| blob | 66a60846c8e351eb70d597b027dac4cfbae8e007 |
1 /* Floating point output for `printf'.
2 Copyright (C) 1995-1999, 2000, 2001, 2002 Free Software Foundation, Inc.
3 This file is part of the GNU C Library.
4 Written by Ulrich Drepper <drepper@gnu.ai.mit.edu>, 1995.
6 The GNU C Library is free software; you can redistribute it and/or
7 modify it under the terms of the GNU Lesser General Public
8 License as published by the Free Software Foundation; either
9 version 2.1 of the License, or (at your option) any later version.
11 The GNU C Library is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 Lesser General Public License for more details.
16 You should have received a copy of the GNU Lesser General Public
17 License along with the GNU C Library; if not, write to the Free
18 Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
19 02111-1307 USA. */
21 /* The gmp headers need some configuration frobs. */
22 #define HAVE_ALLOCA 1
24 #ifdef USE_IN_LIBIO
25 # include <libioP.h>
26 #else
27 # include <stdio.h>
28 #endif
29 #include <alloca.h>
30 #include <ctype.h>
31 #include <float.h>
32 #include <gmp-mparam.h>
33 #include <gmp.h>
34 #include <stdlib/gmp-impl.h>
35 #include <stdlib/longlong.h>
36 #include <stdlib/fpioconst.h>
37 #include <locale/localeinfo.h>
38 #include <limits.h>
39 #include <math.h>
40 #include <printf.h>
41 #include <string.h>
42 #include <unistd.h>
43 #include <stdlib.h>
44 #include <wchar.h>
46 #ifndef NDEBUG
48 #endif
49 #include <assert.h>
51 /* This defines make it possible to use the same code for GNU C library and
52 the GNU I/O library. */
53 #ifdef USE_IN_LIBIO
54 # define PUT(f, s, n) _IO_sputn (f, s, n)
55 # define PAD(f, c, n) (wide ? _IO_wpadn (f, c, n) : INTUSE(_IO_padn) (f, c, n))
56 /* We use this file GNU C library and GNU I/O library. So make
57 names equal. */
58 # undef putc
59 # define putc(c, f) (wide \
60 ? (int)_IO_putwc_unlocked (c, f) : _IO_putc_unlocked (c, f))
61 # define size_t _IO_size_t
62 # define FILE _IO_FILE
64 # define PUT(f, s, n) fwrite (s, 1, n, f)
65 # define PAD(f, c, n) __printf_pad (f, c, n)
68 \f
69 /* Macros for doing the actual output. */
71 #define outchar(ch) \
72 do \
73 { \
74 register const int outc = (ch); \
75 if (putc (outc, fp) == EOF) \
76 return -1; \
77 ++done; \
78 } while (0)
80 #define PRINT(ptr, wptr, len) \
81 do \
82 { \
83 register size_t outlen = (len); \
84 if (len > 20) \
85 { \
86 if (PUT (fp, wide ? (const char *) wptr : ptr, outlen) != outlen) \
87 return -1; \
88 ptr += outlen; \
89 done += outlen; \
90 } \
91 else \
92 { \
93 if (wide) \
94 while (outlen-- > 0) \
95 outchar (*wptr++); \
96 else \
97 while (outlen-- > 0) \
98 outchar (*ptr++); \
99 } \
100 } while (0)
102 #define PADN(ch, len) \
103 do \
104 { \
105 if (PAD (fp, ch, len) != len) \
106 return -1; \
107 done += len; \
108 } \
109 while (0)
110 \f
111 /* We use the GNU MP library to handle large numbers.
113 An MP variable occupies a varying number of entries in its array. We keep
114 track of this number for efficiency reasons. Otherwise we would always
115 have to process the whole array. */
116 #define MPN_VAR(name) mp_limb_t *name; mp_size_t name##size
118 #define MPN_ASSIGN(dst,src) \
119 memcpy (dst, src, (dst##size = src##size) * sizeof (mp_limb_t))
120 #define MPN_GE(u,v) \
121 (u##size > v##size || (u##size == v##size && __mpn_cmp (u, v, u##size) >= 0))
138 internal_function;
141 int
145 {
146 /* The floating-point value to output. */
147 union
148 {
150 __long_double_t ldbl;
151 }
152 fpnum;
154 /* Locale-dependent representation of decimal point. */
158 /* Locale-dependent thousands separator and grouping specification. */
163 /* "NaN" or "Inf" for the special cases. */
167 /* We need just a few limbs for the input before shifting to the right
168 position. */
170 /* We need to shift the contents of fp_input by this amount of bits. */
173 /* The fraction of the floting-point value in question */
175 /* and the exponent. */
177 /* Sign of the exponent. */
179 /* Sign of float number. */
182 /* Scaling factor. */
185 /* Temporary bignum value. */
188 /* Digit which is result of last hack_digit() call. */
191 /* The type of output format that will be used: 'e'/'E' or 'f'. */
194 /* Counter for number of written characters. */
197 /* General helper (carry limb). */
198 mp_limb_t cy;
200 /* Nonzero if this is output on a wide character stream. */
206 {
207 mp_limb_t hi;
212 {
216 }
217 else
218 {
221 else
222 {
231 {
232 /* We're not prepared for an mpn variable with zero
233 limbs. */
236 }
237 }
242 }
245 }
248 /* Figure out the decimal point character. */
250 {
253 }
254 else
255 {
260 _NL_MONETARY_DECIMAL_POINT_WC);
263 _NL_NUMERIC_DECIMAL_POINT_WC);
264 }
265 /* The decimal point character must not be zero. */
270 {
273 else
278 else
279 {
280 /* Figure out the thousands separator character. */
282 {
284 thousands_sepwc =
286 else
287 thousands_sepwc =
289 _NL_MONETARY_THOUSANDS_SEP_WC);
290 }
291 else
292 {
295 else
297 }
303 /* If we are printing multibyte characters and there is a
304 multibyte representation for the thousands separator,
305 we must ensure the wide character thousands separator
306 is available, even if it is fake. */
308 }
309 }
310 else
313 /* Fetch the argument value. */
314 #ifndef __NO_LONG_DOUBLE_MATH
316 {
319 /* Check for special values: not a number or infinity. */
321 {
323 {
326 }
327 else
328 {
331 }
333 }
335 {
337 {
340 }
341 else
342 {
345 }
347 }
348 else
349 {
356 }
357 }
358 else
360 {
363 /* Check for special values: not a number or infinity. */
365 {
367 {
370 }
371 else
372 {
375 }
377 }
379 {
381 {
384 }
385 else
386 {
389 }
391 }
392 else
393 {
399 }
400 }
403 {
426 }
429 /* We need three multiprecision variables. Now that we have the exponent
430 of the number we can allocate the needed memory. It would be more
431 efficient to use variables of the fixed maximum size but because this
432 would be really big it could lead to memory problems. */
433 {
439 }
441 /* We now have to distinguish between numbers with positive and negative
442 exponents because the method used for the one is not applicable/efficient
443 for the other. */
446 {
447 /* |FP| >= 8.0. */
455 {
459 }
460 else
461 {
468 }
472 do
473 {
476 /* The number of the product of two binary numbers with n and m
477 bits respectively has m+n or m+n-1 bits. */
479 {
481 {
482 #ifndef __NO_LONG_DOUBLE_MATH
485 {
486 #define _FPIO_CONST_SHIFT \
487 (((LDBL_MANT_DIG + BITS_PER_MP_LIMB - 1) / BITS_PER_MP_LIMB) \
488 - _FPIO_CONST_OFFSET)
489 /* 64bit const offset is not enough for
490 IEEE quad long double. */
496 }
497 else
498 #endif
499 {
503 }
504 }
505 else
506 {
514 }
517 {
523 }
524 }
526 }
530 /* Optimize number representations. We want to represent the numbers
531 with the lowest number of bytes possible without losing any
532 bytes. Also the highest bit in the scaling factor has to be set
533 (this is a requirement of the MPN division routines). */
535 {
536 /* Determine minimum number of zero bits at the end of
537 both numbers. */
539 ;
541 /* Determine number of bits the scaling factor is misplaced. */
545 {
546 /* The highest bit of the scaling factor is already set. So
547 we only have to remove the trailing empty limbs. */
549 {
554 }
555 }
556 else
557 {
559 {
562 {
567 }
568 }
569 else
572 /* Now shift the numbers to their optimal position. */
574 {
575 /* We cannot save any memory. So just roll both numbers
576 so that the scaling factor has its highest bit set. */
582 }
584 {
585 /* We can save memory by removing the trailing zero limbs
586 and by packing the non-zero limbs which gain another
587 free one. */
595 }
596 else
597 {
598 /* We can only save the memory of the limbs which are zero.
599 The non-zero parts occupy the same number of limbs. */
609 }
610 }
611 }
612 }
614 {
615 /* |FP| < 1.0. */
621 /* Now shift the input value to its right place. */
630 do
631 {
635 {
639 /* The __mpn_mul function expects the first argument to be
640 bigger than the second. */
646 else
660 /* If we increased the exponent by exactly 3 we have to test
661 for overflow. This is done by comparing with 10 shifted
662 to the right position. */
664 {
666 {
670 }
671 else
672 {
677 }
678 }
680 /* We have to be careful when multiplying the last factor.
681 If the result is greater than 1.0 be have to test it
682 against 10.0. If it is greater or equal to 10.0 the
683 multiplication was not valid. This is because we cannot
684 determine the number of bits in the result in advance. */
690 {
691 /* The factor is right. Adapt binary and decimal
692 exponents. */
696 /* If this factor yields a number greater or equal to
697 1.0, we must not shift the non-fractional digits down. */
701 /* Now we optimize the number representation. */
704 {
707 }
708 else
709 {
712 /* Now shift the numbers to their optimal position. */
714 {
715 /* We cannot save any memory. Just roll the
716 number so that the leading digit is in a
717 separate limb. */
722 }
724 {
728 }
729 else
730 {
731 /* We can only save the memory of the limbs which
732 are zero. The non-zero parts occupy the same
733 number of limbs. */
739 }
740 }
742 }
743 }
745 }
747 /* All factors but 10^-1 are tested now. */
749 {
758 {
763 }
764 else
769 }
771 }
772 else
773 {
774 /* This is a special case. We don't need a factor because the
775 numbers are in the range of 0.0 <= fp < 8.0. We simply
776 shift it to the right place and divide it by 1.0 to get the
777 leading digit. (Of course this division is not really made.) */
781 /* Now shift the input value to its right place. */
785 }
787 {
800 {
805 /* d . ddd e +- ddd */
808 }
810 {
814 {
818 }
819 else
820 {
823 }
826 }
827 else
828 {
832 {
835 else
840 }
841 else
842 {
846 /* We need space for the significant digits and perhaps
847 for leading zeros when < 1.0. The number of leading
848 zeros can be as many as would be required for
849 exponential notation with a negative two-digit
850 exponent, which is 4. */
852 }
855 }
858 {
859 /* Guess the number of groups we will make, and thus how
860 many spaces we need for separator characters. */
863 }
865 /* Allocate buffer for output. We need two more because while rounding
866 it is possible that we need two more characters in front of all the
867 other output. If the amount of memory we have to allocate is too
868 large use `malloc' instead of `alloca'. */
871 {
874 /* Signal an error to the caller. */
876 }
877 else
881 /* Do the real work: put digits in allocated buffer. */
883 {
886 {
889 }
895 }
896 else
897 {
898 /* |fp| < 1.0 and the selected type is 'f', so put "0."
899 in the buffer. */
903 }
905 /* Generate the needed number of fractional digits. */
908 {
914 {
918 }
920 }
922 /* Do rounding. */
925 {
931 {
932 /* This is the critical case. */
934 /* Rest of the number is zero -> round to even.
935 (IEEE 754-1985 4.1 says this is the default rounding.) */
938 {
939 /* Here we have to see whether all limbs are zero since no
940 normalization happened. */
945 /* Rest of the number is zero -> round to even.
946 (IEEE 754-1985 4.1 says this is the default rounding.) */
948 }
949 }
952 {
953 /* Process fractional digits. Terminate if not rounded or
954 radix character is reached. */
958 /* Round up. */
960 }
963 {
964 /* Round the integer digits. */
972 /* Round up. */
974 else
975 /* It is more critical. All digits were 9's. */
976 {
978 {
981 }
983 {
984 /* This is the case where for type %g the number fits
985 really in the range for %f output but after rounding
986 the number of digits is too big. */
991 {
992 /* Overwrite the old radix character. */
995 }
1001 /* Now we must print the exponent. */
1003 }
1004 else
1005 {
1006 /* We can simply add another another digit before the
1007 radix. */
1010 }
1012 /* While rounding the number of digits can change.
1013 If the number now exceeds the limits remove some
1014 fractional digits. */
1016 {
1019 }
1020 }
1021 }
1022 }
1024 do_expo:
1025 /* Now remove unnecessary '0' at the end of the string. */
1027 {
1030 }
1031 /* If we eliminate all fractional digits we perhaps also can remove
1032 the radix character. */
1037 /* Add in separator characters, overwriting the same buffer. */
1039 ngroups);
1041 /* Write the exponent if it is needed. */
1043 {
1047 /* Find the magnitude of the exponent. */
1053 /* Exponent always has at least two digits. */
1055 else
1056 do
1057 {
1061 }
1064 }
1066 /* Compute number of characters which must be filled with the padding
1067 character. */
1085 {
1091 {
1092 /* Create the single byte string. */
1101 else
1105 {
1109 /* Signal an error to the caller. */
1111 }
1112 else
1116 /* Now copy the wide character string. Since the character
1117 (except for the decimal point and thousands separator) must
1118 be coming from the ASCII range we can esily convert the
1119 string without mapping tables. */
1125 else
1127 }
1132 /* Free the memory if necessary. */
1134 {
1137 }
1138 }
1142 }
1144 }
1145 \f
1146 /* Return the number of extra grouping characters that will be inserted
1147 into a number with INTDIG_MAX integer digits. */
1149 unsigned int
1151 {
1154 /* We treat all negative values like CHAR_MAX. */
1157 /* No grouping should be done. */
1162 {
1167 #if CHAR_MIN < 0
1169 #endif
1170 )
1171 /* No more grouping should be done. */
1174 {
1175 /* Same grouping repeats. */
1178 }
1179 }
1182 }
1184 /* Group the INTDIG_NO integer digits of the number in [BUF,BUFEND).
1185 There is guaranteed enough space past BUFEND to extend it.
1186 Return the new end of buffer. */
1189 internal_function
1192 {
1198 /* Move the fractional part down. */
1203 do
1204 {
1206 do
1212 #if CHAR_MIN < 0
1214 #endif
1215 )
1216 /* No more grouping should be done. */
1219 /* Same grouping repeats. */
1223 /* Copy the remaining ungrouped digits. */
1224 do
1229 }