* transcode.c (trans_open_i): check the result of rb_transcoding_open.
[ruby-svn.git] / bignum.c
blobe9b7726dd38a80e8eaefa57b9101fc38eee60f75
1 /**********************************************************************
3 bignum.c -
5 $Author$
6 created at: Fri Jun 10 00:48:55 JST 1994
8 Copyright (C) 1993-2007 Yukihiro Matsumoto
10 **********************************************************************/
12 #include "ruby/ruby.h"
14 #include <math.h>
15 #include <float.h>
16 #include <ctype.h>
17 #ifdef HAVE_IEEEFP_H
18 #include <ieeefp.h>
19 #endif
21 VALUE rb_cBignum;
23 #if defined __MINGW32__
24 #define USHORT _USHORT
25 #endif
27 #define BDIGITS(x) (RBIGNUM_DIGITS(x))
28 #define BITSPERDIG (SIZEOF_BDIGITS*CHAR_BIT)
29 #define BIGRAD ((BDIGIT_DBL)1 << BITSPERDIG)
30 #define DIGSPERLONG ((unsigned int)(SIZEOF_LONG/SIZEOF_BDIGITS))
31 #if HAVE_LONG_LONG
32 # define DIGSPERLL ((unsigned int)(SIZEOF_LONG_LONG/SIZEOF_BDIGITS))
33 #endif
34 #define BIGUP(x) ((BDIGIT_DBL)(x) << BITSPERDIG)
35 #define BIGDN(x) RSHIFT(x,BITSPERDIG)
36 #define BIGLO(x) ((BDIGIT)((x) & (BIGRAD-1)))
37 #define BDIGMAX ((BDIGIT)-1)
39 #define BIGZEROP(x) (RBIGNUM_LEN(x) == 0 || \
40 (BDIGITS(x)[0] == 0 && \
41 (RBIGNUM_LEN(x) == 1 || bigzero_p(x))))
43 static int
44 bigzero_p(VALUE x)
46 long i;
47 for (i = RBIGNUM_LEN(x) - 1; 0 <= i; i--) {
48 if (BDIGITS(x)[i]) return 0;
50 return 1;
53 int
54 rb_cmpint(VALUE val, VALUE a, VALUE b)
56 if (NIL_P(val)) {
57 rb_cmperr(a, b);
59 if (FIXNUM_P(val)) return FIX2INT(val);
60 if (TYPE(val) == T_BIGNUM) {
61 if (BIGZEROP(val)) return 0;
62 if (RBIGNUM_SIGN(val)) return 1;
63 return -1;
65 if (RTEST(rb_funcall(val, '>', 1, INT2FIX(0)))) return 1;
66 if (RTEST(rb_funcall(val, '<', 1, INT2FIX(0)))) return -1;
67 return 0;
70 #define RBIGNUM_SET_LEN(b,l) \
71 ((RBASIC(b)->flags & RBIGNUM_EMBED_FLAG) ? \
72 (RBASIC(b)->flags = (RBASIC(b)->flags & ~RBIGNUM_EMBED_LEN_MASK) | \
73 ((l) << RBIGNUM_EMBED_LEN_SHIFT)) : \
74 (RBIGNUM(b)->as.heap.len = (l)))
76 static void
77 rb_big_realloc(VALUE big, long len)
79 BDIGIT *ds;
80 if (RBASIC(big)->flags & RBIGNUM_EMBED_FLAG) {
81 if (RBIGNUM_EMBED_LEN_MAX < len) {
82 ds = ALLOC_N(BDIGIT, len);
83 MEMCPY(ds, RBIGNUM(big)->as.ary, BDIGIT, RBIGNUM_EMBED_LEN_MAX);
84 RBIGNUM(big)->as.heap.len = RBIGNUM_LEN(big);
85 RBIGNUM(big)->as.heap.digits = ds;
86 RBASIC(big)->flags &= ~RBIGNUM_EMBED_FLAG;
89 else {
90 if (len <= RBIGNUM_EMBED_LEN_MAX) {
91 ds = RBIGNUM(big)->as.heap.digits;
92 RBASIC(big)->flags |= RBIGNUM_EMBED_FLAG;
93 RBIGNUM_SET_LEN(big, len);
94 if (ds) {
95 MEMCPY(RBIGNUM(big)->as.ary, ds, BDIGIT, len);
96 xfree(ds);
99 else {
100 if (RBIGNUM_LEN(big) == 0) {
101 RBIGNUM(big)->as.heap.digits = ALLOC_N(BDIGIT, len);
103 else {
104 REALLOC_N(RBIGNUM(big)->as.heap.digits, BDIGIT, len);
110 void
111 rb_big_resize(VALUE big, long len)
113 rb_big_realloc(big, len);
114 RBIGNUM_SET_LEN(big, len);
117 static VALUE
118 bignew_1(VALUE klass, long len, int sign)
120 NEWOBJ(big, struct RBignum);
121 OBJSETUP(big, klass, T_BIGNUM);
122 RBIGNUM_SET_SIGN(big, sign?1:0);
123 if (len <= RBIGNUM_EMBED_LEN_MAX) {
124 RBASIC(big)->flags |= RBIGNUM_EMBED_FLAG;
125 RBIGNUM_SET_LEN(big, len);
127 else {
128 rb_big_resize((VALUE)big, len);
131 return (VALUE)big;
134 #define bignew(len,sign) bignew_1(rb_cBignum,len,sign)
136 VALUE
137 rb_big_clone(VALUE x)
139 VALUE z = bignew_1(CLASS_OF(x), RBIGNUM_LEN(x), RBIGNUM_SIGN(x));
141 MEMCPY(BDIGITS(z), BDIGITS(x), BDIGIT, RBIGNUM_LEN(x));
142 return z;
145 /* modify a bignum by 2's complement */
146 static void
147 get2comp(VALUE x)
149 long i = RBIGNUM_LEN(x);
150 BDIGIT *ds = BDIGITS(x);
151 BDIGIT_DBL num;
153 if (!i) return;
154 while (i--) ds[i] = ~ds[i];
155 i = 0; num = 1;
156 do {
157 num += ds[i];
158 ds[i++] = BIGLO(num);
159 num = BIGDN(num);
160 } while (i < RBIGNUM_LEN(x));
161 if (num != 0) {
162 rb_big_resize(x, RBIGNUM_LEN(x)+1);
163 ds = BDIGITS(x);
164 ds[RBIGNUM_LEN(x)-1] = 1;
168 void
169 rb_big_2comp(VALUE x) /* get 2's complement */
171 get2comp(x);
174 static VALUE
175 bigtrunc(VALUE x)
177 long len = RBIGNUM_LEN(x);
178 BDIGIT *ds = BDIGITS(x);
180 if (len == 0) return x;
181 while (--len && !ds[len]);
182 rb_big_resize(x, len+1);
183 return x;
186 static VALUE
187 bigfixize(VALUE x)
189 long len = RBIGNUM_LEN(x);
190 BDIGIT *ds = BDIGITS(x);
192 if (len*SIZEOF_BDIGITS <= sizeof(long)) {
193 long num = 0;
194 while (len--) {
195 num = BIGUP(num) + ds[len];
197 if (num >= 0) {
198 if (RBIGNUM_SIGN(x)) {
199 if (POSFIXABLE(num)) return LONG2FIX(num);
201 else {
202 if (NEGFIXABLE(-(long)num)) return LONG2FIX(-(long)num);
206 return x;
209 static VALUE
210 bignorm(VALUE x)
212 if (!FIXNUM_P(x) && TYPE(x) == T_BIGNUM) {
213 x = bigfixize(bigtrunc(x));
215 return x;
218 VALUE
219 rb_big_norm(VALUE x)
221 return bignorm(x);
224 VALUE
225 rb_uint2big(VALUE n)
227 BDIGIT_DBL num = n;
228 long i = 0;
229 BDIGIT *digits;
230 VALUE big;
232 big = bignew(DIGSPERLONG, 1);
233 digits = BDIGITS(big);
234 while (i < DIGSPERLONG) {
235 digits[i++] = BIGLO(num);
236 num = BIGDN(num);
239 i = DIGSPERLONG;
240 while (--i && !digits[i]) ;
241 RBIGNUM_SET_LEN(big, i+1);
242 return big;
245 VALUE
246 rb_int2big(SIGNED_VALUE n)
248 long neg = 0;
249 VALUE big;
251 if (n < 0) {
252 n = -n;
253 neg = 1;
255 big = rb_uint2big(n);
256 if (neg) {
257 RBIGNUM_SET_SIGN(big, 0);
259 return big;
262 VALUE
263 rb_uint2inum(VALUE n)
265 if (POSFIXABLE(n)) return LONG2FIX(n);
266 return rb_uint2big(n);
269 VALUE
270 rb_int2inum(SIGNED_VALUE n)
272 if (FIXABLE(n)) return LONG2FIX(n);
273 return rb_int2big(n);
276 #ifdef HAVE_LONG_LONG
278 void
279 rb_quad_pack(char *buf, VALUE val)
281 LONG_LONG q;
283 val = rb_to_int(val);
284 if (FIXNUM_P(val)) {
285 q = FIX2LONG(val);
287 else {
288 long len = RBIGNUM_LEN(val);
289 BDIGIT *ds;
291 if (len > SIZEOF_LONG_LONG/SIZEOF_BDIGITS) {
292 len = SIZEOF_LONG_LONG/SIZEOF_BDIGITS;
294 ds = BDIGITS(val);
295 q = 0;
296 while (len--) {
297 q = BIGUP(q);
298 q += ds[len];
300 if (!RBIGNUM_SIGN(val)) q = -q;
302 memcpy(buf, (char*)&q, SIZEOF_LONG_LONG);
305 VALUE
306 rb_quad_unpack(const char *buf, int sign)
308 unsigned LONG_LONG q;
309 long neg = 0;
310 long i;
311 BDIGIT *digits;
312 VALUE big;
314 memcpy(&q, buf, SIZEOF_LONG_LONG);
315 if (sign) {
316 if (FIXABLE((LONG_LONG)q)) return LONG2FIX((LONG_LONG)q);
317 if ((LONG_LONG)q < 0) {
318 q = -(LONG_LONG)q;
319 neg = 1;
322 else {
323 if (POSFIXABLE(q)) return LONG2FIX(q);
326 i = 0;
327 big = bignew(DIGSPERLL, 1);
328 digits = BDIGITS(big);
329 while (i < DIGSPERLL) {
330 digits[i++] = BIGLO(q);
331 q = BIGDN(q);
334 i = DIGSPERLL;
335 while (i-- && !digits[i]) ;
336 RBIGNUM_SET_LEN(big, i+1);
338 if (neg) {
339 RBIGNUM_SET_SIGN(big, 0);
341 return bignorm(big);
344 #else
346 #define QUAD_SIZE 8
348 void
349 rb_quad_pack(char *buf, VALUE val)
351 long len;
353 memset(buf, 0, QUAD_SIZE);
354 val = rb_to_int(val);
355 if (FIXNUM_P(val)) {
356 val = rb_int2big(FIX2LONG(val));
358 len = RBIGNUM_LEN(val) * SIZEOF_BDIGITS;
359 if (len > QUAD_SIZE) {
360 rb_raise(rb_eRangeError, "bignum too big to convert into `quad int'");
362 memcpy(buf, (char*)BDIGITS(val), len);
363 if (!RBIGNUM_SIGN(val)) {
364 len = QUAD_SIZE;
365 while (len--) {
366 *buf = ~*buf;
367 buf++;
372 #define BNEG(b) (RSHIFT(((BDIGIT*)b)[QUAD_SIZE/SIZEOF_BDIGITS-1],BITSPERDIG-1) != 0)
374 VALUE
375 rb_quad_unpack(const char *buf, int sign)
377 VALUE big = bignew(QUAD_SIZE/SIZEOF_BDIGITS, 1);
379 memcpy((char*)BDIGITS(big), buf, QUAD_SIZE);
380 if (sign && BNEG(buf)) {
381 long len = QUAD_SIZE;
382 char *tmp = (char*)BDIGITS(big);
384 RBIGNUM_SET_SIGN(big, 0);
385 while (len--) {
386 *tmp = ~*tmp;
387 tmp++;
391 return bignorm(big);
394 #endif
396 VALUE
397 rb_cstr_to_inum(const char *str, int base, int badcheck)
399 const char *s = str;
400 char *end;
401 char sign = 1, nondigit = 0;
402 int c;
403 BDIGIT_DBL num;
404 long len, blen = 1;
405 long i;
406 VALUE z;
407 BDIGIT *zds;
409 #define conv_digit(c) \
410 (!ISASCII(c) ? -1 : \
411 ISDIGIT(c) ? ((c) - '0') : \
412 ISLOWER(c) ? ((c) - 'a' + 10) : \
413 ISUPPER(c) ? ((c) - 'A' + 10) : \
416 if (!str) {
417 if (badcheck) goto bad;
418 return INT2FIX(0);
420 while (ISSPACE(*str)) str++;
422 if (str[0] == '+') {
423 str++;
425 else if (str[0] == '-') {
426 str++;
427 sign = 0;
429 if (str[0] == '+' || str[0] == '-') {
430 if (badcheck) goto bad;
431 return INT2FIX(0);
433 if (base <= 0) {
434 if (str[0] == '0') {
435 switch (str[1]) {
436 case 'x': case 'X':
437 base = 16;
438 break;
439 case 'b': case 'B':
440 base = 2;
441 break;
442 case 'o': case 'O':
443 base = 8;
444 break;
445 case 'd': case 'D':
446 base = 10;
447 break;
448 default:
449 base = 8;
452 else if (base < -1) {
453 base = -base;
455 else {
456 base = 10;
459 switch (base) {
460 case 2:
461 len = 1;
462 if (str[0] == '0' && (str[1] == 'b'||str[1] == 'B')) {
463 str += 2;
465 break;
466 case 3:
467 len = 2;
468 break;
469 case 8:
470 if (str[0] == '0' && (str[1] == 'o'||str[1] == 'O')) {
471 str += 2;
473 case 4: case 5: case 6: case 7:
474 len = 3;
475 break;
476 case 10:
477 if (str[0] == '0' && (str[1] == 'd'||str[1] == 'D')) {
478 str += 2;
480 case 9: case 11: case 12: case 13: case 14: case 15:
481 len = 4;
482 break;
483 case 16:
484 len = 4;
485 if (str[0] == '0' && (str[1] == 'x'||str[1] == 'X')) {
486 str += 2;
488 break;
489 default:
490 if (base < 2 || 36 < base) {
491 rb_raise(rb_eArgError, "invalid radix %d", base);
493 if (base <= 32) {
494 len = 5;
496 else {
497 len = 6;
499 break;
501 if (*str == '0') { /* squeeze preceding 0s */
502 int us = 0;
503 while ((c = *++str) == '0' || c == '_') {
504 if (c == '_') {
505 if (++us >= 2)
506 break;
507 } else
508 us = 0;
510 if (!(c = *str) || ISSPACE(c)) --str;
512 c = *str;
513 c = conv_digit(c);
514 if (c < 0 || c >= base) {
515 if (badcheck) goto bad;
516 return INT2FIX(0);
518 len *= strlen(str)*sizeof(char);
520 if (len <= (sizeof(long)*CHAR_BIT)) {
521 unsigned long val = STRTOUL(str, &end, base);
523 if (str < end && *end == '_') goto bigparse;
524 if (badcheck) {
525 if (end == str) goto bad; /* no number */
526 while (*end && ISSPACE(*end)) end++;
527 if (*end) goto bad; /* trailing garbage */
530 if (POSFIXABLE(val)) {
531 if (sign) return LONG2FIX(val);
532 else {
533 long result = -(long)val;
534 return LONG2FIX(result);
537 else {
538 VALUE big = rb_uint2big(val);
539 RBIGNUM_SET_SIGN(big, sign);
540 return bignorm(big);
543 bigparse:
544 len = (len/BITSPERDIG)+1;
545 if (badcheck && *str == '_') goto bad;
547 z = bignew(len, sign);
548 zds = BDIGITS(z);
549 for (i=len;i--;) zds[i]=0;
550 while ((c = *str++) != 0) {
551 if (c == '_') {
552 if (nondigit) {
553 if (badcheck) goto bad;
554 break;
556 nondigit = c;
557 continue;
559 else if ((c = conv_digit(c)) < 0) {
560 break;
562 if (c >= base) break;
563 nondigit = 0;
564 i = 0;
565 num = c;
566 for (;;) {
567 while (i<blen) {
568 num += (BDIGIT_DBL)zds[i]*base;
569 zds[i++] = BIGLO(num);
570 num = BIGDN(num);
572 if (num) {
573 blen++;
574 continue;
576 break;
579 if (badcheck) {
580 str--;
581 if (s+1 < str && str[-1] == '_') goto bad;
582 while (*str && ISSPACE(*str)) str++;
583 if (*str) {
584 bad:
585 rb_invalid_str(s, "Integer");
589 return bignorm(z);
592 VALUE
593 rb_str_to_inum(VALUE str, int base, int badcheck)
595 char *s;
596 long len;
598 StringValue(str);
599 if (badcheck) {
600 s = StringValueCStr(str);
602 else {
603 s = RSTRING_PTR(str);
605 if (s) {
606 len = RSTRING_LEN(str);
607 if (s[len]) { /* no sentinel somehow */
608 char *p = ALLOCA_N(char, len+1);
610 MEMCPY(p, s, char, len);
611 p[len] = '\0';
612 s = p;
615 return rb_cstr_to_inum(s, base, badcheck);
618 #if HAVE_LONG_LONG
620 static VALUE
621 rb_ull2big(unsigned LONG_LONG n)
623 BDIGIT_DBL num = n;
624 long i = 0;
625 BDIGIT *digits;
626 VALUE big;
628 big = bignew(DIGSPERLL, 1);
629 digits = BDIGITS(big);
630 while (i < DIGSPERLL) {
631 digits[i++] = BIGLO(num);
632 num = BIGDN(num);
635 i = DIGSPERLL;
636 while (i-- && !digits[i]) ;
637 RBIGNUM_SET_LEN(big, i+1);
638 return big;
641 static VALUE
642 rb_ll2big(LONG_LONG n)
644 long neg = 0;
645 VALUE big;
647 if (n < 0) {
648 n = -n;
649 neg = 1;
651 big = rb_ull2big(n);
652 if (neg) {
653 RBIGNUM_SET_SIGN(big, 0);
655 return big;
658 VALUE
659 rb_ull2inum(unsigned LONG_LONG n)
661 if (POSFIXABLE(n)) return LONG2FIX(n);
662 return rb_ull2big(n);
665 VALUE
666 rb_ll2inum(LONG_LONG n)
668 if (FIXABLE(n)) return LONG2FIX(n);
669 return rb_ll2big(n);
672 #endif /* HAVE_LONG_LONG */
674 VALUE
675 rb_cstr2inum(const char *str, int base)
677 return rb_cstr_to_inum(str, base, base==0);
680 VALUE
681 rb_str2inum(VALUE str, int base)
683 return rb_str_to_inum(str, base, base==0);
686 const char ruby_digitmap[] = "0123456789abcdefghijklmnopqrstuvwxyz";
688 static VALUE bigsqr(VALUE x);
689 static void bigdivmod(VALUE x, VALUE y, VALUE *divp, VALUE *modp);
691 #define POW2_P(x) (((x)&((x)-1))==0)
693 static inline int
694 ones(register unsigned long x)
696 #if SIZEOF_LONG == 8
697 # define MASK_55 0x5555555555555555UL
698 # define MASK_33 0x3333333333333333UL
699 # define MASK_0f 0x0f0f0f0f0f0f0f0fUL
700 #else
701 # define MASK_55 0x55555555UL
702 # define MASK_33 0x33333333UL
703 # define MASK_0f 0x0f0f0f0fUL
704 #endif
705 x -= (x >> 1) & MASK_55;
706 x = ((x >> 2) & MASK_33) + (x & MASK_33);
707 x = ((x >> 4) + x) & MASK_0f;
708 x += (x >> 8);
709 x += (x >> 16);
710 #if SIZEOF_LONG == 8
711 x += (x >> 32);
712 #endif
713 return (int)(x & 0x7f);
714 #undef MASK_0f
715 #undef MASK_33
716 #undef MASK_55
719 static inline unsigned long
720 next_pow2(register unsigned long x)
722 x |= x >> 1;
723 x |= x >> 2;
724 x |= x >> 4;
725 x |= x >> 8;
726 x |= x >> 16;
727 #if SIZEOF_LONG == 8
728 x |= x >> 32;
729 #endif
730 return x + 1;
733 static inline int
734 floor_log2(register unsigned long x)
736 x |= x >> 1;
737 x |= x >> 2;
738 x |= x >> 4;
739 x |= x >> 8;
740 x |= x >> 16;
741 #if SIZEOF_LONG == 8
742 x |= x >> 32;
743 #endif
744 return (int)ones(x) - 1;
747 static inline int
748 ceil_log2(register unsigned long x)
750 return floor_log2(x) + !POW2_P(x);
753 #define LOG2_KARATSUBA_DIGITS 7
754 #define KARATSUBA_DIGITS (1L<<LOG2_KARATSUBA_DIGITS)
755 #define MAX_BIG2STR_TABLE_ENTRIES 64
757 static VALUE big2str_power_cache[35][MAX_BIG2STR_TABLE_ENTRIES];
759 static void
760 power_cache_init(void)
762 int i, j;
763 for (i = 0; i < 35; ++i) {
764 for (j = 0; j < MAX_BIG2STR_TABLE_ENTRIES; ++j) {
765 big2str_power_cache[i][j] = Qnil;
770 static inline VALUE
771 power_cache_get_power0(int base, int i)
773 if (NIL_P(big2str_power_cache[base - 2][i])) {
774 big2str_power_cache[base - 2][i] =
775 i == 0 ? rb_big_pow(rb_int2big(base), INT2FIX(KARATSUBA_DIGITS))
776 : bigsqr(power_cache_get_power0(base, i - 1));
777 rb_global_variable(&big2str_power_cache[base - 2][i]);
779 return big2str_power_cache[base - 2][i];
782 static VALUE
783 power_cache_get_power(int base, long n1, long* m1)
785 long i, j, m;
786 VALUE t;
788 if (n1 <= KARATSUBA_DIGITS)
789 rb_bug("n1 > KARATSUBA_DIGITS");
791 m = ceil_log2(n1);
792 if (m1) *m1 = 1 << m;
793 i = m - LOG2_KARATSUBA_DIGITS;
794 if (i >= MAX_BIG2STR_TABLE_ENTRIES)
795 i = MAX_BIG2STR_TABLE_ENTRIES - 1;
796 t = power_cache_get_power0(base, i);
798 j = KARATSUBA_DIGITS*(1 << i);
799 while (n1 > j) {
800 t = bigsqr(t);
801 j *= 2;
803 return t;
806 /* big2str_muraken_find_n1
808 * Let a natural number x is given by:
809 * x = 2^0 * x_0 + 2^1 * x_1 + ... + 2^(B*n_0 - 1) * x_{B*n_0 - 1},
810 * where B is BITSPERDIG (i.e. BDIGITS*CHAR_BIT) and n_0 is
811 * RBIGNUM_LEN(x).
813 * Now, we assume n_1 = min_n \{ n | 2^(B*n_0/2) <= b_1^(n_1) \}, so
814 * it is realized that 2^(B*n_0) <= {b_1}^{2*n_1}, where b_1 is a
815 * given radix number. And then, we have n_1 <= (B*n_0) /
816 * (2*log_2(b_1)), therefore n_1 is given by ceil((B*n_0) /
817 * (2*log_2(b_1))).
819 static long
820 big2str_find_n1(VALUE x, int base)
822 static const double log_2[] = {
823 1.0, 1.58496250072116, 2.0,
824 2.32192809488736, 2.58496250072116, 2.8073549220576,
825 3.0, 3.16992500144231, 3.32192809488736,
826 3.4594316186373, 3.58496250072116, 3.70043971814109,
827 3.8073549220576, 3.90689059560852, 4.0,
828 4.08746284125034, 4.16992500144231, 4.24792751344359,
829 4.32192809488736, 4.39231742277876, 4.4594316186373,
830 4.52356195605701, 4.58496250072116, 4.64385618977472,
831 4.70043971814109, 4.75488750216347, 4.8073549220576,
832 4.85798099512757, 4.90689059560852, 4.95419631038688,
833 5.0, 5.04439411935845, 5.08746284125034,
834 5.12928301694497, 5.16992500144231
836 long bits;
838 if (base < 2 || 36 < base)
839 rb_bug("invalid radix %d", base);
841 if (FIXNUM_P(x)) {
842 bits = (SIZEOF_LONG*CHAR_BIT - 1)/2 + 1;
844 else if (BIGZEROP(x)) {
845 return 0;
847 else if (RBIGNUM_LEN(x) >= LONG_MAX/BITSPERDIG) {
848 rb_raise(rb_eRangeError, "bignum too big to convert into `string'");
850 else {
851 bits = BITSPERDIG*RBIGNUM_LEN(x);
854 return (long)ceil(bits/log_2[base - 2]);
857 static long
858 big2str_orig(VALUE x, int base, char* ptr, long len, long hbase, int trim)
860 long i = RBIGNUM_LEN(x), j = len;
861 BDIGIT* ds = BDIGITS(x);
863 while (i && j > 0) {
864 long k = i;
865 BDIGIT_DBL num = 0;
867 while (k--) { /* x / hbase */
868 num = BIGUP(num) + ds[k];
869 ds[k] = (BDIGIT)(num / hbase);
870 num %= hbase;
872 if (trim && ds[i-1] == 0) i--;
873 k = SIZEOF_BDIGITS;
874 while (k--) {
875 ptr[--j] = ruby_digitmap[num % base];
876 num /= base;
877 if (j <= 0) break;
878 if (trim && i == 0 && num == 0) break;
881 if (trim) {
882 while (j < len && ptr[j] == '0') j++;
883 MEMMOVE(ptr, ptr + j, char, len - j);
884 len -= j;
886 return len;
889 static long
890 big2str_karatsuba(VALUE x, int base, char* ptr,
891 long n1, long len, long hbase, int trim)
893 long lh, ll, m1;
894 VALUE b, q, r;
896 if (FIXNUM_P(x)) {
897 VALUE str = rb_fix2str(x, base);
898 char* str_ptr = RSTRING_PTR(str);
899 long str_len = RSTRING_LEN(str);
900 if (trim) {
901 if (FIX2INT(x) == 0) return 0;
902 MEMCPY(ptr, str_ptr, char, str_len);
903 return str_len;
905 else {
906 memset(ptr, '0', len - str_len);
907 MEMCPY(ptr + len - str_len, str_ptr, char, str_len);
908 return len;
911 if (BIGZEROP(x)) {
912 if (trim) return 0;
913 else {
914 memset(ptr, '0', len);
915 return len;
919 if (n1 <= KARATSUBA_DIGITS) {
920 return big2str_orig(x, base, ptr, len, hbase, trim);
923 b = power_cache_get_power(base, n1, &m1);
924 bigdivmod(x, b, &q, &r);
925 lh = big2str_karatsuba(q, base, ptr, (len - m1)/2,
926 len - m1, hbase, trim);
927 ll = big2str_karatsuba(r, base, ptr + lh, m1/2,
928 m1, hbase, !lh && trim);
930 return lh + ll;
933 VALUE
934 rb_big2str0(VALUE x, int base, int trim)
936 int off;
937 VALUE ss, xx;
938 long n1, n2, len, hbase;
939 char* ptr;
941 if (FIXNUM_P(x)) {
942 return rb_fix2str(x, base);
944 if (BIGZEROP(x)) {
945 return rb_usascii_str_new2("0");
948 if (base < 2 || 36 < base)
949 rb_raise(rb_eArgError, "invalid radix %d", base);
951 n2 = big2str_find_n1(x, base);
952 n1 = (n2 + 1) / 2;
953 ss = rb_usascii_str_new(0, n2 + 1); /* plus one for sign */
954 ptr = RSTRING_PTR(ss);
955 ptr[0] = RBIGNUM_SIGN(x) ? '+' : '-';
957 hbase = base*base;
958 #if SIZEOF_BDIGITS > 2
959 hbase *= hbase;
960 #endif
961 off = !(trim && RBIGNUM_SIGN(x)); /* erase plus sign if trim */
962 xx = rb_big_clone(x);
963 RBIGNUM_SET_SIGN(xx, 1);
964 if (n1 <= KARATSUBA_DIGITS) {
965 len = off + big2str_orig(xx, base, ptr + off, n2, hbase, trim);
967 else {
968 len = off + big2str_karatsuba(xx, base, ptr + off, n1,
969 n2, hbase, trim);
972 ptr[len] = '\0';
973 rb_str_resize(ss, len);
975 return ss;
978 VALUE
979 rb_big2str(VALUE x, int base)
981 return rb_big2str0(x, base, 1);
985 * call-seq:
986 * big.to_s(base=10) => string
988 * Returns a string containing the representation of <i>big</i> radix
989 * <i>base</i> (2 through 36).
991 * 12345654321.to_s #=> "12345654321"
992 * 12345654321.to_s(2) #=> "1011011111110110111011110000110001"
993 * 12345654321.to_s(8) #=> "133766736061"
994 * 12345654321.to_s(16) #=> "2dfdbbc31"
995 * 78546939656932.to_s(36) #=> "rubyrules"
998 static VALUE
999 rb_big_to_s(int argc, VALUE *argv, VALUE x)
1001 int base;
1003 if (argc == 0) base = 10;
1004 else {
1005 VALUE b;
1007 rb_scan_args(argc, argv, "01", &b);
1008 base = NUM2INT(b);
1010 return rb_big2str(x, base);
1013 static VALUE
1014 big2ulong(VALUE x, const char *type, int check)
1016 long len = RBIGNUM_LEN(x);
1017 BDIGIT_DBL num;
1018 BDIGIT *ds;
1020 if (len > DIGSPERLONG) {
1021 if (check)
1022 rb_raise(rb_eRangeError, "bignum too big to convert into `%s'", type);
1023 len = DIGSPERLONG;
1025 ds = BDIGITS(x);
1026 num = 0;
1027 while (len--) {
1028 num = BIGUP(num);
1029 num += ds[len];
1031 return num;
1034 VALUE
1035 rb_big2ulong_pack(VALUE x)
1037 VALUE num = big2ulong(x, "unsigned long", Qfalse);
1038 if (!RBIGNUM_SIGN(x)) {
1039 return -num;
1041 return num;
1044 VALUE
1045 rb_big2ulong(VALUE x)
1047 VALUE num = big2ulong(x, "unsigned long", Qtrue);
1049 if (!RBIGNUM_SIGN(x)) {
1050 if ((SIGNED_VALUE)num < 0) {
1051 rb_raise(rb_eRangeError, "bignum out of range of unsigned long");
1053 return -num;
1055 return num;
1058 SIGNED_VALUE
1059 rb_big2long(VALUE x)
1061 VALUE num = big2ulong(x, "long", Qtrue);
1063 if ((SIGNED_VALUE)num < 0 &&
1064 (RBIGNUM_SIGN(x) || (SIGNED_VALUE)num != LONG_MIN)) {
1065 rb_raise(rb_eRangeError, "bignum too big to convert into `long'");
1067 if (!RBIGNUM_SIGN(x)) return -(SIGNED_VALUE)num;
1068 return num;
1071 #if HAVE_LONG_LONG
1073 static unsigned LONG_LONG
1074 big2ull(VALUE x, const char *type)
1076 long len = RBIGNUM_LEN(x);
1077 BDIGIT_DBL num;
1078 BDIGIT *ds;
1080 if (len > SIZEOF_LONG_LONG/SIZEOF_BDIGITS)
1081 rb_raise(rb_eRangeError, "bignum too big to convert into `%s'", type);
1082 ds = BDIGITS(x);
1083 num = 0;
1084 while (len--) {
1085 num = BIGUP(num);
1086 num += ds[len];
1088 return num;
1091 unsigned LONG_LONG
1092 rb_big2ull(VALUE x)
1094 unsigned LONG_LONG num = big2ull(x, "unsigned long long");
1096 if (!RBIGNUM_SIGN(x)) return -num;
1097 return num;
1100 LONG_LONG
1101 rb_big2ll(VALUE x)
1103 unsigned LONG_LONG num = big2ull(x, "long long");
1105 if ((LONG_LONG)num < 0 && (RBIGNUM_SIGN(x)
1106 || (LONG_LONG)num != LLONG_MIN)) {
1107 rb_raise(rb_eRangeError, "bignum too big to convert into `long long'");
1109 if (!RBIGNUM_SIGN(x)) return -(LONG_LONG)num;
1110 return num;
1113 #endif /* HAVE_LONG_LONG */
1115 static VALUE
1116 dbl2big(double d)
1118 long i = 0;
1119 BDIGIT c;
1120 BDIGIT *digits;
1121 VALUE z;
1122 double u = (d < 0)?-d:d;
1124 if (isinf(d)) {
1125 rb_raise(rb_eFloatDomainError, d < 0 ? "-Infinity" : "Infinity");
1127 if (isnan(d)) {
1128 rb_raise(rb_eFloatDomainError, "NaN");
1131 while (!POSFIXABLE(u) || 0 != (long)u) {
1132 u /= (double)(BIGRAD);
1133 i++;
1135 z = bignew(i, d>=0);
1136 digits = BDIGITS(z);
1137 while (i--) {
1138 u *= BIGRAD;
1139 c = (BDIGIT)u;
1140 u -= c;
1141 digits[i] = c;
1144 return z;
1147 VALUE
1148 rb_dbl2big(double d)
1150 return bignorm(dbl2big(d));
1153 static int
1154 nlz(BDIGIT x)
1156 BDIGIT y;
1157 int n = BITSPERDIG;
1158 #if BITSPERDIG > 64
1159 y = x >> 64; if (y) {n -= 64; x = y;}
1160 #endif
1161 #if BITSPERDIG > 32
1162 y = x >> 32; if (y) {n -= 32; x = y;}
1163 #endif
1164 #if BITSPERDIG > 16
1165 y = x >> 16; if (y) {n -= 16; x = y;}
1166 #endif
1167 y = x >> 8; if (y) {n -= 8; x = y;}
1168 y = x >> 4; if (y) {n -= 4; x = y;}
1169 y = x >> 2; if (y) {n -= 2; x = y;}
1170 y = x >> 1; if (y) {return n - 2;}
1171 return n - x;
1174 static double
1175 big2dbl(VALUE x)
1177 double d = 0.0;
1178 long i = RBIGNUM_LEN(x), lo = 0, bits;
1179 BDIGIT *ds = BDIGITS(x), dl;
1181 if (i) {
1182 bits = i * BITSPERDIG - nlz(ds[i-1]);
1183 if (bits > DBL_MANT_DIG+DBL_MAX_EXP) {
1184 d = HUGE_VAL;
1186 else {
1187 if (bits > DBL_MANT_DIG+1)
1188 lo = (bits -= DBL_MANT_DIG+1) / BITSPERDIG;
1189 else
1190 bits = 0;
1191 while (--i > lo) {
1192 d = ds[i] + BIGRAD*d;
1194 dl = ds[i];
1195 if (bits && (dl & (1UL << (bits %= BITSPERDIG)))) {
1196 int carry = dl & ~(~0UL << bits);
1197 if (!carry) {
1198 while (i-- > 0) {
1199 if ((carry = ds[i]) != 0) break;
1202 if (carry) {
1203 dl &= ~0UL << bits;
1204 dl += 1UL << bits;
1205 if (!dl) d += 1;
1208 d = dl + BIGRAD*d;
1209 if (lo) d = ldexp(d, lo * BITSPERDIG);
1212 if (!RBIGNUM_SIGN(x)) d = -d;
1213 return d;
1216 double
1217 rb_big2dbl(VALUE x)
1219 double d = big2dbl(x);
1221 if (isinf(d)) {
1222 rb_warning("Bignum out of Float range");
1223 d = HUGE_VAL;
1225 return d;
1229 * call-seq:
1230 * big.to_f -> float
1232 * Converts <i>big</i> to a <code>Float</code>. If <i>big</i> doesn't
1233 * fit in a <code>Float</code>, the result is infinity.
1237 static VALUE
1238 rb_big_to_f(VALUE x)
1240 return DOUBLE2NUM(rb_big2dbl(x));
1244 * call-seq:
1245 * big <=> numeric => -1, 0, +1
1247 * Comparison---Returns -1, 0, or +1 depending on whether <i>big</i> is
1248 * less than, equal to, or greater than <i>numeric</i>. This is the
1249 * basis for the tests in <code>Comparable</code>.
1253 VALUE
1254 rb_big_cmp(VALUE x, VALUE y)
1256 long xlen = RBIGNUM_LEN(x);
1258 switch (TYPE(y)) {
1259 case T_FIXNUM:
1260 y = rb_int2big(FIX2LONG(y));
1261 break;
1263 case T_BIGNUM:
1264 break;
1266 case T_FLOAT:
1267 return rb_dbl_cmp(rb_big2dbl(x), RFLOAT_VALUE(y));
1269 default:
1270 return rb_num_coerce_cmp(x, y, rb_intern("<=>"));
1273 if (RBIGNUM_SIGN(x) > RBIGNUM_SIGN(y)) return INT2FIX(1);
1274 if (RBIGNUM_SIGN(x) < RBIGNUM_SIGN(y)) return INT2FIX(-1);
1275 if (xlen < RBIGNUM_LEN(y))
1276 return (RBIGNUM_SIGN(x)) ? INT2FIX(-1) : INT2FIX(1);
1277 if (xlen > RBIGNUM_LEN(y))
1278 return (RBIGNUM_SIGN(x)) ? INT2FIX(1) : INT2FIX(-1);
1280 while(xlen-- && (BDIGITS(x)[xlen]==BDIGITS(y)[xlen]));
1281 if (-1 == xlen) return INT2FIX(0);
1282 return (BDIGITS(x)[xlen] > BDIGITS(y)[xlen]) ?
1283 (RBIGNUM_SIGN(x) ? INT2FIX(1) : INT2FIX(-1)) :
1284 (RBIGNUM_SIGN(x) ? INT2FIX(-1) : INT2FIX(1));
1288 * call-seq:
1289 * big == obj => true or false
1291 * Returns <code>true</code> only if <i>obj</i> has the same value
1292 * as <i>big</i>. Contrast this with <code>Bignum#eql?</code>, which
1293 * requires <i>obj</i> to be a <code>Bignum</code>.
1295 * 68719476736 == 68719476736.0 #=> true
1298 VALUE
1299 rb_big_eq(VALUE x, VALUE y)
1301 switch (TYPE(y)) {
1302 case T_FIXNUM:
1303 y = rb_int2big(FIX2LONG(y));
1304 break;
1305 case T_BIGNUM:
1306 break;
1307 case T_FLOAT:
1309 volatile double a, b;
1311 a = RFLOAT_VALUE(y);
1312 if (isnan(a)) return Qfalse;
1313 b = rb_big2dbl(x);
1314 return (a == b)?Qtrue:Qfalse;
1316 default:
1317 return rb_equal(y, x);
1319 if (RBIGNUM_SIGN(x) != RBIGNUM_SIGN(y)) return Qfalse;
1320 if (RBIGNUM_LEN(x) != RBIGNUM_LEN(y)) return Qfalse;
1321 if (MEMCMP(BDIGITS(x),BDIGITS(y),BDIGIT,RBIGNUM_LEN(y)) != 0) return Qfalse;
1322 return Qtrue;
1326 * call-seq:
1327 * big.eql?(obj) => true or false
1329 * Returns <code>true</code> only if <i>obj</i> is a
1330 * <code>Bignum</code> with the same value as <i>big</i>. Contrast this
1331 * with <code>Bignum#==</code>, which performs type conversions.
1333 * 68719476736.eql?(68719476736.0) #=> false
1336 static VALUE
1337 rb_big_eql(VALUE x, VALUE y)
1339 if (TYPE(y) != T_BIGNUM) return Qfalse;
1340 if (RBIGNUM_SIGN(x) != RBIGNUM_SIGN(y)) return Qfalse;
1341 if (RBIGNUM_LEN(x) != RBIGNUM_LEN(y)) return Qfalse;
1342 if (MEMCMP(BDIGITS(x),BDIGITS(y),BDIGIT,RBIGNUM_LEN(y)) != 0) return Qfalse;
1343 return Qtrue;
1347 * call-seq:
1348 * -big => other_big
1350 * Unary minus (returns a new Bignum whose value is 0-big)
1353 static VALUE
1354 rb_big_uminus(VALUE x)
1356 VALUE z = rb_big_clone(x);
1358 RBIGNUM_SET_SIGN(z, !RBIGNUM_SIGN(x));
1360 return bignorm(z);
1364 * call-seq:
1365 * ~big => integer
1367 * Inverts the bits in big. As Bignums are conceptually infinite
1368 * length, the result acts as if it had an infinite number of one
1369 * bits to the left. In hex representations, this is displayed
1370 * as two periods to the left of the digits.
1372 * sprintf("%X", ~0x1122334455) #=> "..FEEDDCCBBAA"
1375 static VALUE
1376 rb_big_neg(VALUE x)
1378 VALUE z = rb_big_clone(x);
1379 BDIGIT *ds;
1380 long i;
1382 if (!RBIGNUM_SIGN(x)) get2comp(z);
1383 ds = BDIGITS(z);
1384 i = RBIGNUM_LEN(x);
1385 if (!i) return INT2FIX(~(SIGNED_VALUE)0);
1386 while (i--) {
1387 ds[i] = ~ds[i];
1389 RBIGNUM_SET_SIGN(z, !RBIGNUM_SIGN(z));
1390 if (RBIGNUM_SIGN(x)) get2comp(z);
1392 return bignorm(z);
1395 static VALUE
1396 bigsub(VALUE x, VALUE y)
1398 VALUE z = 0;
1399 BDIGIT *zds;
1400 BDIGIT_DBL_SIGNED num;
1401 long i = RBIGNUM_LEN(x);
1403 /* if x is larger than y, swap */
1404 if (RBIGNUM_LEN(x) < RBIGNUM_LEN(y)) {
1405 z = x; x = y; y = z; /* swap x y */
1407 else if (RBIGNUM_LEN(x) == RBIGNUM_LEN(y)) {
1408 while (i > 0) {
1409 i--;
1410 if (BDIGITS(x)[i] > BDIGITS(y)[i]) {
1411 break;
1413 if (BDIGITS(x)[i] < BDIGITS(y)[i]) {
1414 z = x; x = y; y = z; /* swap x y */
1415 break;
1420 z = bignew(RBIGNUM_LEN(x), z==0);
1421 zds = BDIGITS(z);
1423 for (i = 0, num = 0; i < RBIGNUM_LEN(y); i++) {
1424 num += (BDIGIT_DBL_SIGNED)BDIGITS(x)[i] - BDIGITS(y)[i];
1425 zds[i] = BIGLO(num);
1426 num = BIGDN(num);
1428 while (num && i < RBIGNUM_LEN(x)) {
1429 num += BDIGITS(x)[i];
1430 zds[i++] = BIGLO(num);
1431 num = BIGDN(num);
1433 while (i < RBIGNUM_LEN(x)) {
1434 zds[i] = BDIGITS(x)[i];
1435 i++;
1438 return z;
1441 static VALUE
1442 bigadd(VALUE x, VALUE y, int sign)
1444 VALUE z;
1445 BDIGIT_DBL num;
1446 long i, len;
1448 sign = (sign == RBIGNUM_SIGN(y));
1449 if (RBIGNUM_SIGN(x) != sign) {
1450 if (sign) return bigsub(y, x);
1451 return bigsub(x, y);
1454 if (RBIGNUM_LEN(x) > RBIGNUM_LEN(y)) {
1455 len = RBIGNUM_LEN(x) + 1;
1456 z = x; x = y; y = z;
1458 else {
1459 len = RBIGNUM_LEN(y) + 1;
1461 z = bignew(len, sign);
1463 len = RBIGNUM_LEN(x);
1464 for (i = 0, num = 0; i < len; i++) {
1465 num += (BDIGIT_DBL)BDIGITS(x)[i] + BDIGITS(y)[i];
1466 BDIGITS(z)[i] = BIGLO(num);
1467 num = BIGDN(num);
1469 len = RBIGNUM_LEN(y);
1470 while (num && i < len) {
1471 num += BDIGITS(y)[i];
1472 BDIGITS(z)[i++] = BIGLO(num);
1473 num = BIGDN(num);
1475 while (i < len) {
1476 BDIGITS(z)[i] = BDIGITS(y)[i];
1477 i++;
1479 BDIGITS(z)[i] = (BDIGIT)num;
1481 return z;
1485 * call-seq:
1486 * big + other => Numeric
1488 * Adds big and other, returning the result.
1491 VALUE
1492 rb_big_plus(VALUE x, VALUE y)
1494 switch (TYPE(y)) {
1495 case T_FIXNUM:
1496 y = rb_int2big(FIX2LONG(y));
1497 /* fall through */
1498 case T_BIGNUM:
1499 return bignorm(bigadd(x, y, 1));
1501 case T_FLOAT:
1502 return DOUBLE2NUM(rb_big2dbl(x) + RFLOAT_VALUE(y));
1504 default:
1505 return rb_num_coerce_bin(x, y, '+');
1510 * call-seq:
1511 * big - other => Numeric
1513 * Subtracts other from big, returning the result.
1516 VALUE
1517 rb_big_minus(VALUE x, VALUE y)
1519 switch (TYPE(y)) {
1520 case T_FIXNUM:
1521 y = rb_int2big(FIX2LONG(y));
1522 /* fall through */
1523 case T_BIGNUM:
1524 return bignorm(bigadd(x, y, 0));
1526 case T_FLOAT:
1527 return DOUBLE2NUM(rb_big2dbl(x) - RFLOAT_VALUE(y));
1529 default:
1530 return rb_num_coerce_bin(x, y, '-');
1534 static void
1535 rb_big_stop(void *ptr)
1537 VALUE *stop = (VALUE*)ptr;
1538 *stop = Qtrue;
1541 struct big_mul_struct {
1542 VALUE x, y, z, stop;
1545 static VALUE
1546 bigmul1(void *ptr)
1548 struct big_mul_struct *bms = (struct big_mul_struct*)ptr;
1549 long i, j;
1550 BDIGIT_DBL n = 0;
1551 VALUE x = bms->x, y = bms->y, z = bms->z;
1552 BDIGIT *zds;
1554 j = RBIGNUM_LEN(x) + RBIGNUM_LEN(y) + 1;
1555 zds = BDIGITS(z);
1556 while (j--) zds[j] = 0;
1557 for (i = 0; i < RBIGNUM_LEN(x); i++) {
1558 BDIGIT_DBL dd;
1559 if (bms->stop) return Qnil;
1560 dd = BDIGITS(x)[i];
1561 if (dd == 0) continue;
1562 n = 0;
1563 for (j = 0; j < RBIGNUM_LEN(y); j++) {
1564 BDIGIT_DBL ee = n + (BDIGIT_DBL)dd * BDIGITS(y)[j];
1565 n = zds[i + j] + ee;
1566 if (ee) zds[i + j] = BIGLO(n);
1567 n = BIGDN(n);
1569 if (n) {
1570 zds[i + j] = n;
1573 return z;
1576 static VALUE
1577 rb_big_mul0(VALUE x, VALUE y)
1579 struct big_mul_struct bms;
1580 volatile VALUE z;
1582 switch (TYPE(y)) {
1583 case T_FIXNUM:
1584 y = rb_int2big(FIX2LONG(y));
1585 break;
1587 case T_BIGNUM:
1588 break;
1590 case T_FLOAT:
1591 return DOUBLE2NUM(rb_big2dbl(x) * RFLOAT_VALUE(y));
1593 default:
1594 return rb_num_coerce_bin(x, y, '*');
1597 bms.x = x;
1598 bms.y = y;
1599 bms.z = bignew(RBIGNUM_LEN(x) + RBIGNUM_LEN(y) + 1, RBIGNUM_SIGN(x)==RBIGNUM_SIGN(y));
1600 bms.stop = Qfalse;
1602 if (RBIGNUM_LEN(x) + RBIGNUM_LEN(y) > 10000) {
1603 z = rb_thread_blocking_region(bigmul1, &bms, rb_big_stop, &bms.stop);
1605 else {
1606 z = bigmul1(&bms);
1609 return z;
1613 * call-seq:
1614 * big * other => Numeric
1616 * Multiplies big and other, returning the result.
1619 VALUE
1620 rb_big_mul(VALUE x, VALUE y)
1622 return bignorm(rb_big_mul0(x, y));
1625 struct big_div_struct {
1626 long nx, ny;
1627 BDIGIT *yds, *zds;
1628 VALUE stop;
1631 static VALUE
1632 bigdivrem1(void *ptr)
1634 struct big_div_struct *bds = (struct big_div_struct*)ptr;
1635 long nx = bds->nx, ny = bds->ny;
1636 long i, j;
1637 BDIGIT *yds = bds->yds, *zds = bds->zds;
1638 BDIGIT_DBL t2;
1639 BDIGIT_DBL_SIGNED num;
1640 BDIGIT q;
1642 j = nx==ny?nx+1:nx;
1643 do {
1644 if (bds->stop) return Qnil;
1645 if (zds[j] == yds[ny-1]) q = BIGRAD-1;
1646 else q = (BDIGIT)((BIGUP(zds[j]) + zds[j-1])/yds[ny-1]);
1647 if (q) {
1648 i = 0; num = 0; t2 = 0;
1649 do { /* multiply and subtract */
1650 BDIGIT_DBL ee;
1651 t2 += (BDIGIT_DBL)yds[i] * q;
1652 ee = num - BIGLO(t2);
1653 num = (BDIGIT_DBL)zds[j - ny + i] + ee;
1654 if (ee) zds[j - ny + i] = BIGLO(num);
1655 num = BIGDN(num);
1656 t2 = BIGDN(t2);
1657 } while (++i < ny);
1658 num += zds[j - ny + i] - t2;/* borrow from high digit; don't update */
1659 while (num) { /* "add back" required */
1660 i = 0; num = 0; q--;
1661 do {
1662 BDIGIT_DBL ee = num + yds[i];
1663 num = (BDIGIT_DBL)zds[j - ny + i] + ee;
1664 if (ee) zds[j - ny + i] = BIGLO(num);
1665 num = BIGDN(num);
1666 } while (++i < ny);
1667 num--;
1670 zds[j] = q;
1671 } while (--j >= ny);
1672 return Qnil;
1675 static VALUE
1676 bigdivrem(VALUE x, VALUE y, VALUE *divp, VALUE *modp)
1678 struct big_div_struct bds;
1679 long nx = RBIGNUM_LEN(x), ny = RBIGNUM_LEN(y);
1680 long i, j;
1681 volatile VALUE yy, z;
1682 BDIGIT *xds, *yds, *zds, *tds;
1683 BDIGIT_DBL t2;
1684 BDIGIT dd, q;
1686 if (BIGZEROP(y)) rb_num_zerodiv();
1687 yds = BDIGITS(y);
1688 if (nx < ny || (nx == ny && BDIGITS(x)[nx - 1] < BDIGITS(y)[ny - 1])) {
1689 if (divp) *divp = rb_int2big(0);
1690 if (modp) *modp = x;
1691 return Qnil;
1693 xds = BDIGITS(x);
1694 if (ny == 1) {
1695 dd = yds[0];
1696 z = rb_big_clone(x);
1697 zds = BDIGITS(z);
1698 t2 = 0; i = nx;
1699 while (i--) {
1700 t2 = BIGUP(t2) + zds[i];
1701 zds[i] = (BDIGIT)(t2 / dd);
1702 t2 %= dd;
1704 RBIGNUM_SET_SIGN(z, RBIGNUM_SIGN(x)==RBIGNUM_SIGN(y));
1705 if (modp) {
1706 *modp = rb_uint2big((VALUE)t2);
1707 RBIGNUM_SET_SIGN(*modp, RBIGNUM_SIGN(x));
1709 if (divp) *divp = z;
1710 return Qnil;
1712 z = bignew(nx==ny?nx+2:nx+1, RBIGNUM_SIGN(x)==RBIGNUM_SIGN(y));
1713 zds = BDIGITS(z);
1714 if (nx==ny) zds[nx+1] = 0;
1715 while (!yds[ny-1]) ny--;
1717 dd = 0;
1718 q = yds[ny-1];
1719 while ((q & (1UL<<(BITSPERDIG-1))) == 0) {
1720 q <<= 1UL;
1721 dd++;
1723 if (dd) {
1724 yy = rb_big_clone(y);
1725 tds = BDIGITS(yy);
1726 j = 0;
1727 t2 = 0;
1728 while (j<ny) {
1729 t2 += (BDIGIT_DBL)yds[j]<<dd;
1730 tds[j++] = BIGLO(t2);
1731 t2 = BIGDN(t2);
1733 yds = tds;
1734 j = 0;
1735 t2 = 0;
1736 while (j<nx) {
1737 t2 += (BDIGIT_DBL)xds[j]<<dd;
1738 zds[j++] = BIGLO(t2);
1739 t2 = BIGDN(t2);
1741 zds[j] = (BDIGIT)t2;
1743 else {
1744 zds[nx] = 0;
1745 j = nx;
1746 while (j--) zds[j] = xds[j];
1749 bds.nx = nx;
1750 bds.ny = ny;
1751 bds.zds = zds;
1752 bds.yds = yds;
1753 bds.stop = Qfalse;
1754 if (RBIGNUM_LEN(x) > 10000 || RBIGNUM_LEN(y) > 10000) {
1755 rb_thread_blocking_region(bigdivrem1, &bds, rb_big_stop, &bds.stop);
1757 else {
1758 bigdivrem1(&bds);
1761 if (divp) { /* move quotient down in z */
1762 *divp = rb_big_clone(z);
1763 zds = BDIGITS(*divp);
1764 j = (nx==ny ? nx+2 : nx+1) - ny;
1765 for (i = 0;i < j;i++) zds[i] = zds[i+ny];
1766 RBIGNUM_SET_LEN(*divp, i);
1768 if (modp) { /* normalize remainder */
1769 *modp = rb_big_clone(z);
1770 zds = BDIGITS(*modp);
1771 while (--ny && !zds[ny]); ++ny;
1772 if (dd) {
1773 t2 = 0; i = ny;
1774 while(i--) {
1775 t2 = (t2 | zds[i]) >> dd;
1776 q = zds[i];
1777 zds[i] = BIGLO(t2);
1778 t2 = BIGUP(q);
1781 RBIGNUM_SET_LEN(*modp, ny);
1782 RBIGNUM_SET_SIGN(*modp, RBIGNUM_SIGN(x));
1784 return z;
1787 static void
1788 bigdivmod(VALUE x, VALUE y, VALUE *divp, VALUE *modp)
1790 VALUE mod;
1792 bigdivrem(x, y, divp, &mod);
1793 if (RBIGNUM_SIGN(x) != RBIGNUM_SIGN(y) && !BIGZEROP(mod)) {
1794 if (divp) *divp = bigadd(*divp, rb_int2big(1), 0);
1795 if (modp) *modp = bigadd(mod, y, 1);
1797 else {
1798 if (divp) *divp = *divp;
1799 if (modp) *modp = mod;
1804 static VALUE
1805 rb_big_divide(VALUE x, VALUE y, ID op)
1807 VALUE z;
1809 switch (TYPE(y)) {
1810 case T_FIXNUM:
1811 y = rb_int2big(FIX2LONG(y));
1812 break;
1814 case T_BIGNUM:
1815 break;
1817 case T_FLOAT:
1819 double div = rb_big2dbl(x) / RFLOAT_VALUE(y);
1820 if (op == '/') {
1821 return DOUBLE2NUM(div);
1823 else {
1824 return rb_dbl2big(div);
1828 default:
1829 return rb_num_coerce_bin(x, y, op);
1831 bigdivmod(x, y, &z, 0);
1833 return bignorm(z);
1837 * call-seq:
1838 * big / other => Numeric
1840 * Divides big by other, returning the result.
1843 VALUE
1844 rb_big_div(VALUE x, VALUE y)
1846 return rb_big_divide(x, y, '/');
1849 VALUE
1850 rb_big_idiv(VALUE x, VALUE y)
1852 return rb_big_divide(x, y, rb_intern("div"));
1856 * call-seq:
1857 * big % other => Numeric
1858 * big.modulo(other) => Numeric
1860 * Returns big modulo other. See Numeric.divmod for more
1861 * information.
1864 VALUE
1865 rb_big_modulo(VALUE x, VALUE y)
1867 VALUE z;
1869 switch (TYPE(y)) {
1870 case T_FIXNUM:
1871 y = rb_int2big(FIX2LONG(y));
1872 break;
1874 case T_BIGNUM:
1875 break;
1877 default:
1878 return rb_num_coerce_bin(x, y, '%');
1880 bigdivmod(x, y, 0, &z);
1882 return bignorm(z);
1886 * call-seq:
1887 * big.remainder(numeric) => number
1889 * Returns the remainder after dividing <i>big</i> by <i>numeric</i>.
1891 * -1234567890987654321.remainder(13731) #=> -6966
1892 * -1234567890987654321.remainder(13731.24) #=> -9906.22531493148
1894 static VALUE
1895 rb_big_remainder(VALUE x, VALUE y)
1897 VALUE z;
1899 switch (TYPE(y)) {
1900 case T_FIXNUM:
1901 y = rb_int2big(FIX2LONG(y));
1902 break;
1904 case T_BIGNUM:
1905 break;
1907 default:
1908 return rb_num_coerce_bin(x, y, rb_intern("remainder"));
1910 bigdivrem(x, y, 0, &z);
1912 return bignorm(z);
1916 * call-seq:
1917 * big.divmod(numeric) => array
1919 * See <code>Numeric#divmod</code>.
1922 VALUE
1923 rb_big_divmod(VALUE x, VALUE y)
1925 VALUE div, mod;
1927 switch (TYPE(y)) {
1928 case T_FIXNUM:
1929 y = rb_int2big(FIX2LONG(y));
1930 break;
1932 case T_BIGNUM:
1933 break;
1935 default:
1936 return rb_num_coerce_bin(x, y, rb_intern("divmod"));
1938 bigdivmod(x, y, &div, &mod);
1940 return rb_assoc_new(bignorm(div), bignorm(mod));
1943 static int
1944 bdigbitsize(BDIGIT x)
1946 int size = 1;
1947 int nb = BITSPERDIG / 2;
1948 BDIGIT bits = (~0 << nb);
1950 if (!x) return 0;
1951 while (x > 1) {
1952 if (x & bits) {
1953 size += nb;
1954 x >>= nb;
1956 x &= ~bits;
1957 nb /= 2;
1958 bits >>= nb;
1961 return size;
1964 static VALUE big_lshift(VALUE, unsigned long);
1965 static VALUE big_rshift(VALUE, unsigned long);
1967 static VALUE big_shift(VALUE x, int n)
1969 if (n < 0)
1970 return big_lshift(x, (unsigned int)-n);
1971 else if (n > 0)
1972 return big_rshift(x, (unsigned int)n);
1973 return x;
1977 * call-seq:
1978 * big.fdiv(numeric) -> float
1980 * Returns the floating point result of dividing <i>big</i> by
1981 * <i>numeric</i>.
1983 * -1234567890987654321.fdiv(13731) #=> -89910996357705.5
1984 * -1234567890987654321.fdiv(13731.24) #=> -89909424858035.7
1988 static VALUE
1989 rb_big_fdiv(VALUE x, VALUE y)
1991 double dx = big2dbl(x);
1992 double dy;
1994 if (isinf(dx)) {
1995 #define DBL_BIGDIG ((DBL_MANT_DIG + BITSPERDIG) / BITSPERDIG)
1996 VALUE z;
1997 int ex, ey;
1999 ex = (RBIGNUM_LEN(bigtrunc(x)) - 1) * BITSPERDIG;
2000 ex += bdigbitsize(BDIGITS(x)[RBIGNUM_LEN(x) - 1]);
2001 ex -= 2 * DBL_BIGDIG * BITSPERDIG;
2002 if (ex) x = big_shift(x, ex);
2004 switch (TYPE(y)) {
2005 case T_FIXNUM:
2006 y = rb_int2big(FIX2LONG(y));
2007 case T_BIGNUM: {
2008 ey = (RBIGNUM_LEN(bigtrunc(y)) - 1) * BITSPERDIG;
2009 ey += bdigbitsize(BDIGITS(y)[RBIGNUM_LEN(y) - 1]);
2010 ey -= DBL_BIGDIG * BITSPERDIG;
2011 if (ey) y = big_shift(y, ey);
2012 bignum:
2013 bigdivrem(x, y, &z, 0);
2014 return DOUBLE2NUM(ldexp(big2dbl(z), ex - ey));
2016 case T_FLOAT:
2017 if (isnan(RFLOAT_VALUE(y))) return y;
2018 y = dbl2big(ldexp(frexp(RFLOAT_VALUE(y), &ey), DBL_MANT_DIG));
2019 ey -= DBL_MANT_DIG;
2020 goto bignum;
2023 switch (TYPE(y)) {
2024 case T_FIXNUM:
2025 dy = (double)FIX2LONG(y);
2026 break;
2028 case T_BIGNUM:
2029 dy = rb_big2dbl(y);
2030 break;
2032 case T_FLOAT:
2033 dy = RFLOAT_VALUE(y);
2034 break;
2036 default:
2037 return rb_num_coerce_bin(x, y, rb_intern("fdiv"));
2039 return DOUBLE2NUM(dx / dy);
2042 static VALUE
2043 bigsqr(VALUE x)
2045 long len = RBIGNUM_LEN(x), k = len / 2, i;
2046 VALUE a, b, a2, z;
2047 BDIGIT_DBL num;
2049 if (len < 4000 / BITSPERDIG) {
2050 return bigtrunc(rb_big_mul0(x, x));
2053 a = bignew(len - k, 1);
2054 MEMCPY(BDIGITS(a), BDIGITS(x) + k, BDIGIT, len - k);
2055 b = bignew(k, 1);
2056 MEMCPY(BDIGITS(b), BDIGITS(x), BDIGIT, k);
2058 a2 = bigtrunc(bigsqr(a));
2059 z = bigsqr(b);
2060 rb_big_realloc(z, (len = 2 * k + RBIGNUM_LEN(a2)) + 1);
2061 while (RBIGNUM_LEN(z) < 2 * k) {
2062 BDIGITS(z)[RBIGNUM_LEN(z)] = 0;
2063 RBIGNUM_SET_LEN(z, RBIGNUM_LEN(z)+1);
2065 MEMCPY(BDIGITS(z) + 2 * k, BDIGITS(a2), BDIGIT, RBIGNUM_LEN(a2));
2066 RBIGNUM_SET_LEN(z, len);
2067 a2 = bigtrunc(rb_big_mul0(a, b));
2068 len = RBIGNUM_LEN(a2);
2069 for (i = 0, num = 0; i < len; i++) {
2070 num += (BDIGIT_DBL)BDIGITS(z)[i + k] + ((BDIGIT_DBL)BDIGITS(a2)[i] << 1);
2071 BDIGITS(z)[i + k] = BIGLO(num);
2072 num = BIGDN(num);
2074 if (num) {
2075 len = RBIGNUM_LEN(z);
2076 for (i += k; i < len && num; ++i) {
2077 num += (BDIGIT_DBL)BDIGITS(z)[i];
2078 BDIGITS(z)[i] = BIGLO(num);
2079 num = BIGDN(num);
2081 if (num) {
2082 BDIGITS(z)[RBIGNUM_LEN(z)] = BIGLO(num);
2083 RBIGNUM_SET_LEN(z, RBIGNUM_LEN(z)+1);
2086 return bigtrunc(z);
2090 * call-seq:
2091 * big ** exponent => numeric
2093 * Raises _big_ to the _exponent_ power (which may be an integer, float,
2094 * or anything that will coerce to a number). The result may be
2095 * a Fixnum, Bignum, or Float
2097 * 123456789 ** 2 #=> 15241578750190521
2098 * 123456789 ** 1.2 #=> 5126464716.09932
2099 * 123456789 ** -2 #=> 6.5610001194102e-17
2102 VALUE
2103 rb_big_pow(VALUE x, VALUE y)
2105 double d;
2106 SIGNED_VALUE yy;
2108 if (y == INT2FIX(0)) return INT2FIX(1);
2109 switch (TYPE(y)) {
2110 case T_FLOAT:
2111 d = RFLOAT_VALUE(y);
2112 break;
2114 case T_BIGNUM:
2115 if (rb_funcall(y, '<', 1, INT2FIX(0)))
2116 return rb_funcall(rb_rational_raw1(x), rb_intern("**"), 1, y);
2118 rb_warn("in a**b, b may be too big");
2119 d = rb_big2dbl(y);
2120 break;
2122 case T_FIXNUM:
2123 yy = FIX2LONG(y);
2125 if (yy < 0)
2126 return rb_funcall(rb_rational_raw1(x), rb_intern("**"), 1, y);
2127 else {
2128 VALUE z = 0;
2129 SIGNED_VALUE mask;
2130 const long BIGLEN_LIMIT = 1024*1024 / SIZEOF_BDIGITS;
2132 if ((RBIGNUM_LEN(x) > BIGLEN_LIMIT) ||
2133 (RBIGNUM_LEN(x) > BIGLEN_LIMIT / yy)) {
2134 rb_warn("in a**b, b may be too big");
2135 d = (double)yy;
2136 break;
2138 for (mask = FIXNUM_MAX + 1; mask; mask >>= 1) {
2139 if (z) z = bigtrunc(bigsqr(z));
2140 if (yy & mask) {
2141 z = z ? bigtrunc(rb_big_mul0(z, x)) : x;
2144 return bignorm(z);
2146 /* NOTREACHED */
2147 break;
2149 default:
2150 return rb_num_coerce_bin(x, y, rb_intern("**"));
2152 return DOUBLE2NUM(pow(rb_big2dbl(x), d));
2155 static VALUE
2156 bit_coerce(VALUE x)
2158 while (!FIXNUM_P(x) && TYPE(x) != T_BIGNUM) {
2159 if (TYPE(x) == T_FLOAT) {
2160 rb_raise(rb_eTypeError, "can't convert Float into Integer");
2162 x = rb_to_int(x);
2164 return x;
2168 * call-seq:
2169 * big & numeric => integer
2171 * Performs bitwise +and+ between _big_ and _numeric_.
2174 VALUE
2175 rb_big_and(VALUE xx, VALUE yy)
2177 volatile VALUE x, y, z;
2178 BDIGIT *ds1, *ds2, *zds;
2179 long i, l1, l2;
2180 char sign;
2182 x = xx;
2183 y = bit_coerce(yy);
2184 if (FIXNUM_P(y)) {
2185 y = rb_int2big(FIX2LONG(y));
2187 if (!RBIGNUM_SIGN(y)) {
2188 y = rb_big_clone(y);
2189 get2comp(y);
2191 if (!RBIGNUM_SIGN(x)) {
2192 x = rb_big_clone(x);
2193 get2comp(x);
2195 if (RBIGNUM_LEN(x) > RBIGNUM_LEN(y)) {
2196 l1 = RBIGNUM_LEN(y);
2197 l2 = RBIGNUM_LEN(x);
2198 ds1 = BDIGITS(y);
2199 ds2 = BDIGITS(x);
2200 sign = RBIGNUM_SIGN(y);
2202 else {
2203 l1 = RBIGNUM_LEN(x);
2204 l2 = RBIGNUM_LEN(y);
2205 ds1 = BDIGITS(x);
2206 ds2 = BDIGITS(y);
2207 sign = RBIGNUM_SIGN(x);
2209 z = bignew(l2, RBIGNUM_SIGN(x) || RBIGNUM_SIGN(y));
2210 zds = BDIGITS(z);
2212 for (i=0; i<l1; i++) {
2213 zds[i] = ds1[i] & ds2[i];
2215 for (; i<l2; i++) {
2216 zds[i] = sign?0:ds2[i];
2218 if (!RBIGNUM_SIGN(z)) get2comp(z);
2219 return bignorm(z);
2223 * call-seq:
2224 * big | numeric => integer
2226 * Performs bitwise +or+ between _big_ and _numeric_.
2229 VALUE
2230 rb_big_or(VALUE xx, VALUE yy)
2232 volatile VALUE x, y, z;
2233 BDIGIT *ds1, *ds2, *zds;
2234 long i, l1, l2;
2235 char sign;
2237 x = xx;
2238 y = bit_coerce(yy);
2239 if (FIXNUM_P(y)) {
2240 y = rb_int2big(FIX2LONG(y));
2243 if (!RBIGNUM_SIGN(y)) {
2244 y = rb_big_clone(y);
2245 get2comp(y);
2247 if (!RBIGNUM_SIGN(x)) {
2248 x = rb_big_clone(x);
2249 get2comp(x);
2251 if (RBIGNUM_LEN(x) > RBIGNUM_LEN(y)) {
2252 l1 = RBIGNUM_LEN(y);
2253 l2 = RBIGNUM_LEN(x);
2254 ds1 = BDIGITS(y);
2255 ds2 = BDIGITS(x);
2256 sign = RBIGNUM_SIGN(y);
2258 else {
2259 l1 = RBIGNUM_LEN(x);
2260 l2 = RBIGNUM_LEN(y);
2261 ds1 = BDIGITS(x);
2262 ds2 = BDIGITS(y);
2263 sign = RBIGNUM_SIGN(x);
2265 z = bignew(l2, RBIGNUM_SIGN(x) && RBIGNUM_SIGN(y));
2266 zds = BDIGITS(z);
2268 for (i=0; i<l1; i++) {
2269 zds[i] = ds1[i] | ds2[i];
2271 for (; i<l2; i++) {
2272 zds[i] = sign?ds2[i]:(BIGRAD-1);
2274 if (!RBIGNUM_SIGN(z)) get2comp(z);
2276 return bignorm(z);
2280 * call-seq:
2281 * big ^ numeric => integer
2283 * Performs bitwise +exclusive or+ between _big_ and _numeric_.
2286 VALUE
2287 rb_big_xor(VALUE xx, VALUE yy)
2289 volatile VALUE x, y;
2290 VALUE z;
2291 BDIGIT *ds1, *ds2, *zds;
2292 long i, l1, l2;
2293 char sign;
2295 x = xx;
2296 y = bit_coerce(yy);
2297 if (FIXNUM_P(y)) {
2298 y = rb_int2big(FIX2LONG(y));
2301 if (!RBIGNUM_SIGN(y)) {
2302 y = rb_big_clone(y);
2303 get2comp(y);
2305 if (!RBIGNUM_SIGN(x)) {
2306 x = rb_big_clone(x);
2307 get2comp(x);
2309 if (RBIGNUM_LEN(x) > RBIGNUM_LEN(y)) {
2310 l1 = RBIGNUM_LEN(y);
2311 l2 = RBIGNUM_LEN(x);
2312 ds1 = BDIGITS(y);
2313 ds2 = BDIGITS(x);
2314 sign = RBIGNUM_SIGN(y);
2316 else {
2317 l1 = RBIGNUM_LEN(x);
2318 l2 = RBIGNUM_LEN(y);
2319 ds1 = BDIGITS(x);
2320 ds2 = BDIGITS(y);
2321 sign = RBIGNUM_SIGN(x);
2323 RBIGNUM_SET_SIGN(x, RBIGNUM_SIGN(x)?1:0);
2324 RBIGNUM_SET_SIGN(y, RBIGNUM_SIGN(y)?1:0);
2325 z = bignew(l2, !(RBIGNUM_SIGN(x) ^ RBIGNUM_SIGN(y)));
2326 zds = BDIGITS(z);
2328 for (i=0; i<l1; i++) {
2329 zds[i] = ds1[i] ^ ds2[i];
2331 for (; i<l2; i++) {
2332 zds[i] = sign?ds2[i]:~ds2[i];
2334 if (!RBIGNUM_SIGN(z)) get2comp(z);
2336 return bignorm(z);
2339 static VALUE
2340 check_shiftdown(VALUE y, VALUE x)
2342 if (!RBIGNUM_LEN(x)) return INT2FIX(0);
2343 if (RBIGNUM_LEN(y) > SIZEOF_LONG / SIZEOF_BDIGITS) {
2344 return RBIGNUM_SIGN(x) ? INT2FIX(0) : INT2FIX(-1);
2346 return Qnil;
2350 * call-seq:
2351 * big << numeric => integer
2353 * Shifts big left _numeric_ positions (right if _numeric_ is negative).
2356 VALUE
2357 rb_big_lshift(VALUE x, VALUE y)
2359 long shift;
2360 int neg = 0;
2362 for (;;) {
2363 if (FIXNUM_P(y)) {
2364 shift = FIX2LONG(y);
2365 if (shift < 0) {
2366 neg = 1;
2367 shift = -shift;
2369 break;
2371 else if (TYPE(y) == T_BIGNUM) {
2372 if (!RBIGNUM_SIGN(y)) {
2373 VALUE t = check_shiftdown(y, x);
2374 if (!NIL_P(t)) return t;
2375 neg = 1;
2377 shift = big2ulong(y, "long", Qtrue);
2378 break;
2380 y = rb_to_int(y);
2383 if (neg) return big_rshift(x, shift);
2384 return big_lshift(x, shift);
2387 static VALUE
2388 big_lshift(VALUE x, unsigned long shift)
2390 BDIGIT *xds, *zds;
2391 long s1 = shift/BITSPERDIG;
2392 int s2 = shift%BITSPERDIG;
2393 VALUE z;
2394 BDIGIT_DBL num = 0;
2395 long len, i;
2397 len = RBIGNUM_LEN(x);
2398 z = bignew(len+s1+1, RBIGNUM_SIGN(x));
2399 zds = BDIGITS(z);
2400 for (i=0; i<s1; i++) {
2401 *zds++ = 0;
2403 xds = BDIGITS(x);
2404 for (i=0; i<len; i++) {
2405 num = num | (BDIGIT_DBL)*xds++<<s2;
2406 *zds++ = BIGLO(num);
2407 num = BIGDN(num);
2409 *zds = BIGLO(num);
2410 return bignorm(z);
2414 * call-seq:
2415 * big >> numeric => integer
2417 * Shifts big right _numeric_ positions (left if _numeric_ is negative).
2420 VALUE
2421 rb_big_rshift(VALUE x, VALUE y)
2423 long shift;
2424 int neg = 0;
2426 for (;;) {
2427 if (FIXNUM_P(y)) {
2428 shift = FIX2LONG(y);
2429 if (shift < 0) {
2430 neg = 1;
2431 shift = -shift;
2433 break;
2435 else if (TYPE(y) == T_BIGNUM) {
2436 if (RBIGNUM_SIGN(y)) {
2437 VALUE t = check_shiftdown(y, x);
2438 if (!NIL_P(t)) return t;
2440 else {
2441 neg = 1;
2443 shift = big2ulong(y, "long", Qtrue);
2444 break;
2446 y = rb_to_int(y);
2449 if (neg) return big_lshift(x, shift);
2450 return big_rshift(x, shift);
2453 static VALUE
2454 big_rshift(VALUE x, unsigned long shift)
2456 BDIGIT *xds, *zds;
2457 long s1 = shift/BITSPERDIG;
2458 int s2 = shift%BITSPERDIG;
2459 VALUE z;
2460 BDIGIT_DBL num = 0;
2461 long i, j;
2462 volatile VALUE save_x;
2464 if (s1 > RBIGNUM_LEN(x)) {
2465 if (RBIGNUM_SIGN(x))
2466 return INT2FIX(0);
2467 else
2468 return INT2FIX(-1);
2470 if (!RBIGNUM_SIGN(x)) {
2471 save_x = x = rb_big_clone(x);
2472 get2comp(x);
2474 xds = BDIGITS(x);
2475 i = RBIGNUM_LEN(x); j = i - s1;
2476 if (j == 0) {
2477 if (RBIGNUM_SIGN(x)) return INT2FIX(0);
2478 else return INT2FIX(-1);
2480 z = bignew(j, RBIGNUM_SIGN(x));
2481 if (!RBIGNUM_SIGN(x)) {
2482 num = ((BDIGIT_DBL)~0) << BITSPERDIG;
2484 zds = BDIGITS(z);
2485 while (i--, j--) {
2486 num = (num | xds[i]) >> s2;
2487 zds[j] = BIGLO(num);
2488 num = BIGUP(xds[i]);
2490 if (!RBIGNUM_SIGN(x)) {
2491 get2comp(z);
2493 return bignorm(z);
2497 * call-seq:
2498 * big[n] -> 0, 1
2500 * Bit Reference---Returns the <em>n</em>th bit in the (assumed) binary
2501 * representation of <i>big</i>, where <i>big</i>[0] is the least
2502 * significant bit.
2504 * a = 9**15
2505 * 50.downto(0) do |n|
2506 * print a[n]
2507 * end
2509 * <em>produces:</em>
2511 * 000101110110100000111000011110010100111100010111001
2515 static VALUE
2516 rb_big_aref(VALUE x, VALUE y)
2518 BDIGIT *xds;
2519 BDIGIT_DBL num;
2520 VALUE shift;
2521 long i, s1, s2;
2523 if (TYPE(y) == T_BIGNUM) {
2524 if (!RBIGNUM_SIGN(y))
2525 return INT2FIX(0);
2526 if (RBIGNUM_LEN(bigtrunc(y)) > DIGSPERLONG) {
2527 out_of_range:
2528 return RBIGNUM_SIGN(x) ? INT2FIX(0) : INT2FIX(1);
2530 shift = big2ulong(y, "long", Qfalse);
2532 else {
2533 i = NUM2LONG(y);
2534 if (i < 0) return INT2FIX(0);
2535 shift = (VALUE)i;
2537 s1 = shift/BITSPERDIG;
2538 s2 = shift%BITSPERDIG;
2540 if (s1 >= RBIGNUM_LEN(x)) goto out_of_range;
2541 if (!RBIGNUM_SIGN(x)) {
2542 xds = BDIGITS(x);
2543 i = 0; num = 1;
2544 while (num += ~xds[i], ++i <= s1) {
2545 num = BIGDN(num);
2548 else {
2549 num = BDIGITS(x)[s1];
2551 if (num & ((BDIGIT_DBL)1<<s2))
2552 return INT2FIX(1);
2553 return INT2FIX(0);
2557 * call-seq:
2558 * big.hash => fixnum
2560 * Compute a hash based on the value of _big_.
2563 static VALUE
2564 rb_big_hash(VALUE x)
2566 int hash;
2568 hash = rb_memhash(BDIGITS(x), sizeof(BDIGIT)*RBIGNUM_LEN(x)) ^ RBIGNUM_SIGN(x);
2569 return INT2FIX(hash);
2573 * MISSING: documentation
2576 static VALUE
2577 rb_big_coerce(VALUE x, VALUE y)
2579 if (FIXNUM_P(y)) {
2580 return rb_assoc_new(rb_int2big(FIX2LONG(y)), x);
2582 else if (TYPE(y) == T_BIGNUM) {
2583 return rb_assoc_new(y, x);
2585 else {
2586 rb_raise(rb_eTypeError, "can't coerce %s to Bignum",
2587 rb_obj_classname(y));
2589 /* not reached */
2590 return Qnil;
2594 * call-seq:
2595 * big.abs -> aBignum
2597 * Returns the absolute value of <i>big</i>.
2599 * -1234567890987654321.abs #=> 1234567890987654321
2602 static VALUE
2603 rb_big_abs(VALUE x)
2605 if (!RBIGNUM_SIGN(x)) {
2606 x = rb_big_clone(x);
2607 RBIGNUM_SET_SIGN(x, 1);
2609 return x;
2613 * call-seq:
2614 * big.size -> integer
2616 * Returns the number of bytes in the machine representation of
2617 * <i>big</i>.
2619 * (256**10 - 1).size #=> 12
2620 * (256**20 - 1).size #=> 20
2621 * (256**40 - 1).size #=> 40
2624 static VALUE
2625 rb_big_size(VALUE big)
2627 return LONG2FIX(RBIGNUM_LEN(big)*SIZEOF_BDIGITS);
2631 * call-seq:
2632 * big.odd? -> true or false
2634 * Returns <code>true</code> if <i>big</i> is an odd number.
2637 static VALUE
2638 rb_big_odd_p(VALUE num)
2640 if (BDIGITS(num)[0] & 1) {
2641 return Qtrue;
2643 return Qfalse;
2647 * call-seq:
2648 * big.even? -> true or false
2650 * Returns <code>true</code> if <i>big</i> is an even number.
2653 static VALUE
2654 rb_big_even_p(VALUE num)
2656 if (BDIGITS(num)[0] & 1) {
2657 return Qfalse;
2659 return Qtrue;
2663 * Bignum objects hold integers outside the range of
2664 * Fixnum. Bignum objects are created
2665 * automatically when integer calculations would otherwise overflow a
2666 * Fixnum. When a calculation involving
2667 * Bignum objects returns a result that will fit in a
2668 * Fixnum, the result is automatically converted.
2670 * For the purposes of the bitwise operations and <code>[]</code>, a
2671 * Bignum is treated as if it were an infinite-length
2672 * bitstring with 2's complement representation.
2674 * While Fixnum values are immediate, Bignum
2675 * objects are not---assignment and parameter passing work with
2676 * references to objects, not the objects themselves.
2680 void
2681 Init_Bignum(void)
2683 rb_cBignum = rb_define_class("Bignum", rb_cInteger);
2685 rb_define_method(rb_cBignum, "to_s", rb_big_to_s, -1);
2686 rb_define_method(rb_cBignum, "coerce", rb_big_coerce, 1);
2687 rb_define_method(rb_cBignum, "-@", rb_big_uminus, 0);
2688 rb_define_method(rb_cBignum, "+", rb_big_plus, 1);
2689 rb_define_method(rb_cBignum, "-", rb_big_minus, 1);
2690 rb_define_method(rb_cBignum, "*", rb_big_mul, 1);
2691 rb_define_method(rb_cBignum, "/", rb_big_div, 1);
2692 rb_define_method(rb_cBignum, "%", rb_big_modulo, 1);
2693 rb_define_method(rb_cBignum, "div", rb_big_idiv, 1);
2694 rb_define_method(rb_cBignum, "divmod", rb_big_divmod, 1);
2695 rb_define_method(rb_cBignum, "modulo", rb_big_modulo, 1);
2696 rb_define_method(rb_cBignum, "remainder", rb_big_remainder, 1);
2697 rb_define_method(rb_cBignum, "fdiv", rb_big_fdiv, 1);
2698 rb_define_method(rb_cBignum, "**", rb_big_pow, 1);
2699 rb_define_method(rb_cBignum, "&", rb_big_and, 1);
2700 rb_define_method(rb_cBignum, "|", rb_big_or, 1);
2701 rb_define_method(rb_cBignum, "^", rb_big_xor, 1);
2702 rb_define_method(rb_cBignum, "~", rb_big_neg, 0);
2703 rb_define_method(rb_cBignum, "<<", rb_big_lshift, 1);
2704 rb_define_method(rb_cBignum, ">>", rb_big_rshift, 1);
2705 rb_define_method(rb_cBignum, "[]", rb_big_aref, 1);
2707 rb_define_method(rb_cBignum, "<=>", rb_big_cmp, 1);
2708 rb_define_method(rb_cBignum, "==", rb_big_eq, 1);
2709 rb_define_method(rb_cBignum, "eql?", rb_big_eql, 1);
2710 rb_define_method(rb_cBignum, "hash", rb_big_hash, 0);
2711 rb_define_method(rb_cBignum, "to_f", rb_big_to_f, 0);
2712 rb_define_method(rb_cBignum, "abs", rb_big_abs, 0);
2713 rb_define_method(rb_cBignum, "size", rb_big_size, 0);
2714 rb_define_method(rb_cBignum, "odd?", rb_big_odd_p, 0);
2715 rb_define_method(rb_cBignum, "even?", rb_big_even_p, 0);
2717 power_cache_init();