xref: /freebsd/contrib/bc/include/num.h (revision ec0ea6efa1ad229d75c394c1a9b9cac33af2b1d3)
1 /*
2  * *****************************************************************************
3  *
4  * SPDX-License-Identifier: BSD-2-Clause
5  *
6  * Copyright (c) 2018-2021 Gavin D. Howard and contributors.
7  *
8  * Redistribution and use in source and binary forms, with or without
9  * modification, are permitted provided that the following conditions are met:
10  *
11  * * Redistributions of source code must retain the above copyright notice, this
12  *   list of conditions and the following disclaimer.
13  *
14  * * Redistributions in binary form must reproduce the above copyright notice,
15  *   this list of conditions and the following disclaimer in the documentation
16  *   and/or other materials provided with the distribution.
17  *
18  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
19  * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
20  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
21  * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
22  * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
23  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
24  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
25  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
26  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
27  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
28  * POSSIBILITY OF SUCH DAMAGE.
29  *
30  * *****************************************************************************
31  *
32  * Definitions for the num type.
33  *
34  */
35 
36 #ifndef BC_NUM_H
37 #define BC_NUM_H
38 
39 #include <limits.h>
40 #include <stdbool.h>
41 #include <stddef.h>
42 #include <stdint.h>
43 
44 #include <sys/types.h>
45 
46 #include <status.h>
47 #include <vector.h>
48 #include <bcl.h>
49 
50 #ifndef BC_ENABLE_EXTRA_MATH
51 #define BC_ENABLE_EXTRA_MATH (1)
52 #endif // BC_ENABLE_EXTRA_MATH
53 
54 /// Everything in bc is base 10..
55 #define BC_BASE (10)
56 
57 /// Alias.
58 typedef unsigned long ulong;
59 
60 /// This is here because BcBigDig came first, but when I created bcl, it's
61 /// definition has to be defined first.
62 typedef BclBigDig BcBigDig;
63 
64 #if BC_LONG_BIT >= 64
65 
66 /// The biggest number held by a BcBigDig.
67 #define BC_NUM_BIGDIG_MAX ((BcBigDig) UINT64_MAX)
68 
69 /// The number of decimal digits in one limb.
70 #define BC_BASE_DIGS (9)
71 
72 /// The max number + 1 that one limb can hold.
73 #define BC_BASE_POW (1000000000)
74 
75 /// An alias for portability.
76 #define BC_NUM_BIGDIG_C UINT64_C
77 
78 /// The actual limb type.
79 typedef int_least32_t BcDig;
80 
81 #elif BC_LONG_BIT >= 32
82 
83 /// The biggest number held by a BcBigDig.
84 #define BC_NUM_BIGDIG_MAX ((BcBigDig) UINT32_MAX)
85 
86 /// The number of decimal digits in one limb.
87 #define BC_BASE_DIGS (4)
88 
89 /// The max number + 1 that one limb can hold.
90 #define BC_BASE_POW (10000)
91 
92 /// An alias for portability.
93 #define BC_NUM_BIGDIG_C UINT32_C
94 
95 /// The actual limb type.
96 typedef int_least16_t BcDig;
97 
98 #else
99 
100 /// LONG_BIT must be at least 32 on POSIX. We depend on that.
101 #error BC_LONG_BIT must be at least 32
102 
103 #endif // BC_LONG_BIT >= 64
104 
105 /// The default (and minimum) number of limbs when allocating a number.
106 #define BC_NUM_DEF_SIZE (8)
107 
108 /// The actual number struct. This is where the magic happens.
109 typedef struct BcNum {
110 
111 	/// The limb array. It is restrict because *no* other item should own the
112 	/// array. For more information, see the development manual
113 	/// (manuals/development.md#numbers).
114 	BcDig *restrict num;
115 
116 	/// The number of limbs before the decimal (radix) point. This also stores
117 	/// the negative bit in the least significant bit since it uses at least two
118 	/// bits less than scale. It is also used less than scale. See the
119 	/// development manual (manuals/development.md#numbers) for more info.
120 	size_t rdx;
121 
122 	/// The actual scale of the number. This is different from rdx because there
123 	/// are multiple digits in one limb, and in the last limb, only some of the
124 	/// digits may be part of the scale. However, scale must always match rdx
125 	/// (except when the number is 0), or there is a bug. For more information,
126 	/// see the development manual (manuals/development.md#numbers).
127 	size_t scale;
128 
129 	/// The number of valid limbs in the array. If this is 0, then the number is
130 	/// 0 as well.
131 	size_t len;
132 
133 	/// The capacity of the limbs array. This is how many limbs the number could
134 	/// expand to without reallocation.
135 	size_t cap;
136 
137 } BcNum;
138 
139 #if BC_ENABLE_EXTRA_MATH
140 
141 // Forward declaration
142 struct BcRNG;
143 
144 #endif // BC_ENABLE_EXTRA_MATH
145 
146 /// The minimum obase.
147 #define BC_NUM_MIN_BASE (BC_NUM_BIGDIG_C(2))
148 
149 /// The maximum ibase allowed by POSIX.
150 #define BC_NUM_MAX_POSIX_IBASE (BC_NUM_BIGDIG_C(16))
151 
152 /// The actual ibase supported by this implementation.
153 #define BC_NUM_MAX_IBASE (BC_NUM_BIGDIG_C(36))
154 
155 /// The max base allowed by bc_num_parseChar().
156 #define BC_NUM_MAX_LBASE (BC_NUM_BIGDIG_C('Z' + BC_BASE + 1))
157 
158 /// The default number of characters to print before a backslash newline.
159 #define BC_NUM_PRINT_WIDTH (BC_NUM_BIGDIG_C(69))
160 
161 /// The base for printing streams from numbers.
162 #define BC_NUM_STREAM_BASE (256)
163 
164 // This sets a default for the Karatsuba length.
165 #ifndef BC_NUM_KARATSUBA_LEN
166 #define BC_NUM_KARATSUBA_LEN (BC_NUM_BIGDIG_C(32))
167 #elif BC_NUM_KARATSUBA_LEN < 16
168 #error BC_NUM_KARATSUBA_LEN must be at least 16.
169 #endif // BC_NUM_KARATSUBA_LEN
170 
171 // A crude, but always big enough, calculation of
172 // the size required for ibase and obase BcNum's.
173 #define BC_NUM_BIGDIG_LOG10 (BC_NUM_DEF_SIZE)
174 
175 /**
176  * Returns non-zero if the BcNum @a n is non-zero.
177  * @param n  The number to test.
178  * @return   Non-zero if @a n is non-zero, zero otherwise.
179  */
180 #define BC_NUM_NONZERO(n) ((n)->len)
181 
182 /**
183  * Returns true if the BcNum @a n is zero.
184  * @param n  The number to test.
185  * @return   True if @a n is zero, false otherwise.
186  */
187 #define BC_NUM_ZERO(n) (!BC_NUM_NONZERO(n))
188 
189 /**
190  * Returns true if the BcNum @a n is one with no scale.
191  * @param n  The number to test.
192  * @return   True if @a n equals 1 with no scale, false otherwise.
193  */
194 #define BC_NUM_ONE(n) ((n)->len == 1 && (n)->rdx == 0 && (n)->num[0] == 1)
195 
196 /**
197  * Converts the letter @a c into a number.
198  * @param c  The letter to convert.
199  * @return   The number corresponding to the letter.
200  */
201 #define BC_NUM_NUM_LETTER(c) ((c) - 'A' + BC_BASE)
202 
203 /// The number of allocations done by bc_num_k(). If you change the number of
204 /// allocations, you must change this. This is done in order to allocate them
205 /// all as one allocation and just give them all pointers to different parts.
206 /// Works pretty well, but you have to be careful.
207 #define BC_NUM_KARATSUBA_ALLOCS (6)
208 
209 /**
210  * Rounds @a s (scale) up to the next power of BC_BASE_DIGS. This also check for
211  * overflow and gives a fatal error if that happens because we just can't go
212  * over the limits we have imposed.
213  * @param s  The scale to round up.
214  * @return   @a s rounded up to the next power of BC_BASE_DIGS.
215  */
216 #define BC_NUM_ROUND_POW(s) (bc_vm_growSize((s), BC_BASE_DIGS - 1))
217 
218 /**
219  * Returns the equivalent rdx for the scale @a s.
220  * @param s  The scale to convert.
221  * @return   The rdx for @a s.
222  */
223 #define BC_NUM_RDX(s) (BC_NUM_ROUND_POW(s) / BC_BASE_DIGS)
224 
225 /**
226  * Returns the actual rdx of @a n. (It removes the negative bit.)
227  * @param n  The number.
228  * @return   The real rdx of @a n.
229  */
230 #define BC_NUM_RDX_VAL(n) ((n)->rdx >> 1)
231 
232 /**
233  * Returns the actual rdx of @a n, where @a n is not a pointer. (It removes the
234  * negative bit.)
235  * @param n  The number.
236  * @return   The real rdx of @a n.
237  */
238 #define BC_NUM_RDX_VAL_NP(n) ((n).rdx >> 1)
239 
240 /**
241  * Sets the rdx of @a n to @a v.
242  * @param n  The number.
243  * @param v  The value to set the rdx to.
244  */
245 #define BC_NUM_RDX_SET(n, v) \
246 	((n)->rdx = (((v) << 1) | ((n)->rdx & (BcBigDig) 1)))
247 
248 /**
249  * Sets the rdx of @a n to @a v, where @a n is not a pointer.
250  * @param n  The number.
251  * @param v  The value to set the rdx to.
252  */
253 #define BC_NUM_RDX_SET_NP(n, v) \
254 	((n).rdx = (((v) << 1) | ((n).rdx & (BcBigDig) 1)))
255 
256 /**
257  * Sets the rdx of @a n to @a v and the negative bit to @a neg.
258  * @param n    The number.
259  * @param v    The value to set the rdx to.
260  * @param neg  The value to set the negative bit to.
261  */
262 #define BC_NUM_RDX_SET_NEG(n, v, neg) \
263 	((n)->rdx = (((v) << 1) | (neg)))
264 
265 /**
266  * Returns true if the rdx and scale for @a n match.
267  * @param n  The number to test.
268  * @return   True if the rdx and scale of @a n match, false otherwise.
269  */
270 #define BC_NUM_RDX_VALID(n) \
271 	(BC_NUM_ZERO(n) || BC_NUM_RDX_VAL(n) * BC_BASE_DIGS >= (n)->scale)
272 
273 /**
274  * Returns true if the rdx and scale for @a n match, where @a n is not a
275  * pointer.
276  * @param n  The number to test.
277  * @return   True if the rdx and scale of @a n match, false otherwise.
278  */
279 #define BC_NUM_RDX_VALID_NP(n) \
280 	((!(n).len) || BC_NUM_RDX_VAL_NP(n) * BC_BASE_DIGS >= (n).scale)
281 
282 /**
283  * Returns true if @a n is negative, false otherwise.
284  * @param n  The number to test.
285  * @return   True if @a n is negative, false otherwise.
286  */
287 #define BC_NUM_NEG(n) ((n)->rdx & ((BcBigDig) 1))
288 
289 /**
290  * Returns true if @a n is negative, false otherwise, where @a n is not a
291  * pointer.
292  * @param n  The number to test.
293  * @return   True if @a n is negative, false otherwise.
294  */
295 #define BC_NUM_NEG_NP(n) ((n).rdx & ((BcBigDig) 1))
296 
297 /**
298  * Clears the negative bit on @a n.
299  * @param n  The number.
300  */
301 #define BC_NUM_NEG_CLR(n) ((n)->rdx &= ~((BcBigDig) 1))
302 
303 /**
304  * Clears the negative bit on @a n, where @a n is not a pointer.
305  * @param n  The number.
306  */
307 #define BC_NUM_NEG_CLR_NP(n) ((n).rdx &= ~((BcBigDig) 1))
308 
309 /**
310  * Sets the negative bit on @a n.
311  * @param n  The number.
312  */
313 #define BC_NUM_NEG_SET(n) ((n)->rdx |= ((BcBigDig) 1))
314 
315 /**
316  * Toggles the negative bit on @a n.
317  * @param n  The number.
318  */
319 #define BC_NUM_NEG_TGL(n) ((n)->rdx ^= ((BcBigDig) 1))
320 
321 /**
322  * Toggles the negative bit on @a n, where @a n is not a pointer.
323  * @param n  The number.
324  */
325 #define BC_NUM_NEG_TGL_NP(n) ((n).rdx ^= ((BcBigDig) 1))
326 
327 /**
328  * Returns the rdx val for @a n if the negative bit is set to @a v.
329  * @param n  The number.
330  * @param v  The value for the negative bit.
331  * @return   The value of the rdx of @a n if the negative bit were set to @a v.
332  */
333 #define BC_NUM_NEG_VAL(n, v) (((n)->rdx & ~((BcBigDig) 1)) | (v))
334 
335 /**
336  * Returns the rdx val for @a n if the negative bit is set to @a v, where @a n
337  * is not a pointer.
338  * @param n  The number.
339  * @param v  The value for the negative bit.
340  * @return   The value of the rdx of @a n if the negative bit were set to @a v.
341  */
342 #define BC_NUM_NEG_VAL_NP(n, v) (((n).rdx & ~((BcBigDig) 1)) | (v))
343 
344 /**
345  * Returns the size, in bytes, of limb array with @a n limbs.
346  * @param n  The number.
347  * @return   The size, in bytes, of a limb array with @a n limbs.
348  */
349 #define BC_NUM_SIZE(n) ((n) * sizeof(BcDig))
350 
351 // These are for debugging only.
352 #if BC_DEBUG_CODE
353 #define BC_NUM_PRINT(x) fprintf(stderr, "%s = %lu\n", #x, (unsigned long)(x))
354 #define DUMP_NUM bc_num_dump
355 #else // BC_DEBUG_CODE
356 #undef DUMP_NUM
357 #define DUMP_NUM(x,y)
358 #define BC_NUM_PRINT(x)
359 #endif // BC_DEBUG_CODE
360 
361 /**
362  * A function type for binary operators.
363  * @param a      The first parameter.
364  * @param b      The second parameter.
365  * @param c      The return value.
366  * @param scale  The current scale.
367  */
368 typedef void (*BcNumBinaryOp)(BcNum* a, BcNum* b, BcNum* c, size_t scale);
369 
370 /**
371  * A function type for binary operators *after* @a c has been properly
372  * allocated. At this point, *nothing* should be pointing to @a c (in any way
373  * that matters, anyway).
374  * @param a      The first operand.
375  * @param b      The second operand.
376  * @param c      The return parameter.
377  * @param scale  The current scale.
378  */
379 typedef void (*BcNumBinOp)(BcNum* a, BcNum* b, BcNum* restrict c, size_t scale);
380 
381 /**
382  * A function type for getting the allocation size needed for a binary operator.
383  * Any function used for this *must* return enough space for *all* possible
384  * invocations of the operator.
385  * @param a      The first parameter.
386  * @param b      The second parameter.
387  * @param scale  The current scale.
388  * @return       The size of allocation needed for the result of the operator
389  *               with @a a, @a b, and @a scale.
390  */
391 typedef size_t (*BcNumBinaryOpReq)(const BcNum* a, const BcNum* b,
392                                    size_t scale);
393 
394 /**
395  * A function type for printing a "digit." Functions of this type will print one
396  * digit in a number. Digits are printed differently based on the base, which is
397  * why there is more than one implementation of this function type.
398  * @param n       The "digit" to print.
399  * @param len     The "length" of the digit, or number of characters that will
400  *                need to be printed for the digit.
401  * @param rdx     True if a decimal (radix) point should be printed.
402  * @param bslash  True if a backslash+newline should be printed if the character
403  *                limit for the line is reached, false otherwise.
404  */
405 typedef void (*BcNumDigitOp)(size_t n, size_t len, bool rdx, bool bslash);
406 
407 /**
408  * A function type to run an operator on @a a and @a b and store the result in
409  * @a a. This is used in karatsuba for faster adds and subtracts at the end.
410  * @param a    The first parameter and return value.
411  * @param b    The second parameter.
412  * @param len  The minimum length of both arrays.
413  */
414 typedef void (*BcNumShiftAddOp)(BcDig* restrict a, const BcDig* restrict b,
415                                 size_t len);
416 
417 /**
418  * Initializes @a n with @a req limbs in its array.
419  * @param n    The number to initialize.
420  * @param req  The number of limbs @a n must have in its limb array.
421  */
422 void bc_num_init(BcNum *restrict n, size_t req);
423 
424 /**
425  * Initializes (sets up) @a n with the preallocated limb array @a num that has
426  * size @a cap. This is called by @a bc_num_init(), but it is also used by parts
427  * of bc that use statically allocated limb arrays.
428  * @param n    The number to initialize.
429  * @param num  The preallocated limb array.
430  * @param cap  The capacity of @a num.
431  */
432 void bc_num_setup(BcNum *restrict n, BcDig *restrict num, size_t cap);
433 
434 /**
435  * Copies @a s into @a d. This does a deep copy and requires that @a d is
436  * already a valid and allocated BcNum.
437  * @param d  The destination BcNum.
438  * @param s  The source BcNum.
439  */
440 void bc_num_copy(BcNum *d, const BcNum *s);
441 
442 /**
443  * Creates @a d and copies @a s into @a d. This does a deep copy and requires
444  * that @a d is *not* a valid or allocated BcNum.
445  * @param d  The destination BcNum.
446  * @param s  The source BcNum.
447  */
448 void bc_num_createCopy(BcNum *d, const BcNum *s);
449 
450 /**
451  * Creates (initializes) @a n and sets its value to the equivalent of @a val.
452  * @a n must *not* be a valid or preallocated BcNum.
453  * @param n    The number to initialize and set.
454  * @param val  The value to set @a n's value to.
455  */
456 void bc_num_createFromBigdig(BcNum *restrict n, BcBigDig val);
457 
458 /**
459  * Makes @a n valid for holding strings. @a n must *not* be allocated; this
460  * simply clears some fields, including setting the num field to NULL.
461  * @param n  The number to clear.
462  */
463 void bc_num_clear(BcNum *restrict n);
464 
465 /**
466  * Frees @a num, which is a BcNum as a void pointer. This is a destructor.
467  * @param num  The BcNum to free as a void pointer.
468  */
469 void bc_num_free(void *num);
470 
471 /**
472  * Returns the scale of @a n.
473  * @param n  The number.
474  * @return   The scale of @a n.
475  */
476 size_t bc_num_scale(const BcNum *restrict n);
477 
478 /**
479  * Returns the length (in decimal digits) of @a n. This is complicated. First,
480  * if the number is zero, we always return at least one, but we also return the
481  * scale if it exists. Then, If it is not zero, it opens a whole other can of
482  * worms. Read the comments in the definition.
483  * @param n  The number.
484  * @return   The length of @a n.
485  */
486 size_t bc_num_len(const BcNum *restrict n);
487 
488 /**
489  * Convert a number to a BcBigDig (hardware integer). This version does error
490  * checking, and if it finds an error, throws it. Otherwise, it calls
491  * bc_num_bigdig2().
492  * @param n  The number to convert.
493  * @return   The number as a hardware integer.
494  */
495 BcBigDig bc_num_bigdig(const BcNum *restrict n);
496 
497 /**
498  * Convert a number to a BcBigDig (hardware integer). This version does no error
499  * checking.
500  * @param n  The number to convert.
501  * @return   The number as a hardware integer.
502  */
503 BcBigDig bc_num_bigdig2(const BcNum *restrict n);
504 
505 /**
506  * Sets @a n to the value of @a val. @a n is expected to be a valid and
507  * allocated BcNum.
508  * @param n    The number to set.
509  * @param val  The value to set the number to.
510  */
511 void bc_num_bigdig2num(BcNum *restrict n, BcBigDig val);
512 
513 #if BC_ENABLE_EXTRA_MATH
514 
515 /**
516  * Generates a random arbitrary-size integer less than or equal to @a a and
517  * returns it in @a b. This implements irand().
518  * @param a    The limit for the integer to generate.
519  * @param b    The return value.
520  * @param rng  The pseudo-random number generator.
521  */
522 void bc_num_irand(BcNum *restrict a, BcNum *restrict b,
523                   struct BcRNG *restrict rng);
524 
525 /**
526  * Sets the seed for the PRNG @a rng from @a n.
527  * @param n    The new seed for the PRNG.
528  * @param rng  The PRNG to set the seed for.
529  */
530 void bc_num_rng(const BcNum *restrict n, struct BcRNG *rng);
531 
532 /**
533  * Sets @a n to the value produced by the PRNG. This implements rand().
534  * @param n    The number to set.
535  * @param rng  The pseudo-random number generator.
536  */
537 void bc_num_createFromRNG(BcNum *restrict n, struct BcRNG *rng);
538 
539 #endif // BC_ENABLE_EXTRA_MATH
540 
541 /**
542  * The add function. This is a BcNumBinaryOp function.
543  * @param a      The first parameter.
544  * @param b      The second parameter.
545  * @param c      The return value.
546  * @param scale  The current scale.
547  */
548 void bc_num_add(BcNum *a, BcNum *b, BcNum *c, size_t scale);
549 
550 /**
551  * The subtract function. This is a BcNumBinaryOp function.
552  * @param a      The first parameter.
553  * @param b      The second parameter.
554  * @param c      The return value.
555  * @param scale  The current scale.
556  */
557 void bc_num_sub(BcNum *a, BcNum *b, BcNum *c, size_t scale);
558 
559 /**
560  * The multiply function.
561  * @param a      The first parameter. This is a BcNumBinaryOp function.
562  * @param b      The second parameter.
563  * @param c      The return value.
564  * @param scale  The current scale.
565  */
566 void bc_num_mul(BcNum *a, BcNum *b, BcNum *c, size_t scale);
567 
568 /**
569  * The division function.
570  * @param a      The first parameter. This is a BcNumBinaryOp function.
571  * @param b      The second parameter.
572  * @param c      The return value.
573  * @param scale  The current scale.
574  */
575 void bc_num_div(BcNum *a, BcNum *b, BcNum *c, size_t scale);
576 
577 /**
578  * The modulus function.
579  * @param a      The first parameter. This is a BcNumBinaryOp function.
580  * @param b      The second parameter.
581  * @param c      The return value.
582  * @param scale  The current scale.
583  */
584 void bc_num_mod(BcNum *a, BcNum *b, BcNum *c, size_t scale);
585 
586 /**
587  * The power function.
588  * @param a      The first parameter. This is a BcNumBinaryOp function.
589  * @param b      The second parameter.
590  * @param c      The return value.
591  * @param scale  The current scale.
592  */
593 void bc_num_pow(BcNum *a, BcNum *b, BcNum *c, size_t scale);
594 #if BC_ENABLE_EXTRA_MATH
595 
596 /**
597  * The places function (@ operator). This is a BcNumBinaryOp function.
598  * @param a      The first parameter.
599  * @param b      The second parameter.
600  * @param c      The return value.
601  * @param scale  The current scale.
602  */
603 void bc_num_places(BcNum *a, BcNum *b, BcNum *c, size_t scale);
604 
605 /**
606  * The left shift function (<< operator). This is a BcNumBinaryOp function.
607  * @param a      The first parameter.
608  * @param b      The second parameter.
609  * @param c      The return value.
610  * @param scale  The current scale.
611  */
612 void bc_num_lshift(BcNum *a, BcNum *b, BcNum *c, size_t scale);
613 
614 /**
615  * The right shift function (>> operator). This is a BcNumBinaryOp function.
616  * @param a      The first parameter.
617  * @param b      The second parameter.
618  * @param c      The return value.
619  * @param scale  The current scale.
620  */
621 void bc_num_rshift(BcNum *a, BcNum *b, BcNum *c, size_t scale);
622 
623 #endif // BC_ENABLE_EXTRA_MATH
624 
625 /**
626  * Square root.
627  * @param a      The first parameter.
628  * @param b      The return value.
629  * @param scale  The current scale.
630  */
631 void bc_num_sqrt(BcNum *restrict a, BcNum *restrict b, size_t scale);
632 
633 /**
634  * Divsion and modulus together. This is a dc extension.
635  * @param a      The first parameter.
636  * @param b      The second parameter.
637  * @param c      The first return value (quotient).
638  * @param d      The second return value (modulus).
639  * @param scale  The current scale.
640  */
641 void bc_num_divmod(BcNum *a, BcNum *b, BcNum *c, BcNum *d, size_t scale);
642 
643 /**
644  * A function returning the required allocation size for an addition or a
645  * subtraction. This is a BcNumBinaryOpReq function.
646  * @param a      The first parameter.
647  * @param b      The second parameter.
648  * @param scale  The current scale.
649  * @return       The size of allocation needed for the result of add or subtract
650  *               with @a a, @a b, and @a scale.
651  */
652 size_t bc_num_addReq(const BcNum* a, const BcNum* b, size_t scale);
653 
654 /**
655  * A function returning the required allocation size for a multiplication. This
656  * is a BcNumBinaryOpReq function.
657  * @param a      The first parameter.
658  * @param b      The second parameter.
659  * @param scale  The current scale.
660  * @return       The size of allocation needed for the result of multiplication
661  *               with @a a, @a b, and @a scale.
662  */
663 size_t bc_num_mulReq(const BcNum *a, const BcNum *b, size_t scale);
664 
665 /**
666  * A function returning the required allocation size for a division or modulus.
667  * This is a BcNumBinaryOpReq function.
668  * @param a      The first parameter.
669  * @param b      The second parameter.
670  * @param scale  The current scale.
671  * @return       The size of allocation needed for the result of division or
672  *               modulus with @a a, @a b, and @a scale.
673  */
674 size_t bc_num_divReq(const BcNum *a, const BcNum *b, size_t scale);
675 
676 /**
677  * A function returning the required allocation size for an exponentiation. This
678  * is a BcNumBinaryOpReq function.
679  * @param a      The first parameter.
680  * @param b      The second parameter.
681  * @param scale  The current scale.
682  * @return       The size of allocation needed for the result of exponentiation
683  *               with @a a, @a b, and @a scale.
684  */
685 size_t bc_num_powReq(const BcNum *a, const BcNum *b, size_t scale);
686 
687 #if BC_ENABLE_EXTRA_MATH
688 
689 /**
690  * A function returning the required allocation size for a places, left shift,
691  * or right shift. This is a BcNumBinaryOpReq function.
692  * @param a      The first parameter.
693  * @param b      The second parameter.
694  * @param scale  The current scale.
695  * @return       The size of allocation needed for the result of places, left
696  *               shift, or right shift with @a a, @a b, and @a scale.
697  */
698 size_t bc_num_placesReq(const BcNum *a, const BcNum *b, size_t scale);
699 
700 #endif // BC_ENABLE_EXTRA_MATH
701 
702 /**
703  * Truncate @a n *by* @a places decimal places. This only extends places *after*
704  * the decimal point.
705  * @param n       The number to truncate.
706  * @param places  The number of places to truncate @a n by.
707  */
708 void bc_num_truncate(BcNum *restrict n, size_t places);
709 
710 /**
711  * Extend @a n *by* @a places decimal places. This only extends places *after*
712  * the decimal point.
713  * @param n       The number to truncate.
714  * @param places  The number of places to extend @a n by.
715  */
716 void bc_num_extend(BcNum *restrict n, size_t places);
717 
718 /**
719  * Shifts @a n right by @a places decimal places. This is the workhorse of the
720  * right shift operator, and would be static to src/num.c, except that
721  * src/library.c uses it for efficiency when executing its frand.
722  * @param n       The number to shift right.
723  * @param places  The number of decimal places to shift @a n right by.
724  */
725 void bc_num_shiftRight(BcNum *restrict n, size_t places);
726 
727 /**
728  * Compare a and b and return the result of their comparison as an ssize_t.
729  * Returns >0 if @a a is greater than @a b, <0 if @a a is less than @a b, and =0
730  * if a == b.
731  * @param a  The first number.
732  * @param b  The second number.
733  * @return   The result of the comparison.
734  */
735 ssize_t bc_num_cmp(const BcNum *a, const BcNum *b);
736 
737 /**
738  * Modular exponentiation.
739  * @param a      The first parameter.
740  * @param b      The second parameter.
741  * @param c      The third parameter.
742  * @param d      The return value.
743  */
744 void bc_num_modexp(BcNum *a, BcNum *b, BcNum *c, BcNum *restrict d);
745 
746 /**
747  * Sets @a n to zero with a scale of zero.
748  * @param n  The number to zero.
749  */
750 void bc_num_zero(BcNum *restrict n);
751 
752 /**
753  * Sets @a n to one with a scale of zero.
754  * @param n  The number to set to one.
755  */
756 void bc_num_one(BcNum *restrict n);
757 
758 /**
759  * An efficient function to compare @a n to zero.
760  * @param n  The number to compare to zero.
761  * @return   The result of the comparison.
762  */
763 ssize_t bc_num_cmpZero(const BcNum *n);
764 
765 #if !defined(NDEBUG) || BC_ENABLE_LIBRARY
766 
767 /**
768  * Check a number string for validity and return true if it is, false otherwise.
769  * The library needs this to check user-supplied strings, but in bc and dc, this
770  * is only used for debug asserts because the parsers should get the numbers
771  * parsed right, which should ensure they are always valid.
772  * @param val  The string to check.
773  * @return     True if the string is a valid number, false otherwise.
774  */
775 bool bc_num_strValid(const char *restrict val);
776 
777 #endif // !defined(NDEBUG) || BC_ENABLE_LIBRARY
778 
779 /**
780  * Parses a number string into the number @a n according to @a base.
781  * @param n     The number to set to the parsed value.
782  * @param val   The number string to parse.
783  * @param base  The base to parse the number string by.
784  */
785 void bc_num_parse(BcNum *restrict n, const char *restrict val, BcBigDig base);
786 
787 /**
788  * Prints the number @a n according to @a base.
789  * @param n        The number to print.
790  * @param base     The base to print the number by.
791  * @param newline  True if a newline should be inserted at the end, false
792  *                 otherwise.
793  */
794 void bc_num_print(BcNum *restrict n, BcBigDig base, bool newline);
795 
796 #if !BC_ENABLE_LIBRARY
797 
798 /**
799  * Prints a number as a character stream.
800  * @param n     The number to print as a character stream.
801  */
802 void bc_num_stream(BcNum *restrict n);
803 
804 #endif // !BC_ENABLE_LIBRARY
805 
806 #if BC_DEBUG_CODE
807 
808 /**
809  * Print a number with a label. This is a debug-only function.
810  * @param n          The number to print.
811  * @param name       The label to print the number with.
812  * @param emptyline  True if there should be an empty line after the number.
813  */
814 void bc_num_printDebug(const BcNum *n, const char *name, bool emptyline);
815 
816 /**
817  * Print the limbs of @a n. This is a debug-only function.
818  * @param n          The number to print.
819  * @param len        The length of the number.
820  * @param emptyline  True if there should be an empty line after the number.
821  */
822 void bc_num_printDigs(const BcDig* n, size_t len, bool emptyline);
823 
824 /**
825  * Print debug info about @a n along with its limbs.
826  * @param n          The number to print.
827  * @param name       The label to print the number with.
828  * @param emptyline  True if there should be an empty line after the number.
829  */
830 void bc_num_printWithDigs(const BcNum *n, const char *name, bool emptyline);
831 
832 /**
833  * Dump debug info about a BcNum variable.
834  * @param varname  The variable name.
835  * @param n        The number.
836  */
837 void bc_num_dump(const char *varname, const BcNum *n);
838 
839 #endif // BC_DEBUG_CODE
840 
841 /// A reference to an array of hex digits for easy conversion for printing.
842 extern const char bc_num_hex_digits[];
843 
844 /// An array of powers of 10 for easy conversion from number of digits to
845 //powers.
846 extern const BcBigDig bc_num_pow10[BC_BASE_DIGS + 1];
847 
848 /// A reference to a constant array that is the max of a BigDig.
849 extern const BcDig bc_num_bigdigMax[];
850 
851 /// A reference to a constant size of the above array.
852 extern const size_t bc_num_bigdigMax_size;
853 
854 /// A reference to a constant array that is 2 times the max of a BigDig.
855 extern const BcDig bc_num_bigdigMax2[];
856 
857 /// A reference to a constant size of the above array.
858 extern const size_t bc_num_bigdigMax2_size;
859 
860 #endif // BC_NUM_H
861