1 /* Test of POSIX compatible vsprintf() and sprintf() functions.
2 Copyright (C) 2007-2008 Free Software Foundation, Inc.
4 This program is free software: you can redistribute it and/or modify
5 it under the terms of the GNU General Public License as published by
6 the Free Software Foundation; either version 3 of the License, or
7 (at your option) any later version.
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program. If not, see <http://www.gnu.org/licenses/>. */
17 /* Written by Bruno Haible <bruno@clisp.org>, 2007. */
21 /* The SGI MIPS floating-point format does not distinguish 0.0 and -0.0. */
25 static double plus_zero = 0.0;
26 double minus_zero = - plus_zero;
27 return memcmp (&plus_zero, &minus_zero, sizeof (double)) != 0;
30 /* HP cc on HP-UX 10.20 has a bug with the constant expression -0.0.
31 So we use -zerod instead. */
34 /* On HP-UX 10.20, negating 0.0L does not yield -0.0L.
35 So we use minus_zerol instead.
36 Note that the expression -LDBL_MIN * LDBL_MIN does not work on other
37 platforms, such as when cross-compiling to PowerPC on MacOS X 10.5. */
38 #if defined __hpux || defined __sgi
39 long double minus_zerol = -LDBL_MIN * LDBL_MIN;
41 long double minus_zerol = -0.0L;
44 /* Representation of an 80-bit 'long double' as an initializer for a sequence
45 of 'unsigned int' words. */
46 #ifdef WORDS_BIGENDIAN
47 # define LDBL80_WORDS(exponent,manthi,mantlo) \
48 { ((unsigned int) (exponent) << 16) | ((unsigned int) (manthi) >> 16), \
49 ((unsigned int) (manthi) << 16) | (unsigned int) (mantlo) >> 16), \
50 (unsigned int) (mantlo) << 16 \
53 # define LDBL80_WORDS(exponent,manthi,mantlo) \
54 { mantlo, manthi, exponent }
58 strmatch (const char *pattern, const char *string)
60 if (strlen (pattern) != strlen (string))
62 for (; *pattern != '\0'; pattern++, string++)
63 if (*pattern != '*' && *string != *pattern)
68 /* Test whether string[start_index..end_index-1] is a valid textual
69 representation of NaN. */
71 strisnan (const char *string, size_t start_index, size_t end_index, int uppercase)
73 if (start_index < end_index)
75 if (string[start_index] == '-')
77 if (start_index + 3 <= end_index
78 && memcmp (string + start_index, uppercase ? "NAN" : "nan", 3) == 0)
81 if (start_index == end_index
82 || (string[start_index] == '(' && string[end_index - 1] == ')'))
90 test_function (int (*my_sprintf) (char *, const char *, ...))
94 /* Test return value convention. */
99 memcpy (buf, "DEADBEEF", 8);
100 retval = my_sprintf (buf, "%d", 12345);
101 ASSERT (retval == 5);
102 ASSERT (memcmp (buf, "12345\0EF", 8) == 0);
105 /* Test support of size specifiers as in C99. */
110 my_sprintf (result, "%ju %d", (uintmax_t) 12345671, 33, 44, 55);
111 ASSERT (strcmp (result, "12345671 33") == 0);
112 ASSERT (retval == strlen (result));
118 my_sprintf (result, "%zu %d", (size_t) 12345672, 33, 44, 55);
119 ASSERT (strcmp (result, "12345672 33") == 0);
120 ASSERT (retval == strlen (result));
126 my_sprintf (result, "%tu %d", (ptrdiff_t) 12345673, 33, 44, 55);
127 ASSERT (strcmp (result, "12345673 33") == 0);
128 ASSERT (retval == strlen (result));
134 my_sprintf (result, "%Lg %d", (long double) 1.5, 33, 44, 55);
135 ASSERT (strcmp (result, "1.5 33") == 0);
136 ASSERT (retval == strlen (result));
139 /* Test the support of the 'a' and 'A' conversion specifier for hexadecimal
140 output of floating-point numbers. */
142 { /* A positive number. */
145 my_sprintf (result, "%a %d", 3.1416015625, 33, 44, 55);
146 ASSERT (strcmp (result, "0x1.922p+1 33") == 0
147 || strcmp (result, "0x3.244p+0 33") == 0
148 || strcmp (result, "0x6.488p-1 33") == 0
149 || strcmp (result, "0xc.91p-2 33") == 0);
150 ASSERT (retval == strlen (result));
153 { /* A negative number. */
156 my_sprintf (result, "%A %d", -3.1416015625, 33, 44, 55);
157 ASSERT (strcmp (result, "-0X1.922P+1 33") == 0
158 || strcmp (result, "-0X3.244P+0 33") == 0
159 || strcmp (result, "-0X6.488P-1 33") == 0
160 || strcmp (result, "-0XC.91P-2 33") == 0);
161 ASSERT (retval == strlen (result));
164 { /* Positive zero. */
167 my_sprintf (result, "%a %d", 0.0, 33, 44, 55);
168 ASSERT (strcmp (result, "0x0p+0 33") == 0);
169 ASSERT (retval == strlen (result));
172 { /* Negative zero. */
175 my_sprintf (result, "%a %d", -zerod, 33, 44, 55);
176 if (have_minus_zero ())
177 ASSERT (strcmp (result, "-0x0p+0 33") == 0);
178 ASSERT (retval == strlen (result));
181 { /* Positive infinity. */
184 my_sprintf (result, "%a %d", 1.0 / 0.0, 33, 44, 55);
185 ASSERT (strcmp (result, "inf 33") == 0);
186 ASSERT (retval == strlen (result));
189 { /* Negative infinity. */
192 my_sprintf (result, "%a %d", -1.0 / 0.0, 33, 44, 55);
193 ASSERT (strcmp (result, "-inf 33") == 0);
194 ASSERT (retval == strlen (result));
200 my_sprintf (result, "%a %d", NaNd (), 33, 44, 55);
201 ASSERT (strlen (result) >= 3 + 3
202 && strisnan (result, 0, strlen (result) - 3, 0)
203 && strcmp (result + strlen (result) - 3, " 33") == 0);
204 ASSERT (retval == strlen (result));
207 { /* Rounding near the decimal point. */
210 my_sprintf (result, "%.0a %d", 1.5, 33, 44, 55);
211 ASSERT (strcmp (result, "0x2p+0 33") == 0
212 || strcmp (result, "0x3p-1 33") == 0
213 || strcmp (result, "0x6p-2 33") == 0
214 || strcmp (result, "0xcp-3 33") == 0);
215 ASSERT (retval == strlen (result));
218 { /* Rounding with precision 0. */
221 my_sprintf (result, "%.0a %d", 1.51, 33, 44, 55);
222 ASSERT (strcmp (result, "0x2p+0 33") == 0
223 || strcmp (result, "0x3p-1 33") == 0
224 || strcmp (result, "0x6p-2 33") == 0
225 || strcmp (result, "0xcp-3 33") == 0);
226 ASSERT (retval == strlen (result));
229 { /* Rounding with precision 1. */
232 my_sprintf (result, "%.1a %d", 1.51, 33, 44, 55);
233 ASSERT (strcmp (result, "0x1.8p+0 33") == 0
234 || strcmp (result, "0x3.0p-1 33") == 0
235 || strcmp (result, "0x6.1p-2 33") == 0
236 || strcmp (result, "0xc.1p-3 33") == 0);
237 ASSERT (retval == strlen (result));
240 { /* Rounding with precision 2. */
243 my_sprintf (result, "%.2a %d", 1.51, 33, 44, 55);
244 ASSERT (strcmp (result, "0x1.83p+0 33") == 0
245 || strcmp (result, "0x3.05p-1 33") == 0
246 || strcmp (result, "0x6.0ap-2 33") == 0
247 || strcmp (result, "0xc.14p-3 33") == 0);
248 ASSERT (retval == strlen (result));
251 { /* Rounding with precision 3. */
254 my_sprintf (result, "%.3a %d", 1.51, 33, 44, 55);
255 ASSERT (strcmp (result, "0x1.829p+0 33") == 0
256 || strcmp (result, "0x3.052p-1 33") == 0
257 || strcmp (result, "0x6.0a4p-2 33") == 0
258 || strcmp (result, "0xc.148p-3 33") == 0);
259 ASSERT (retval == strlen (result));
262 { /* Rounding can turn a ...FFF into a ...000. */
265 my_sprintf (result, "%.3a %d", 1.49999, 33, 44, 55);
266 ASSERT (strcmp (result, "0x1.800p+0 33") == 0
267 || strcmp (result, "0x3.000p-1 33") == 0
268 || strcmp (result, "0x6.000p-2 33") == 0
269 || strcmp (result, "0xc.000p-3 33") == 0);
270 ASSERT (retval == strlen (result));
273 { /* Rounding can turn a ...FFF into a ...000.
274 This shows a MacOS X 10.3.9 (Darwin 7.9) bug. */
277 my_sprintf (result, "%.1a %d", 1.999, 33, 44, 55);
278 ASSERT (strcmp (result, "0x1.0p+1 33") == 0
279 || strcmp (result, "0x2.0p+0 33") == 0
280 || strcmp (result, "0x4.0p-1 33") == 0
281 || strcmp (result, "0x8.0p-2 33") == 0);
282 ASSERT (retval == strlen (result));
288 my_sprintf (result, "%10a %d", 1.75, 33, 44, 55);
289 ASSERT (strcmp (result, " 0x1.cp+0 33") == 0
290 || strcmp (result, " 0x3.8p-1 33") == 0
291 || strcmp (result, " 0x7p-2 33") == 0
292 || strcmp (result, " 0xep-3 33") == 0);
293 ASSERT (retval == strlen (result));
296 { /* Small precision. */
299 my_sprintf (result, "%.10a %d", 1.75, 33, 44, 55);
300 ASSERT (strcmp (result, "0x1.c000000000p+0 33") == 0
301 || strcmp (result, "0x3.8000000000p-1 33") == 0
302 || strcmp (result, "0x7.0000000000p-2 33") == 0
303 || strcmp (result, "0xe.0000000000p-3 33") == 0);
304 ASSERT (retval == strlen (result));
307 { /* Large precision. */
310 my_sprintf (result, "%.50a %d", 1.75, 33, 44, 55);
311 ASSERT (strcmp (result, "0x1.c0000000000000000000000000000000000000000000000000p+0 33") == 0
312 || strcmp (result, "0x3.80000000000000000000000000000000000000000000000000p-1 33") == 0
313 || strcmp (result, "0x7.00000000000000000000000000000000000000000000000000p-2 33") == 0
314 || strcmp (result, "0xe.00000000000000000000000000000000000000000000000000p-3 33") == 0);
315 ASSERT (retval == strlen (result));
321 my_sprintf (result, "%-10a %d", 1.75, 33, 44, 55);
322 ASSERT (strcmp (result, "0x1.cp+0 33") == 0
323 || strcmp (result, "0x3.8p-1 33") == 0
324 || strcmp (result, "0x7p-2 33") == 0
325 || strcmp (result, "0xep-3 33") == 0);
326 ASSERT (retval == strlen (result));
329 { /* FLAG_SHOWSIGN. */
332 my_sprintf (result, "%+a %d", 1.75, 33, 44, 55);
333 ASSERT (strcmp (result, "+0x1.cp+0 33") == 0
334 || strcmp (result, "+0x3.8p-1 33") == 0
335 || strcmp (result, "+0x7p-2 33") == 0
336 || strcmp (result, "+0xep-3 33") == 0);
337 ASSERT (retval == strlen (result));
343 my_sprintf (result, "% a %d", 1.75, 33, 44, 55);
344 ASSERT (strcmp (result, " 0x1.cp+0 33") == 0
345 || strcmp (result, " 0x3.8p-1 33") == 0
346 || strcmp (result, " 0x7p-2 33") == 0
347 || strcmp (result, " 0xep-3 33") == 0);
348 ASSERT (retval == strlen (result));
354 my_sprintf (result, "%#a %d", 1.75, 33, 44, 55);
355 ASSERT (strcmp (result, "0x1.cp+0 33") == 0
356 || strcmp (result, "0x3.8p-1 33") == 0
357 || strcmp (result, "0x7.p-2 33") == 0
358 || strcmp (result, "0xe.p-3 33") == 0);
359 ASSERT (retval == strlen (result));
365 my_sprintf (result, "%#a %d", 1.0, 33, 44, 55);
366 ASSERT (strcmp (result, "0x1.p+0 33") == 0
367 || strcmp (result, "0x2.p-1 33") == 0
368 || strcmp (result, "0x4.p-2 33") == 0
369 || strcmp (result, "0x8.p-3 33") == 0);
370 ASSERT (retval == strlen (result));
373 { /* FLAG_ZERO with finite number. */
376 my_sprintf (result, "%010a %d", 1.75, 33, 44, 55);
377 ASSERT (strcmp (result, "0x001.cp+0 33") == 0
378 || strcmp (result, "0x003.8p-1 33") == 0
379 || strcmp (result, "0x00007p-2 33") == 0
380 || strcmp (result, "0x0000ep-3 33") == 0);
381 ASSERT (retval == strlen (result));
384 { /* FLAG_ZERO with infinite number. */
387 my_sprintf (result, "%010a %d", 1.0 / 0.0, 33, 44, 55);
388 /* "0000000inf 33" is not a valid result; see
389 <http://lists.gnu.org/archive/html/bug-gnulib/2007-04/msg00107.html> */
390 ASSERT (strcmp (result, " inf 33") == 0);
391 ASSERT (retval == strlen (result));
394 { /* FLAG_ZERO with NaN. */
397 my_sprintf (result, "%050a %d", NaNd (), 33, 44, 55);
398 /* "0000000nan 33" is not a valid result; see
399 <http://lists.gnu.org/archive/html/bug-gnulib/2007-04/msg00107.html> */
400 ASSERT (strlen (result) == 50 + 3
401 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
402 && strcmp (result + strlen (result) - 3, " 33") == 0);
403 ASSERT (retval == strlen (result));
406 { /* A positive number. */
409 my_sprintf (result, "%La %d", 3.1416015625L, 33, 44, 55);
410 ASSERT (strcmp (result, "0x1.922p+1 33") == 0
411 || strcmp (result, "0x3.244p+0 33") == 0
412 || strcmp (result, "0x6.488p-1 33") == 0
413 || strcmp (result, "0xc.91p-2 33") == 0);
414 ASSERT (retval == strlen (result));
417 { /* A negative number. */
420 my_sprintf (result, "%LA %d", -3.1416015625L, 33, 44, 55);
421 ASSERT (strcmp (result, "-0X1.922P+1 33") == 0
422 || strcmp (result, "-0X3.244P+0 33") == 0
423 || strcmp (result, "-0X6.488P-1 33") == 0
424 || strcmp (result, "-0XC.91P-2 33") == 0);
425 ASSERT (retval == strlen (result));
428 { /* Positive zero. */
431 my_sprintf (result, "%La %d", 0.0L, 33, 44, 55);
432 ASSERT (strcmp (result, "0x0p+0 33") == 0);
433 ASSERT (retval == strlen (result));
436 { /* Negative zero. */
439 my_sprintf (result, "%La %d", minus_zerol, 33, 44, 55);
440 if (have_minus_zero ())
441 ASSERT (strcmp (result, "-0x0p+0 33") == 0);
442 ASSERT (retval == strlen (result));
445 { /* Positive infinity. */
448 my_sprintf (result, "%La %d", 1.0L / 0.0L, 33, 44, 55);
449 ASSERT (strcmp (result, "inf 33") == 0);
450 ASSERT (retval == strlen (result));
453 { /* Negative infinity. */
456 my_sprintf (result, "%La %d", -1.0L / 0.0L, 33, 44, 55);
457 ASSERT (strcmp (result, "-inf 33") == 0);
458 ASSERT (retval == strlen (result));
464 my_sprintf (result, "%La %d", NaNl (), 33, 44, 55);
465 ASSERT (strlen (result) >= 3 + 3
466 && strisnan (result, 0, strlen (result) - 3, 0)
467 && strcmp (result + strlen (result) - 3, " 33") == 0);
468 ASSERT (retval == strlen (result));
470 #if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
472 static union { unsigned int word[4]; long double value; } x =
473 { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
476 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
477 ASSERT (strlen (result) >= 3 + 3
478 && strisnan (result, 0, strlen (result) - 3, 0)
479 && strcmp (result + strlen (result) - 3, " 33") == 0);
480 ASSERT (retval == strlen (result));
483 /* Signalling NaN. */
484 static union { unsigned int word[4]; long double value; } x =
485 { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
488 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
489 ASSERT (strlen (result) >= 3 + 3
490 && strisnan (result, 0, strlen (result) - 3, 0)
491 && strcmp (result + strlen (result) - 3, " 33") == 0);
492 ASSERT (retval == strlen (result));
494 /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
495 Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
496 Intel IA-64 Architecture Software Developer's Manual, Volume 1:
497 Application Architecture.
498 Table 5-2 "Floating-Point Register Encodings"
499 Figure 5-6 "Memory to Floating-Point Register Data Translation"
502 static union { unsigned int word[4]; long double value; } x =
503 { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
506 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
507 ASSERT (strlen (result) >= 3 + 3
508 && strisnan (result, 0, strlen (result) - 3, 0)
509 && strcmp (result + strlen (result) - 3, " 33") == 0);
510 ASSERT (retval == strlen (result));
512 { /* Pseudo-Infinity. */
513 static union { unsigned int word[4]; long double value; } x =
514 { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
517 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
518 ASSERT (strlen (result) >= 3 + 3
519 && strisnan (result, 0, strlen (result) - 3, 0)
520 && strcmp (result + strlen (result) - 3, " 33") == 0);
521 ASSERT (retval == strlen (result));
524 static union { unsigned int word[4]; long double value; } x =
525 { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
528 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
529 ASSERT (strlen (result) >= 3 + 3
530 && strisnan (result, 0, strlen (result) - 3, 0)
531 && strcmp (result + strlen (result) - 3, " 33") == 0);
532 ASSERT (retval == strlen (result));
534 { /* Unnormalized number. */
535 static union { unsigned int word[4]; long double value; } x =
536 { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
539 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
540 ASSERT (strlen (result) >= 3 + 3
541 && strisnan (result, 0, strlen (result) - 3, 0)
542 && strcmp (result + strlen (result) - 3, " 33") == 0);
543 ASSERT (retval == strlen (result));
545 { /* Pseudo-Denormal. */
546 static union { unsigned int word[4]; long double value; } x =
547 { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
550 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
551 ASSERT (strlen (result) >= 3 + 3
552 && strisnan (result, 0, strlen (result) - 3, 0)
553 && strcmp (result + strlen (result) - 3, " 33") == 0);
554 ASSERT (retval == strlen (result));
558 { /* Rounding near the decimal point. */
561 my_sprintf (result, "%.0La %d", 1.5L, 33, 44, 55);
562 ASSERT (strcmp (result, "0x2p+0 33") == 0
563 || strcmp (result, "0x3p-1 33") == 0
564 || strcmp (result, "0x6p-2 33") == 0
565 || strcmp (result, "0xcp-3 33") == 0);
566 ASSERT (retval == strlen (result));
569 { /* Rounding with precision 0. */
572 my_sprintf (result, "%.0La %d", 1.51L, 33, 44, 55);
573 ASSERT (strcmp (result, "0x2p+0 33") == 0
574 || strcmp (result, "0x3p-1 33") == 0
575 || strcmp (result, "0x6p-2 33") == 0
576 || strcmp (result, "0xcp-3 33") == 0);
577 ASSERT (retval == strlen (result));
580 { /* Rounding with precision 1. */
583 my_sprintf (result, "%.1La %d", 1.51L, 33, 44, 55);
584 ASSERT (strcmp (result, "0x1.8p+0 33") == 0
585 || strcmp (result, "0x3.0p-1 33") == 0
586 || strcmp (result, "0x6.1p-2 33") == 0
587 || strcmp (result, "0xc.1p-3 33") == 0);
588 ASSERT (retval == strlen (result));
591 { /* Rounding with precision 2. */
594 my_sprintf (result, "%.2La %d", 1.51L, 33, 44, 55);
595 ASSERT (strcmp (result, "0x1.83p+0 33") == 0
596 || strcmp (result, "0x3.05p-1 33") == 0
597 || strcmp (result, "0x6.0ap-2 33") == 0
598 || strcmp (result, "0xc.14p-3 33") == 0);
599 ASSERT (retval == strlen (result));
602 { /* Rounding with precision 3. */
605 my_sprintf (result, "%.3La %d", 1.51L, 33, 44, 55);
606 ASSERT (strcmp (result, "0x1.829p+0 33") == 0
607 || strcmp (result, "0x3.052p-1 33") == 0
608 || strcmp (result, "0x6.0a4p-2 33") == 0
609 || strcmp (result, "0xc.148p-3 33") == 0);
610 ASSERT (retval == strlen (result));
613 { /* Rounding can turn a ...FFF into a ...000. */
616 my_sprintf (result, "%.3La %d", 1.49999L, 33, 44, 55);
617 ASSERT (strcmp (result, "0x1.800p+0 33") == 0
618 || strcmp (result, "0x3.000p-1 33") == 0
619 || strcmp (result, "0x6.000p-2 33") == 0
620 || strcmp (result, "0xc.000p-3 33") == 0);
621 ASSERT (retval == strlen (result));
624 { /* Rounding can turn a ...FFF into a ...000.
625 This shows a MacOS X 10.3.9 (Darwin 7.9) bug and a
626 glibc 2.4 bug <http://sourceware.org/bugzilla/show_bug.cgi?id=2908>. */
629 my_sprintf (result, "%.1La %d", 1.999L, 33, 44, 55);
630 ASSERT (strcmp (result, "0x1.0p+1 33") == 0
631 || strcmp (result, "0x2.0p+0 33") == 0
632 || strcmp (result, "0x4.0p-1 33") == 0
633 || strcmp (result, "0x8.0p-2 33") == 0);
634 ASSERT (retval == strlen (result));
640 my_sprintf (result, "%10La %d", 1.75L, 33, 44, 55);
641 ASSERT (strcmp (result, " 0x1.cp+0 33") == 0
642 || strcmp (result, " 0x3.8p-1 33") == 0
643 || strcmp (result, " 0x7p-2 33") == 0
644 || strcmp (result, " 0xep-3 33") == 0);
645 ASSERT (retval == strlen (result));
648 { /* Small precision. */
651 my_sprintf (result, "%.10La %d", 1.75L, 33, 44, 55);
652 ASSERT (strcmp (result, "0x1.c000000000p+0 33") == 0
653 || strcmp (result, "0x3.8000000000p-1 33") == 0
654 || strcmp (result, "0x7.0000000000p-2 33") == 0
655 || strcmp (result, "0xe.0000000000p-3 33") == 0);
656 ASSERT (retval == strlen (result));
659 { /* Large precision. */
662 my_sprintf (result, "%.50La %d", 1.75L, 33, 44, 55);
663 ASSERT (strcmp (result, "0x1.c0000000000000000000000000000000000000000000000000p+0 33") == 0
664 || strcmp (result, "0x3.80000000000000000000000000000000000000000000000000p-1 33") == 0
665 || strcmp (result, "0x7.00000000000000000000000000000000000000000000000000p-2 33") == 0
666 || strcmp (result, "0xe.00000000000000000000000000000000000000000000000000p-3 33") == 0);
667 ASSERT (retval == strlen (result));
673 my_sprintf (result, "%-10La %d", 1.75L, 33, 44, 55);
674 ASSERT (strcmp (result, "0x1.cp+0 33") == 0
675 || strcmp (result, "0x3.8p-1 33") == 0
676 || strcmp (result, "0x7p-2 33") == 0
677 || strcmp (result, "0xep-3 33") == 0);
678 ASSERT (retval == strlen (result));
681 { /* FLAG_SHOWSIGN. */
684 my_sprintf (result, "%+La %d", 1.75L, 33, 44, 55);
685 ASSERT (strcmp (result, "+0x1.cp+0 33") == 0
686 || strcmp (result, "+0x3.8p-1 33") == 0
687 || strcmp (result, "+0x7p-2 33") == 0
688 || strcmp (result, "+0xep-3 33") == 0);
689 ASSERT (retval == strlen (result));
695 my_sprintf (result, "% La %d", 1.75L, 33, 44, 55);
696 ASSERT (strcmp (result, " 0x1.cp+0 33") == 0
697 || strcmp (result, " 0x3.8p-1 33") == 0
698 || strcmp (result, " 0x7p-2 33") == 0
699 || strcmp (result, " 0xep-3 33") == 0);
700 ASSERT (retval == strlen (result));
706 my_sprintf (result, "%#La %d", 1.75L, 33, 44, 55);
707 ASSERT (strcmp (result, "0x1.cp+0 33") == 0
708 || strcmp (result, "0x3.8p-1 33") == 0
709 || strcmp (result, "0x7.p-2 33") == 0
710 || strcmp (result, "0xe.p-3 33") == 0);
711 ASSERT (retval == strlen (result));
717 my_sprintf (result, "%#La %d", 1.0L, 33, 44, 55);
718 ASSERT (strcmp (result, "0x1.p+0 33") == 0
719 || strcmp (result, "0x2.p-1 33") == 0
720 || strcmp (result, "0x4.p-2 33") == 0
721 || strcmp (result, "0x8.p-3 33") == 0);
722 ASSERT (retval == strlen (result));
725 { /* FLAG_ZERO with finite number. */
728 my_sprintf (result, "%010La %d", 1.75L, 33, 44, 55);
729 ASSERT (strcmp (result, "0x001.cp+0 33") == 0
730 || strcmp (result, "0x003.8p-1 33") == 0
731 || strcmp (result, "0x00007p-2 33") == 0
732 || strcmp (result, "0x0000ep-3 33") == 0);
733 ASSERT (retval == strlen (result));
736 { /* FLAG_ZERO with infinite number. */
739 my_sprintf (result, "%010La %d", 1.0L / 0.0L, 33, 44, 55);
740 /* "0000000inf 33" is not a valid result; see
741 <http://lists.gnu.org/archive/html/bug-gnulib/2007-04/msg00107.html> */
742 ASSERT (strcmp (result, " inf 33") == 0);
743 ASSERT (retval == strlen (result));
746 { /* FLAG_ZERO with NaN. */
749 my_sprintf (result, "%050La %d", NaNl (), 33, 44, 55);
750 /* "0000000nan 33" is not a valid result; see
751 <http://lists.gnu.org/archive/html/bug-gnulib/2007-04/msg00107.html> */
752 ASSERT (strlen (result) == 50 + 3
753 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
754 && strcmp (result + strlen (result) - 3, " 33") == 0);
755 ASSERT (retval == strlen (result));
758 /* Test the support of the %f format directive. */
760 { /* A positive number. */
763 my_sprintf (result, "%f %d", 12.75, 33, 44, 55);
764 ASSERT (strcmp (result, "12.750000 33") == 0);
765 ASSERT (retval == strlen (result));
768 { /* A larger positive number. */
771 my_sprintf (result, "%f %d", 1234567.0, 33, 44, 55);
772 ASSERT (strcmp (result, "1234567.000000 33") == 0);
773 ASSERT (retval == strlen (result));
776 { /* Small and large positive numbers. */
777 static struct { double value; const char *string; } data[] =
779 { 1.234321234321234e-37, "0.000000" },
780 { 1.234321234321234e-36, "0.000000" },
781 { 1.234321234321234e-35, "0.000000" },
782 { 1.234321234321234e-34, "0.000000" },
783 { 1.234321234321234e-33, "0.000000" },
784 { 1.234321234321234e-32, "0.000000" },
785 { 1.234321234321234e-31, "0.000000" },
786 { 1.234321234321234e-30, "0.000000" },
787 { 1.234321234321234e-29, "0.000000" },
788 { 1.234321234321234e-28, "0.000000" },
789 { 1.234321234321234e-27, "0.000000" },
790 { 1.234321234321234e-26, "0.000000" },
791 { 1.234321234321234e-25, "0.000000" },
792 { 1.234321234321234e-24, "0.000000" },
793 { 1.234321234321234e-23, "0.000000" },
794 { 1.234321234321234e-22, "0.000000" },
795 { 1.234321234321234e-21, "0.000000" },
796 { 1.234321234321234e-20, "0.000000" },
797 { 1.234321234321234e-19, "0.000000" },
798 { 1.234321234321234e-18, "0.000000" },
799 { 1.234321234321234e-17, "0.000000" },
800 { 1.234321234321234e-16, "0.000000" },
801 { 1.234321234321234e-15, "0.000000" },
802 { 1.234321234321234e-14, "0.000000" },
803 { 1.234321234321234e-13, "0.000000" },
804 { 1.234321234321234e-12, "0.000000" },
805 { 1.234321234321234e-11, "0.000000" },
806 { 1.234321234321234e-10, "0.000000" },
807 { 1.234321234321234e-9, "0.000000" },
808 { 1.234321234321234e-8, "0.000000" },
809 { 1.234321234321234e-7, "0.000000" },
810 { 1.234321234321234e-6, "0.000001" },
811 { 1.234321234321234e-5, "0.000012" },
812 { 1.234321234321234e-4, "0.000123" },
813 { 1.234321234321234e-3, "0.001234" },
814 { 1.234321234321234e-2, "0.012343" },
815 { 1.234321234321234e-1, "0.123432" },
816 { 1.234321234321234, "1.234321" },
817 { 1.234321234321234e1, "12.343212" },
818 { 1.234321234321234e2, "123.432123" },
819 { 1.234321234321234e3, "1234.321234" },
820 { 1.234321234321234e4, "12343.212343" },
821 { 1.234321234321234e5, "123432.123432" },
822 { 1.234321234321234e6, "1234321.234321" },
823 { 1.234321234321234e7, "12343212.343212" },
824 { 1.234321234321234e8, "123432123.432123" },
825 { 1.234321234321234e9, "1234321234.321234" },
826 { 1.234321234321234e10, "12343212343.2123**" },
827 { 1.234321234321234e11, "123432123432.123***" },
828 { 1.234321234321234e12, "1234321234321.23****" },
829 { 1.234321234321234e13, "12343212343212.3*****" },
830 { 1.234321234321234e14, "123432123432123.******" },
831 { 1.234321234321234e15, "1234321234321234.000000" },
832 { 1.234321234321234e16, "123432123432123**.000000" },
833 { 1.234321234321234e17, "123432123432123***.000000" },
834 { 1.234321234321234e18, "123432123432123****.000000" },
835 { 1.234321234321234e19, "123432123432123*****.000000" },
836 { 1.234321234321234e20, "123432123432123******.000000" },
837 { 1.234321234321234e21, "123432123432123*******.000000" },
838 { 1.234321234321234e22, "123432123432123********.000000" },
839 { 1.234321234321234e23, "123432123432123*********.000000" },
840 { 1.234321234321234e24, "123432123432123**********.000000" },
841 { 1.234321234321234e25, "123432123432123***********.000000" },
842 { 1.234321234321234e26, "123432123432123************.000000" },
843 { 1.234321234321234e27, "123432123432123*************.000000" },
844 { 1.234321234321234e28, "123432123432123**************.000000" },
845 { 1.234321234321234e29, "123432123432123***************.000000" },
846 { 1.234321234321234e30, "123432123432123****************.000000" },
847 { 1.234321234321234e31, "123432123432123*****************.000000" },
848 { 1.234321234321234e32, "123432123432123******************.000000" },
849 { 1.234321234321234e33, "123432123432123*******************.000000" },
850 { 1.234321234321234e34, "123432123432123********************.000000" },
851 { 1.234321234321234e35, "123432123432123*********************.000000" },
852 { 1.234321234321234e36, "123432123432123**********************.000000" }
855 for (k = 0; k < SIZEOF (data); k++)
859 my_sprintf (result, "%f", data[k].value);
860 ASSERT (strmatch (data[k].string, result));
861 ASSERT (retval == strlen (result));
865 { /* A negative number. */
868 my_sprintf (result, "%f %d", -0.03125, 33, 44, 55);
869 ASSERT (strcmp (result, "-0.031250 33") == 0);
870 ASSERT (retval == strlen (result));
873 { /* Positive zero. */
876 my_sprintf (result, "%f %d", 0.0, 33, 44, 55);
877 ASSERT (strcmp (result, "0.000000 33") == 0);
878 ASSERT (retval == strlen (result));
881 { /* Negative zero. */
884 my_sprintf (result, "%f %d", -zerod, 33, 44, 55);
885 if (have_minus_zero ())
886 ASSERT (strcmp (result, "-0.000000 33") == 0);
887 ASSERT (retval == strlen (result));
890 { /* Positive infinity. */
893 my_sprintf (result, "%f %d", 1.0 / 0.0, 33, 44, 55);
894 ASSERT (strcmp (result, "inf 33") == 0
895 || strcmp (result, "infinity 33") == 0);
896 ASSERT (retval == strlen (result));
899 { /* Negative infinity. */
902 my_sprintf (result, "%f %d", -1.0 / 0.0, 33, 44, 55);
903 ASSERT (strcmp (result, "-inf 33") == 0
904 || strcmp (result, "-infinity 33") == 0);
905 ASSERT (retval == strlen (result));
911 my_sprintf (result, "%f %d", NaNd (), 33, 44, 55);
912 ASSERT (strlen (result) >= 3 + 3
913 && strisnan (result, 0, strlen (result) - 3, 0)
914 && strcmp (result + strlen (result) - 3, " 33") == 0);
915 ASSERT (retval == strlen (result));
921 my_sprintf (result, "%10f %d", 1.75, 33, 44, 55);
922 ASSERT (strcmp (result, " 1.750000 33") == 0);
923 ASSERT (retval == strlen (result));
929 my_sprintf (result, "%-10f %d", 1.75, 33, 44, 55);
930 ASSERT (strcmp (result, "1.750000 33") == 0);
931 ASSERT (retval == strlen (result));
934 { /* FLAG_SHOWSIGN. */
937 my_sprintf (result, "%+f %d", 1.75, 33, 44, 55);
938 ASSERT (strcmp (result, "+1.750000 33") == 0);
939 ASSERT (retval == strlen (result));
945 my_sprintf (result, "% f %d", 1.75, 33, 44, 55);
946 ASSERT (strcmp (result, " 1.750000 33") == 0);
947 ASSERT (retval == strlen (result));
953 my_sprintf (result, "%#f %d", 1.75, 33, 44, 55);
954 ASSERT (strcmp (result, "1.750000 33") == 0);
955 ASSERT (retval == strlen (result));
961 my_sprintf (result, "%#.f %d", 1.75, 33, 44, 55);
962 ASSERT (strcmp (result, "2. 33") == 0);
963 ASSERT (retval == strlen (result));
966 { /* FLAG_ZERO with finite number. */
969 my_sprintf (result, "%015f %d", 1234.0, 33, 44, 55);
970 ASSERT (strcmp (result, "00001234.000000 33") == 0);
971 ASSERT (retval == strlen (result));
974 { /* FLAG_ZERO with infinite number. */
977 my_sprintf (result, "%015f %d", -1.0 / 0.0, 33, 44, 55);
978 ASSERT (strcmp (result, " -inf 33") == 0
979 || strcmp (result, " -infinity 33") == 0);
980 ASSERT (retval == strlen (result));
983 { /* FLAG_ZERO with NaN. */
986 my_sprintf (result, "%050f %d", NaNd (), 33, 44, 55);
987 ASSERT (strlen (result) == 50 + 3
988 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
989 && strcmp (result + strlen (result) - 3, " 33") == 0);
990 ASSERT (retval == strlen (result));
996 my_sprintf (result, "%.f %d", 1234.0, 33, 44, 55);
997 ASSERT (strcmp (result, "1234 33") == 0);
998 ASSERT (retval == strlen (result));
1001 { /* Precision with no rounding. */
1004 my_sprintf (result, "%.2f %d", 999.951, 33, 44, 55);
1005 ASSERT (strcmp (result, "999.95 33") == 0);
1006 ASSERT (retval == strlen (result));
1009 { /* Precision with rounding. */
1012 my_sprintf (result, "%.2f %d", 999.996, 33, 44, 55);
1013 ASSERT (strcmp (result, "1000.00 33") == 0);
1014 ASSERT (retval == strlen (result));
1017 { /* A positive number. */
1020 my_sprintf (result, "%Lf %d", 12.75L, 33, 44, 55);
1021 ASSERT (strcmp (result, "12.750000 33") == 0);
1022 ASSERT (retval == strlen (result));
1025 { /* A larger positive number. */
1028 my_sprintf (result, "%Lf %d", 1234567.0L, 33, 44, 55);
1029 ASSERT (strcmp (result, "1234567.000000 33") == 0);
1030 ASSERT (retval == strlen (result));
1033 { /* Small and large positive numbers. */
1034 static struct { long double value; const char *string; } data[] =
1036 { 1.234321234321234e-37L, "0.000000" },
1037 { 1.234321234321234e-36L, "0.000000" },
1038 { 1.234321234321234e-35L, "0.000000" },
1039 { 1.234321234321234e-34L, "0.000000" },
1040 { 1.234321234321234e-33L, "0.000000" },
1041 { 1.234321234321234e-32L, "0.000000" },
1042 { 1.234321234321234e-31L, "0.000000" },
1043 { 1.234321234321234e-30L, "0.000000" },
1044 { 1.234321234321234e-29L, "0.000000" },
1045 { 1.234321234321234e-28L, "0.000000" },
1046 { 1.234321234321234e-27L, "0.000000" },
1047 { 1.234321234321234e-26L, "0.000000" },
1048 { 1.234321234321234e-25L, "0.000000" },
1049 { 1.234321234321234e-24L, "0.000000" },
1050 { 1.234321234321234e-23L, "0.000000" },
1051 { 1.234321234321234e-22L, "0.000000" },
1052 { 1.234321234321234e-21L, "0.000000" },
1053 { 1.234321234321234e-20L, "0.000000" },
1054 { 1.234321234321234e-19L, "0.000000" },
1055 { 1.234321234321234e-18L, "0.000000" },
1056 { 1.234321234321234e-17L, "0.000000" },
1057 { 1.234321234321234e-16L, "0.000000" },
1058 { 1.234321234321234e-15L, "0.000000" },
1059 { 1.234321234321234e-14L, "0.000000" },
1060 { 1.234321234321234e-13L, "0.000000" },
1061 { 1.234321234321234e-12L, "0.000000" },
1062 { 1.234321234321234e-11L, "0.000000" },
1063 { 1.234321234321234e-10L, "0.000000" },
1064 { 1.234321234321234e-9L, "0.000000" },
1065 { 1.234321234321234e-8L, "0.000000" },
1066 { 1.234321234321234e-7L, "0.000000" },
1067 { 1.234321234321234e-6L, "0.000001" },
1068 { 1.234321234321234e-5L, "0.000012" },
1069 { 1.234321234321234e-4L, "0.000123" },
1070 { 1.234321234321234e-3L, "0.001234" },
1071 { 1.234321234321234e-2L, "0.012343" },
1072 { 1.234321234321234e-1L, "0.123432" },
1073 { 1.234321234321234L, "1.234321" },
1074 { 1.234321234321234e1L, "12.343212" },
1075 { 1.234321234321234e2L, "123.432123" },
1076 { 1.234321234321234e3L, "1234.321234" },
1077 { 1.234321234321234e4L, "12343.212343" },
1078 { 1.234321234321234e5L, "123432.123432" },
1079 { 1.234321234321234e6L, "1234321.234321" },
1080 { 1.234321234321234e7L, "12343212.343212" },
1081 { 1.234321234321234e8L, "123432123.432123" },
1082 { 1.234321234321234e9L, "1234321234.321234" },
1083 { 1.234321234321234e10L, "12343212343.2123**" },
1084 { 1.234321234321234e11L, "123432123432.123***" },
1085 { 1.234321234321234e12L, "1234321234321.23****" },
1086 { 1.234321234321234e13L, "12343212343212.3*****" },
1087 { 1.234321234321234e14L, "123432123432123.******" },
1088 { 1.234321234321234e15L, "1234321234321234.000000" },
1089 { 1.234321234321234e16L, "123432123432123**.000000" },
1090 { 1.234321234321234e17L, "123432123432123***.000000" },
1091 { 1.234321234321234e18L, "123432123432123****.000000" },
1092 { 1.234321234321234e19L, "123432123432123*****.000000" },
1093 { 1.234321234321234e20L, "123432123432123******.000000" },
1094 { 1.234321234321234e21L, "123432123432123*******.000000" },
1095 { 1.234321234321234e22L, "123432123432123********.000000" },
1096 { 1.234321234321234e23L, "123432123432123*********.000000" },
1097 { 1.234321234321234e24L, "123432123432123**********.000000" },
1098 { 1.234321234321234e25L, "123432123432123***********.000000" },
1099 { 1.234321234321234e26L, "123432123432123************.000000" },
1100 { 1.234321234321234e27L, "123432123432123*************.000000" },
1101 { 1.234321234321234e28L, "123432123432123**************.000000" },
1102 { 1.234321234321234e29L, "123432123432123***************.000000" },
1103 { 1.234321234321234e30L, "123432123432123****************.000000" },
1104 { 1.234321234321234e31L, "123432123432123*****************.000000" },
1105 { 1.234321234321234e32L, "123432123432123******************.000000" },
1106 { 1.234321234321234e33L, "123432123432123*******************.000000" },
1107 { 1.234321234321234e34L, "123432123432123********************.000000" },
1108 { 1.234321234321234e35L, "123432123432123*********************.000000" },
1109 { 1.234321234321234e36L, "123432123432123**********************.000000" }
1112 for (k = 0; k < SIZEOF (data); k++)
1116 my_sprintf (result, "%Lf", data[k].value);
1117 ASSERT (strmatch (data[k].string, result));
1118 ASSERT (retval == strlen (result));
1122 { /* A negative number. */
1125 my_sprintf (result, "%Lf %d", -0.03125L, 33, 44, 55);
1126 ASSERT (strcmp (result, "-0.031250 33") == 0);
1127 ASSERT (retval == strlen (result));
1130 { /* Positive zero. */
1133 my_sprintf (result, "%Lf %d", 0.0L, 33, 44, 55);
1134 ASSERT (strcmp (result, "0.000000 33") == 0);
1135 ASSERT (retval == strlen (result));
1138 { /* Negative zero. */
1141 my_sprintf (result, "%Lf %d", minus_zerol, 33, 44, 55);
1142 if (have_minus_zero ())
1143 ASSERT (strcmp (result, "-0.000000 33") == 0);
1144 ASSERT (retval == strlen (result));
1147 { /* Positive infinity. */
1150 my_sprintf (result, "%Lf %d", 1.0L / 0.0L, 33, 44, 55);
1151 ASSERT (strcmp (result, "inf 33") == 0
1152 || strcmp (result, "infinity 33") == 0);
1153 ASSERT (retval == strlen (result));
1156 { /* Negative infinity. */
1159 my_sprintf (result, "%Lf %d", -1.0L / 0.0L, 33, 44, 55);
1160 ASSERT (strcmp (result, "-inf 33") == 0
1161 || strcmp (result, "-infinity 33") == 0);
1162 ASSERT (retval == strlen (result));
1168 my_sprintf (result, "%Lf %d", NaNl (), 33, 44, 55);
1169 ASSERT (strlen (result) >= 3 + 3
1170 && strisnan (result, 0, strlen (result) - 3, 0)
1171 && strcmp (result + strlen (result) - 3, " 33") == 0);
1172 ASSERT (retval == strlen (result));
1174 #if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
1176 static union { unsigned int word[4]; long double value; } x =
1177 { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
1180 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1181 ASSERT (strlen (result) >= 3 + 3
1182 && strisnan (result, 0, strlen (result) - 3, 0)
1183 && strcmp (result + strlen (result) - 3, " 33") == 0);
1184 ASSERT (retval == strlen (result));
1187 /* Signalling NaN. */
1188 static union { unsigned int word[4]; long double value; } x =
1189 { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
1192 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1193 ASSERT (strlen (result) >= 3 + 3
1194 && strisnan (result, 0, strlen (result) - 3, 0)
1195 && strcmp (result + strlen (result) - 3, " 33") == 0);
1196 ASSERT (retval == strlen (result));
1198 /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
1199 Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
1200 Intel IA-64 Architecture Software Developer's Manual, Volume 1:
1201 Application Architecture.
1202 Table 5-2 "Floating-Point Register Encodings"
1203 Figure 5-6 "Memory to Floating-Point Register Data Translation"
1206 static union { unsigned int word[4]; long double value; } x =
1207 { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
1210 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1211 ASSERT (strlen (result) >= 3 + 3
1212 && strisnan (result, 0, strlen (result) - 3, 0)
1213 && strcmp (result + strlen (result) - 3, " 33") == 0);
1214 ASSERT (retval == strlen (result));
1216 { /* Pseudo-Infinity. */
1217 static union { unsigned int word[4]; long double value; } x =
1218 { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
1221 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1222 ASSERT (strlen (result) >= 3 + 3
1223 && strisnan (result, 0, strlen (result) - 3, 0)
1224 && strcmp (result + strlen (result) - 3, " 33") == 0);
1225 ASSERT (retval == strlen (result));
1227 { /* Pseudo-Zero. */
1228 static union { unsigned int word[4]; long double value; } x =
1229 { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
1232 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1233 ASSERT (strlen (result) >= 3 + 3
1234 && strisnan (result, 0, strlen (result) - 3, 0)
1235 && strcmp (result + strlen (result) - 3, " 33") == 0);
1236 ASSERT (retval == strlen (result));
1238 { /* Unnormalized number. */
1239 static union { unsigned int word[4]; long double value; } x =
1240 { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
1243 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1244 ASSERT (strlen (result) >= 3 + 3
1245 && strisnan (result, 0, strlen (result) - 3, 0)
1246 && strcmp (result + strlen (result) - 3, " 33") == 0);
1247 ASSERT (retval == strlen (result));
1249 { /* Pseudo-Denormal. */
1250 static union { unsigned int word[4]; long double value; } x =
1251 { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
1254 my_sprintf (result, "%Lf %d", x.value, 33, 44, 55);
1255 ASSERT (strlen (result) >= 3 + 3
1256 && strisnan (result, 0, strlen (result) - 3, 0)
1257 && strcmp (result + strlen (result) - 3, " 33") == 0);
1258 ASSERT (retval == strlen (result));
1265 my_sprintf (result, "%10Lf %d", 1.75L, 33, 44, 55);
1266 ASSERT (strcmp (result, " 1.750000 33") == 0);
1267 ASSERT (retval == strlen (result));
1273 my_sprintf (result, "%-10Lf %d", 1.75L, 33, 44, 55);
1274 ASSERT (strcmp (result, "1.750000 33") == 0);
1275 ASSERT (retval == strlen (result));
1278 { /* FLAG_SHOWSIGN. */
1281 my_sprintf (result, "%+Lf %d", 1.75L, 33, 44, 55);
1282 ASSERT (strcmp (result, "+1.750000 33") == 0);
1283 ASSERT (retval == strlen (result));
1289 my_sprintf (result, "% Lf %d", 1.75L, 33, 44, 55);
1290 ASSERT (strcmp (result, " 1.750000 33") == 0);
1291 ASSERT (retval == strlen (result));
1297 my_sprintf (result, "%#Lf %d", 1.75L, 33, 44, 55);
1298 ASSERT (strcmp (result, "1.750000 33") == 0);
1299 ASSERT (retval == strlen (result));
1305 my_sprintf (result, "%#.Lf %d", 1.75L, 33, 44, 55);
1306 ASSERT (strcmp (result, "2. 33") == 0);
1307 ASSERT (retval == strlen (result));
1310 { /* FLAG_ZERO with finite number. */
1313 my_sprintf (result, "%015Lf %d", 1234.0L, 33, 44, 55);
1314 ASSERT (strcmp (result, "00001234.000000 33") == 0);
1315 ASSERT (retval == strlen (result));
1318 { /* FLAG_ZERO with infinite number. */
1321 my_sprintf (result, "%015Lf %d", -1.0L / 0.0L, 33, 44, 55);
1322 ASSERT (strcmp (result, " -inf 33") == 0
1323 || strcmp (result, " -infinity 33") == 0);
1324 ASSERT (retval == strlen (result));
1327 { /* FLAG_ZERO with NaN. */
1330 my_sprintf (result, "%050Lf %d", NaNl (), 33, 44, 55);
1331 ASSERT (strlen (result) == 50 + 3
1332 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
1333 && strcmp (result + strlen (result) - 3, " 33") == 0);
1334 ASSERT (retval == strlen (result));
1340 my_sprintf (result, "%.Lf %d", 1234.0L, 33, 44, 55);
1341 ASSERT (strcmp (result, "1234 33") == 0);
1342 ASSERT (retval == strlen (result));
1345 { /* Precision with no rounding. */
1348 my_sprintf (result, "%.2Lf %d", 999.951L, 33, 44, 55);
1349 ASSERT (strcmp (result, "999.95 33") == 0);
1350 ASSERT (retval == strlen (result));
1353 { /* Precision with rounding. */
1356 my_sprintf (result, "%.2Lf %d", 999.996L, 33, 44, 55);
1357 ASSERT (strcmp (result, "1000.00 33") == 0);
1358 ASSERT (retval == strlen (result));
1361 /* Test the support of the %F format directive. */
1363 { /* A positive number. */
1366 my_sprintf (result, "%F %d", 12.75, 33, 44, 55);
1367 ASSERT (strcmp (result, "12.750000 33") == 0);
1368 ASSERT (retval == strlen (result));
1371 { /* A larger positive number. */
1374 my_sprintf (result, "%F %d", 1234567.0, 33, 44, 55);
1375 ASSERT (strcmp (result, "1234567.000000 33") == 0);
1376 ASSERT (retval == strlen (result));
1379 { /* A negative number. */
1382 my_sprintf (result, "%F %d", -0.03125, 33, 44, 55);
1383 ASSERT (strcmp (result, "-0.031250 33") == 0);
1384 ASSERT (retval == strlen (result));
1387 { /* Positive zero. */
1390 my_sprintf (result, "%F %d", 0.0, 33, 44, 55);
1391 ASSERT (strcmp (result, "0.000000 33") == 0);
1392 ASSERT (retval == strlen (result));
1395 { /* Negative zero. */
1398 my_sprintf (result, "%F %d", -zerod, 33, 44, 55);
1399 if (have_minus_zero ())
1400 ASSERT (strcmp (result, "-0.000000 33") == 0);
1401 ASSERT (retval == strlen (result));
1404 { /* Positive infinity. */
1407 my_sprintf (result, "%F %d", 1.0 / 0.0, 33, 44, 55);
1408 ASSERT (strcmp (result, "INF 33") == 0
1409 || strcmp (result, "INFINITY 33") == 0);
1410 ASSERT (retval == strlen (result));
1413 { /* Negative infinity. */
1416 my_sprintf (result, "%F %d", -1.0 / 0.0, 33, 44, 55);
1417 ASSERT (strcmp (result, "-INF 33") == 0
1418 || strcmp (result, "-INFINITY 33") == 0);
1419 ASSERT (retval == strlen (result));
1425 my_sprintf (result, "%F %d", NaNd (), 33, 44, 55);
1426 ASSERT (strlen (result) >= 3 + 3
1427 && strisnan (result, 0, strlen (result) - 3, 1)
1428 && strcmp (result + strlen (result) - 3, " 33") == 0);
1429 ASSERT (retval == strlen (result));
1435 my_sprintf (result, "%015F %d", 1234.0, 33, 44, 55);
1436 ASSERT (strcmp (result, "00001234.000000 33") == 0);
1437 ASSERT (retval == strlen (result));
1440 { /* FLAG_ZERO with infinite number. */
1443 my_sprintf (result, "%015F %d", -1.0 / 0.0, 33, 44, 55);
1444 ASSERT (strcmp (result, " -INF 33") == 0
1445 || strcmp (result, " -INFINITY 33") == 0);
1446 ASSERT (retval == strlen (result));
1452 my_sprintf (result, "%.F %d", 1234.0, 33, 44, 55);
1453 ASSERT (strcmp (result, "1234 33") == 0);
1454 ASSERT (retval == strlen (result));
1457 { /* Precision with no rounding. */
1460 my_sprintf (result, "%.2F %d", 999.951, 33, 44, 55);
1461 ASSERT (strcmp (result, "999.95 33") == 0);
1462 ASSERT (retval == strlen (result));
1465 { /* Precision with rounding. */
1468 my_sprintf (result, "%.2F %d", 999.996, 33, 44, 55);
1469 ASSERT (strcmp (result, "1000.00 33") == 0);
1470 ASSERT (retval == strlen (result));
1473 { /* A positive number. */
1476 my_sprintf (result, "%LF %d", 12.75L, 33, 44, 55);
1477 ASSERT (strcmp (result, "12.750000 33") == 0);
1478 ASSERT (retval == strlen (result));
1481 { /* A larger positive number. */
1484 my_sprintf (result, "%LF %d", 1234567.0L, 33, 44, 55);
1485 ASSERT (strcmp (result, "1234567.000000 33") == 0);
1486 ASSERT (retval == strlen (result));
1489 { /* A negative number. */
1492 my_sprintf (result, "%LF %d", -0.03125L, 33, 44, 55);
1493 ASSERT (strcmp (result, "-0.031250 33") == 0);
1494 ASSERT (retval == strlen (result));
1497 { /* Positive zero. */
1500 my_sprintf (result, "%LF %d", 0.0L, 33, 44, 55);
1501 ASSERT (strcmp (result, "0.000000 33") == 0);
1502 ASSERT (retval == strlen (result));
1505 { /* Negative zero. */
1508 my_sprintf (result, "%LF %d", minus_zerol, 33, 44, 55);
1509 if (have_minus_zero ())
1510 ASSERT (strcmp (result, "-0.000000 33") == 0);
1511 ASSERT (retval == strlen (result));
1514 { /* Positive infinity. */
1517 my_sprintf (result, "%LF %d", 1.0L / 0.0L, 33, 44, 55);
1518 ASSERT (strcmp (result, "INF 33") == 0
1519 || strcmp (result, "INFINITY 33") == 0);
1520 ASSERT (retval == strlen (result));
1523 { /* Negative infinity. */
1526 my_sprintf (result, "%LF %d", -1.0L / 0.0L, 33, 44, 55);
1527 ASSERT (strcmp (result, "-INF 33") == 0
1528 || strcmp (result, "-INFINITY 33") == 0);
1529 ASSERT (retval == strlen (result));
1535 my_sprintf (result, "%LF %d", NaNl (), 33, 44, 55);
1536 ASSERT (strlen (result) >= 3 + 3
1537 && strisnan (result, 0, strlen (result) - 3, 1)
1538 && strcmp (result + strlen (result) - 3, " 33") == 0);
1539 ASSERT (retval == strlen (result));
1545 my_sprintf (result, "%015LF %d", 1234.0L, 33, 44, 55);
1546 ASSERT (strcmp (result, "00001234.000000 33") == 0);
1547 ASSERT (retval == strlen (result));
1550 { /* FLAG_ZERO with infinite number. */
1553 my_sprintf (result, "%015LF %d", -1.0L / 0.0L, 33, 44, 55);
1554 ASSERT (strcmp (result, " -INF 33") == 0
1555 || strcmp (result, " -INFINITY 33") == 0);
1556 ASSERT (retval == strlen (result));
1562 my_sprintf (result, "%.LF %d", 1234.0L, 33, 44, 55);
1563 ASSERT (strcmp (result, "1234 33") == 0);
1564 ASSERT (retval == strlen (result));
1567 { /* Precision with no rounding. */
1570 my_sprintf (result, "%.2LF %d", 999.951L, 33, 44, 55);
1571 ASSERT (strcmp (result, "999.95 33") == 0);
1572 ASSERT (retval == strlen (result));
1575 { /* Precision with rounding. */
1578 my_sprintf (result, "%.2LF %d", 999.996L, 33, 44, 55);
1579 ASSERT (strcmp (result, "1000.00 33") == 0);
1580 ASSERT (retval == strlen (result));
1583 /* Test the support of the %e format directive. */
1585 { /* A positive number. */
1588 my_sprintf (result, "%e %d", 12.75, 33, 44, 55);
1589 ASSERT (strcmp (result, "1.275000e+01 33") == 0
1590 || strcmp (result, "1.275000e+001 33") == 0);
1591 ASSERT (retval == strlen (result));
1594 { /* A larger positive number. */
1597 my_sprintf (result, "%e %d", 1234567.0, 33, 44, 55);
1598 ASSERT (strcmp (result, "1.234567e+06 33") == 0
1599 || strcmp (result, "1.234567e+006 33") == 0);
1600 ASSERT (retval == strlen (result));
1603 { /* Small and large positive numbers. */
1604 static struct { double value; const char *string; } data[] =
1606 { 1.234321234321234e-37, "1.234321e-37" },
1607 { 1.234321234321234e-36, "1.234321e-36" },
1608 { 1.234321234321234e-35, "1.234321e-35" },
1609 { 1.234321234321234e-34, "1.234321e-34" },
1610 { 1.234321234321234e-33, "1.234321e-33" },
1611 { 1.234321234321234e-32, "1.234321e-32" },
1612 { 1.234321234321234e-31, "1.234321e-31" },
1613 { 1.234321234321234e-30, "1.234321e-30" },
1614 { 1.234321234321234e-29, "1.234321e-29" },
1615 { 1.234321234321234e-28, "1.234321e-28" },
1616 { 1.234321234321234e-27, "1.234321e-27" },
1617 { 1.234321234321234e-26, "1.234321e-26" },
1618 { 1.234321234321234e-25, "1.234321e-25" },
1619 { 1.234321234321234e-24, "1.234321e-24" },
1620 { 1.234321234321234e-23, "1.234321e-23" },
1621 { 1.234321234321234e-22, "1.234321e-22" },
1622 { 1.234321234321234e-21, "1.234321e-21" },
1623 { 1.234321234321234e-20, "1.234321e-20" },
1624 { 1.234321234321234e-19, "1.234321e-19" },
1625 { 1.234321234321234e-18, "1.234321e-18" },
1626 { 1.234321234321234e-17, "1.234321e-17" },
1627 { 1.234321234321234e-16, "1.234321e-16" },
1628 { 1.234321234321234e-15, "1.234321e-15" },
1629 { 1.234321234321234e-14, "1.234321e-14" },
1630 { 1.234321234321234e-13, "1.234321e-13" },
1631 { 1.234321234321234e-12, "1.234321e-12" },
1632 { 1.234321234321234e-11, "1.234321e-11" },
1633 { 1.234321234321234e-10, "1.234321e-10" },
1634 { 1.234321234321234e-9, "1.234321e-09" },
1635 { 1.234321234321234e-8, "1.234321e-08" },
1636 { 1.234321234321234e-7, "1.234321e-07" },
1637 { 1.234321234321234e-6, "1.234321e-06" },
1638 { 1.234321234321234e-5, "1.234321e-05" },
1639 { 1.234321234321234e-4, "1.234321e-04" },
1640 { 1.234321234321234e-3, "1.234321e-03" },
1641 { 1.234321234321234e-2, "1.234321e-02" },
1642 { 1.234321234321234e-1, "1.234321e-01" },
1643 { 1.234321234321234, "1.234321e+00" },
1644 { 1.234321234321234e1, "1.234321e+01" },
1645 { 1.234321234321234e2, "1.234321e+02" },
1646 { 1.234321234321234e3, "1.234321e+03" },
1647 { 1.234321234321234e4, "1.234321e+04" },
1648 { 1.234321234321234e5, "1.234321e+05" },
1649 { 1.234321234321234e6, "1.234321e+06" },
1650 { 1.234321234321234e7, "1.234321e+07" },
1651 { 1.234321234321234e8, "1.234321e+08" },
1652 { 1.234321234321234e9, "1.234321e+09" },
1653 { 1.234321234321234e10, "1.234321e+10" },
1654 { 1.234321234321234e11, "1.234321e+11" },
1655 { 1.234321234321234e12, "1.234321e+12" },
1656 { 1.234321234321234e13, "1.234321e+13" },
1657 { 1.234321234321234e14, "1.234321e+14" },
1658 { 1.234321234321234e15, "1.234321e+15" },
1659 { 1.234321234321234e16, "1.234321e+16" },
1660 { 1.234321234321234e17, "1.234321e+17" },
1661 { 1.234321234321234e18, "1.234321e+18" },
1662 { 1.234321234321234e19, "1.234321e+19" },
1663 { 1.234321234321234e20, "1.234321e+20" },
1664 { 1.234321234321234e21, "1.234321e+21" },
1665 { 1.234321234321234e22, "1.234321e+22" },
1666 { 1.234321234321234e23, "1.234321e+23" },
1667 { 1.234321234321234e24, "1.234321e+24" },
1668 { 1.234321234321234e25, "1.234321e+25" },
1669 { 1.234321234321234e26, "1.234321e+26" },
1670 { 1.234321234321234e27, "1.234321e+27" },
1671 { 1.234321234321234e28, "1.234321e+28" },
1672 { 1.234321234321234e29, "1.234321e+29" },
1673 { 1.234321234321234e30, "1.234321e+30" },
1674 { 1.234321234321234e31, "1.234321e+31" },
1675 { 1.234321234321234e32, "1.234321e+32" },
1676 { 1.234321234321234e33, "1.234321e+33" },
1677 { 1.234321234321234e34, "1.234321e+34" },
1678 { 1.234321234321234e35, "1.234321e+35" },
1679 { 1.234321234321234e36, "1.234321e+36" }
1682 for (k = 0; k < SIZEOF (data); k++)
1686 my_sprintf (result, "%e", data[k].value);
1687 const char *expected = data[k].string;
1688 ASSERT (strcmp (result, expected) == 0
1689 /* Some implementations produce exponents with 3 digits. */
1690 || (strlen (result) == strlen (expected) + 1
1691 && memcmp (result, expected, strlen (expected) - 2) == 0
1692 && result[strlen (expected) - 2] == '0'
1693 && strcmp (result + strlen (expected) - 1,
1694 expected + strlen (expected) - 2)
1696 ASSERT (retval == strlen (result));
1700 { /* A negative number. */
1703 my_sprintf (result, "%e %d", -0.03125, 33, 44, 55);
1704 ASSERT (strcmp (result, "-3.125000e-02 33") == 0
1705 || strcmp (result, "-3.125000e-002 33") == 0);
1706 ASSERT (retval == strlen (result));
1709 { /* Positive zero. */
1712 my_sprintf (result, "%e %d", 0.0, 33, 44, 55);
1713 ASSERT (strcmp (result, "0.000000e+00 33") == 0
1714 || strcmp (result, "0.000000e+000 33") == 0);
1715 ASSERT (retval == strlen (result));
1718 { /* Negative zero. */
1721 my_sprintf (result, "%e %d", -zerod, 33, 44, 55);
1722 if (have_minus_zero ())
1723 ASSERT (strcmp (result, "-0.000000e+00 33") == 0
1724 || strcmp (result, "-0.000000e+000 33") == 0);
1725 ASSERT (retval == strlen (result));
1728 { /* Positive infinity. */
1731 my_sprintf (result, "%e %d", 1.0 / 0.0, 33, 44, 55);
1732 ASSERT (strcmp (result, "inf 33") == 0
1733 || strcmp (result, "infinity 33") == 0);
1734 ASSERT (retval == strlen (result));
1737 { /* Negative infinity. */
1740 my_sprintf (result, "%e %d", -1.0 / 0.0, 33, 44, 55);
1741 ASSERT (strcmp (result, "-inf 33") == 0
1742 || strcmp (result, "-infinity 33") == 0);
1743 ASSERT (retval == strlen (result));
1749 my_sprintf (result, "%e %d", NaNd (), 33, 44, 55);
1750 ASSERT (strlen (result) >= 3 + 3
1751 && strisnan (result, 0, strlen (result) - 3, 0)
1752 && strcmp (result + strlen (result) - 3, " 33") == 0);
1753 ASSERT (retval == strlen (result));
1759 my_sprintf (result, "%15e %d", 1.75, 33, 44, 55);
1760 ASSERT (strcmp (result, " 1.750000e+00 33") == 0
1761 || strcmp (result, " 1.750000e+000 33") == 0);
1762 ASSERT (retval == strlen (result));
1768 my_sprintf (result, "%-15e %d", 1.75, 33, 44, 55);
1769 ASSERT (strcmp (result, "1.750000e+00 33") == 0
1770 || strcmp (result, "1.750000e+000 33") == 0);
1771 ASSERT (retval == strlen (result));
1774 { /* FLAG_SHOWSIGN. */
1777 my_sprintf (result, "%+e %d", 1.75, 33, 44, 55);
1778 ASSERT (strcmp (result, "+1.750000e+00 33") == 0
1779 || strcmp (result, "+1.750000e+000 33") == 0);
1780 ASSERT (retval == strlen (result));
1786 my_sprintf (result, "% e %d", 1.75, 33, 44, 55);
1787 ASSERT (strcmp (result, " 1.750000e+00 33") == 0
1788 || strcmp (result, " 1.750000e+000 33") == 0);
1789 ASSERT (retval == strlen (result));
1795 my_sprintf (result, "%#e %d", 1.75, 33, 44, 55);
1796 ASSERT (strcmp (result, "1.750000e+00 33") == 0
1797 || strcmp (result, "1.750000e+000 33") == 0);
1798 ASSERT (retval == strlen (result));
1804 my_sprintf (result, "%#.e %d", 1.75, 33, 44, 55);
1805 ASSERT (strcmp (result, "2.e+00 33") == 0
1806 || strcmp (result, "2.e+000 33") == 0);
1807 ASSERT (retval == strlen (result));
1813 my_sprintf (result, "%#.e %d", 9.75, 33, 44, 55);
1814 ASSERT (strcmp (result, "1.e+01 33") == 0
1815 || strcmp (result, "1.e+001 33") == 0);
1816 ASSERT (retval == strlen (result));
1819 { /* FLAG_ZERO with finite number. */
1822 my_sprintf (result, "%015e %d", 1234.0, 33, 44, 55);
1823 ASSERT (strcmp (result, "0001.234000e+03 33") == 0
1824 || strcmp (result, "001.234000e+003 33") == 0);
1825 ASSERT (retval == strlen (result));
1828 { /* FLAG_ZERO with infinite number. */
1831 my_sprintf (result, "%015e %d", -1.0 / 0.0, 33, 44, 55);
1832 ASSERT (strcmp (result, " -inf 33") == 0
1833 || strcmp (result, " -infinity 33") == 0);
1834 ASSERT (retval == strlen (result));
1837 { /* FLAG_ZERO with NaN. */
1840 my_sprintf (result, "%050e %d", NaNd (), 33, 44, 55);
1841 ASSERT (strlen (result) == 50 + 3
1842 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
1843 && strcmp (result + strlen (result) - 3, " 33") == 0);
1844 ASSERT (retval == strlen (result));
1850 my_sprintf (result, "%.e %d", 1234.0, 33, 44, 55);
1851 ASSERT (strcmp (result, "1e+03 33") == 0
1852 || strcmp (result, "1e+003 33") == 0);
1853 ASSERT (retval == strlen (result));
1856 { /* Precision with no rounding. */
1859 my_sprintf (result, "%.4e %d", 999.951, 33, 44, 55);
1860 ASSERT (strcmp (result, "9.9995e+02 33") == 0
1861 || strcmp (result, "9.9995e+002 33") == 0);
1862 ASSERT (retval == strlen (result));
1865 { /* Precision with rounding. */
1868 my_sprintf (result, "%.4e %d", 999.996, 33, 44, 55);
1869 ASSERT (strcmp (result, "1.0000e+03 33") == 0
1870 || strcmp (result, "1.0000e+003 33") == 0);
1871 ASSERT (retval == strlen (result));
1874 { /* A positive number. */
1877 my_sprintf (result, "%Le %d", 12.75L, 33, 44, 55);
1878 ASSERT (strcmp (result, "1.275000e+01 33") == 0
1879 || strcmp (result, "1.275000e+001 33") == 0);
1880 ASSERT (retval == strlen (result));
1883 { /* A larger positive number. */
1886 my_sprintf (result, "%Le %d", 1234567.0L, 33, 44, 55);
1887 ASSERT (strcmp (result, "1.234567e+06 33") == 0
1888 || strcmp (result, "1.234567e+006 33") == 0);
1889 ASSERT (retval == strlen (result));
1892 { /* Small and large positive numbers. */
1893 static struct { long double value; const char *string; } data[] =
1895 { 1.234321234321234e-37L, "1.234321e-37" },
1896 { 1.234321234321234e-36L, "1.234321e-36" },
1897 { 1.234321234321234e-35L, "1.234321e-35" },
1898 { 1.234321234321234e-34L, "1.234321e-34" },
1899 { 1.234321234321234e-33L, "1.234321e-33" },
1900 { 1.234321234321234e-32L, "1.234321e-32" },
1901 { 1.234321234321234e-31L, "1.234321e-31" },
1902 { 1.234321234321234e-30L, "1.234321e-30" },
1903 { 1.234321234321234e-29L, "1.234321e-29" },
1904 { 1.234321234321234e-28L, "1.234321e-28" },
1905 { 1.234321234321234e-27L, "1.234321e-27" },
1906 { 1.234321234321234e-26L, "1.234321e-26" },
1907 { 1.234321234321234e-25L, "1.234321e-25" },
1908 { 1.234321234321234e-24L, "1.234321e-24" },
1909 { 1.234321234321234e-23L, "1.234321e-23" },
1910 { 1.234321234321234e-22L, "1.234321e-22" },
1911 { 1.234321234321234e-21L, "1.234321e-21" },
1912 { 1.234321234321234e-20L, "1.234321e-20" },
1913 { 1.234321234321234e-19L, "1.234321e-19" },
1914 { 1.234321234321234e-18L, "1.234321e-18" },
1915 { 1.234321234321234e-17L, "1.234321e-17" },
1916 { 1.234321234321234e-16L, "1.234321e-16" },
1917 { 1.234321234321234e-15L, "1.234321e-15" },
1918 { 1.234321234321234e-14L, "1.234321e-14" },
1919 { 1.234321234321234e-13L, "1.234321e-13" },
1920 { 1.234321234321234e-12L, "1.234321e-12" },
1921 { 1.234321234321234e-11L, "1.234321e-11" },
1922 { 1.234321234321234e-10L, "1.234321e-10" },
1923 { 1.234321234321234e-9L, "1.234321e-09" },
1924 { 1.234321234321234e-8L, "1.234321e-08" },
1925 { 1.234321234321234e-7L, "1.234321e-07" },
1926 { 1.234321234321234e-6L, "1.234321e-06" },
1927 { 1.234321234321234e-5L, "1.234321e-05" },
1928 { 1.234321234321234e-4L, "1.234321e-04" },
1929 { 1.234321234321234e-3L, "1.234321e-03" },
1930 { 1.234321234321234e-2L, "1.234321e-02" },
1931 { 1.234321234321234e-1L, "1.234321e-01" },
1932 { 1.234321234321234L, "1.234321e+00" },
1933 { 1.234321234321234e1L, "1.234321e+01" },
1934 { 1.234321234321234e2L, "1.234321e+02" },
1935 { 1.234321234321234e3L, "1.234321e+03" },
1936 { 1.234321234321234e4L, "1.234321e+04" },
1937 { 1.234321234321234e5L, "1.234321e+05" },
1938 { 1.234321234321234e6L, "1.234321e+06" },
1939 { 1.234321234321234e7L, "1.234321e+07" },
1940 { 1.234321234321234e8L, "1.234321e+08" },
1941 { 1.234321234321234e9L, "1.234321e+09" },
1942 { 1.234321234321234e10L, "1.234321e+10" },
1943 { 1.234321234321234e11L, "1.234321e+11" },
1944 { 1.234321234321234e12L, "1.234321e+12" },
1945 { 1.234321234321234e13L, "1.234321e+13" },
1946 { 1.234321234321234e14L, "1.234321e+14" },
1947 { 1.234321234321234e15L, "1.234321e+15" },
1948 { 1.234321234321234e16L, "1.234321e+16" },
1949 { 1.234321234321234e17L, "1.234321e+17" },
1950 { 1.234321234321234e18L, "1.234321e+18" },
1951 { 1.234321234321234e19L, "1.234321e+19" },
1952 { 1.234321234321234e20L, "1.234321e+20" },
1953 { 1.234321234321234e21L, "1.234321e+21" },
1954 { 1.234321234321234e22L, "1.234321e+22" },
1955 { 1.234321234321234e23L, "1.234321e+23" },
1956 { 1.234321234321234e24L, "1.234321e+24" },
1957 { 1.234321234321234e25L, "1.234321e+25" },
1958 { 1.234321234321234e26L, "1.234321e+26" },
1959 { 1.234321234321234e27L, "1.234321e+27" },
1960 { 1.234321234321234e28L, "1.234321e+28" },
1961 { 1.234321234321234e29L, "1.234321e+29" },
1962 { 1.234321234321234e30L, "1.234321e+30" },
1963 { 1.234321234321234e31L, "1.234321e+31" },
1964 { 1.234321234321234e32L, "1.234321e+32" },
1965 { 1.234321234321234e33L, "1.234321e+33" },
1966 { 1.234321234321234e34L, "1.234321e+34" },
1967 { 1.234321234321234e35L, "1.234321e+35" },
1968 { 1.234321234321234e36L, "1.234321e+36" }
1971 for (k = 0; k < SIZEOF (data); k++)
1975 my_sprintf (result, "%Le", data[k].value);
1976 const char *expected = data[k].string;
1977 ASSERT (strcmp (result, expected) == 0
1978 /* Some implementations produce exponents with 3 digits. */
1979 || (strlen (result) == strlen (expected) + 1
1980 && memcmp (result, expected, strlen (expected) - 2) == 0
1981 && result[strlen (expected) - 2] == '0'
1982 && strcmp (result + strlen (expected) - 1,
1983 expected + strlen (expected) - 2)
1985 ASSERT (retval == strlen (result));
1989 { /* A negative number. */
1992 my_sprintf (result, "%Le %d", -0.03125L, 33, 44, 55);
1993 ASSERT (strcmp (result, "-3.125000e-02 33") == 0
1994 || strcmp (result, "-3.125000e-002 33") == 0);
1995 ASSERT (retval == strlen (result));
1998 { /* Positive zero. */
2001 my_sprintf (result, "%Le %d", 0.0L, 33, 44, 55);
2002 ASSERT (strcmp (result, "0.000000e+00 33") == 0
2003 || strcmp (result, "0.000000e+000 33") == 0);
2004 ASSERT (retval == strlen (result));
2007 { /* Negative zero. */
2010 my_sprintf (result, "%Le %d", minus_zerol, 33, 44, 55);
2011 if (have_minus_zero ())
2012 ASSERT (strcmp (result, "-0.000000e+00 33") == 0
2013 || strcmp (result, "-0.000000e+000 33") == 0);
2014 ASSERT (retval == strlen (result));
2017 { /* Positive infinity. */
2020 my_sprintf (result, "%Le %d", 1.0L / 0.0L, 33, 44, 55);
2021 ASSERT (strcmp (result, "inf 33") == 0
2022 || strcmp (result, "infinity 33") == 0);
2023 ASSERT (retval == strlen (result));
2026 { /* Negative infinity. */
2029 my_sprintf (result, "%Le %d", -1.0L / 0.0L, 33, 44, 55);
2030 ASSERT (strcmp (result, "-inf 33") == 0
2031 || strcmp (result, "-infinity 33") == 0);
2032 ASSERT (retval == strlen (result));
2038 my_sprintf (result, "%Le %d", NaNl (), 33, 44, 55);
2039 ASSERT (strlen (result) >= 3 + 3
2040 && strisnan (result, 0, strlen (result) - 3, 0)
2041 && strcmp (result + strlen (result) - 3, " 33") == 0);
2042 ASSERT (retval == strlen (result));
2044 #if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
2046 static union { unsigned int word[4]; long double value; } x =
2047 { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
2050 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2051 ASSERT (strlen (result) >= 3 + 3
2052 && strisnan (result, 0, strlen (result) - 3, 0)
2053 && strcmp (result + strlen (result) - 3, " 33") == 0);
2054 ASSERT (retval == strlen (result));
2057 /* Signalling NaN. */
2058 static union { unsigned int word[4]; long double value; } x =
2059 { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
2062 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2063 ASSERT (strlen (result) >= 3 + 3
2064 && strisnan (result, 0, strlen (result) - 3, 0)
2065 && strcmp (result + strlen (result) - 3, " 33") == 0);
2066 ASSERT (retval == strlen (result));
2068 /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
2069 Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
2070 Intel IA-64 Architecture Software Developer's Manual, Volume 1:
2071 Application Architecture.
2072 Table 5-2 "Floating-Point Register Encodings"
2073 Figure 5-6 "Memory to Floating-Point Register Data Translation"
2076 static union { unsigned int word[4]; long double value; } x =
2077 { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
2080 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2081 ASSERT (strlen (result) >= 3 + 3
2082 && strisnan (result, 0, strlen (result) - 3, 0)
2083 && strcmp (result + strlen (result) - 3, " 33") == 0);
2084 ASSERT (retval == strlen (result));
2086 { /* Pseudo-Infinity. */
2087 static union { unsigned int word[4]; long double value; } x =
2088 { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
2091 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2092 ASSERT (strlen (result) >= 3 + 3
2093 && strisnan (result, 0, strlen (result) - 3, 0)
2094 && strcmp (result + strlen (result) - 3, " 33") == 0);
2095 ASSERT (retval == strlen (result));
2097 { /* Pseudo-Zero. */
2098 static union { unsigned int word[4]; long double value; } x =
2099 { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
2102 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2103 ASSERT (strlen (result) >= 3 + 3
2104 && strisnan (result, 0, strlen (result) - 3, 0)
2105 && strcmp (result + strlen (result) - 3, " 33") == 0);
2106 ASSERT (retval == strlen (result));
2108 { /* Unnormalized number. */
2109 static union { unsigned int word[4]; long double value; } x =
2110 { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
2113 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2114 ASSERT (strlen (result) >= 3 + 3
2115 && strisnan (result, 0, strlen (result) - 3, 0)
2116 && strcmp (result + strlen (result) - 3, " 33") == 0);
2117 ASSERT (retval == strlen (result));
2119 { /* Pseudo-Denormal. */
2120 static union { unsigned int word[4]; long double value; } x =
2121 { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
2124 my_sprintf (result, "%Le %d", x.value, 33, 44, 55);
2125 ASSERT (strlen (result) >= 3 + 3
2126 && strisnan (result, 0, strlen (result) - 3, 0)
2127 && strcmp (result + strlen (result) - 3, " 33") == 0);
2128 ASSERT (retval == strlen (result));
2135 my_sprintf (result, "%15Le %d", 1.75L, 33, 44, 55);
2136 ASSERT (strcmp (result, " 1.750000e+00 33") == 0
2137 || strcmp (result, " 1.750000e+000 33") == 0);
2138 ASSERT (retval == strlen (result));
2144 my_sprintf (result, "%-15Le %d", 1.75L, 33, 44, 55);
2145 ASSERT (strcmp (result, "1.750000e+00 33") == 0
2146 || strcmp (result, "1.750000e+000 33") == 0);
2147 ASSERT (retval == strlen (result));
2150 { /* FLAG_SHOWSIGN. */
2153 my_sprintf (result, "%+Le %d", 1.75L, 33, 44, 55);
2154 ASSERT (strcmp (result, "+1.750000e+00 33") == 0
2155 || strcmp (result, "+1.750000e+000 33") == 0);
2156 ASSERT (retval == strlen (result));
2162 my_sprintf (result, "% Le %d", 1.75L, 33, 44, 55);
2163 ASSERT (strcmp (result, " 1.750000e+00 33") == 0
2164 || strcmp (result, " 1.750000e+000 33") == 0);
2165 ASSERT (retval == strlen (result));
2171 my_sprintf (result, "%#Le %d", 1.75L, 33, 44, 55);
2172 ASSERT (strcmp (result, "1.750000e+00 33") == 0
2173 || strcmp (result, "1.750000e+000 33") == 0);
2174 ASSERT (retval == strlen (result));
2180 my_sprintf (result, "%#.Le %d", 1.75L, 33, 44, 55);
2181 ASSERT (strcmp (result, "2.e+00 33") == 0
2182 || strcmp (result, "2.e+000 33") == 0);
2183 ASSERT (retval == strlen (result));
2189 my_sprintf (result, "%#.Le %d", 9.75L, 33, 44, 55);
2190 ASSERT (strcmp (result, "1.e+01 33") == 0
2191 || strcmp (result, "1.e+001 33") == 0);
2192 ASSERT (retval == strlen (result));
2195 { /* FLAG_ZERO with finite number. */
2198 my_sprintf (result, "%015Le %d", 1234.0L, 33, 44, 55);
2199 ASSERT (strcmp (result, "0001.234000e+03 33") == 0
2200 || strcmp (result, "001.234000e+003 33") == 0);
2201 ASSERT (retval == strlen (result));
2204 { /* FLAG_ZERO with infinite number. */
2207 my_sprintf (result, "%015Le %d", -1.0L / 0.0L, 33, 44, 55);
2208 ASSERT (strcmp (result, " -inf 33") == 0
2209 || strcmp (result, " -infinity 33") == 0);
2210 ASSERT (retval == strlen (result));
2213 { /* FLAG_ZERO with NaN. */
2216 my_sprintf (result, "%050Le %d", NaNl (), 33, 44, 55);
2217 ASSERT (strlen (result) == 50 + 3
2218 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
2219 && strcmp (result + strlen (result) - 3, " 33") == 0);
2220 ASSERT (retval == strlen (result));
2226 my_sprintf (result, "%.Le %d", 1234.0L, 33, 44, 55);
2227 ASSERT (strcmp (result, "1e+03 33") == 0
2228 || strcmp (result, "1e+003 33") == 0);
2229 ASSERT (retval == strlen (result));
2232 { /* Precision with no rounding. */
2235 my_sprintf (result, "%.4Le %d", 999.951L, 33, 44, 55);
2236 ASSERT (strcmp (result, "9.9995e+02 33") == 0
2237 || strcmp (result, "9.9995e+002 33") == 0);
2238 ASSERT (retval == strlen (result));
2241 { /* Precision with rounding. */
2244 my_sprintf (result, "%.4Le %d", 999.996L, 33, 44, 55);
2245 ASSERT (strcmp (result, "1.0000e+03 33") == 0
2246 || strcmp (result, "1.0000e+003 33") == 0);
2247 ASSERT (retval == strlen (result));
2250 /* Test the support of the %g format directive. */
2252 { /* A positive number. */
2255 my_sprintf (result, "%g %d", 12.75, 33, 44, 55);
2256 ASSERT (strcmp (result, "12.75 33") == 0);
2257 ASSERT (retval == strlen (result));
2260 { /* A larger positive number. */
2263 my_sprintf (result, "%g %d", 1234567.0, 33, 44, 55);
2264 ASSERT (strcmp (result, "1.23457e+06 33") == 0
2265 || strcmp (result, "1.23457e+006 33") == 0);
2266 ASSERT (retval == strlen (result));
2269 { /* Small and large positive numbers. */
2270 static struct { double value; const char *string; } data[] =
2272 { 1.234321234321234e-37, "1.23432e-37" },
2273 { 1.234321234321234e-36, "1.23432e-36" },
2274 { 1.234321234321234e-35, "1.23432e-35" },
2275 { 1.234321234321234e-34, "1.23432e-34" },
2276 { 1.234321234321234e-33, "1.23432e-33" },
2277 { 1.234321234321234e-32, "1.23432e-32" },
2278 { 1.234321234321234e-31, "1.23432e-31" },
2279 { 1.234321234321234e-30, "1.23432e-30" },
2280 { 1.234321234321234e-29, "1.23432e-29" },
2281 { 1.234321234321234e-28, "1.23432e-28" },
2282 { 1.234321234321234e-27, "1.23432e-27" },
2283 { 1.234321234321234e-26, "1.23432e-26" },
2284 { 1.234321234321234e-25, "1.23432e-25" },
2285 { 1.234321234321234e-24, "1.23432e-24" },
2286 { 1.234321234321234e-23, "1.23432e-23" },
2287 { 1.234321234321234e-22, "1.23432e-22" },
2288 { 1.234321234321234e-21, "1.23432e-21" },
2289 { 1.234321234321234e-20, "1.23432e-20" },
2290 { 1.234321234321234e-19, "1.23432e-19" },
2291 { 1.234321234321234e-18, "1.23432e-18" },
2292 { 1.234321234321234e-17, "1.23432e-17" },
2293 { 1.234321234321234e-16, "1.23432e-16" },
2294 { 1.234321234321234e-15, "1.23432e-15" },
2295 { 1.234321234321234e-14, "1.23432e-14" },
2296 { 1.234321234321234e-13, "1.23432e-13" },
2297 { 1.234321234321234e-12, "1.23432e-12" },
2298 { 1.234321234321234e-11, "1.23432e-11" },
2299 { 1.234321234321234e-10, "1.23432e-10" },
2300 { 1.234321234321234e-9, "1.23432e-09" },
2301 { 1.234321234321234e-8, "1.23432e-08" },
2302 { 1.234321234321234e-7, "1.23432e-07" },
2303 { 1.234321234321234e-6, "1.23432e-06" },
2304 { 1.234321234321234e-5, "1.23432e-05" },
2305 { 1.234321234321234e-4, "0.000123432" },
2306 { 1.234321234321234e-3, "0.00123432" },
2307 { 1.234321234321234e-2, "0.0123432" },
2308 { 1.234321234321234e-1, "0.123432" },
2309 { 1.234321234321234, "1.23432" },
2310 { 1.234321234321234e1, "12.3432" },
2311 { 1.234321234321234e2, "123.432" },
2312 { 1.234321234321234e3, "1234.32" },
2313 { 1.234321234321234e4, "12343.2" },
2314 { 1.234321234321234e5, "123432" },
2315 { 1.234321234321234e6, "1.23432e+06" },
2316 { 1.234321234321234e7, "1.23432e+07" },
2317 { 1.234321234321234e8, "1.23432e+08" },
2318 { 1.234321234321234e9, "1.23432e+09" },
2319 { 1.234321234321234e10, "1.23432e+10" },
2320 { 1.234321234321234e11, "1.23432e+11" },
2321 { 1.234321234321234e12, "1.23432e+12" },
2322 { 1.234321234321234e13, "1.23432e+13" },
2323 { 1.234321234321234e14, "1.23432e+14" },
2324 { 1.234321234321234e15, "1.23432e+15" },
2325 { 1.234321234321234e16, "1.23432e+16" },
2326 { 1.234321234321234e17, "1.23432e+17" },
2327 { 1.234321234321234e18, "1.23432e+18" },
2328 { 1.234321234321234e19, "1.23432e+19" },
2329 { 1.234321234321234e20, "1.23432e+20" },
2330 { 1.234321234321234e21, "1.23432e+21" },
2331 { 1.234321234321234e22, "1.23432e+22" },
2332 { 1.234321234321234e23, "1.23432e+23" },
2333 { 1.234321234321234e24, "1.23432e+24" },
2334 { 1.234321234321234e25, "1.23432e+25" },
2335 { 1.234321234321234e26, "1.23432e+26" },
2336 { 1.234321234321234e27, "1.23432e+27" },
2337 { 1.234321234321234e28, "1.23432e+28" },
2338 { 1.234321234321234e29, "1.23432e+29" },
2339 { 1.234321234321234e30, "1.23432e+30" },
2340 { 1.234321234321234e31, "1.23432e+31" },
2341 { 1.234321234321234e32, "1.23432e+32" },
2342 { 1.234321234321234e33, "1.23432e+33" },
2343 { 1.234321234321234e34, "1.23432e+34" },
2344 { 1.234321234321234e35, "1.23432e+35" },
2345 { 1.234321234321234e36, "1.23432e+36" }
2348 for (k = 0; k < SIZEOF (data); k++)
2352 my_sprintf (result, "%g", data[k].value);
2353 const char *expected = data[k].string;
2354 ASSERT (strcmp (result, expected) == 0
2355 /* Some implementations produce exponents with 3 digits. */
2356 || (expected[strlen (expected) - 4] == 'e'
2357 && strlen (result) == strlen (expected) + 1
2358 && memcmp (result, expected, strlen (expected) - 2) == 0
2359 && result[strlen (expected) - 2] == '0'
2360 && strcmp (result + strlen (expected) - 1,
2361 expected + strlen (expected) - 2)
2363 ASSERT (retval == strlen (result));
2367 { /* A negative number. */
2370 my_sprintf (result, "%g %d", -0.03125, 33, 44, 55);
2371 ASSERT (strcmp (result, "-0.03125 33") == 0);
2372 ASSERT (retval == strlen (result));
2375 { /* Positive zero. */
2378 my_sprintf (result, "%g %d", 0.0, 33, 44, 55);
2379 ASSERT (strcmp (result, "0 33") == 0);
2380 ASSERT (retval == strlen (result));
2383 { /* Negative zero. */
2386 my_sprintf (result, "%g %d", -zerod, 33, 44, 55);
2387 if (have_minus_zero ())
2388 ASSERT (strcmp (result, "-0 33") == 0);
2389 ASSERT (retval == strlen (result));
2392 { /* Positive infinity. */
2395 my_sprintf (result, "%g %d", 1.0 / 0.0, 33, 44, 55);
2396 ASSERT (strcmp (result, "inf 33") == 0
2397 || strcmp (result, "infinity 33") == 0);
2398 ASSERT (retval == strlen (result));
2401 { /* Negative infinity. */
2404 my_sprintf (result, "%g %d", -1.0 / 0.0, 33, 44, 55);
2405 ASSERT (strcmp (result, "-inf 33") == 0
2406 || strcmp (result, "-infinity 33") == 0);
2407 ASSERT (retval == strlen (result));
2413 my_sprintf (result, "%g %d", NaNd (), 33, 44, 55);
2414 ASSERT (strlen (result) >= 3 + 3
2415 && strisnan (result, 0, strlen (result) - 3, 0)
2416 && strcmp (result + strlen (result) - 3, " 33") == 0);
2417 ASSERT (retval == strlen (result));
2423 my_sprintf (result, "%10g %d", 1.75, 33, 44, 55);
2424 ASSERT (strcmp (result, " 1.75 33") == 0);
2425 ASSERT (retval == strlen (result));
2431 my_sprintf (result, "%-10g %d", 1.75, 33, 44, 55);
2432 ASSERT (strcmp (result, "1.75 33") == 0);
2433 ASSERT (retval == strlen (result));
2436 { /* FLAG_SHOWSIGN. */
2439 my_sprintf (result, "%+g %d", 1.75, 33, 44, 55);
2440 ASSERT (strcmp (result, "+1.75 33") == 0);
2441 ASSERT (retval == strlen (result));
2447 my_sprintf (result, "% g %d", 1.75, 33, 44, 55);
2448 ASSERT (strcmp (result, " 1.75 33") == 0);
2449 ASSERT (retval == strlen (result));
2455 my_sprintf (result, "%#g %d", 1.75, 33, 44, 55);
2456 ASSERT (strcmp (result, "1.75000 33") == 0);
2457 ASSERT (retval == strlen (result));
2463 my_sprintf (result, "%#.g %d", 1.75, 33, 44, 55);
2464 ASSERT (strcmp (result, "2. 33") == 0);
2465 ASSERT (retval == strlen (result));
2471 my_sprintf (result, "%#.g %d", 9.75, 33, 44, 55);
2472 ASSERT (strcmp (result, "1.e+01 33") == 0
2473 || strcmp (result, "1.e+001 33") == 0);
2474 ASSERT (retval == strlen (result));
2477 { /* FLAG_ZERO with finite number. */
2480 my_sprintf (result, "%010g %d", 1234.0, 33, 44, 55);
2481 ASSERT (strcmp (result, "0000001234 33") == 0);
2482 ASSERT (retval == strlen (result));
2485 { /* FLAG_ZERO with infinite number. */
2488 my_sprintf (result, "%015g %d", -1.0 / 0.0, 33, 44, 55);
2489 ASSERT (strcmp (result, " -inf 33") == 0
2490 || strcmp (result, " -infinity 33") == 0);
2491 ASSERT (retval == strlen (result));
2494 { /* FLAG_ZERO with NaN. */
2497 my_sprintf (result, "%050g %d", NaNd (), 33, 44, 55);
2498 ASSERT (strlen (result) == 50 + 3
2499 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
2500 && strcmp (result + strlen (result) - 3, " 33") == 0);
2501 ASSERT (retval == strlen (result));
2507 my_sprintf (result, "%.g %d", 1234.0, 33, 44, 55);
2508 ASSERT (strcmp (result, "1e+03 33") == 0
2509 || strcmp (result, "1e+003 33") == 0);
2510 ASSERT (retval == strlen (result));
2513 { /* Precision with no rounding. */
2516 my_sprintf (result, "%.5g %d", 999.951, 33, 44, 55);
2517 ASSERT (strcmp (result, "999.95 33") == 0);
2518 ASSERT (retval == strlen (result));
2521 { /* Precision with rounding. */
2524 my_sprintf (result, "%.5g %d", 999.996, 33, 44, 55);
2525 ASSERT (strcmp (result, "1000 33") == 0);
2526 ASSERT (retval == strlen (result));
2529 { /* A positive number. */
2532 my_sprintf (result, "%Lg %d", 12.75L, 33, 44, 55);
2533 ASSERT (strcmp (result, "12.75 33") == 0);
2534 ASSERT (retval == strlen (result));
2537 { /* A larger positive number. */
2540 my_sprintf (result, "%Lg %d", 1234567.0L, 33, 44, 55);
2541 ASSERT (strcmp (result, "1.23457e+06 33") == 0
2542 || strcmp (result, "1.23457e+006 33") == 0);
2543 ASSERT (retval == strlen (result));
2546 { /* Small and large positive numbers. */
2547 static struct { long double value; const char *string; } data[] =
2549 { 1.234321234321234e-37L, "1.23432e-37" },
2550 { 1.234321234321234e-36L, "1.23432e-36" },
2551 { 1.234321234321234e-35L, "1.23432e-35" },
2552 { 1.234321234321234e-34L, "1.23432e-34" },
2553 { 1.234321234321234e-33L, "1.23432e-33" },
2554 { 1.234321234321234e-32L, "1.23432e-32" },
2555 { 1.234321234321234e-31L, "1.23432e-31" },
2556 { 1.234321234321234e-30L, "1.23432e-30" },
2557 { 1.234321234321234e-29L, "1.23432e-29" },
2558 { 1.234321234321234e-28L, "1.23432e-28" },
2559 { 1.234321234321234e-27L, "1.23432e-27" },
2560 { 1.234321234321234e-26L, "1.23432e-26" },
2561 { 1.234321234321234e-25L, "1.23432e-25" },
2562 { 1.234321234321234e-24L, "1.23432e-24" },
2563 { 1.234321234321234e-23L, "1.23432e-23" },
2564 { 1.234321234321234e-22L, "1.23432e-22" },
2565 { 1.234321234321234e-21L, "1.23432e-21" },
2566 { 1.234321234321234e-20L, "1.23432e-20" },
2567 { 1.234321234321234e-19L, "1.23432e-19" },
2568 { 1.234321234321234e-18L, "1.23432e-18" },
2569 { 1.234321234321234e-17L, "1.23432e-17" },
2570 { 1.234321234321234e-16L, "1.23432e-16" },
2571 { 1.234321234321234e-15L, "1.23432e-15" },
2572 { 1.234321234321234e-14L, "1.23432e-14" },
2573 { 1.234321234321234e-13L, "1.23432e-13" },
2574 { 1.234321234321234e-12L, "1.23432e-12" },
2575 { 1.234321234321234e-11L, "1.23432e-11" },
2576 { 1.234321234321234e-10L, "1.23432e-10" },
2577 { 1.234321234321234e-9L, "1.23432e-09" },
2578 { 1.234321234321234e-8L, "1.23432e-08" },
2579 { 1.234321234321234e-7L, "1.23432e-07" },
2580 { 1.234321234321234e-6L, "1.23432e-06" },
2581 { 1.234321234321234e-5L, "1.23432e-05" },
2582 { 1.234321234321234e-4L, "0.000123432" },
2583 { 1.234321234321234e-3L, "0.00123432" },
2584 { 1.234321234321234e-2L, "0.0123432" },
2585 { 1.234321234321234e-1L, "0.123432" },
2586 { 1.234321234321234L, "1.23432" },
2587 { 1.234321234321234e1L, "12.3432" },
2588 { 1.234321234321234e2L, "123.432" },
2589 { 1.234321234321234e3L, "1234.32" },
2590 { 1.234321234321234e4L, "12343.2" },
2591 { 1.234321234321234e5L, "123432" },
2592 { 1.234321234321234e6L, "1.23432e+06" },
2593 { 1.234321234321234e7L, "1.23432e+07" },
2594 { 1.234321234321234e8L, "1.23432e+08" },
2595 { 1.234321234321234e9L, "1.23432e+09" },
2596 { 1.234321234321234e10L, "1.23432e+10" },
2597 { 1.234321234321234e11L, "1.23432e+11" },
2598 { 1.234321234321234e12L, "1.23432e+12" },
2599 { 1.234321234321234e13L, "1.23432e+13" },
2600 { 1.234321234321234e14L, "1.23432e+14" },
2601 { 1.234321234321234e15L, "1.23432e+15" },
2602 { 1.234321234321234e16L, "1.23432e+16" },
2603 { 1.234321234321234e17L, "1.23432e+17" },
2604 { 1.234321234321234e18L, "1.23432e+18" },
2605 { 1.234321234321234e19L, "1.23432e+19" },
2606 { 1.234321234321234e20L, "1.23432e+20" },
2607 { 1.234321234321234e21L, "1.23432e+21" },
2608 { 1.234321234321234e22L, "1.23432e+22" },
2609 { 1.234321234321234e23L, "1.23432e+23" },
2610 { 1.234321234321234e24L, "1.23432e+24" },
2611 { 1.234321234321234e25L, "1.23432e+25" },
2612 { 1.234321234321234e26L, "1.23432e+26" },
2613 { 1.234321234321234e27L, "1.23432e+27" },
2614 { 1.234321234321234e28L, "1.23432e+28" },
2615 { 1.234321234321234e29L, "1.23432e+29" },
2616 { 1.234321234321234e30L, "1.23432e+30" },
2617 { 1.234321234321234e31L, "1.23432e+31" },
2618 { 1.234321234321234e32L, "1.23432e+32" },
2619 { 1.234321234321234e33L, "1.23432e+33" },
2620 { 1.234321234321234e34L, "1.23432e+34" },
2621 { 1.234321234321234e35L, "1.23432e+35" },
2622 { 1.234321234321234e36L, "1.23432e+36" }
2625 for (k = 0; k < SIZEOF (data); k++)
2629 my_sprintf (result, "%Lg", data[k].value);
2630 const char *expected = data[k].string;
2631 ASSERT (strcmp (result, expected) == 0
2632 /* Some implementations produce exponents with 3 digits. */
2633 || (expected[strlen (expected) - 4] == 'e'
2634 && strlen (result) == strlen (expected) + 1
2635 && memcmp (result, expected, strlen (expected) - 2) == 0
2636 && result[strlen (expected) - 2] == '0'
2637 && strcmp (result + strlen (expected) - 1,
2638 expected + strlen (expected) - 2)
2640 ASSERT (retval == strlen (result));
2644 { /* A negative number. */
2647 my_sprintf (result, "%Lg %d", -0.03125L, 33, 44, 55);
2648 ASSERT (strcmp (result, "-0.03125 33") == 0);
2649 ASSERT (retval == strlen (result));
2652 { /* Positive zero. */
2655 my_sprintf (result, "%Lg %d", 0.0L, 33, 44, 55);
2656 ASSERT (strcmp (result, "0 33") == 0);
2657 ASSERT (retval == strlen (result));
2660 { /* Negative zero. */
2663 my_sprintf (result, "%Lg %d", minus_zerol, 33, 44, 55);
2664 if (have_minus_zero ())
2665 ASSERT (strcmp (result, "-0 33") == 0);
2666 ASSERT (retval == strlen (result));
2669 { /* Positive infinity. */
2672 my_sprintf (result, "%Lg %d", 1.0L / 0.0L, 33, 44, 55);
2673 ASSERT (strcmp (result, "inf 33") == 0
2674 || strcmp (result, "infinity 33") == 0);
2675 ASSERT (retval == strlen (result));
2678 { /* Negative infinity. */
2681 my_sprintf (result, "%Lg %d", -1.0L / 0.0L, 33, 44, 55);
2682 ASSERT (strcmp (result, "-inf 33") == 0
2683 || strcmp (result, "-infinity 33") == 0);
2684 ASSERT (retval == strlen (result));
2690 my_sprintf (result, "%Lg %d", NaNl (), 33, 44, 55);
2691 ASSERT (strlen (result) >= 3 + 3
2692 && strisnan (result, 0, strlen (result) - 3, 0)
2693 && strcmp (result + strlen (result) - 3, " 33") == 0);
2694 ASSERT (retval == strlen (result));
2696 #if CHECK_PRINTF_SAFE && ((defined __ia64 && LDBL_MANT_DIG == 64) || (defined __x86_64__ || defined __amd64__) || (defined __i386 || defined __i386__ || defined _I386 || defined _M_IX86 || defined _X86_))
2698 static union { unsigned int word[4]; long double value; } x =
2699 { LDBL80_WORDS (0xFFFF, 0xC3333333, 0x00000000) };
2702 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
2703 ASSERT (strlen (result) >= 3 + 3
2704 && strisnan (result, 0, strlen (result) - 3, 0)
2705 && strcmp (result + strlen (result) - 3, " 33") == 0);
2706 ASSERT (retval == strlen (result));
2709 /* Signalling NaN. */
2710 static union { unsigned int word[4]; long double value; } x =
2711 { LDBL80_WORDS (0xFFFF, 0x83333333, 0x00000000) };
2714 my_sprintf (result, "%La %d", x.value, 33, 44, 55);
2715 ASSERT (strlen (result) >= 3 + 3
2716 && strisnan (result, 0, strlen (result) - 3, 0)
2717 && strcmp (result + strlen (result) - 3, " 33") == 0);
2718 ASSERT (retval == strlen (result));
2720 /* The isnanl function should recognize Pseudo-NaNs, Pseudo-Infinities,
2721 Pseudo-Zeroes, Unnormalized Numbers, and Pseudo-Denormals, as defined in
2722 Intel IA-64 Architecture Software Developer's Manual, Volume 1:
2723 Application Architecture.
2724 Table 5-2 "Floating-Point Register Encodings"
2725 Figure 5-6 "Memory to Floating-Point Register Data Translation"
2728 static union { unsigned int word[4]; long double value; } x =
2729 { LDBL80_WORDS (0xFFFF, 0x40000001, 0x00000000) };
2732 my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
2733 ASSERT (strlen (result) >= 3 + 3
2734 && strisnan (result, 0, strlen (result) - 3, 0)
2735 && strcmp (result + strlen (result) - 3, " 33") == 0);
2736 ASSERT (retval == strlen (result));
2738 { /* Pseudo-Infinity. */
2739 static union { unsigned int word[4]; long double value; } x =
2740 { LDBL80_WORDS (0xFFFF, 0x00000000, 0x00000000) };
2743 my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
2744 ASSERT (strlen (result) >= 3 + 3
2745 && strisnan (result, 0, strlen (result) - 3, 0)
2746 && strcmp (result + strlen (result) - 3, " 33") == 0);
2747 ASSERT (retval == strlen (result));
2749 { /* Pseudo-Zero. */
2750 static union { unsigned int word[4]; long double value; } x =
2751 { LDBL80_WORDS (0x4004, 0x00000000, 0x00000000) };
2754 my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
2755 ASSERT (strlen (result) >= 3 + 3
2756 && strisnan (result, 0, strlen (result) - 3, 0)
2757 && strcmp (result + strlen (result) - 3, " 33") == 0);
2758 ASSERT (retval == strlen (result));
2760 { /* Unnormalized number. */
2761 static union { unsigned int word[4]; long double value; } x =
2762 { LDBL80_WORDS (0x4000, 0x63333333, 0x00000000) };
2765 my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
2766 ASSERT (strlen (result) >= 3 + 3
2767 && strisnan (result, 0, strlen (result) - 3, 0)
2768 && strcmp (result + strlen (result) - 3, " 33") == 0);
2769 ASSERT (retval == strlen (result));
2771 { /* Pseudo-Denormal. */
2772 static union { unsigned int word[4]; long double value; } x =
2773 { LDBL80_WORDS (0x0000, 0x83333333, 0x00000000) };
2776 my_sprintf (result, "%Lg %d", x.value, 33, 44, 55);
2777 ASSERT (strlen (result) >= 3 + 3
2778 && strisnan (result, 0, strlen (result) - 3, 0)
2779 && strcmp (result + strlen (result) - 3, " 33") == 0);
2780 ASSERT (retval == strlen (result));
2787 my_sprintf (result, "%10Lg %d", 1.75L, 33, 44, 55);
2788 ASSERT (strcmp (result, " 1.75 33") == 0);
2789 ASSERT (retval == strlen (result));
2795 my_sprintf (result, "%-10Lg %d", 1.75L, 33, 44, 55);
2796 ASSERT (strcmp (result, "1.75 33") == 0);
2797 ASSERT (retval == strlen (result));
2800 { /* FLAG_SHOWSIGN. */
2803 my_sprintf (result, "%+Lg %d", 1.75L, 33, 44, 55);
2804 ASSERT (strcmp (result, "+1.75 33") == 0);
2805 ASSERT (retval == strlen (result));
2811 my_sprintf (result, "% Lg %d", 1.75L, 33, 44, 55);
2812 ASSERT (strcmp (result, " 1.75 33") == 0);
2813 ASSERT (retval == strlen (result));
2819 my_sprintf (result, "%#Lg %d", 1.75L, 33, 44, 55);
2820 ASSERT (strcmp (result, "1.75000 33") == 0);
2821 ASSERT (retval == strlen (result));
2827 my_sprintf (result, "%#.Lg %d", 1.75L, 33, 44, 55);
2828 ASSERT (strcmp (result, "2. 33") == 0);
2829 ASSERT (retval == strlen (result));
2835 my_sprintf (result, "%#.Lg %d", 9.75L, 33, 44, 55);
2836 ASSERT (strcmp (result, "1.e+01 33") == 0
2837 || strcmp (result, "1.e+001 33") == 0);
2838 ASSERT (retval == strlen (result));
2841 { /* FLAG_ZERO with finite number. */
2844 my_sprintf (result, "%010Lg %d", 1234.0L, 33, 44, 55);
2845 ASSERT (strcmp (result, "0000001234 33") == 0);
2846 ASSERT (retval == strlen (result));
2849 { /* FLAG_ZERO with infinite number. */
2852 my_sprintf (result, "%015Lg %d", -1.0L / 0.0L, 33, 44, 55);
2853 ASSERT (strcmp (result, " -inf 33") == 0
2854 || strcmp (result, " -infinity 33") == 0);
2855 ASSERT (retval == strlen (result));
2858 { /* FLAG_ZERO with NaN. */
2861 my_sprintf (result, "%050Lg %d", NaNl (), 33, 44, 55);
2862 ASSERT (strlen (result) == 50 + 3
2863 && strisnan (result, strspn (result, " "), strlen (result) - 3, 0)
2864 && strcmp (result + strlen (result) - 3, " 33") == 0);
2865 ASSERT (retval == strlen (result));
2871 my_sprintf (result, "%.Lg %d", 1234.0L, 33, 44, 55);
2872 ASSERT (strcmp (result, "1e+03 33") == 0
2873 || strcmp (result, "1e+003 33") == 0);
2874 ASSERT (retval == strlen (result));
2877 { /* Precision with no rounding. */
2880 my_sprintf (result, "%.5Lg %d", 999.951L, 33, 44, 55);
2881 ASSERT (strcmp (result, "999.95 33") == 0);
2882 ASSERT (retval == strlen (result));
2885 { /* Precision with rounding. */
2888 my_sprintf (result, "%.5Lg %d", 999.996L, 33, 44, 55);
2889 ASSERT (strcmp (result, "1000 33") == 0);
2890 ASSERT (retval == strlen (result));
2893 /* Test the support of the %n format directive. */
2899 my_sprintf (result, "%d %n", 123, &count, 33, 44, 55);
2900 ASSERT (strcmp (result, "123 ") == 0);
2901 ASSERT (retval == strlen (result));
2902 ASSERT (count == 4);
2905 /* Test the support of the POSIX/XSI format strings with positions. */
2910 my_sprintf (result, "%2$d %1$d", 33, 55);
2911 ASSERT (strcmp (result, "55 33") == 0);
2912 ASSERT (retval == strlen (result));
2915 /* Test the support of the grouping flag. */
2920 my_sprintf (result, "%'d %d", 1234567, 99);
2921 ASSERT (result[strlen (result) - 1] == '9');
2922 ASSERT (retval == strlen (result));
2925 /* Test the support of the left-adjust flag. */
2930 my_sprintf (result, "a%*sc", -3, "b");
2931 ASSERT (strcmp (result, "ab c") == 0);
2932 ASSERT (retval == strlen (result));
2938 my_sprintf (result, "a%-*sc", 3, "b");
2939 ASSERT (strcmp (result, "ab c") == 0);
2940 ASSERT (retval == strlen (result));
2946 my_sprintf (result, "a%-*sc", -3, "b");
2947 ASSERT (strcmp (result, "ab c") == 0);
2948 ASSERT (retval == strlen (result));
2951 /* Test the support of large precision. */
2956 my_sprintf (result, "%.4000d %d", 1234567, 99);
2958 for (i = 0; i < 4000 - 7; i++)
2959 ASSERT (result[i] == '0');
2960 ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
2961 ASSERT (retval == strlen (result));
2967 my_sprintf (result, "%.*d %d", 4000, 1234567, 99);
2969 for (i = 0; i < 4000 - 7; i++)
2970 ASSERT (result[i] == '0');
2971 ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
2972 ASSERT (retval == strlen (result));
2978 my_sprintf (result, "%.4000d %d", -1234567, 99);
2980 ASSERT (result[0] == '-');
2981 for (i = 0; i < 4000 - 7; i++)
2982 ASSERT (result[1 + i] == '0');
2983 ASSERT (strcmp (result + 1 + 4000 - 7, "1234567 99") == 0);
2984 ASSERT (retval == strlen (result));
2990 my_sprintf (result, "%.4000u %d", 1234567, 99);
2992 for (i = 0; i < 4000 - 7; i++)
2993 ASSERT (result[i] == '0');
2994 ASSERT (strcmp (result + 4000 - 7, "1234567 99") == 0);
2995 ASSERT (retval == strlen (result));
3001 my_sprintf (result, "%.4000o %d", 1234567, 99);
3003 for (i = 0; i < 4000 - 7; i++)
3004 ASSERT (result[i] == '0');
3005 ASSERT (strcmp (result + 4000 - 7, "4553207 99") == 0);
3006 ASSERT (retval == strlen (result));
3012 my_sprintf (result, "%.4000x %d", 1234567, 99);
3014 for (i = 0; i < 4000 - 6; i++)
3015 ASSERT (result[i] == '0');
3016 ASSERT (strcmp (result + 4000 - 6, "12d687 99") == 0);
3017 ASSERT (retval == strlen (result));
3023 my_sprintf (result, "%#.4000x %d", 1234567, 99);
3025 ASSERT (result[0] == '0');
3026 ASSERT (result[1] == 'x');
3027 for (i = 0; i < 4000 - 6; i++)
3028 ASSERT (result[2 + i] == '0');
3029 ASSERT (strcmp (result + 2 + 4000 - 6, "12d687 99") == 0);
3030 ASSERT (retval == strlen (result));
3039 for (i = 0; i < sizeof (input) - 1; i++)
3040 input[i] = 'a' + ((1000000 / (i + 1)) % 26);
3042 retval = my_sprintf (result, "%.4000s %d", input, 99);
3043 ASSERT (memcmp (result, input, 4000) == 0);
3044 ASSERT (strcmp (result + 4000, " 99") == 0);
3045 ASSERT (retval == strlen (result));