
  USItype sffrac;
1640
  FLO_union_type au;
1641
 
1642
  au.value = arg_a;
1643
  unpack_d (&au, &in);
1644
 
1645
  sffrac = in.fraction.ll >> F_T_BITOFF;
1646
 
1647
  /* We set the lowest guard bit in SFFRAC if we discarded any non
1648
     zero bits.  */
1649
  if ((in.fraction.ll & (((UTItype) 1 << F_T_BITOFF) - 1)) != 0)
1650
    sffrac |= 1;
1651
 
1652
  return __make_fp (in.class, in.sign, in.normal_exp, sffrac);
1653
}
1654
#endif /* L_tf_to_sf */
1655
#endif /* TFLOAT */
1656
 
1657
#endif /* ! FLOAT */
1658
#endif /* !EXTENDED_FLOAT_STUBS */

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