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/*      A C version of Kahan's Floating Point Test "Paranoia"
2
 
3
Thos Sumner, UCSF, Feb. 1985
4
David Gay, BTL, Jan. 1986
5
 
6
This is a rewrite from the Pascal version by
7
 
8
B. A. Wichmann, 18 Jan. 1985
9
 
10
(and does NOT exhibit good C programming style).
11
 
12
Adjusted to use Standard C headers 19 Jan. 1992 (dmg);
13
 
14
(C) Apr 19 1983 in BASIC version by:
15
Professor W. M. Kahan,
16
567 Evans Hall
17
Electrical Engineering & Computer Science Dept.
18
University of California
19
Berkeley, California 94720
20
USA
21
 
22
converted to Pascal by:
23
B. A. Wichmann
24
National Physical Laboratory
25
Teddington Middx
26
TW11 OLW
27
UK
28
 
29
converted to C by:
30
 
31
David M. Gay            and     Thos Sumner
32
AT&T Bell Labs                  Computer Center, Rm. U-76
33
600 Mountain Avenue             University of California
34
Murray Hill, NJ 07974           San Francisco, CA 94143
35
USA                             USA
36
 
37
with simultaneous corrections to the Pascal source (reflected
38
in the Pascal source available over netlib).
39
[A couple of bug fixes from dgh = sun!dhough incorporated 31 July 1986.]
40
 
41
Reports of results on various systems from all the versions
42
of Paranoia are being collected by Richard Karpinski at the
43
same address as Thos Sumner.  This includes sample outputs,
44
bug reports, and criticisms.
45
 
46
You may copy this program freely if you acknowledge its source.
47
Comments on the Pascal version to NPL, please.
48
 
49
The following is from the introductory commentary from Wichmann's work:
50
 
51
The BASIC program of Kahan is written in Microsoft BASIC using many
52
facilities which have no exact analogy in Pascal.  The Pascal
53
version below cannot therefore be exactly the same.  Rather than be
54
a minimal transcription of the BASIC program, the Pascal coding
55
follows the conventional style of block-structured languages.  Hence
56
the Pascal version could be useful in producing versions in other
57
structured languages.
58
 
59
Rather than use identifiers of minimal length (which therefore have
60
little mnemonic significance), the Pascal version uses meaningful
61
identifiers as follows [Note: A few changes have been made for C]:
62
 
63
 
64
BASIC   C               BASIC   C               BASIC   C
65
 
66
A                       J                       S    StickyBit
67
A1   AInverse           J0   NoErrors           T
68
B    Radix                    [Failure]         T0   Underflow
69
B1   BInverse           J1   NoErrors           T2   ThirtyTwo
70
B2   RadixD2                  [SeriousDefect]   T5   OneAndHalf
71
B9   BMinusU2           J2   NoErrors           T7   TwentySeven
72
C                             [Defect]          T8   TwoForty
73
C1   CInverse           J3   NoErrors           U    OneUlp
74
D                             [Flaw]            U0   UnderflowThreshold
75
D4   FourD              K    PageNo             U1
76
E0                      L    Milestone          U2
77
E1                      M                       V
78
E2   Exp2               N                       V0
79
E3                      N1                      V8
80
E5   MinSqEr            O    Zero               V9
81
E6   SqEr               O1   One                W
82
E7   MaxSqEr            O2   Two                X
83
E8                      O3   Three              X1
84
E9                      O4   Four               X8
85
F1   MinusOne           O5   Five               X9   Random1
86
F2   Half               O8   Eight              Y
87
F3   Third              O9   Nine               Y1
88
F6                      P    Precision          Y2
89
F9                      Q                       Y9   Random2
90
G1   GMult              Q8                      Z
91
G2   GDiv               Q9                      Z0   PseudoZero
92
G3   GAddSub            R                       Z1
93
H                       R1   RMult              Z2
94
H1   HInverse           R2   RDiv               Z9
95
I                       R3   RAddSub
96
IO   NoTrials           R4   RSqrt
97
I3   IEEE               R9   Random9
98
 
99
SqRWrng
100
 
101
All the variables in BASIC are true variables and in consequence,
102
the program is more difficult to follow since the "constants" must
103
be determined (the glossary is very helpful).  The Pascal version
104
uses Real constants, but checks are added to ensure that the values
105
are correctly converted by the compiler.
106
 
107
The major textual change to the Pascal version apart from the
108
identifiersis that named procedures are used, inserting parameters
109
wherehelpful.  New procedures are also introduced.  The
110
correspondence is as follows:
111
 
112
 
113
BASIC       Pascal
114
lines
115
 
116
90- 140   Pause
117
170- 250   Instructions
118
380- 460   Heading
119
480- 670   Characteristics
120
690- 870   History
121
2940-2950   Random
122
3710-3740   NewD
123
4040-4080   DoesYequalX
124
4090-4110   PrintIfNPositive
125
4640-4850   TestPartialUnderflow
126
 
127
*/
128
 
129
  /* This version of paranoia has been modified to work with GCC's internal
130
     software floating point emulation library, as a sanity check of same.
131
 
132
     I'm doing this in C++ so that I can do operator overloading and not
133
     have to modify so damned much of the existing code.  */
134
 
135
  extern "C" {
136
#include <stdio.h>
137
#include <stddef.h>
138
#include <limits.h>
139
#include <string.h>
140
#include <stdlib.h>
141
#include <math.h>
142
#include <unistd.h>
143
#include <float.h>
144
 
145
    /* This part is made all the more awful because many gcc headers are
146
       not prepared at all to be parsed as C++.  The biggest stickler
147
       here is const structure members.  So we include exactly the pieces
148
       that we need.  */
149
 
150
#define GTY(x)
151
 
152
#include "ansidecl.h"
153
#include "auto-host.h"
154
#include "hwint.h"
155
 
156
#undef EXTRA_MODES_FILE
157
 
158
    struct rtx_def;
159
    typedef struct rtx_def *rtx;
160
    struct rtvec_def;
161
    typedef struct rtvec_def *rtvec;
162
    union tree_node;
163
    typedef union tree_node *tree;
164
 
165
#define DEFTREECODE(SYM, STRING, TYPE, NARGS)   SYM,
166
    enum tree_code {
167
#include "tree.def"
168
      LAST_AND_UNUSED_TREE_CODE
169
    };
170
#undef DEFTREECODE
171
 
172
#define ENUM_BITFIELD(X) enum X
173
#define class klass
174
 
175
#include "real.h"
176
 
177
#undef class
178
  }
179
 
180
/* We never produce signals from the library.  Thus setjmp need do nothing.  */
181
#undef setjmp
182
#define setjmp(x)  (0)
183
 
184
static bool verbose = false;
185
static int verbose_index = 0;
186
 
187
/* ====================================================================== */
188
/* The implementation of the abstract floating point class based on gcc's
189
   real.c.  I.e. the object of this exercise.  Templated so that we can
190
   all fp sizes.  */
191
 
192
class real_c_float
193
{
194
 public:
195
  static const enum machine_mode MODE = SFmode;
196
 
197
 private:
198
  static const int external_max = 128 / 32;
199
  static const int internal_max
200
    = (sizeof (REAL_VALUE_TYPE) + sizeof (long) + 1) / sizeof (long);
201
  long image[external_max < internal_max ? internal_max : external_max];
202
 
203
  void from_long(long);
204
  void from_str(const char *);
205
  void binop(int code, const real_c_float&);
206
  void unop(int code);
207
  bool cmp(int code, const real_c_float&) const;
208
 
209
 public:
210
  real_c_float()
211
    { }
212
  real_c_float(long l)
213
    { from_long(l); }
214
  real_c_float(const char *s)
215
    { from_str(s); }
216
  real_c_float(const real_c_float &b)
217
    { memcpy(image, b.image, sizeof(image)); }
218
 
219
  const real_c_float& operator= (long l)
220
    { from_long(l); return *this; }
221
  const real_c_float& operator= (const char *s)
222
    { from_str(s); return *this; }
223
  const real_c_float& operator= (const real_c_float &b)
224
    { memcpy(image, b.image, sizeof(image)); return *this; }
225
 
226
  const real_c_float& operator+= (const real_c_float &b)
227
    { binop(PLUS_EXPR, b); return *this; }
228
  const real_c_float& operator-= (const real_c_float &b)
229
    { binop(MINUS_EXPR, b); return *this; }
230
  const real_c_float& operator*= (const real_c_float &b)
231
    { binop(MULT_EXPR, b); return *this; }
232
  const real_c_float& operator/= (const real_c_float &b)
233
    { binop(RDIV_EXPR, b); return *this; }
234
 
235
  real_c_float operator- () const
236
    { real_c_float r(*this); r.unop(NEGATE_EXPR); return r; }
237
  real_c_float abs () const
238
    { real_c_float r(*this); r.unop(ABS_EXPR); return r; }
239
 
240
  bool operator <  (const real_c_float &b) const { return cmp(LT_EXPR, b); }
241
  bool operator <= (const real_c_float &b) const { return cmp(LE_EXPR, b); }
242
  bool operator == (const real_c_float &b) const { return cmp(EQ_EXPR, b); }
243
  bool operator != (const real_c_float &b) const { return cmp(NE_EXPR, b); }
244
  bool operator >= (const real_c_float &b) const { return cmp(GE_EXPR, b); }
245
  bool operator >  (const real_c_float &b) const { return cmp(GT_EXPR, b); }
246
 
247
  const char * str () const;
248
  const char * hex () const;
249
  long integer () const;
250
  int exp () const;
251
  void ldexp (int);
252
};
253
 
254
void
255
real_c_float::from_long (long l)
256
{
257
  REAL_VALUE_TYPE f;
258
 
259
  real_from_integer (&f, MODE, l, l < 0 ? -1 : 0, 0);
260
  real_to_target (image, &f, MODE);
261
}
262
 
263
void
264
real_c_float::from_str (const char *s)
265
{
266
  REAL_VALUE_TYPE f;
267
  const char *p = s;
268
 
269
  if (*p == '-' || *p == '+')
270
    p++;
271
  if (strcasecmp(p, "inf") == 0)
272
    {
273
      real_inf (&f);
274
      if (*s == '-')
275
        real_arithmetic (&f, NEGATE_EXPR, &f, NULL);
276
    }
277
  else if (strcasecmp(p, "nan") == 0)
278
    real_nan (&f, "", 1, MODE);
279
  else
280
    real_from_string (&f, s);
281
 
282
  real_to_target (image, &f, MODE);
283
}
284
 
285
void
286
real_c_float::binop (int code, const real_c_float &b)
287
{
288
  REAL_VALUE_TYPE ai, bi, ri;
289
 
290
  real_from_target (&ai, image, MODE);
291
  real_from_target (&bi, b.image, MODE);
292
  real_arithmetic (&ri, code, &ai, &bi);
293
  real_to_target (image, &ri, MODE);
294
 
295
  if (verbose)
296
    {
297
      char ab[64], bb[64], rb[64];
298
      const real_format *fmt = real_format_for_mode[MODE - QFmode];
299
      const int digits = (fmt->p * fmt->log2_b + 3) / 4;
300
      char symbol_for_code;
301
 
302
      real_from_target (&ri, image, MODE);
303
      real_to_hexadecimal (ab, &ai, sizeof(ab), digits, 0);
304
      real_to_hexadecimal (bb, &bi, sizeof(bb), digits, 0);
305
      real_to_hexadecimal (rb, &ri, sizeof(rb), digits, 0);
306
 
307
      switch (code)
308
        {
309
        case PLUS_EXPR:
310
          symbol_for_code = '+';
311
          break;
312
        case MINUS_EXPR:
313
          symbol_for_code = '-';
314
          break;
315
        case MULT_EXPR:
316
          symbol_for_code = '*';
317
          break;
318
        case RDIV_EXPR:
319
          symbol_for_code = '/';
320
          break;
321
        default:
322
          abort ();
323
        }
324
 
325
      fprintf (stderr, "%6d: %s %c %s = %s\n", verbose_index++,
326
               ab, symbol_for_code, bb, rb);
327
    }
328
}
329
 
330
void
331
real_c_float::unop (int code)
332
{
333
  REAL_VALUE_TYPE ai, ri;
334
 
335
  real_from_target (&ai, image, MODE);
336
  real_arithmetic (&ri, code, &ai, NULL);
337
  real_to_target (image, &ri, MODE);
338
 
339
  if (verbose)
340
    {
341
      char ab[64], rb[64];
342
      const real_format *fmt = real_format_for_mode[MODE - QFmode];
343
      const int digits = (fmt->p * fmt->log2_b + 3) / 4;
344
      const char *symbol_for_code;
345
 
346
      real_from_target (&ri, image, MODE);
347
      real_to_hexadecimal (ab, &ai, sizeof(ab), digits, 0);
348
      real_to_hexadecimal (rb, &ri, sizeof(rb), digits, 0);
349
 
350
      switch (code)
351
        {
352
        case NEGATE_EXPR:
353
          symbol_for_code = "-";
354
          break;
355
        case ABS_EXPR:
356
          symbol_for_code = "abs ";
357
          break;
358
        default:
359
          abort ();
360
        }
361
 
362
      fprintf (stderr, "%6d: %s%s = %s\n", verbose_index++,
363
               symbol_for_code, ab, rb);
364
    }
365
}
366
 
367
bool
368
real_c_float::cmp (int code, const real_c_float &b) const
369
{
370
  REAL_VALUE_TYPE ai, bi;
371
  bool ret;
372
 
373
  real_from_target (&ai, image, MODE);
374
  real_from_target (&bi, b.image, MODE);
375
  ret = real_compare (code, &ai, &bi);
376
 
377
  if (verbose)
378
    {
379
      char ab[64], bb[64];
380
      const real_format *fmt = real_format_for_mode[MODE - QFmode];
381
      const int digits = (fmt->p * fmt->log2_b + 3) / 4;
382
      const char *symbol_for_code;
383
 
384
      real_to_hexadecimal (ab, &ai, sizeof(ab), digits, 0);
385
      real_to_hexadecimal (bb, &bi, sizeof(bb), digits, 0);
386
 
387
      switch (code)
388
        {
389
        case LT_EXPR:
390
          symbol_for_code = "<";
391
          break;
392
        case LE_EXPR:
393
          symbol_for_code = "<=";
394
          break;
395
        case EQ_EXPR:
396
          symbol_for_code = "==";
397
          break;
398
        case NE_EXPR:
399
          symbol_for_code = "!=";
400
          break;
401
        case GE_EXPR:
402
          symbol_for_code = ">=";
403
          break;
404
        case GT_EXPR:
405
          symbol_for_code = ">";
406
          break;
407
        default:
408
          abort ();
409
        }
410
 
411
      fprintf (stderr, "%6d: %s %s %s = %s\n", verbose_index++,
412
               ab, symbol_for_code, bb, (ret ? "true" : "false"));
413
    }
414
 
415
  return ret;
416
}
417
 
418
const char *
419
real_c_float::str() const
420
{
421
  REAL_VALUE_TYPE f;
422
  const real_format *fmt = real_format_for_mode[MODE - QFmode];
423
  const int digits = int(fmt->p * fmt->log2_b * .30102999566398119521 + 1);
424
 
425
  real_from_target (&f, image, MODE);
426
  char *buf = new char[digits + 10];
427
  real_to_decimal (buf, &f, digits+10, digits, 0);
428
 
429
  return buf;
430
}
431
 
432
const char *
433
real_c_float::hex() const
434
{
435
  REAL_VALUE_TYPE f;
436
  const real_format *fmt = real_format_for_mode[MODE - QFmode];
437
  const int digits = (fmt->p * fmt->log2_b + 3) / 4;
438
 
439
  real_from_target (&f, image, MODE);
440
  char *buf = new char[digits + 10];
441
  real_to_hexadecimal (buf, &f, digits+10, digits, 0);
442
 
443
  return buf;
444
}
445
 
446
long
447
real_c_float::integer() const
448
{
449
  REAL_VALUE_TYPE f;
450
  real_from_target (&f, image, MODE);
451
  return real_to_integer (&f);
452
}
453
 
454
int
455
real_c_float::exp() const
456
{
457
  REAL_VALUE_TYPE f;
458
  real_from_target (&f, image, MODE);
459
  return real_exponent (&f);
460
}
461
 
462
void
463
real_c_float::ldexp (int exp)
464
{
465
  REAL_VALUE_TYPE ai;
466
 
467
  real_from_target (&ai, image, MODE);
468
  real_ldexp (&ai, &ai, exp);
469
  real_to_target (image, &ai, MODE);
470
}
471
 
472
/* ====================================================================== */
473
/* An implementation of the abstract floating point class that uses native
474
   arithmetic.  Exists for reference and debugging.  */
475
 
476
template<typename T>
477
class native_float
478
{
479
 private:
480
  // Force intermediate results back to memory.
481
  volatile T image;
482
 
483
  static T from_str (const char *);
484
  static T do_abs (T);
485
  static T verbose_binop (T, char, T, T);
486
  static T verbose_unop (const char *, T, T);
487
  static bool verbose_cmp (T, const char *, T, bool);
488
 
489
 public:
490
  native_float()
491
    { }
492
  native_float(long l)
493
    { image = l; }
494
  native_float(const char *s)
495
    { image = from_str(s); }
496
  native_float(const native_float &b)
497
    { image = b.image; }
498
 
499
  const native_float& operator= (long l)
500
    { image = l; return *this; }
501
  const native_float& operator= (const char *s)
502
    { image = from_str(s); return *this; }
503
  const native_float& operator= (const native_float &b)
504
    { image = b.image; return *this; }
505
 
506
  const native_float& operator+= (const native_float &b)
507
    {
508
      image = verbose_binop(image, '+', b.image, image + b.image);
509
      return *this;
510
    }
511
  const native_float& operator-= (const native_float &b)
512
    {
513
      image = verbose_binop(image, '-', b.image, image - b.image);
514
      return *this;
515
    }
516
  const native_float& operator*= (const native_float &b)
517
    {
518
      image = verbose_binop(image, '*', b.image, image * b.image);
519
      return *this;
520
    }
521
  const native_float& operator/= (const native_float &b)
522
    {
523
      image = verbose_binop(image, '/', b.image, image / b.image);
524
      return *this;
525
    }
526
 
527
  native_float operator- () const
528
    {
529
      native_float r;
530
      r.image = verbose_unop("-", image, -image);
531
      return r;
532
    }
533
  native_float abs () const
534
    {
535
      native_float r;
536
      r.image = verbose_unop("abs ", image, do_abs(image));
537
      return r;
538
    }
539
 
540
  bool operator <  (const native_float &b) const
541
    { return verbose_cmp(image, "<", b.image, image <  b.image); }
542
  bool operator <= (const native_float &b) const
543
    { return verbose_cmp(image, "<=", b.image, image <= b.image); }
544
  bool operator == (const native_float &b) const
545
    { return verbose_cmp(image, "==", b.image, image == b.image); }
546
  bool operator != (const native_float &b) const
547
    { return verbose_cmp(image, "!=", b.image, image != b.image); }
548
  bool operator >= (const native_float &b) const
549
    { return verbose_cmp(image, ">=", b.image, image >= b.image); }
550
  bool operator >  (const native_float &b) const
551
    { return verbose_cmp(image, ">", b.image, image > b.image); }
552
 
553
  const char * str () const;
554
  const char * hex () const;
555
  long integer () const
556
    { return long(image); }
557
  int exp () const;
558
  void ldexp (int);
559
};
560
 
561
template<typename T>
562
inline T
563
native_float<T>::from_str (const char *s)
564
{
565
  return strtold (s, NULL);
566
}
567
 
568
template<>
569
inline float
570
native_float<float>::from_str (const char *s)
571
{
572
  return strtof (s, NULL);
573
}
574
 
575
template<>
576
inline double
577
native_float<double>::from_str (const char *s)
578
{
579
  return strtod (s, NULL);
580
}
581
 
582
template<typename T>
583
inline T
584
native_float<T>::do_abs (T image)
585
{
586
  return fabsl (image);
587
}
588
 
589
template<>
590
inline float
591
native_float<float>::do_abs (float image)
592
{
593
  return fabsf (image);
594
}
595
 
596
template<>
597
inline double
598
native_float<double>::do_abs (double image)
599
{
600
  return fabs (image);
601
}
602
 
603
template<typename T>
604
T
605
native_float<T>::verbose_binop (T a, char symbol, T b, T r)
606
{
607
  if (verbose)
608
    {
609
      const int digits = int(sizeof(T) * CHAR_BIT / 4) - 1;
610
#ifdef NO_LONG_DOUBLE
611
      fprintf (stderr, "%6d: %.*a %c %.*a = %.*a\n", verbose_index++,
612
               digits, (double)a, symbol,
613
               digits, (double)b, digits, (double)r);
614
#else
615
      fprintf (stderr, "%6d: %.*La %c %.*La = %.*La\n", verbose_index++,
616
               digits, (long double)a, symbol,
617
               digits, (long double)b, digits, (long double)r);
618
#endif
619
    }
620
  return r;
621
}
622
 
623
template<typename T>
624
T
625
native_float<T>::verbose_unop (const char *symbol, T a, T r)
626
{
627
  if (verbose)
628
    {
629
      const int digits = int(sizeof(T) * CHAR_BIT / 4) - 1;
630
#ifdef NO_LONG_DOUBLE
631
      fprintf (stderr, "%6d: %s%.*a = %.*a\n", verbose_index++,
632
               symbol, digits, (double)a, digits, (double)r);
633
#else
634
      fprintf (stderr, "%6d: %s%.*La = %.*La\n", verbose_index++,
635
               symbol, digits, (long double)a, digits, (long double)r);
636
#endif
637
    }
638
  return r;
639
}
640
 
641
template<typename T>
642
bool
643
native_float<T>::verbose_cmp (T a, const char *symbol, T b, bool r)
644
{
645
  if (verbose)
646
    {
647
      const int digits = int(sizeof(T) * CHAR_BIT / 4) - 1;
648
#ifndef NO_LONG_DOUBLE
649
      fprintf (stderr, "%6d: %.*a %s %.*a = %s\n", verbose_index++,
650
               digits, (double)a, symbol,
651
               digits, (double)b, (r ? "true" : "false"));
652
#else
653
      fprintf (stderr, "%6d: %.*La %s %.*La = %s\n", verbose_index++,
654
               digits, (long double)a, symbol,
655
               digits, (long double)b, (r ? "true" : "false"));
656
#endif
657
    }
658
  return r;
659
}
660
 
661
template<typename T>
662
const char *
663
native_float<T>::str() const
664
{
665
  char *buf = new char[50];
666
  const int digits = int(sizeof(T) * CHAR_BIT * .30102999566398119521 + 1);
667
#ifndef NO_LONG_DOUBLE
668
  sprintf (buf, "%.*e", digits - 1, (double) image);
669
#else
670
  sprintf (buf, "%.*Le", digits - 1, (long double) image);
671
#endif
672
  return buf;
673
}
674
 
675
template<typename T>
676
const char *
677
native_float<T>::hex() const
678
{
679
  char *buf = new char[50];
680
  const int digits = int(sizeof(T) * CHAR_BIT / 4);
681
#ifndef NO_LONG_DOUBLE
682
  sprintf (buf, "%.*a", digits - 1, (double) image);
683
#else
684
  sprintf (buf, "%.*La", digits - 1, (long double) image);
685
#endif
686
  return buf;
687
}
688
 
689
template<typename T>
690
int
691
native_float<T>::exp() const
692
{
693
  int e;
694
  frexp (image, &e);
695
  return e;
696
}
697
 
698
template<typename T>
699
void
700
native_float<T>::ldexp (int exp)
701
{
702
  image = ldexpl (image, exp);
703
}
704
 
705
template<>
706
void
707
native_float<float>::ldexp (int exp)
708
{
709
  image = ldexpf (image, exp);
710
}
711
 
712
template<>
713
void
714
native_float<double>::ldexp (int exp)
715
{
716
  image = ::ldexp (image, exp);
717
}
718
 
719
/* ====================================================================== */
720
/* Some libm routines that Paranoia expects to be available.  */
721
 
722
template<typename FLOAT>
723
inline FLOAT
724
FABS (const FLOAT &f)
725
{
726
  return f.abs();
727
}
728
 
729
template<typename FLOAT, typename RHS>
730
inline FLOAT
731
operator+ (const FLOAT &a, const RHS &b)
732
{
733
  return FLOAT(a) += FLOAT(b);
734
}
735
 
736
template<typename FLOAT, typename RHS>
737
inline FLOAT
738
operator- (const FLOAT &a, const RHS &b)
739
{
740
  return FLOAT(a) -= FLOAT(b);
741
}
742
 
743
template<typename FLOAT, typename RHS>
744
inline FLOAT
745
operator* (const FLOAT &a, const RHS &b)
746
{
747
  return FLOAT(a) *= FLOAT(b);
748
}
749
 
750
template<typename FLOAT, typename RHS>
751
inline FLOAT
752
operator/ (const FLOAT &a, const RHS &b)
753
{
754
  return FLOAT(a) /= FLOAT(b);
755
}
756
 
757
template<typename FLOAT>
758
FLOAT
759
FLOOR (const FLOAT &f)
760
{
761
  /* ??? This is only correct when F is representable as an integer.  */
762
  long i = f.integer();
763
  FLOAT r;
764
 
765
  r = i;
766
  if (i < 0 && f != r)
767
    r = i - 1;
768
 
769
  return r;
770
}
771
 
772
template<typename FLOAT>
773
FLOAT
774
SQRT (const FLOAT &f)
775
{
776
#if 0
777
  FLOAT zero = long(0);
778
  FLOAT two = 2;
779
  FLOAT one = 1;
780
  FLOAT diff, diff2;
781
  FLOAT z, t;
782
 
783
  if (f == zero)
784
    return zero;
785
  if (f < zero)
786
    return zero / zero;
787
  if (f == one)
788
    return f;
789
 
790
  z = f;
791
  z.ldexp (-f.exp() / 2);
792
 
793
  diff2 = FABS (z * z - f);
794
  if (diff2 > zero)
795
    while (1)
796
      {
797
        t = (f / (two * z)) + (z / two);
798
        diff = FABS (t * t - f);
799
        if (diff >= diff2)
800
          break;
801
        z = t;
802
        diff2 = diff;
803
      }
804
 
805
  return z;
806
#elif defined(NO_LONG_DOUBLE)
807
  double d;
808
  char buf[64];
809
 
810
  d = strtod (f.hex(), NULL);
811
  d = sqrt (d);
812
  sprintf(buf, "%.35a", d);
813
 
814
  return FLOAT(buf);
815
#else
816
  long double ld;
817
  char buf[64];
818
 
819
  ld = strtold (f.hex(), NULL);
820
  ld = sqrtl (ld);
821
  sprintf(buf, "%.35La", ld);
822
 
823
  return FLOAT(buf);
824
#endif
825
}
826
 
827
template<typename FLOAT>
828
FLOAT
829
LOG (FLOAT x)
830
{
831
#if 0
832
  FLOAT zero = long(0);
833
  FLOAT one = 1;
834
 
835
  if (x <= zero)
836
    return zero / zero;
837
  if (x == one)
838
    return zero;
839
 
840
  int exp = x.exp() - 1;
841
  x.ldexp(-exp);
842
 
843
  FLOAT xm1 = x - one;
844
  FLOAT y = xm1;
845
  long n = 2;
846
 
847
  FLOAT sum = xm1;
848
  while (1)
849
    {
850
      y *= xm1;
851
      FLOAT term = y / FLOAT (n);
852
      FLOAT next = sum + term;
853
      if (next == sum)
854
        break;
855
      sum = next;
856
      if (++n == 1000)
857
        break;
858
    }
859
 
860
  if (exp)
861
    sum += FLOAT (exp) * FLOAT(".69314718055994530941");
862
 
863
  return sum;
864
#elif defined (NO_LONG_DOUBLE)
865
  double d;
866
  char buf[64];
867
 
868
  d = strtod (x.hex(), NULL);
869
  d = log (d);
870
  sprintf(buf, "%.35a", d);
871
 
872
  return FLOAT(buf);
873
#else
874
  long double ld;
875
  char buf[64];
876
 
877
  ld = strtold (x.hex(), NULL);
878
  ld = logl (ld);
879
  sprintf(buf, "%.35La", ld);
880
 
881
  return FLOAT(buf);
882
#endif
883
}
884
 
885
template<typename FLOAT>
886
FLOAT
887
EXP (const FLOAT &x)
888
{
889
  /* Cheat.  */
890
#ifdef NO_LONG_DOUBLE
891
  double d;
892
  char buf[64];
893
 
894
  d = strtod (x.hex(), NULL);
895
  d = exp (d);
896
  sprintf(buf, "%.35a", d);
897
 
898
  return FLOAT(buf);
899
#else
900
  long double ld;
901
  char buf[64];
902
 
903
  ld = strtold (x.hex(), NULL);
904
  ld = expl (ld);
905
  sprintf(buf, "%.35La", ld);
906
 
907
  return FLOAT(buf);
908
#endif
909
}
910
 
911
template<typename FLOAT>
912
FLOAT
913
POW (const FLOAT &base, const FLOAT &exp)
914
{
915
  /* Cheat.  */
916
#ifdef NO_LONG_DOUBLE
917
  double d1, d2;
918
  char buf[64];
919
 
920
  d1 = strtod (base.hex(), NULL);
921
  d2 = strtod (exp.hex(), NULL);
922
  d1 = pow (d1, d2);
923
  sprintf(buf, "%.35a", d1);
924
 
925
  return FLOAT(buf);
926
#else
927
  long double ld1, ld2;
928
  char buf[64];
929
 
930
  ld1 = strtold (base.hex(), NULL);
931
  ld2 = strtold (exp.hex(), NULL);
932
  ld1 = powl (ld1, ld2);
933
  sprintf(buf, "%.35La", ld1);
934
 
935
  return FLOAT(buf);
936
#endif
937
}
938
 
939
/* ====================================================================== */
940
/* Real Paranoia begins again here.  We wrap the thing in a template so
941
   that we can instantiate it for each floating point type we care for.  */
942
 
943
int NoTrials = 20;              /*Number of tests for commutativity. */
944
bool do_pause = false;
945
 
946
enum Guard { No, Yes };
947
enum Rounding { Other, Rounded, Chopped };
948
enum Class { Failure, Serious, Defect, Flaw };
949
 
950
template<typename FLOAT>
951
struct Paranoia
952
{
953
  FLOAT Radix, BInvrse, RadixD2, BMinusU2;
954
 
955
  /* Small floating point constants.  */
956
  FLOAT Zero;
957
  FLOAT Half;
958
  FLOAT One;
959
  FLOAT Two;
960
  FLOAT Three;
961
  FLOAT Four;
962
  FLOAT Five;
963
  FLOAT Eight;
964
  FLOAT Nine;
965
  FLOAT TwentySeven;
966
  FLOAT ThirtyTwo;
967
  FLOAT TwoForty;
968
  FLOAT MinusOne;
969
  FLOAT OneAndHalf;
970
 
971
  /* Declarations of Variables.  */
972
  int Indx;
973
  char ch[8];
974
  FLOAT AInvrse, A1;
975
  FLOAT C, CInvrse;
976
  FLOAT D, FourD;
977
  FLOAT E0, E1, Exp2, E3, MinSqEr;
978
  FLOAT SqEr, MaxSqEr, E9;
979
  FLOAT Third;
980
  FLOAT F6, F9;
981
  FLOAT H, HInvrse;
982
  int I;
983
  FLOAT StickyBit, J;
984
  FLOAT MyZero;
985
  FLOAT Precision;
986
  FLOAT Q, Q9;
987
  FLOAT R, Random9;
988
  FLOAT T, Underflow, S;
989
  FLOAT OneUlp, UfThold, U1, U2;
990
  FLOAT V, V0, V9;
991
  FLOAT W;
992
  FLOAT X, X1, X2, X8, Random1;
993
  FLOAT Y, Y1, Y2, Random2;
994
  FLOAT Z, PseudoZero, Z1, Z2, Z9;
995
  int ErrCnt[4];
996
  int Milestone;
997
  int PageNo;
998
  int M, N, N1;
999
  Guard GMult, GDiv, GAddSub;
1000
  Rounding RMult, RDiv, RAddSub, RSqrt;
1001
  int Break, Done, NotMonot, Monot, Anomaly, IEEE, SqRWrng, UfNGrad;
1002
 
1003
  /* Computed constants. */
1004
  /*U1  gap below 1.0, i.e, 1.0-U1 is next number below 1.0 */
1005
  /*U2  gap above 1.0, i.e, 1.0+U2 is next number above 1.0 */
1006
 
1007
  int main ();
1008
 
1009
  FLOAT Sign (FLOAT);
1010
  FLOAT Random ();
1011
  void Pause ();
1012
  void BadCond (int, const char *);
1013
  void SqXMinX (int);
1014
  void TstCond (int, int, const char *);
1015
  void notify (const char *);
1016
  void IsYeqX ();
1017
  void NewD ();
1018
  void PrintIfNPositive ();
1019
  void SR3750 ();
1020
  void TstPtUf ();
1021
 
1022
  // Pretend we're bss.
1023
  Paranoia() { memset(this, 0, sizeof (*this)); }
1024
};
1025
 
1026
template<typename FLOAT>
1027
int
1028
Paranoia<FLOAT>::main()
1029
{
1030
  /* First two assignments use integer right-hand sides. */
1031
  Zero = long(0);
1032
  One = long(1);
1033
  Two = long(2);
1034
  Three = long(3);
1035
  Four = long(4);
1036
  Five = long(5);
1037
  Eight = long(8);
1038
  Nine = long(9);
1039
  TwentySeven = long(27);
1040
  ThirtyTwo = long(32);
1041
  TwoForty = long(240);
1042
  MinusOne = long(-1);
1043
  Half = "0x1p-1";
1044
  OneAndHalf = "0x3p-1";
1045
  ErrCnt[Failure] = 0;
1046
  ErrCnt[Serious] = 0;
1047
  ErrCnt[Defect] = 0;
1048
  ErrCnt[Flaw] = 0;
1049
  PageNo = 1;
1050
        /*=============================================*/
1051
  Milestone = 7;
1052
        /*=============================================*/
1053
  printf ("Program is now RUNNING tests on small integers:\n");
1054
 
1055
  TstCond (Failure, (Zero + Zero == Zero), "0+0 != 0");
1056
  TstCond (Failure, (One - One == Zero), "1-1 != 0");
1057
  TstCond (Failure, (One > Zero), "1 <= 0");
1058
  TstCond (Failure, (One + One == Two), "1+1 != 2");
1059
 
1060
  Z = -Zero;
1061
  if (Z != Zero)
1062
    {
1063
      ErrCnt[Failure] = ErrCnt[Failure] + 1;
1064
      printf ("Comparison alleges that -0.0 is Non-zero!\n");
1065
      U2 = "0.001";
1066
      Radix = 1;
1067
      TstPtUf ();
1068
    }
1069
 
1070
  TstCond (Failure, (Three == Two + One), "3 != 2+1");
1071
  TstCond (Failure, (Four == Three + One), "4 != 3+1");
1072
  TstCond (Failure, (Four + Two * (-Two) == Zero), "4 + 2*(-2) != 0");
1073
  TstCond (Failure, (Four - Three - One == Zero), "4-3-1 != 0");
1074
 
1075
  TstCond (Failure, (MinusOne == (Zero - One)), "-1 != 0-1");
1076
  TstCond (Failure, (MinusOne + One == Zero), "-1+1 != 0");
1077
  TstCond (Failure, (One + MinusOne == Zero), "1+(-1) != 0");
1078
  TstCond (Failure, (MinusOne + FABS (One) == Zero), "-1+abs(1) != 0");
1079
  TstCond (Failure, (MinusOne + MinusOne * MinusOne == Zero),
1080
           "-1+(-1)*(-1) != 0");
1081
 
1082
  TstCond (Failure, Half + MinusOne + Half == Zero, "1/2 + (-1) + 1/2 != 0");
1083
 
1084
        /*=============================================*/
1085
  Milestone = 10;
1086
        /*=============================================*/
1087
 
1088
  TstCond (Failure, (Nine == Three * Three), "9 != 3*3");
1089
  TstCond (Failure, (TwentySeven == Nine * Three), "27 != 9*3");
1090
  TstCond (Failure, (Eight == Four + Four), "8 != 4+4");
1091
  TstCond (Failure, (ThirtyTwo == Eight * Four), "32 != 8*4");
1092
  TstCond (Failure, (ThirtyTwo - TwentySeven - Four - One == Zero),
1093
           "32-27-4-1 != 0");
1094
 
1095
  TstCond (Failure, Five == Four + One, "5 != 4+1");
1096
  TstCond (Failure, TwoForty == Four * Five * Three * Four, "240 != 4*5*3*4");
1097
  TstCond (Failure, TwoForty / Three - Four * Four * Five == Zero,
1098
           "240/3 - 4*4*5 != 0");
1099
  TstCond (Failure, TwoForty / Four - Five * Three * Four == Zero,
1100
           "240/4 - 5*3*4 != 0");
1101
  TstCond (Failure, TwoForty / Five - Four * Three * Four == Zero,
1102
           "240/5 - 4*3*4 != 0");
1103
 
1104
  if (ErrCnt[Failure] == 0)
1105
    {
1106
      printf ("-1, 0, 1/2, 1, 2, 3, 4, 5, 9, 27, 32 & 240 are O.K.\n");
1107
      printf ("\n");
1108
    }
1109
  printf ("Searching for Radix and Precision.\n");
1110
  W = One;
1111
  do
1112
    {
1113
      W = W + W;
1114
      Y = W + One;
1115
      Z = Y - W;
1116
      Y = Z - One;
1117
    }
1118
  while (MinusOne + FABS (Y) < Zero);
1119
  /*.. now W is just big enough that |((W+1)-W)-1| >= 1 ... */
1120
  Precision = Zero;
1121
  Y = One;
1122
  do
1123
    {
1124
      Radix = W + Y;
1125
      Y = Y + Y;
1126
      Radix = Radix - W;
1127
    }
1128
  while (Radix == Zero);
1129
  if (Radix < Two)
1130
    Radix = One;
1131
  printf ("Radix = %s .\n", Radix.str());
1132
  if (Radix != One)
1133
    {
1134
      W = One;
1135
      do
1136
        {
1137
          Precision = Precision + One;
1138
          W = W * Radix;
1139
          Y = W + One;
1140
        }
1141
      while ((Y - W) == One);
1142
    }
1143
  /*... now W == Radix^Precision is barely too big to satisfy (W+1)-W == 1
1144
     ... */
1145
  U1 = One / W;
1146
  U2 = Radix * U1;
1147
  printf ("Closest relative separation found is U1 = %s .\n\n", U1.str());
1148
  printf ("Recalculating radix and precision\n ");
1149
 
1150
  /*save old values */
1151
  E0 = Radix;
1152
  E1 = U1;
1153
  E9 = U2;
1154
  E3 = Precision;
1155
 
1156
  X = Four / Three;
1157
  Third = X - One;
1158
  F6 = Half - Third;
1159
  X = F6 + F6;
1160
  X = FABS (X - Third);
1161
  if (X < U2)
1162
    X = U2;
1163
 
1164
  /*... now X = (unknown no.) ulps of 1+... */
1165
  do
1166
    {
1167
      U2 = X;
1168
      Y = Half * U2 + ThirtyTwo * U2 * U2;
1169
      Y = One + Y;
1170
      X = Y - One;
1171
    }
1172
  while (!((U2 <= X) || (X <= Zero)));
1173
 
1174
  /*... now U2 == 1 ulp of 1 + ... */
1175
  X = Two / Three;
1176
  F6 = X - Half;
1177
  Third = F6 + F6;
1178
  X = Third - Half;
1179
  X = FABS (X + F6);
1180
  if (X < U1)
1181
    X = U1;
1182
 
1183
  /*... now  X == (unknown no.) ulps of 1 -... */
1184
  do
1185
    {
1186
      U1 = X;
1187
      Y = Half * U1 + ThirtyTwo * U1 * U1;
1188
      Y = Half - Y;
1189
      X = Half + Y;
1190
      Y = Half - X;
1191
      X = Half + Y;
1192
    }
1193
  while (!((U1 <= X) || (X <= Zero)));
1194
  /*... now U1 == 1 ulp of 1 - ... */
1195
  if (U1 == E1)
1196
    printf ("confirms closest relative separation U1 .\n");
1197
  else
1198
    printf ("gets better closest relative separation U1 = %s .\n", U1.str());
1199
  W = One / U1;
1200
  F9 = (Half - U1) + Half;
1201
 
1202
  Radix = FLOOR (FLOAT ("0.01") + U2 / U1);
1203
  if (Radix == E0)
1204
    printf ("Radix confirmed.\n");
1205
  else
1206
    printf ("MYSTERY: recalculated Radix = %s .\n", Radix.str());
1207
  TstCond (Defect, Radix <= Eight + Eight,
1208
           "Radix is too big: roundoff problems");
1209
  TstCond (Flaw, (Radix == Two) || (Radix == 10)
1210
           || (Radix == One), "Radix is not as good as 2 or 10");
1211
        /*=============================================*/
1212
  Milestone = 20;
1213
        /*=============================================*/
1214
  TstCond (Failure, F9 - Half < Half,
1215
           "(1-U1)-1/2 < 1/2 is FALSE, prog. fails?");
1216
  X = F9;
1217
  I = 1;
1218
  Y = X - Half;
1219
  Z = Y - Half;
1220
  TstCond (Failure, (X != One)
1221
           || (Z == Zero), "Comparison is fuzzy,X=1 but X-1/2-1/2 != 0");
1222
  X = One + U2;
1223
  I = 0;
1224
        /*=============================================*/
1225
  Milestone = 25;
1226
        /*=============================================*/
1227
  /*... BMinusU2 = nextafter(Radix, 0) */
1228
  BMinusU2 = Radix - One;
1229
  BMinusU2 = (BMinusU2 - U2) + One;
1230
  /* Purify Integers */
1231
  if (Radix != One)
1232
    {
1233
      X = -TwoForty * LOG (U1) / LOG (Radix);
1234
      Y = FLOOR (Half + X);
1235
      if (FABS (X - Y) * Four < One)
1236
        X = Y;
1237
      Precision = X / TwoForty;
1238
      Y = FLOOR (Half + Precision);
1239
      if (FABS (Precision - Y) * TwoForty < Half)
1240
        Precision = Y;
1241
    }
1242
  if ((Precision != FLOOR (Precision)) || (Radix == One))
1243
    {
1244
      printf ("Precision cannot be characterized by an Integer number\n");
1245
      printf
1246
        ("of significant digits but, by itself, this is a minor flaw.\n");
1247
    }
1248
  if (Radix == One)
1249
    printf
1250
      ("logarithmic encoding has precision characterized solely by U1.\n");
1251
  else
1252
    printf ("The number of significant digits of the Radix is %s .\n",
1253
            Precision.str());
1254
  TstCond (Serious, U2 * Nine * Nine * TwoForty < One,
1255
           "Precision worse than 5 decimal figures  ");
1256
        /*=============================================*/
1257
  Milestone = 30;
1258
        /*=============================================*/
1259
  /* Test for extra-precise subexpressions */
1260
  X = FABS (((Four / Three - One) - One / Four) * Three - One / Four);
1261
  do
1262
    {
1263
      Z2 = X;
1264
      X = (One + (Half * Z2 + ThirtyTwo * Z2 * Z2)) - One;
1265
    }
1266
  while (!((Z2 <= X) || (X <= Zero)));
1267
  X = Y = Z = FABS ((Three / Four - Two / Three) * Three - One / Four);
1268
  do
1269
    {
1270
      Z1 = Z;
1271
      Z = (One / Two - ((One / Two - (Half * Z1 + ThirtyTwo * Z1 * Z1))
1272
                        + One / Two)) + One / Two;
1273
    }
1274
  while (!((Z1 <= Z) || (Z <= Zero)));
1275
  do
1276
    {
1277
      do
1278
        {
1279
          Y1 = Y;
1280
          Y =
1281
            (Half - ((Half - (Half * Y1 + ThirtyTwo * Y1 * Y1)) + Half)) +
1282
            Half;
1283
        }
1284
      while (!((Y1 <= Y) || (Y <= Zero)));
1285
      X1 = X;
1286
      X = ((Half * X1 + ThirtyTwo * X1 * X1) - F9) + F9;
1287
    }
1288
  while (!((X1 <= X) || (X <= Zero)));
1289
  if ((X1 != Y1) || (X1 != Z1))
1290
    {
1291
      BadCond (Serious, "Disagreements among the values X1, Y1, Z1,\n");
1292
      printf ("respectively  %s,  %s,  %s,\n", X1.str(), Y1.str(), Z1.str());
1293
      printf ("are symptoms of inconsistencies introduced\n");
1294
      printf ("by extra-precise evaluation of arithmetic subexpressions.\n");
1295
      notify ("Possibly some part of this");
1296
      if ((X1 == U1) || (Y1 == U1) || (Z1 == U1))
1297
        printf ("That feature is not tested further by this program.\n");
1298
    }
1299
  else
1300
    {
1301
      if ((Z1 != U1) || (Z2 != U2))
1302
        {
1303
          if ((Z1 >= U1) || (Z2 >= U2))
1304
            {
1305
              BadCond (Failure, "");
1306
              notify ("Precision");
1307
              printf ("\tU1 = %s, Z1 - U1 = %s\n", U1.str(), (Z1 - U1).str());
1308
              printf ("\tU2 = %s, Z2 - U2 = %s\n", U2.str(), (Z2 - U2).str());
1309
            }
1310
          else
1311
            {
1312
              if ((Z1 <= Zero) || (Z2 <= Zero))
1313
                {
1314
                  printf ("Because of unusual Radix = %s", Radix.str());
1315
                  printf (", or exact rational arithmetic a result\n");
1316
                  printf ("Z1 = %s, or Z2 = %s ", Z1.str(), Z2.str());
1317
                  notify ("of an\nextra-precision");
1318
                }
1319
              if (Z1 != Z2 || Z1 > Zero)
1320
                {
1321
                  X = Z1 / U1;
1322
                  Y = Z2 / U2;
1323
                  if (Y > X)
1324
                    X = Y;
1325
                  Q = -LOG (X);
1326
                  printf ("Some subexpressions appear to be calculated "
1327
                          "extra precisely\n");
1328
                  printf ("with about %s extra B-digits, i.e.\n",
1329
                          (Q / LOG (Radix)).str());
1330
                  printf ("roughly %s extra significant decimals.\n",
1331
                          (Q / LOG (FLOAT (10))).str());
1332
                }
1333
              printf
1334
                ("That feature is not tested further by this program.\n");
1335
            }
1336
        }
1337
    }
1338
  Pause ();
1339
        /*=============================================*/
1340
  Milestone = 35;
1341
        /*=============================================*/
1342
  if (Radix >= Two)
1343
    {
1344
      X = W / (Radix * Radix);
1345
      Y = X + One;
1346
      Z = Y - X;
1347
      T = Z + U2;
1348
      X = T - Z;
1349
      TstCond (Failure, X == U2,
1350
               "Subtraction is not normalized X=Y,X+Z != Y+Z!");
1351
      if (X == U2)
1352
        printf ("Subtraction appears to be normalized, as it should be.");
1353
    }
1354
  printf ("\nChecking for guard digit in *, /, and -.\n");
1355
  Y = F9 * One;
1356
  Z = One * F9;
1357
  X = F9 - Half;
1358
  Y = (Y - Half) - X;
1359
  Z = (Z - Half) - X;
1360
  X = One + U2;
1361
  T = X * Radix;
1362
  R = Radix * X;
1363
  X = T - Radix;
1364
  X = X - Radix * U2;
1365
  T = R - Radix;
1366
  T = T - Radix * U2;
1367
  X = X * (Radix - One);
1368
  T = T * (Radix - One);
1369
  if ((X == Zero) && (Y == Zero) && (Z == Zero) && (T == Zero))
1370
    GMult = Yes;
1371
  else
1372
    {
1373
      GMult = No;
1374
      TstCond (Serious, false, "* lacks a Guard Digit, so 1*X != X");
1375
    }
1376
  Z = Radix * U2;
1377
  X = One + Z;
1378
  Y = FABS ((X + Z) - X * X) - U2;
1379
  X = One - U2;
1380
  Z = FABS ((X - U2) - X * X) - U1;
1381
  TstCond (Failure, (Y <= Zero)
1382
           && (Z <= Zero), "* gets too many final digits wrong.\n");
1383
  Y = One - U2;
1384
  X = One + U2;
1385
  Z = One / Y;
1386
  Y = Z - X;
1387
  X = One / Three;
1388
  Z = Three / Nine;
1389
  X = X - Z;
1390
  T = Nine / TwentySeven;
1391
  Z = Z - T;
1392
  TstCond (Defect, X == Zero && Y == Zero && Z == Zero,
1393
           "Division lacks a Guard Digit, so error can exceed 1 ulp\n"
1394
           "or  1/3  and  3/9  and  9/27 may disagree");
1395
  Y = F9 / One;
1396
  X = F9 - Half;
1397
  Y = (Y - Half) - X;
1398
  X = One + U2;
1399
  T = X / One;
1400
  X = T - X;
1401
  if ((X == Zero) && (Y == Zero) && (Z == Zero))
1402
    GDiv = Yes;
1403
  else
1404
    {
1405
      GDiv = No;
1406
      TstCond (Serious, false, "Division lacks a Guard Digit, so X/1 != X");
1407
    }
1408
  X = One / (One + U2);
1409
  Y = X - Half - Half;
1410
  TstCond (Serious, Y < Zero, "Computed value of 1/1.000..1 >= 1");
1411
  X = One - U2;
1412
  Y = One + Radix * U2;
1413
  Z = X * Radix;
1414
  T = Y * Radix;
1415
  R = Z / Radix;
1416
  StickyBit = T / Radix;
1417
  X = R - X;
1418
  Y = StickyBit - Y;
1419
  TstCond (Failure, X == Zero && Y == Zero,
1420
           "* and/or / gets too many last digits wrong");
1421
  Y = One - U1;
1422
  X = One - F9;
1423
  Y = One - Y;
1424
  T = Radix - U2;
1425
  Z = Radix - BMinusU2;
1426
  T = Radix - T;
1427
  if ((X == U1) && (Y == U1) && (Z == U2) && (T == U2))
1428
    GAddSub = Yes;
1429
  else
1430
    {
1431
      GAddSub = No;
1432
      TstCond (Serious, false,
1433
               "- lacks Guard Digit, so cancellation is obscured");
1434
    }
1435
  if (F9 != One && F9 - One >= Zero)
1436
    {
1437
      BadCond (Serious, "comparison alleges  (1-U1) < 1  although\n");
1438
      printf ("  subtraction yields  (1-U1) - 1 = 0 , thereby vitiating\n");
1439
      printf ("  such precautions against division by zero as\n");
1440
      printf ("  ...  if (X == 1.0) {.....} else {.../(X-1.0)...}\n");
1441
    }
1442
  if (GMult == Yes && GDiv == Yes && GAddSub == Yes)
1443
    printf
1444
      ("     *, /, and - appear to have guard digits, as they should.\n");
1445
        /*=============================================*/
1446
  Milestone = 40;
1447
        /*=============================================*/
1448
  Pause ();
1449
  printf ("Checking rounding on multiply, divide and add/subtract.\n");
1450
  RMult = Other;
1451
  RDiv = Other;
1452
  RAddSub = Other;
1453
  RadixD2 = Radix / Two;
1454
  A1 = Two;
1455
  Done = false;
1456
  do
1457
    {
1458
      AInvrse = Radix;
1459
      do
1460
        {
1461
          X = AInvrse;
1462
          AInvrse = AInvrse / A1;
1463
        }
1464
      while (!(FLOOR (AInvrse) != AInvrse));
1465
      Done = (X == One) || (A1 > Three);
1466
      if (!Done)
1467
        A1 = Nine + One;
1468
    }
1469
  while (!(Done));
1470
  if (X == One)
1471
    A1 = Radix;
1472
  AInvrse = One / A1;
1473
  X = A1;
1474
  Y = AInvrse;
1475
  Done = false;
1476
  do
1477
    {
1478
      Z = X * Y - Half;
1479
      TstCond (Failure, Z == Half, "X * (1/X) differs from 1");
1480
      Done = X == Radix;
1481
      X = Radix;
1482
      Y = One / X;
1483
    }
1484
  while (!(Done));
1485
  Y2 = One + U2;
1486
  Y1 = One - U2;
1487
  X = OneAndHalf - U2;
1488
  Y = OneAndHalf + U2;
1489
  Z = (X - U2) * Y2;
1490
  T = Y * Y1;
1491
  Z = Z - X;
1492
  T = T - X;
1493
  X = X * Y2;
1494
  Y = (Y + U2) * Y1;
1495
  X = X - OneAndHalf;
1496
  Y = Y - OneAndHalf;
1497
  if ((X == Zero) && (Y == Zero) && (Z == Zero) && (T <= Zero))
1498
    {
1499
      X = (OneAndHalf + U2) * Y2;
1500
      Y = OneAndHalf - U2 - U2;
1501
      Z = OneAndHalf + U2 + U2;
1502
      T = (OneAndHalf - U2) * Y1;
1503
      X = X - (Z + U2);
1504
      StickyBit = Y * Y1;
1505
      S = Z * Y2;
1506
      T = T - Y;
1507
      Y = (U2 - Y) + StickyBit;
1508
      Z = S - (Z + U2 + U2);
1509
      StickyBit = (Y2 + U2) * Y1;
1510
      Y1 = Y2 * Y1;
1511
      StickyBit = StickyBit - Y2;
1512
      Y1 = Y1 - Half;
1513
      if ((X == Zero) && (Y == Zero) && (Z == Zero) && (T == Zero)
1514
          && (StickyBit == Zero) && (Y1 == Half))
1515
        {
1516
          RMult = Rounded;
1517
          printf ("Multiplication appears to round correctly.\n");
1518
        }
1519
      else if ((X + U2 == Zero) && (Y < Zero) && (Z + U2 == Zero)
1520
               && (T < Zero) && (StickyBit + U2 == Zero) && (Y1 < Half))
1521
        {
1522
          RMult = Chopped;
1523
          printf ("Multiplication appears to chop.\n");
1524
        }
1525
      else
1526
        printf ("* is neither chopped nor correctly rounded.\n");
1527
      if ((RMult == Rounded) && (GMult == No))
1528
        notify ("Multiplication");
1529
    }
1530
  else
1531
    printf ("* is neither chopped nor correctly rounded.\n");
1532
        /*=============================================*/
1533
  Milestone = 45;
1534
        /*=============================================*/
1535
  Y2 = One + U2;
1536
  Y1 = One - U2;
1537
  Z = OneAndHalf + U2 + U2;
1538
  X = Z / Y2;
1539
  T = OneAndHalf - U2 - U2;
1540
  Y = (T - U2) / Y1;
1541
  Z = (Z + U2) / Y2;
1542
  X = X - OneAndHalf;
1543
  Y = Y - T;
1544
  T = T / Y1;
1545
  Z = Z - (OneAndHalf + U2);
1546
  T = (U2 - OneAndHalf) + T;
1547
  if (!((X > Zero) || (Y > Zero) || (Z > Zero) || (T > Zero)))
1548
    {
1549
      X = OneAndHalf / Y2;
1550
      Y = OneAndHalf - U2;
1551
      Z = OneAndHalf + U2;
1552
      X = X - Y;
1553
      T = OneAndHalf / Y1;
1554
      Y = Y / Y1;
1555
      T = T - (Z + U2);
1556
      Y = Y - Z;
1557
      Z = Z / Y2;
1558
      Y1 = (Y2 + U2) / Y2;
1559
      Z = Z - OneAndHalf;
1560
      Y2 = Y1 - Y2;
1561
      Y1 = (F9 - U1) / F9;
1562
      if ((X == Zero) && (Y == Zero) && (Z == Zero) && (T == Zero)
1563
          && (Y2 == Zero) && (Y2 == Zero) && (Y1 - Half == F9 - Half))
1564
        {
1565
          RDiv = Rounded;
1566
          printf ("Division appears to round correctly.\n");
1567
          if (GDiv == No)
1568
            notify ("Division");
1569
        }
1570
      else if ((X < Zero) && (Y < Zero) && (Z < Zero) && (T < Zero)
1571
               && (Y2 < Zero) && (Y1 - Half < F9 - Half))
1572
        {
1573
          RDiv = Chopped;
1574
          printf ("Division appears to chop.\n");
1575
        }
1576
    }
1577
  if (RDiv == Other)
1578
    printf ("/ is neither chopped nor correctly rounded.\n");
1579
  BInvrse = One / Radix;
1580
  TstCond (Failure, (BInvrse * Radix - Half == Half),
1581
           "Radix * ( 1 / Radix ) differs from 1");
1582
        /*=============================================*/
1583
  Milestone = 50;
1584
        /*=============================================*/
1585
  TstCond (Failure, ((F9 + U1) - Half == Half)
1586
           && ((BMinusU2 + U2) - One == Radix - One),
1587
           "Incomplete carry-propagation in Addition");
1588
  X = One - U1 * U1;
1589
  Y = One + U2 * (One - U2);
1590
  Z = F9 - Half;
1591
  X = (X - Half) - Z;
1592
  Y = Y - One;
1593
  if ((X == Zero) && (Y == Zero))
1594
    {
1595
      RAddSub = Chopped;
1596
      printf ("Add/Subtract appears to be chopped.\n");
1597
    }
1598
  if (GAddSub == Yes)
1599
    {
1600
      X = (Half + U2) * U2;
1601
      Y = (Half - U2) * U2;
1602
      X = One + X;
1603
      Y = One + Y;
1604
      X = (One + U2) - X;
1605
      Y = One - Y;
1606
      if ((X == Zero) && (Y == Zero))
1607
        {
1608
          X = (Half + U2) * U1;
1609
          Y = (Half - U2) * U1;
1610
          X = One - X;
1611
          Y = One - Y;
1612
          X = F9 - X;
1613
          Y = One - Y;
1614
          if ((X == Zero) && (Y == Zero))
1615
            {
1616
              RAddSub = Rounded;
1617
              printf ("Addition/Subtraction appears to round correctly.\n");
1618
              if (GAddSub == No)
1619
                notify ("Add/Subtract");
1620
            }
1621
          else
1622
            printf ("Addition/Subtraction neither rounds nor chops.\n");
1623
        }
1624
      else
1625
        printf ("Addition/Subtraction neither rounds nor chops.\n");
1626
    }
1627
  else
1628
    printf ("Addition/Subtraction neither rounds nor chops.\n");
1629
  S = One;
1630
  X = One + Half * (One + Half);
1631
  Y = (One + U2) * Half;
1632
  Z = X - Y;
1633
  T = Y - X;
1634
  StickyBit = Z + T;
1635
  if (StickyBit != Zero)
1636
    {
1637
      S = Zero;
1638
      BadCond (Flaw, "(X - Y) + (Y - X) is non zero!\n");
1639
    }
1640
  StickyBit = Zero;
1641
  if ((GMult == Yes) && (GDiv == Yes) && (GAddSub == Yes)
1642
      && (RMult == Rounded) && (RDiv == Rounded)
1643
      && (RAddSub == Rounded) && (FLOOR (RadixD2) == RadixD2))
1644
    {
1645
      printf ("Checking for sticky bit.\n");
1646
      X = (Half + U1) * U2;
1647
      Y = Half * U2;
1648
      Z = One + Y;
1649
      T = One + X;
1650
      if ((Z - One <= Zero) && (T - One >= U2))
1651
        {
1652
          Z = T + Y;
1653
          Y = Z - X;
1654
          if ((Z - T >= U2) && (Y - T == Zero))
1655
            {
1656
              X = (Half + U1) * U1;
1657
              Y = Half * U1;
1658
              Z = One - Y;
1659
              T = One - X;
1660
              if ((Z - One == Zero) && (T - F9 == Zero))
1661
                {
1662
                  Z = (Half - U1) * U1;
1663
                  T = F9 - Z;
1664
                  Q = F9 - Y;
1665
                  if ((T - F9 == Zero) && (F9 - U1 - Q == Zero))
1666
                    {
1667
                      Z = (One + U2) * OneAndHalf;
1668
                      T = (OneAndHalf + U2) - Z + U2;
1669
                      X = One + Half / Radix;
1670
                      Y = One + Radix * U2;
1671
                      Z = X * Y;
1672
                      if (T == Zero && X + Radix * U2 - Z == Zero)
1673
                        {
1674
                          if (Radix != Two)
1675
                            {
1676
                              X = Two + U2;
1677
                              Y = X / Two;
1678
                              if ((Y - One == Zero))
1679
                                StickyBit = S;
1680
                            }
1681
                          else
1682
                            StickyBit = S;
1683
                        }
1684
                    }
1685
                }
1686
            }
1687
        }
1688
    }
1689
  if (StickyBit == One)
1690
    printf ("Sticky bit apparently used correctly.\n");
1691
  else
1692
    printf ("Sticky bit used incorrectly or not at all.\n");
1693
  TstCond (Flaw, !(GMult == No || GDiv == No || GAddSub == No ||
1694
                   RMult == Other || RDiv == Other || RAddSub == Other),
1695
           "lack(s) of guard digits or failure(s) to correctly round or chop\n\
1696
(noted above) count as one flaw in the final tally below");
1697
        /*=============================================*/
1698
  Milestone = 60;
1699
        /*=============================================*/
1700
  printf ("\n");
1701
  printf ("Does Multiplication commute?  ");
1702
  printf ("Testing on %d random pairs.\n", NoTrials);
1703
  Random9 = SQRT (FLOAT (3));
1704
  Random1 = Third;
1705
  I = 1;
1706
  do
1707
    {
1708
      X = Random ();
1709
      Y = Random ();
1710
      Z9 = Y * X;
1711
      Z = X * Y;
1712
      Z9 = Z - Z9;
1713
      I = I + 1;
1714
    }
1715
  while (!((I > NoTrials) || (Z9 != Zero)));
1716
  if (I == NoTrials)
1717
    {
1718
      Random1 = One + Half / Three;
1719
      Random2 = (U2 + U1) + One;
1720
      Z = Random1 * Random2;
1721
      Y = Random2 * Random1;
1722
      Z9 = (One + Half / Three) * ((U2 + U1) + One) - (One + Half /
1723
                                                       Three) * ((U2 + U1) +
1724
                                                                 One);
1725
    }
1726
  if (!((I == NoTrials) || (Z9 == Zero)))
1727
    BadCond (Defect, "X * Y == Y * X trial fails.\n");
1728
  else
1729
    printf ("     No failures found in %d integer pairs.\n", NoTrials);
1730
        /*=============================================*/
1731
  Milestone = 70;
1732
        /*=============================================*/
1733
  printf ("\nRunning test of square root(x).\n");
1734
  TstCond (Failure, (Zero == SQRT (Zero))
1735
           && (-Zero == SQRT (-Zero))
1736
           && (One == SQRT (One)), "Square root of 0.0, -0.0 or 1.0 wrong");
1737
  MinSqEr = Zero;
1738
  MaxSqEr = Zero;
1739
  J = Zero;
1740
  X = Radix;
1741
  OneUlp = U2;
1742
  SqXMinX (Serious);
1743
  X = BInvrse;
1744
  OneUlp = BInvrse * U1;
1745
  SqXMinX (Serious);
1746
  X = U1;
1747
  OneUlp = U1 * U1;
1748
  SqXMinX (Serious);
1749
  if (J != Zero)
1750
    Pause ();
1751
  printf ("Testing if sqrt(X * X) == X for %d Integers X.\n", NoTrials);
1752
  J = Zero;
1753
  X = Two;
1754
  Y = Radix;
1755
  if ((Radix != One))
1756
    do
1757
      {
1758
        X = Y;
1759
        Y = Radix * Y;
1760
      }
1761
    while (!((Y - X >= NoTrials)));
1762
  OneUlp = X * U2;
1763
  I = 1;
1764
  while (I <= NoTrials)
1765
    {
1766
      X = X + One;
1767
      SqXMinX (Defect);
1768
      if (J > Zero)
1769
        break;
1770
      I = I + 1;
1771
    }
1772
  printf ("Test for sqrt monotonicity.\n");
1773
  I = -1;
1774
  X = BMinusU2;
1775
  Y = Radix;
1776
  Z = Radix + Radix * U2;
1777
  NotMonot = false;
1778
  Monot = false;
1779
  while (!(NotMonot || Monot))
1780
    {
1781
      I = I + 1;
1782
      X = SQRT (X);
1783
      Q = SQRT (Y);
1784
      Z = SQRT (Z);
1785
      if ((X > Q) || (Q > Z))
1786
        NotMonot = true;
1787
      else
1788
        {
1789
          Q = FLOOR (Q + Half);
1790
          if (!(I > 0 || Radix == Q * Q))
1791
            Monot = true;
1792
          else if (I > 0)
1793
            {
1794
              if (I > 1)
1795
                Monot = true;
1796
              else
1797
                {
1798
                  Y = Y * BInvrse;
1799
                  X = Y - U1;
1800
                  Z = Y + U1;
1801
                }
1802
            }
1803
          else
1804
            {
1805
              Y = Q;
1806
              X = Y - U2;
1807
              Z = Y + U2;
1808
            }
1809
        }
1810
    }
1811
  if (Monot)
1812
    printf ("sqrt has passed a test for Monotonicity.\n");
1813
  else
1814
    {
1815
      BadCond (Defect, "");
1816
      printf ("sqrt(X) is non-monotonic for X near %s .\n", Y.str());
1817
    }
1818
        /*=============================================*/
1819
  Milestone = 110;
1820
        /*=============================================*/
1821
  printf ("Seeking Underflow thresholds UfThold and E0.\n");
1822
  D = U1;
1823
  if (Precision != FLOOR (Precision))
1824
    {
1825
      D = BInvrse;
1826
      X = Precision;
1827
      do
1828
        {
1829
          D = D * BInvrse;
1830
          X = X - One;
1831
        }
1832
      while (X > Zero);
1833
    }
1834
  Y = One;
1835
  Z = D;
1836
  /* ... D is power of 1/Radix < 1. */
1837
  do
1838
    {
1839
      C = Y;
1840
      Y = Z;
1841
      Z = Y * Y;
1842
    }
1843
  while ((Y > Z) && (Z + Z > Z));
1844
  Y = C;
1845
  Z = Y * D;
1846
  do
1847
    {
1848
      C = Y;
1849
      Y = Z;
1850
      Z = Y * D;
1851
    }
1852
  while ((Y > Z) && (Z + Z > Z));
1853
  if (Radix < Two)
1854
    HInvrse = Two;
1855
  else
1856
    HInvrse = Radix;
1857
  H = One / HInvrse;
1858
  /* ... 1/HInvrse == H == Min(1/Radix, 1/2) */
1859
  CInvrse = One / C;
1860
  E0 = C;
1861
  Z = E0 * H;
1862
  /* ...1/Radix^(BIG Integer) << 1 << CInvrse == 1/C */
1863
  do
1864
    {
1865
      Y = E0;
1866
      E0 = Z;
1867
      Z = E0 * H;
1868
    }
1869
  while ((E0 > Z) && (Z + Z > Z));
1870
  UfThold = E0;
1871
  E1 = Zero;
1872
  Q = Zero;
1873
  E9 = U2;
1874
  S = One + E9;
1875
  D = C * S;
1876
  if (D <= C)
1877
    {
1878
      E9 = Radix * U2;
1879
      S = One + E9;
1880
      D = C * S;
1881
      if (D <= C)
1882
        {
1883
          BadCond (Failure,
1884
                   "multiplication gets too many last digits wrong.\n");
1885
          Underflow = E0;
1886
          Y1 = Zero;
1887
          PseudoZero = Z;
1888
          Pause ();
1889
        }
1890
    }
1891
  else
1892
    {
1893
      Underflow = D;
1894
      PseudoZero = Underflow * H;
1895
      UfThold = Zero;
1896
      do
1897
        {
1898
          Y1 = Underflow;
1899
          Underflow = PseudoZero;
1900
          if (E1 + E1 <= E1)
1901
            {
1902
              Y2 = Underflow * HInvrse;
1903
              E1 = FABS (Y1 - Y2);
1904
              Q = Y1;
1905
              if ((UfThold == Zero) && (Y1 != Y2))
1906
                UfThold = Y1;
1907
            }
1908
          PseudoZero = PseudoZero * H;
1909
        }
1910
      while ((Underflow > PseudoZero)
1911
             && (PseudoZero + PseudoZero > PseudoZero));
1912
    }
1913
  /* Comment line 4530 .. 4560 */
1914
  if (PseudoZero != Zero)
1915
    {
1916
      printf ("\n");
1917
      Z = PseudoZero;
1918
      /* ... Test PseudoZero for "phoney- zero" violates */
1919
      /* ... PseudoZero < Underflow or PseudoZero < PseudoZero + PseudoZero
1920
         ... */
1921
      if (PseudoZero <= Zero)
1922
        {
1923
          BadCond (Failure, "Positive expressions can underflow to an\n");
1924
          printf ("allegedly negative value\n");
1925
          printf ("PseudoZero that prints out as: %s .\n", PseudoZero.str());
1926
          X = -PseudoZero;
1927
          if (X <= Zero)
1928
            {
1929
              printf ("But -PseudoZero, which should be\n");
1930
              printf ("positive, isn't; it prints out as  %s .\n", X.str());
1931
            }
1932
        }
1933
      else
1934
        {
1935
          BadCond (Flaw, "Underflow can stick at an allegedly positive\n");
1936
          printf ("value PseudoZero that prints out as %s .\n",
1937
                  PseudoZero.str());
1938
        }
1939
      TstPtUf ();
1940
    }
1941
        /*=============================================*/
1942
  Milestone = 120;
1943
        /*=============================================*/
1944
  if (CInvrse * Y > CInvrse * Y1)
1945
    {
1946
      S = H * S;
1947
      E0 = Underflow;
1948
    }
1949
  if (!((E1 == Zero) || (E1 == E0)))
1950
    {
1951
      BadCond (Defect, "");
1952
      if (E1 < E0)
1953
        {
1954
          printf ("Products underflow at a higher");
1955
          printf (" threshold than differences.\n");
1956
          if (PseudoZero == Zero)
1957
            E0 = E1;
1958
        }
1959
      else
1960
        {
1961
          printf ("Difference underflows at a higher");
1962
          printf (" threshold than products.\n");
1963
        }
1964
    }
1965
  printf ("Smallest strictly positive number found is E0 = %s .\n", E0.str());
1966
  Z = E0;
1967
  TstPtUf ();
1968
  Underflow = E0;
1969
  if (N == 1)
1970
    Underflow = Y;
1971
  I = 4;
1972
  if (E1 == Zero)
1973
    I = 3;
1974
  if (UfThold == Zero)
1975
    I = I - 2;
1976
  UfNGrad = true;
1977
  switch (I)
1978
    {
1979
    case 1:
1980
      UfThold = Underflow;
1981
      if ((CInvrse * Q) != ((CInvrse * Y) * S))
1982
        {
1983
          UfThold = Y;
1984
          BadCond (Failure, "Either accuracy deteriorates as numbers\n");
1985
          printf ("approach a threshold = %s\n", UfThold.str());
1986
          printf (" coming down from %s\n", C.str());
1987
          printf
1988
            (" or else multiplication gets too many last digits wrong.\n");
1989
        }
1990
      Pause ();
1991
      break;
1992
 
1993
    case 2:
1994
      BadCond (Failure,
1995
               "Underflow confuses Comparison, which alleges that\n");
1996
      printf ("Q == Y while denying that |Q - Y| == 0; these values\n");
1997
      printf ("print out as Q = %s, Y = %s .\n", Q.str(), Y2.str());
1998
      printf ("|Q - Y| = %s .\n", FABS (Q - Y2).str());
1999
      UfThold = Q;
2000
      break;
2001
 
2002
    case 3:
2003
      X = X;
2004
      break;
2005
 
2006
    case 4:
2007
      if ((Q == UfThold) && (E1 == E0) && (FABS (UfThold - E1 / E9) <= E1))
2008
        {
2009
          UfNGrad = false;
2010
          printf ("Underflow is gradual; it incurs Absolute Error =\n");
2011
          printf ("(roundoff in UfThold) < E0.\n");
2012
          Y = E0 * CInvrse;
2013
          Y = Y * (OneAndHalf + U2);
2014
          X = CInvrse * (One + U2);
2015
          Y = Y / X;
2016
          IEEE = (Y == E0);
2017
        }
2018
    }
2019
  if (UfNGrad)
2020
    {
2021
      printf ("\n");
2022
      if (setjmp (ovfl_buf))
2023
        {
2024
          printf ("Underflow / UfThold failed!\n");
2025
          R = H + H;
2026
        }
2027
      else
2028
        R = SQRT (Underflow / UfThold);
2029
      if (R <= H)
2030
        {
2031
          Z = R * UfThold;
2032
          X = Z * (One + R * H * (One + H));
2033
        }
2034
      else
2035
        {
2036
          Z = UfThold;
2037
          X = Z * (One + H * H * (One + H));
2038
        }
2039
      if (!((X == Z) || (X - Z != Zero)))
2040
        {
2041
          BadCond (Flaw, "");
2042
          printf ("X = %s\n\tis not equal to Z = %s .\n", X.str(), Z.str());
2043
          Z9 = X - Z;
2044
          printf ("yet X - Z yields %s .\n", Z9.str());
2045
          printf ("    Should this NOT signal Underflow, ");
2046
          printf ("this is a SERIOUS DEFECT\nthat causes ");
2047
          printf ("confusion when innocent statements like\n");;
2048
          printf ("    if (X == Z)  ...  else");
2049
          printf ("  ... (f(X) - f(Z)) / (X - Z) ...\n");
2050
          printf ("encounter Division by Zero although actually\n");
2051
          if (setjmp (ovfl_buf))
2052
            printf ("X / Z fails!\n");
2053
          else
2054
            printf ("X / Z = 1 + %s .\n", ((X / Z - Half) - Half).str());
2055
        }
2056
    }
2057
  printf ("The Underflow threshold is %s, below which\n", UfThold.str());
2058
  printf ("calculation may suffer larger Relative error than ");
2059
  printf ("merely roundoff.\n");
2060
  Y2 = U1 * U1;
2061
  Y = Y2 * Y2;
2062
  Y2 = Y * U1;
2063
  if (Y2 <= UfThold)
2064
    {
2065
      if (Y > E0)
2066
        {
2067
          BadCond (Defect, "");
2068
          I = 5;
2069
        }
2070
      else
2071
        {
2072
          BadCond (Serious, "");
2073
          I = 4;
2074
        }
2075
      printf ("Range is too narrow; U1^%d Underflows.\n", I);
2076
    }
2077
        /*=============================================*/
2078
  Milestone = 130;
2079
        /*=============================================*/
2080
  Y = -FLOOR (Half - TwoForty * LOG (UfThold) / LOG (HInvrse)) / TwoForty;
2081
  Y2 = Y + Y;
2082
  printf ("Since underflow occurs below the threshold\n");
2083
  printf ("UfThold = (%s) ^ (%s)\nonly underflow ", HInvrse.str(), Y.str());
2084
  printf ("should afflict the expression\n\t(%s) ^ (%s);\n",
2085
          HInvrse.str(), Y2.str());
2086
  printf ("actually calculating yields:");
2087
  if (setjmp (ovfl_buf))
2088
    {
2089
      BadCond (Serious, "trap on underflow.\n");
2090
    }
2091
  else
2092
    {
2093
      V9 = POW (HInvrse, Y2);
2094
      printf (" %s .\n", V9.str());
2095
      if (!((V9 >= Zero) && (V9 <= (Radix + Radix + E9) * UfThold)))
2096
        {
2097
          BadCond (Serious, "this is not between 0 and underflow\n");
2098
          printf ("   threshold = %s .\n", UfThold.str());
2099
        }
2100
      else if (!(V9 > UfThold * (One + E9)))
2101
        printf ("This computed value is O.K.\n");
2102
      else
2103
        {
2104
          BadCond (Defect, "this is not between 0 and underflow\n");
2105
          printf ("   threshold = %s .\n", UfThold.str());
2106
        }
2107
    }
2108
        /*=============================================*/
2109
  Milestone = 160;
2110
        /*=============================================*/
2111
  Pause ();
2112
  printf ("Searching for Overflow threshold:\n");
2113
  printf ("This may generate an error.\n");
2114
  Y = -CInvrse;
2115
  V9 = HInvrse * Y;
2116
  if (setjmp (ovfl_buf))
2117
    {
2118
      I = 0;
2119
      V9 = Y;
2120
      goto overflow;
2121
    }
2122
  do
2123
    {
2124
      V = Y;
2125
      Y = V9;
2126
      V9 = HInvrse * Y;
2127
    }
2128
  while (V9 < Y);
2129
  I = 1;
2130
overflow:
2131
  Z = V9;
2132
  printf ("Can `Z = -Y' overflow?\n");
2133
  printf ("Trying it on Y = %s .\n", Y.str());
2134
  V9 = -Y;
2135
  V0 = V9;
2136
  if (V - Y == V + V0)
2137
    printf ("Seems O.K.\n");
2138
  else
2139
    {
2140
      printf ("finds a ");
2141
      BadCond (Flaw, "-(-Y) differs from Y.\n");
2142
    }
2143
  if (Z != Y)
2144
    {
2145
      BadCond (Serious, "");
2146
      printf ("overflow past %s\n\tshrinks to %s .\n", Y.str(), Z.str());
2147
    }
2148
  if (I)
2149
    {
2150
      Y = V * (HInvrse * U2 - HInvrse);
2151
      Z = Y + ((One - HInvrse) * U2) * V;
2152
      if (Z < V0)
2153
        Y = Z;
2154
      if (Y < V0)
2155
        V = Y;
2156
      if (V0 - V < V0)
2157
        V = V0;
2158
    }
2159
  else
2160
    {
2161
      V = Y * (HInvrse * U2 - HInvrse);
2162
      V = V + ((One - HInvrse) * U2) * Y;
2163
    }
2164
  printf ("Overflow threshold is V  = %s .\n", V.str());
2165
  if (I)
2166
    printf ("Overflow saturates at V0 = %s .\n", V0.str());
2167
  else
2168
    printf ("There is no saturation value because "
2169
            "the system traps on overflow.\n");
2170
  V9 = V * One;
2171
  printf ("No Overflow should be signaled for V * 1 = %s\n", V9.str());
2172
  V9 = V / One;
2173
  printf ("                           nor for V / 1 = %s.\n", V9.str());
2174
  printf ("Any overflow signal separating this * from the one\n");
2175
  printf ("above is a DEFECT.\n");
2176
        /*=============================================*/
2177
  Milestone = 170;
2178
        /*=============================================*/
2179
  if (!(-V < V && -V0 < V0 && -UfThold < V && UfThold < V))
2180
    {
2181
      BadCond (Failure, "Comparisons involving ");
2182
      printf ("+-%s, +-%s\nand +-%s are confused by Overflow.",
2183
              V.str(), V0.str(), UfThold.str());
2184
    }
2185
        /*=============================================*/
2186
  Milestone = 175;
2187
        /*=============================================*/
2188
  printf ("\n");
2189
  for (Indx = 1; Indx <= 3; ++Indx)
2190
    {
2191
      switch (Indx)
2192
        {
2193
        case 1:
2194
          Z = UfThold;
2195
          break;
2196
        case 2:
2197
          Z = E0;
2198
          break;
2199
        case 3:
2200
          Z = PseudoZero;
2201
          break;
2202
        }
2203
      if (Z != Zero)
2204
        {
2205
          V9 = SQRT (Z);
2206
          Y = V9 * V9;
2207
          if (Y / (One - Radix * E9) < Z || Y > (One + Radix * E9) * Z)
2208
            {                   /* dgh: + E9 --> * E9 */
2209
              if (V9 > U1)
2210
                BadCond (Serious, "");
2211
              else
2212
                BadCond (Defect, "");
2213
              printf ("Comparison alleges that what prints as Z = %s\n",
2214
                      Z.str());
2215
              printf (" is too far from sqrt(Z) ^ 2 = %s .\n", Y.str());
2216
            }
2217
        }
2218
    }
2219
        /*=============================================*/
2220
  Milestone = 180;
2221
        /*=============================================*/
2222
  for (Indx = 1; Indx <= 2; ++Indx)
2223
    {
2224
      if (Indx == 1)
2225
        Z = V;
2226
      else
2227
        Z = V0;
2228
      V9 = SQRT (Z);
2229
      X = (One - Radix * E9) * V9;
2230
      V9 = V9 * X;
2231
      if (((V9 < (One - Two * Radix * E9) * Z) || (V9 > Z)))
2232
        {
2233
          Y = V9;
2234
          if (X < W)
2235
            BadCond (Serious, "");
2236
          else
2237
            BadCond (Defect, "");
2238
          printf ("Comparison alleges that Z = %s\n", Z.str());
2239
          printf (" is too far from sqrt(Z) ^ 2 (%s) .\n", Y.str());
2240
        }
2241
    }
2242
        /*=============================================*/
2243
  Milestone = 190;
2244
        /*=============================================*/
2245
  Pause ();
2246
  X = UfThold * V;
2247
  Y = Radix * Radix;
2248
  if (X * Y < One || X > Y)
2249
    {
2250
      if (X * Y < U1 || X > Y / U1)
2251
        BadCond (Defect, "Badly");
2252
      else
2253
        BadCond (Flaw, "");
2254
 
2255
      printf (" unbalanced range; UfThold * V = %s\n\t%s\n",
2256
              X.str(), "is too far from 1.\n");
2257
    }
2258
        /*=============================================*/
2259
  Milestone = 200;
2260
        /*=============================================*/
2261
  for (Indx = 1; Indx <= 5; ++Indx)
2262
    {
2263
      X = F9;
2264
      switch (Indx)
2265
        {
2266
        case 2:
2267
          X = One + U2;
2268
          break;
2269
        case 3:
2270
          X = V;
2271
          break;
2272
        case 4:
2273
          X = UfThold;
2274
          break;
2275
        case 5:
2276
          X = Radix;
2277
        }
2278
      Y = X;
2279
      if (setjmp (ovfl_buf))
2280
        printf ("  X / X  traps when X = %s\n", X.str());
2281
      else
2282
        {
2283
          V9 = (Y / X - Half) - Half;
2284
          if (V9 == Zero)
2285
            continue;
2286
          if (V9 == -U1 && Indx < 5)
2287
            BadCond (Flaw, "");
2288
          else
2289
            BadCond (Serious, "");
2290
          printf ("  X / X differs from 1 when X = %s\n", X.str());
2291
          printf ("  instead, X / X - 1/2 - 1/2 = %s .\n", V9.str());
2292
        }
2293
    }
2294
        /*=============================================*/
2295
  Milestone = 210;
2296
        /*=============================================*/
2297
  MyZero = Zero;
2298
  printf ("\n");
2299
  printf ("What message and/or values does Division by Zero produce?\n");
2300
  printf ("    Trying to compute 1 / 0 produces ...");
2301
  if (!setjmp (ovfl_buf))
2302
    printf ("  %s .\n", (One / MyZero).str());
2303
  printf ("\n    Trying to compute 0 / 0 produces ...");
2304
  if (!setjmp (ovfl_buf))
2305
    printf ("  %s .\n", (Zero / MyZero).str());
2306
        /*=============================================*/
2307
  Milestone = 220;
2308
        /*=============================================*/
2309
  Pause ();
2310
  printf ("\n");
2311
  {
2312
    static const char *msg[] = {
2313
      "FAILUREs  encountered =",
2314
      "SERIOUS DEFECTs  discovered =",
2315
      "DEFECTs  discovered =",
2316
      "FLAWs  discovered ="
2317
    };
2318
    int i;
2319
    for (i = 0; i < 4; i++)
2320
      if (ErrCnt[i])
2321
        printf ("The number of  %-29s %d.\n", msg[i], ErrCnt[i]);
2322
  }
2323
  printf ("\n");
2324
  if ((ErrCnt[Failure] + ErrCnt[Serious] + ErrCnt[Defect] + ErrCnt[Flaw]) > 0)
2325
    {
2326
      if ((ErrCnt[Failure] + ErrCnt[Serious] + ErrCnt[Defect] == 0)
2327
          && (ErrCnt[Flaw] > 0))
2328
        {
2329
          printf ("The arithmetic diagnosed seems ");
2330
          printf ("Satisfactory though flawed.\n");
2331
        }
2332
      if ((ErrCnt[Failure] + ErrCnt[Serious] == 0) && (ErrCnt[Defect] > 0))
2333
        {
2334
          printf ("The arithmetic diagnosed may be Acceptable\n");
2335
          printf ("despite inconvenient Defects.\n");
2336
        }
2337
      if ((ErrCnt[Failure] + ErrCnt[Serious]) > 0)
2338
        {
2339
          printf ("The arithmetic diagnosed has ");
2340
          printf ("unacceptable Serious Defects.\n");
2341
        }
2342
      if (ErrCnt[Failure] > 0)
2343
        {
2344
          printf ("Potentially fatal FAILURE may have spoiled this");
2345
          printf (" program's subsequent diagnoses.\n");
2346
        }
2347
    }
2348
  else
2349
    {
2350
      printf ("No failures, defects nor flaws have been discovered.\n");
2351
      if (!((RMult == Rounded) && (RDiv == Rounded)
2352
            && (RAddSub == Rounded) && (RSqrt == Rounded)))
2353
        printf ("The arithmetic diagnosed seems Satisfactory.\n");
2354
      else
2355
        {
2356
          if (StickyBit >= One &&
2357
              (Radix - Two) * (Radix - Nine - One) == Zero)
2358
            {
2359
              printf ("Rounding appears to conform to ");
2360
              printf ("the proposed IEEE standard P");
2361
              if ((Radix == Two) &&
2362
                  ((Precision - Four * Three * Two) *
2363
                   (Precision - TwentySeven - TwentySeven + One) == Zero))
2364
                printf ("754");
2365
              else
2366
                printf ("854");
2367
              if (IEEE)
2368
                printf (".\n");
2369
              else
2370
                {
2371
                  printf (",\nexcept for possibly Double Rounding");
2372
                  printf (" during Gradual Underflow.\n");
2373
                }
2374
            }
2375
          printf ("The arithmetic diagnosed appears to be Excellent!\n");
2376
        }
2377
    }
2378
  printf ("END OF TEST.\n");
2379
  return 0;
2380
}
2381
 
2382
template<typename FLOAT>
2383
FLOAT
2384
Paranoia<FLOAT>::Sign (FLOAT X)
2385
{
2386
  return X >= FLOAT (long (0)) ? 1 : -1;
2387
}
2388
 
2389
template<typename FLOAT>
2390
void
2391
Paranoia<FLOAT>::Pause ()
2392
{
2393
  if (do_pause)
2394
    {
2395
      fputs ("Press return...", stdout);
2396
      fflush (stdout);
2397
      getchar();
2398
    }
2399
  printf ("\nDiagnosis resumes after milestone Number %d", Milestone);
2400
  printf ("          Page: %d\n\n", PageNo);
2401
  ++Milestone;
2402
  ++PageNo;
2403
}
2404
 
2405
template<typename FLOAT>
2406
void
2407
Paranoia<FLOAT>::TstCond (int K, int Valid, const char *T)
2408
{
2409
  if (!Valid)
2410
    {
2411
      BadCond (K, T);
2412
      printf (".\n");
2413
    }
2414
}
2415
 
2416
template<typename FLOAT>
2417
void
2418
Paranoia<FLOAT>::BadCond (int K, const char *T)
2419
{
2420
  static const char *msg[] = { "FAILURE", "SERIOUS DEFECT", "DEFECT", "FLAW" };
2421
 
2422
  ErrCnt[K] = ErrCnt[K] + 1;
2423
  printf ("%s:  %s", msg[K], T);
2424
}
2425
 
2426
/* Random computes
2427
     X = (Random1 + Random9)^5
2428
     Random1 = X - FLOOR(X) + 0.000005 * X;
2429
   and returns the new value of Random1.  */
2430
 
2431
template<typename FLOAT>
2432
FLOAT
2433
Paranoia<FLOAT>::Random ()
2434
{
2435
  FLOAT X, Y;
2436
 
2437
  X = Random1 + Random9;
2438
  Y = X * X;
2439
  Y = Y * Y;
2440
  X = X * Y;
2441
  Y = X - FLOOR (X);
2442
  Random1 = Y + X * FLOAT ("0.000005");
2443
  return (Random1);
2444
}
2445
 
2446
template<typename FLOAT>
2447
void
2448
Paranoia<FLOAT>::SqXMinX (int ErrKind)
2449
{
2450
  FLOAT XA, XB;
2451
 
2452
  XB = X * BInvrse;
2453
  XA = X - XB;
2454
  SqEr = ((SQRT (X * X) - XB) - XA) / OneUlp;
2455
  if (SqEr != Zero)
2456
    {
2457
      if (SqEr < MinSqEr)
2458
        MinSqEr = SqEr;
2459
      if (SqEr > MaxSqEr)
2460
        MaxSqEr = SqEr;
2461
      J = J + 1;
2462
      BadCond (ErrKind, "\n");
2463
      printf ("sqrt(%s) - %s  = %s\n", (X * X).str(), X.str(),
2464
              (OneUlp * SqEr).str());
2465
      printf ("\tinstead of correct value 0 .\n");
2466
    }
2467
}
2468
 
2469
template<typename FLOAT>
2470
void
2471
Paranoia<FLOAT>::NewD ()
2472
{
2473
  X = Z1 * Q;
2474
  X = FLOOR (Half - X / Radix) * Radix + X;
2475
  Q = (Q - X * Z) / Radix + X * X * (D / Radix);
2476
  Z = Z - Two * X * D;
2477
  if (Z <= Zero)
2478
    {
2479
      Z = -Z;
2480
      Z1 = -Z1;
2481
    }
2482
  D = Radix * D;
2483
}
2484
 
2485
template<typename FLOAT>
2486
void
2487
Paranoia<FLOAT>::SR3750 ()
2488
{
2489
  if (!((X - Radix < Z2 - Radix) || (X - Z2 > W - Z2)))
2490
    {
2491
      I = I + 1;
2492
      X2 = SQRT (X * D);
2493
      Y2 = (X2 - Z2) - (Y - Z2);
2494
      X2 = X8 / (Y - Half);
2495
      X2 = X2 - Half * X2 * X2;
2496
      SqEr = (Y2 + Half) + (Half - X2);
2497
      if (SqEr < MinSqEr)
2498
        MinSqEr = SqEr;
2499
      SqEr = Y2 - X2;
2500
      if (SqEr > MaxSqEr)
2501
        MaxSqEr = SqEr;
2502
    }
2503
}
2504
 
2505
template<typename FLOAT>
2506
void
2507
Paranoia<FLOAT>::IsYeqX ()
2508
{
2509
  if (Y != X)
2510
    {
2511
      if (N <= 0)
2512
        {
2513
          if (Z == Zero && Q <= Zero)
2514
            printf ("WARNING:  computing\n");
2515
          else
2516
            BadCond (Defect, "computing\n");
2517
          printf ("\t(%s) ^ (%s)\n", Z.str(), Q.str());
2518
          printf ("\tyielded %s;\n", Y.str());
2519
          printf ("\twhich compared unequal to correct %s ;\n", X.str());
2520
          printf ("\t\tthey differ by %s .\n", (Y - X).str());
2521
        }
2522
      N = N + 1;                /* ... count discrepancies. */
2523
    }
2524
}
2525
 
2526
template<typename FLOAT>
2527
void
2528
Paranoia<FLOAT>::PrintIfNPositive ()
2529
{
2530
  if (N > 0)
2531
    printf ("Similar discrepancies have occurred %d times.\n", N);
2532
}
2533
 
2534
template<typename FLOAT>
2535
void
2536
Paranoia<FLOAT>::TstPtUf ()
2537
{
2538
  N = 0;
2539
  if (Z != Zero)
2540
    {
2541
      printf ("Since comparison denies Z = 0, evaluating ");
2542
      printf ("(Z + Z) / Z should be safe.\n");
2543
      if (setjmp (ovfl_buf))
2544
        goto very_serious;
2545
      Q9 = (Z + Z) / Z;
2546
      printf ("What the machine gets for (Z + Z) / Z is %s .\n", Q9.str());
2547
      if (FABS (Q9 - Two) < Radix * U2)
2548
        {
2549
          printf ("This is O.K., provided Over/Underflow");
2550
          printf (" has NOT just been signaled.\n");
2551
        }
2552
      else
2553
        {
2554
          if ((Q9 < One) || (Q9 > Two))
2555
            {
2556
            very_serious:
2557
              N = 1;
2558
              ErrCnt[Serious] = ErrCnt[Serious] + 1;
2559
              printf ("This is a VERY SERIOUS DEFECT!\n");
2560
            }
2561
          else
2562
            {
2563
              N = 1;
2564
              ErrCnt[Defect] = ErrCnt[Defect] + 1;
2565
              printf ("This is a DEFECT!\n");
2566
            }
2567
        }
2568
      V9 = Z * One;
2569
      Random1 = V9;
2570
      V9 = One * Z;
2571
      Random2 = V9;
2572
      V9 = Z / One;
2573
      if ((Z == Random1) && (Z == Random2) && (Z == V9))
2574
        {
2575
          if (N > 0)
2576
            Pause ();
2577
        }
2578
      else
2579
        {
2580
          N = 1;
2581
          BadCond (Defect, "What prints as Z = ");
2582
          printf ("%s\n\tcompares different from  ", Z.str());
2583
          if (Z != Random1)
2584
            printf ("Z * 1 = %s ", Random1.str());
2585
          if (!((Z == Random2) || (Random2 == Random1)))
2586
            printf ("1 * Z == %s\n", Random2.str());
2587
          if (!(Z == V9))
2588
            printf ("Z / 1 = %s\n", V9.str());
2589
          if (Random2 != Random1)
2590
            {
2591
              ErrCnt[Defect] = ErrCnt[Defect] + 1;
2592
              BadCond (Defect, "Multiplication does not commute!\n");
2593
              printf ("\tComparison alleges that 1 * Z = %s\n", Random2.str());
2594
              printf ("\tdiffers from Z * 1 = %s\n", Random1.str());
2595
            }
2596
          Pause ();
2597
        }
2598
    }
2599
}
2600
 
2601
template<typename FLOAT>
2602
void
2603
Paranoia<FLOAT>::notify (const char *s)
2604
{
2605
  printf ("%s test appears to be inconsistent...\n", s);
2606
  printf ("   PLEASE NOTIFY KARPINKSI!\n");
2607
}
2608
 
2609
/* ====================================================================== */
2610
 
2611
int main(int ac, char **av)
2612
{
2613
  setbuf(stdout, NULL);
2614
  setbuf(stderr, NULL);
2615
 
2616
  while (1)
2617
    switch (getopt (ac, av, "pvg:fdl"))
2618
      {
2619
      case -1:
2620
        return 0;
2621
      case 'p':
2622
        do_pause = true;
2623
        break;
2624
      case 'v':
2625
        verbose = true;
2626
        break;
2627
      case 'g':
2628
        {
2629
          static const struct {
2630
            const char *name;
2631
            const struct real_format *fmt;
2632
          } fmts[] = {
2633
#define F(x) { #x, &x##_format }
2634
            F(ieee_single),
2635
            F(ieee_double),
2636
            F(ieee_extended_motorola),
2637
            F(ieee_extended_intel_96),
2638
            F(ieee_extended_intel_128),
2639
            F(ibm_extended),
2640
            F(ieee_quad),
2641
            F(vax_f),
2642
            F(vax_d),
2643
            F(vax_g),
2644
            F(i370_single),
2645
            F(i370_double),
2646
            F(c4x_single),
2647
            F(c4x_extended),
2648
            F(real_internal),
2649
#undef F
2650
          };
2651
 
2652
          int i, n = sizeof (fmts)/sizeof(*fmts);
2653
 
2654
          for (i = 0; i < n; ++i)
2655
            if (strcmp (fmts[i].name, optarg) == 0)
2656
              break;
2657
 
2658
          if (i == n)
2659
            {
2660
              printf ("Unknown implementation \"%s\"; "
2661
                      "available implementations:\n", optarg);
2662
              for (i = 0; i < n; ++i)
2663
                printf ("\t%s\n", fmts[i].name);
2664
              return 1;
2665
            }
2666
 
2667
          // We cheat and use the same mode all the time, but vary
2668
          // the format used for that mode.
2669
          real_format_for_mode[int(real_c_float::MODE) - int(QFmode)]
2670
            = fmts[i].fmt;
2671
 
2672
          Paranoia<real_c_float>().main();
2673
          break;
2674
        }
2675
 
2676
      case 'f':
2677
        Paranoia < native_float<float> >().main();
2678
        break;
2679
      case 'd':
2680
        Paranoia < native_float<double> >().main();
2681
        break;
2682
      case 'l':
2683
#ifndef NO_LONG_DOUBLE
2684
        Paranoia < native_float<long double> >().main();
2685
#endif
2686
        break;
2687
 
2688
      case '?':
2689
        puts ("-p\tpause between pages");
2690
        puts ("-g<FMT>\treal.c implementation FMT");
2691
        puts ("-f\tnative float");
2692
        puts ("-d\tnative double");
2693
        puts ("-l\tnative long double");
2694
        return 0;
2695
      }
2696
}
2697
 
2698
/* GCC stuff referenced by real.o.  */
2699
 
2700
extern "C" void
2701
fancy_abort ()
2702
{
2703
  abort ();
2704
}
2705
 
2706
int target_flags = 0;
2707
 
2708
extern "C" int
2709
floor_log2_wide (unsigned HOST_WIDE_INT x)
2710
{
2711
  int log = -1;
2712
  while (x != 0)
2713
    log++,
2714
    x >>= 1;
2715
  return log;
2716
}

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