xref: /freebsd/stand/ficl/math64.c (revision 848ee2a3a8b47c9905fc51fefcf60eb371edbb98)
1 /*******************************************************************
2 ** m a t h 6 4 . c
3 ** Forth Inspired Command Language - 64 bit math support routines
4 ** Author: John Sadler (john_sadler@alum.mit.edu)
5 ** Created: 25 January 1998
6 ** Rev 2.03: Support for 128 bit DP math. This file really ouught to
7 ** be renamed!
8 ** $Id: math64.c,v 1.9 2001/12/05 07:21:34 jsadler Exp $
9 *******************************************************************/
10 /*
11 ** Copyright (c) 1997-2001 John Sadler (john_sadler@alum.mit.edu)
12 ** All rights reserved.
13 **
14 ** Get the latest Ficl release at http://ficl.sourceforge.net
15 **
16 ** I am interested in hearing from anyone who uses ficl. If you have
17 ** a problem, a success story, a defect, an enhancement request, or
18 ** if you would like to contribute to the ficl release, please
19 ** contact me by email at the address above.
20 **
21 ** L I C E N S E  and  D I S C L A I M E R
22 **
23 ** Redistribution and use in source and binary forms, with or without
24 ** modification, are permitted provided that the following conditions
25 ** are met:
26 ** 1. Redistributions of source code must retain the above copyright
27 **    notice, this list of conditions and the following disclaimer.
28 ** 2. Redistributions in binary form must reproduce the above copyright
29 **    notice, this list of conditions and the following disclaimer in the
30 **    documentation and/or other materials provided with the distribution.
31 **
32 ** THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
33 ** ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
34 ** IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
35 ** ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
36 ** FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
37 ** DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
38 ** OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
39 ** HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
40 ** LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
41 ** OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
42 ** SUCH DAMAGE.
43 */
44 
45 /* $FreeBSD$ */
46 
47 #include "ficl.h"
48 #include "math64.h"
49 
50 
51 /**************************************************************************
52                         m 6 4 A b s
53 ** Returns the absolute value of an DPINT
54 **************************************************************************/
55 DPINT m64Abs(DPINT x)
56 {
57     if (m64IsNegative(x))
58         x = m64Negate(x);
59 
60     return x;
61 }
62 
63 
64 /**************************************************************************
65                         m 6 4 F l o o r e d D i v I
66 **
67 ** FROM THE FORTH ANS...
68 ** Floored division is integer division in which the remainder carries
69 ** the sign of the divisor or is zero, and the quotient is rounded to
70 ** its arithmetic floor. Symmetric division is integer division in which
71 ** the remainder carries the sign of the dividend or is zero and the
72 ** quotient is the mathematical quotient rounded towards zero or
73 ** truncated. Examples of each are shown in tables 3.3 and 3.4.
74 **
75 ** Table 3.3 - Floored Division Example
76 ** Dividend        Divisor Remainder       Quotient
77 ** --------        ------- ---------       --------
78 **  10                7       3                1
79 ** -10                7       4               -2
80 **  10               -7      -4               -2
81 ** -10               -7      -3                1
82 **
83 **
84 ** Table 3.4 - Symmetric Division Example
85 ** Dividend        Divisor Remainder       Quotient
86 ** --------        ------- ---------       --------
87 **  10                7       3                1
88 ** -10                7      -3               -1
89 **  10               -7       3               -1
90 ** -10               -7      -3                1
91 **************************************************************************/
92 INTQR m64FlooredDivI(DPINT num, FICL_INT den)
93 {
94     INTQR qr;
95     UNSQR uqr;
96     int signRem = 1;
97     int signQuot = 1;
98 
99     if (m64IsNegative(num))
100     {
101         num = m64Negate(num);
102         signQuot = -signQuot;
103     }
104 
105     if (den < 0)
106     {
107         den      = -den;
108         signRem  = -signRem;
109         signQuot = -signQuot;
110     }
111 
112     uqr = ficlLongDiv(m64CastIU(num), (FICL_UNS)den);
113     qr = m64CastQRUI(uqr);
114     if (signQuot < 0)
115     {
116         qr.quot = -qr.quot;
117         if (qr.rem != 0)
118         {
119             qr.quot--;
120             qr.rem = den - qr.rem;
121         }
122     }
123 
124     if (signRem < 0)
125         qr.rem = -qr.rem;
126 
127     return qr;
128 }
129 
130 
131 /**************************************************************************
132                         m 6 4 I s N e g a t i v e
133 ** Returns TRUE if the specified DPINT has its sign bit set.
134 **************************************************************************/
135 int m64IsNegative(DPINT x)
136 {
137     return (x.hi < 0);
138 }
139 
140 
141 /**************************************************************************
142                         m 6 4 M a c
143 ** Mixed precision multiply and accumulate primitive for number building.
144 ** Multiplies DPUNS u by FICL_UNS mul and adds FICL_UNS add. Mul is typically
145 ** the numeric base, and add represents a digit to be appended to the
146 ** growing number.
147 ** Returns the result of the operation
148 **************************************************************************/
149 DPUNS m64Mac(DPUNS u, FICL_UNS mul, FICL_UNS add)
150 {
151     DPUNS resultLo = ficlLongMul(u.lo, mul);
152     DPUNS resultHi = ficlLongMul(u.hi, mul);
153     resultLo.hi += resultHi.lo;
154     resultHi.lo = resultLo.lo + add;
155 
156     if (resultHi.lo < resultLo.lo)
157         resultLo.hi++;
158 
159     resultLo.lo = resultHi.lo;
160 
161     return resultLo;
162 }
163 
164 
165 /**************************************************************************
166                         m 6 4 M u l I
167 ** Multiplies a pair of FICL_INTs and returns an DPINT result.
168 **************************************************************************/
169 DPINT m64MulI(FICL_INT x, FICL_INT y)
170 {
171     DPUNS prod;
172     int sign = 1;
173 
174     if (x < 0)
175     {
176         sign = -sign;
177         x = -x;
178     }
179 
180     if (y < 0)
181     {
182         sign = -sign;
183         y = -y;
184     }
185 
186     prod = ficlLongMul(x, y);
187     if (sign > 0)
188         return m64CastUI(prod);
189     else
190         return m64Negate(m64CastUI(prod));
191 }
192 
193 
194 /**************************************************************************
195                         m 6 4 N e g a t e
196 ** Negates an DPINT by complementing and incrementing.
197 **************************************************************************/
198 DPINT m64Negate(DPINT x)
199 {
200     x.hi = ~x.hi;
201     x.lo = ~x.lo;
202     x.lo ++;
203     if (x.lo == 0)
204         x.hi++;
205 
206     return x;
207 }
208 
209 
210 /**************************************************************************
211                         m 6 4 P u s h
212 ** Push an DPINT onto the specified stack in the order required
213 ** by ANS Forth (most significant cell on top)
214 ** These should probably be macros...
215 **************************************************************************/
216 void  i64Push(FICL_STACK *pStack, DPINT i64)
217 {
218     stackPushINT(pStack, i64.lo);
219     stackPushINT(pStack, i64.hi);
220     return;
221 }
222 
223 void  u64Push(FICL_STACK *pStack, DPUNS u64)
224 {
225     stackPushINT(pStack, u64.lo);
226     stackPushINT(pStack, u64.hi);
227     return;
228 }
229 
230 
231 /**************************************************************************
232                         m 6 4 P o p
233 ** Pops an DPINT off the stack in the order required by ANS Forth
234 ** (most significant cell on top)
235 ** These should probably be macros...
236 **************************************************************************/
237 DPINT i64Pop(FICL_STACK *pStack)
238 {
239     DPINT ret;
240     ret.hi = stackPopINT(pStack);
241     ret.lo = stackPopINT(pStack);
242     return ret;
243 }
244 
245 DPUNS u64Pop(FICL_STACK *pStack)
246 {
247     DPUNS ret;
248     ret.hi = stackPopINT(pStack);
249     ret.lo = stackPopINT(pStack);
250     return ret;
251 }
252 
253 
254 /**************************************************************************
255                         m 6 4 S y m m e t r i c D i v
256 ** Divide an DPINT by a FICL_INT and return a FICL_INT quotient and a
257 ** FICL_INT remainder. The absolute values of quotient and remainder are not
258 ** affected by the signs of the numerator and denominator (the operation
259 ** is symmetric on the number line)
260 **************************************************************************/
261 INTQR m64SymmetricDivI(DPINT num, FICL_INT den)
262 {
263     INTQR qr;
264     UNSQR uqr;
265     int signRem = 1;
266     int signQuot = 1;
267 
268     if (m64IsNegative(num))
269     {
270         num = m64Negate(num);
271         signRem  = -signRem;
272         signQuot = -signQuot;
273     }
274 
275     if (den < 0)
276     {
277         den      = -den;
278         signQuot = -signQuot;
279     }
280 
281     uqr = ficlLongDiv(m64CastIU(num), (FICL_UNS)den);
282     qr = m64CastQRUI(uqr);
283     if (signRem < 0)
284         qr.rem = -qr.rem;
285 
286     if (signQuot < 0)
287         qr.quot = -qr.quot;
288 
289     return qr;
290 }
291 
292 
293 /**************************************************************************
294                         m 6 4 U M o d
295 ** Divides a DPUNS by base (an UNS16) and returns an UNS16 remainder.
296 ** Writes the quotient back to the original DPUNS as a side effect.
297 ** This operation is typically used to convert an DPUNS to a text string
298 ** in any base. See words.c:numberSignS, for example.
299 ** Mechanics: performs 4 ficlLongDivs, each of which produces 16 bits
300 ** of the quotient. C does not provide a way to divide an FICL_UNS by an
301 ** UNS16 and get an FICL_UNS quotient (ldiv is closest, but it's signed,
302 ** unfortunately), so I've used ficlLongDiv.
303 **************************************************************************/
304 #if (BITS_PER_CELL == 32)
305 
306 #define UMOD_SHIFT 16
307 #define UMOD_MASK 0x0000ffff
308 
309 #elif (BITS_PER_CELL == 64)
310 
311 #define UMOD_SHIFT 32
312 #define UMOD_MASK 0x00000000ffffffff
313 
314 #endif
315 
316 UNS16 m64UMod(DPUNS *pUD, UNS16 base)
317 {
318     DPUNS ud;
319     UNSQR qr;
320     DPUNS result;
321 
322     result.hi = result.lo = 0;
323 
324     ud.hi = 0;
325     ud.lo = pUD->hi >> UMOD_SHIFT;
326     qr = ficlLongDiv(ud, (FICL_UNS)base);
327     result.hi = qr.quot << UMOD_SHIFT;
328 
329     ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->hi & UMOD_MASK);
330     qr = ficlLongDiv(ud, (FICL_UNS)base);
331     result.hi |= qr.quot & UMOD_MASK;
332 
333     ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->lo >> UMOD_SHIFT);
334     qr = ficlLongDiv(ud, (FICL_UNS)base);
335     result.lo = qr.quot << UMOD_SHIFT;
336 
337     ud.lo = (qr.rem << UMOD_SHIFT) | (pUD->lo & UMOD_MASK);
338     qr = ficlLongDiv(ud, (FICL_UNS)base);
339     result.lo |= qr.quot & UMOD_MASK;
340 
341     *pUD = result;
342 
343     return (UNS16)(qr.rem);
344 }
345 
346 
347 /**************************************************************************
348 ** Contributed by
349 ** Michael A. Gauland   gaulandm@mdhost.cse.tek.com
350 **************************************************************************/
351 #if PORTABLE_LONGMULDIV != 0
352 /**************************************************************************
353                         m 6 4 A d d
354 **
355 **************************************************************************/
356 DPUNS m64Add(DPUNS x, DPUNS y)
357 {
358     DPUNS result;
359     int carry;
360 
361     result.hi = x.hi + y.hi;
362     result.lo = x.lo + y.lo;
363 
364 
365     carry  = ((x.lo | y.lo) & CELL_HI_BIT) && !(result.lo & CELL_HI_BIT);
366     carry |= ((x.lo & y.lo) & CELL_HI_BIT);
367 
368     if (carry)
369     {
370         result.hi++;
371     }
372 
373     return result;
374 }
375 
376 
377 /**************************************************************************
378                         m 6 4 S u b
379 **
380 **************************************************************************/
381 DPUNS m64Sub(DPUNS x, DPUNS y)
382 {
383     DPUNS result;
384 
385     result.hi = x.hi - y.hi;
386     result.lo = x.lo - y.lo;
387 
388     if (x.lo < y.lo)
389     {
390         result.hi--;
391     }
392 
393     return result;
394 }
395 
396 
397 /**************************************************************************
398                         m 6 4 A S L
399 ** 64 bit left shift
400 **************************************************************************/
401 DPUNS m64ASL( DPUNS x )
402 {
403     DPUNS result;
404 
405     result.hi = x.hi << 1;
406     if (x.lo & CELL_HI_BIT)
407     {
408         result.hi++;
409     }
410 
411     result.lo = x.lo << 1;
412 
413     return result;
414 }
415 
416 
417 /**************************************************************************
418                         m 6 4 A S R
419 ** 64 bit right shift (unsigned - no sign extend)
420 **************************************************************************/
421 DPUNS m64ASR( DPUNS x )
422 {
423     DPUNS result;
424 
425     result.lo = x.lo >> 1;
426     if (x.hi & 1)
427     {
428         result.lo |= CELL_HI_BIT;
429     }
430 
431     result.hi = x.hi >> 1;
432     return result;
433 }
434 
435 
436 /**************************************************************************
437                         m 6 4 O r
438 ** 64 bit bitwise OR
439 **************************************************************************/
440 DPUNS m64Or( DPUNS x, DPUNS y )
441 {
442     DPUNS result;
443 
444     result.hi = x.hi | y.hi;
445     result.lo = x.lo | y.lo;
446 
447     return result;
448 }
449 
450 
451 /**************************************************************************
452                         m 6 4 C o m p a r e
453 ** Return -1 if x < y; 0 if x==y, and 1 if x > y.
454 **************************************************************************/
455 int m64Compare(DPUNS x, DPUNS y)
456 {
457     int result;
458 
459     if (x.hi > y.hi)
460     {
461         result = +1;
462     }
463     else if (x.hi < y.hi)
464     {
465         result = -1;
466     }
467     else
468     {
469         /* High parts are equal */
470         if (x.lo > y.lo)
471         {
472             result = +1;
473         }
474         else if (x.lo < y.lo)
475         {
476             result = -1;
477         }
478         else
479         {
480             result = 0;
481         }
482     }
483 
484     return result;
485 }
486 
487 
488 /**************************************************************************
489                         f i c l L o n g M u l
490 ** Portable versions of ficlLongMul and ficlLongDiv in C
491 ** Contributed by:
492 ** Michael A. Gauland   gaulandm@mdhost.cse.tek.com
493 **************************************************************************/
494 DPUNS ficlLongMul(FICL_UNS x, FICL_UNS y)
495 {
496     DPUNS result = { 0, 0 };
497     DPUNS addend;
498 
499     addend.lo = y;
500     addend.hi = 0; /* No sign extension--arguments are unsigned */
501 
502     while (x != 0)
503     {
504         if ( x & 1)
505         {
506             result = m64Add(result, addend);
507         }
508         x >>= 1;
509         addend = m64ASL(addend);
510     }
511     return result;
512 }
513 
514 
515 /**************************************************************************
516                         f i c l L o n g D i v
517 ** Portable versions of ficlLongMul and ficlLongDiv in C
518 ** Contributed by:
519 ** Michael A. Gauland   gaulandm@mdhost.cse.tek.com
520 **************************************************************************/
521 UNSQR ficlLongDiv(DPUNS q, FICL_UNS y)
522 {
523     UNSQR result;
524     DPUNS quotient;
525     DPUNS subtrahend;
526     DPUNS mask;
527 
528     quotient.lo = 0;
529     quotient.hi = 0;
530 
531     subtrahend.lo = y;
532     subtrahend.hi = 0;
533 
534     mask.lo = 1;
535     mask.hi = 0;
536 
537     while ((m64Compare(subtrahend, q) < 0) &&
538            (subtrahend.hi & CELL_HI_BIT) == 0)
539     {
540         mask = m64ASL(mask);
541         subtrahend = m64ASL(subtrahend);
542     }
543 
544     while (mask.lo != 0 || mask.hi != 0)
545     {
546         if (m64Compare(subtrahend, q) <= 0)
547         {
548             q = m64Sub( q, subtrahend);
549             quotient = m64Or(quotient, mask);
550         }
551         mask = m64ASR(mask);
552         subtrahend = m64ASR(subtrahend);
553     }
554 
555     result.quot = quotient.lo;
556     result.rem = q.lo;
557     return result;
558 }
559 
560 #endif
561 
562