xref: /openbmc/linux/arch/m68k/math-emu/fp_arith.c (revision 4f3db074)
1 /*
2 
3    fp_arith.c: floating-point math routines for the Linux-m68k
4    floating point emulator.
5 
6    Copyright (c) 1998-1999 David Huggins-Daines.
7 
8    Somewhat based on the AlphaLinux floating point emulator, by David
9    Mosberger-Tang.
10 
11    You may copy, modify, and redistribute this file under the terms of
12    the GNU General Public License, version 2, or any later version, at
13    your convenience.
14  */
15 
16 #include "fp_emu.h"
17 #include "multi_arith.h"
18 #include "fp_arith.h"
19 
20 const struct fp_ext fp_QNaN =
21 {
22 	.exp = 0x7fff,
23 	.mant = { .m64 = ~0 }
24 };
25 
26 const struct fp_ext fp_Inf =
27 {
28 	.exp = 0x7fff,
29 };
30 
31 /* let's start with the easy ones */
32 
33 struct fp_ext *
34 fp_fabs(struct fp_ext *dest, struct fp_ext *src)
35 {
36 	dprint(PINSTR, "fabs\n");
37 
38 	fp_monadic_check(dest, src);
39 
40 	dest->sign = 0;
41 
42 	return dest;
43 }
44 
45 struct fp_ext *
46 fp_fneg(struct fp_ext *dest, struct fp_ext *src)
47 {
48 	dprint(PINSTR, "fneg\n");
49 
50 	fp_monadic_check(dest, src);
51 
52 	dest->sign = !dest->sign;
53 
54 	return dest;
55 }
56 
57 /* Now, the slightly harder ones */
58 
59 /* fp_fadd: Implements the kernel of the FADD, FSADD, FDADD, FSUB,
60    FDSUB, and FCMP instructions. */
61 
62 struct fp_ext *
63 fp_fadd(struct fp_ext *dest, struct fp_ext *src)
64 {
65 	int diff;
66 
67 	dprint(PINSTR, "fadd\n");
68 
69 	fp_dyadic_check(dest, src);
70 
71 	if (IS_INF(dest)) {
72 		/* infinity - infinity == NaN */
73 		if (IS_INF(src) && (src->sign != dest->sign))
74 			fp_set_nan(dest);
75 		return dest;
76 	}
77 	if (IS_INF(src)) {
78 		fp_copy_ext(dest, src);
79 		return dest;
80 	}
81 
82 	if (IS_ZERO(dest)) {
83 		if (IS_ZERO(src)) {
84 			if (src->sign != dest->sign) {
85 				if (FPDATA->rnd == FPCR_ROUND_RM)
86 					dest->sign = 1;
87 				else
88 					dest->sign = 0;
89 			}
90 		} else
91 			fp_copy_ext(dest, src);
92 		return dest;
93 	}
94 
95 	dest->lowmant = src->lowmant = 0;
96 
97 	if ((diff = dest->exp - src->exp) > 0)
98 		fp_denormalize(src, diff);
99 	else if ((diff = -diff) > 0)
100 		fp_denormalize(dest, diff);
101 
102 	if (dest->sign == src->sign) {
103 		if (fp_addmant(dest, src))
104 			if (!fp_addcarry(dest))
105 				return dest;
106 	} else {
107 		if (dest->mant.m64 < src->mant.m64) {
108 			fp_submant(dest, src, dest);
109 			dest->sign = !dest->sign;
110 		} else
111 			fp_submant(dest, dest, src);
112 	}
113 
114 	return dest;
115 }
116 
117 /* fp_fsub: Implements the kernel of the FSUB, FSSUB, and FDSUB
118    instructions.
119 
120    Remember that the arguments are in assembler-syntax order! */
121 
122 struct fp_ext *
123 fp_fsub(struct fp_ext *dest, struct fp_ext *src)
124 {
125 	dprint(PINSTR, "fsub ");
126 
127 	src->sign = !src->sign;
128 	return fp_fadd(dest, src);
129 }
130 
131 
132 struct fp_ext *
133 fp_fcmp(struct fp_ext *dest, struct fp_ext *src)
134 {
135 	dprint(PINSTR, "fcmp ");
136 
137 	FPDATA->temp[1] = *dest;
138 	src->sign = !src->sign;
139 	return fp_fadd(&FPDATA->temp[1], src);
140 }
141 
142 struct fp_ext *
143 fp_ftst(struct fp_ext *dest, struct fp_ext *src)
144 {
145 	dprint(PINSTR, "ftst\n");
146 
147 	(void)dest;
148 
149 	return src;
150 }
151 
152 struct fp_ext *
153 fp_fmul(struct fp_ext *dest, struct fp_ext *src)
154 {
155 	union fp_mant128 temp;
156 	int exp;
157 
158 	dprint(PINSTR, "fmul\n");
159 
160 	fp_dyadic_check(dest, src);
161 
162 	/* calculate the correct sign now, as it's necessary for infinities */
163 	dest->sign = src->sign ^ dest->sign;
164 
165 	/* Handle infinities */
166 	if (IS_INF(dest)) {
167 		if (IS_ZERO(src))
168 			fp_set_nan(dest);
169 		return dest;
170 	}
171 	if (IS_INF(src)) {
172 		if (IS_ZERO(dest))
173 			fp_set_nan(dest);
174 		else
175 			fp_copy_ext(dest, src);
176 		return dest;
177 	}
178 
179 	/* Of course, as we all know, zero * anything = zero.  You may
180 	   not have known that it might be a positive or negative
181 	   zero... */
182 	if (IS_ZERO(dest) || IS_ZERO(src)) {
183 		dest->exp = 0;
184 		dest->mant.m64 = 0;
185 		dest->lowmant = 0;
186 
187 		return dest;
188 	}
189 
190 	exp = dest->exp + src->exp - 0x3ffe;
191 
192 	/* shift up the mantissa for denormalized numbers,
193 	   so that the highest bit is set, this makes the
194 	   shift of the result below easier */
195 	if ((long)dest->mant.m32[0] >= 0)
196 		exp -= fp_overnormalize(dest);
197 	if ((long)src->mant.m32[0] >= 0)
198 		exp -= fp_overnormalize(src);
199 
200 	/* now, do a 64-bit multiply with expansion */
201 	fp_multiplymant(&temp, dest, src);
202 
203 	/* normalize it back to 64 bits and stuff it back into the
204 	   destination struct */
205 	if ((long)temp.m32[0] > 0) {
206 		exp--;
207 		fp_putmant128(dest, &temp, 1);
208 	} else
209 		fp_putmant128(dest, &temp, 0);
210 
211 	if (exp >= 0x7fff) {
212 		fp_set_ovrflw(dest);
213 		return dest;
214 	}
215 	dest->exp = exp;
216 	if (exp < 0) {
217 		fp_set_sr(FPSR_EXC_UNFL);
218 		fp_denormalize(dest, -exp);
219 	}
220 
221 	return dest;
222 }
223 
224 /* fp_fdiv: Implements the "kernel" of the FDIV, FSDIV, FDDIV and
225    FSGLDIV instructions.
226 
227    Note that the order of the operands is counter-intuitive: instead
228    of src / dest, the result is actually dest / src. */
229 
230 struct fp_ext *
231 fp_fdiv(struct fp_ext *dest, struct fp_ext *src)
232 {
233 	union fp_mant128 temp;
234 	int exp;
235 
236 	dprint(PINSTR, "fdiv\n");
237 
238 	fp_dyadic_check(dest, src);
239 
240 	/* calculate the correct sign now, as it's necessary for infinities */
241 	dest->sign = src->sign ^ dest->sign;
242 
243 	/* Handle infinities */
244 	if (IS_INF(dest)) {
245 		/* infinity / infinity = NaN (quiet, as always) */
246 		if (IS_INF(src))
247 			fp_set_nan(dest);
248 		/* infinity / anything else = infinity (with approprate sign) */
249 		return dest;
250 	}
251 	if (IS_INF(src)) {
252 		/* anything / infinity = zero (with appropriate sign) */
253 		dest->exp = 0;
254 		dest->mant.m64 = 0;
255 		dest->lowmant = 0;
256 
257 		return dest;
258 	}
259 
260 	/* zeroes */
261 	if (IS_ZERO(dest)) {
262 		/* zero / zero = NaN */
263 		if (IS_ZERO(src))
264 			fp_set_nan(dest);
265 		/* zero / anything else = zero */
266 		return dest;
267 	}
268 	if (IS_ZERO(src)) {
269 		/* anything / zero = infinity (with appropriate sign) */
270 		fp_set_sr(FPSR_EXC_DZ);
271 		dest->exp = 0x7fff;
272 		dest->mant.m64 = 0;
273 
274 		return dest;
275 	}
276 
277 	exp = dest->exp - src->exp + 0x3fff;
278 
279 	/* shift up the mantissa for denormalized numbers,
280 	   so that the highest bit is set, this makes lots
281 	   of things below easier */
282 	if ((long)dest->mant.m32[0] >= 0)
283 		exp -= fp_overnormalize(dest);
284 	if ((long)src->mant.m32[0] >= 0)
285 		exp -= fp_overnormalize(src);
286 
287 	/* now, do the 64-bit divide */
288 	fp_dividemant(&temp, dest, src);
289 
290 	/* normalize it back to 64 bits and stuff it back into the
291 	   destination struct */
292 	if (!temp.m32[0]) {
293 		exp--;
294 		fp_putmant128(dest, &temp, 32);
295 	} else
296 		fp_putmant128(dest, &temp, 31);
297 
298 	if (exp >= 0x7fff) {
299 		fp_set_ovrflw(dest);
300 		return dest;
301 	}
302 	dest->exp = exp;
303 	if (exp < 0) {
304 		fp_set_sr(FPSR_EXC_UNFL);
305 		fp_denormalize(dest, -exp);
306 	}
307 
308 	return dest;
309 }
310 
311 struct fp_ext *
312 fp_fsglmul(struct fp_ext *dest, struct fp_ext *src)
313 {
314 	int exp;
315 
316 	dprint(PINSTR, "fsglmul\n");
317 
318 	fp_dyadic_check(dest, src);
319 
320 	/* calculate the correct sign now, as it's necessary for infinities */
321 	dest->sign = src->sign ^ dest->sign;
322 
323 	/* Handle infinities */
324 	if (IS_INF(dest)) {
325 		if (IS_ZERO(src))
326 			fp_set_nan(dest);
327 		return dest;
328 	}
329 	if (IS_INF(src)) {
330 		if (IS_ZERO(dest))
331 			fp_set_nan(dest);
332 		else
333 			fp_copy_ext(dest, src);
334 		return dest;
335 	}
336 
337 	/* Of course, as we all know, zero * anything = zero.  You may
338 	   not have known that it might be a positive or negative
339 	   zero... */
340 	if (IS_ZERO(dest) || IS_ZERO(src)) {
341 		dest->exp = 0;
342 		dest->mant.m64 = 0;
343 		dest->lowmant = 0;
344 
345 		return dest;
346 	}
347 
348 	exp = dest->exp + src->exp - 0x3ffe;
349 
350 	/* do a 32-bit multiply */
351 	fp_mul64(dest->mant.m32[0], dest->mant.m32[1],
352 		 dest->mant.m32[0] & 0xffffff00,
353 		 src->mant.m32[0] & 0xffffff00);
354 
355 	if (exp >= 0x7fff) {
356 		fp_set_ovrflw(dest);
357 		return dest;
358 	}
359 	dest->exp = exp;
360 	if (exp < 0) {
361 		fp_set_sr(FPSR_EXC_UNFL);
362 		fp_denormalize(dest, -exp);
363 	}
364 
365 	return dest;
366 }
367 
368 struct fp_ext *
369 fp_fsgldiv(struct fp_ext *dest, struct fp_ext *src)
370 {
371 	int exp;
372 	unsigned long quot, rem;
373 
374 	dprint(PINSTR, "fsgldiv\n");
375 
376 	fp_dyadic_check(dest, src);
377 
378 	/* calculate the correct sign now, as it's necessary for infinities */
379 	dest->sign = src->sign ^ dest->sign;
380 
381 	/* Handle infinities */
382 	if (IS_INF(dest)) {
383 		/* infinity / infinity = NaN (quiet, as always) */
384 		if (IS_INF(src))
385 			fp_set_nan(dest);
386 		/* infinity / anything else = infinity (with approprate sign) */
387 		return dest;
388 	}
389 	if (IS_INF(src)) {
390 		/* anything / infinity = zero (with appropriate sign) */
391 		dest->exp = 0;
392 		dest->mant.m64 = 0;
393 		dest->lowmant = 0;
394 
395 		return dest;
396 	}
397 
398 	/* zeroes */
399 	if (IS_ZERO(dest)) {
400 		/* zero / zero = NaN */
401 		if (IS_ZERO(src))
402 			fp_set_nan(dest);
403 		/* zero / anything else = zero */
404 		return dest;
405 	}
406 	if (IS_ZERO(src)) {
407 		/* anything / zero = infinity (with appropriate sign) */
408 		fp_set_sr(FPSR_EXC_DZ);
409 		dest->exp = 0x7fff;
410 		dest->mant.m64 = 0;
411 
412 		return dest;
413 	}
414 
415 	exp = dest->exp - src->exp + 0x3fff;
416 
417 	dest->mant.m32[0] &= 0xffffff00;
418 	src->mant.m32[0] &= 0xffffff00;
419 
420 	/* do the 32-bit divide */
421 	if (dest->mant.m32[0] >= src->mant.m32[0]) {
422 		fp_sub64(dest->mant, src->mant);
423 		fp_div64(quot, rem, dest->mant.m32[0], 0, src->mant.m32[0]);
424 		dest->mant.m32[0] = 0x80000000 | (quot >> 1);
425 		dest->mant.m32[1] = (quot & 1) | rem;	/* only for rounding */
426 	} else {
427 		fp_div64(quot, rem, dest->mant.m32[0], 0, src->mant.m32[0]);
428 		dest->mant.m32[0] = quot;
429 		dest->mant.m32[1] = rem;		/* only for rounding */
430 		exp--;
431 	}
432 
433 	if (exp >= 0x7fff) {
434 		fp_set_ovrflw(dest);
435 		return dest;
436 	}
437 	dest->exp = exp;
438 	if (exp < 0) {
439 		fp_set_sr(FPSR_EXC_UNFL);
440 		fp_denormalize(dest, -exp);
441 	}
442 
443 	return dest;
444 }
445 
446 /* fp_roundint: Internal rounding function for use by several of these
447    emulated instructions.
448 
449    This one rounds off the fractional part using the rounding mode
450    specified. */
451 
452 static void fp_roundint(struct fp_ext *dest, int mode)
453 {
454 	union fp_mant64 oldmant;
455 	unsigned long mask;
456 
457 	if (!fp_normalize_ext(dest))
458 		return;
459 
460 	/* infinities and zeroes */
461 	if (IS_INF(dest) || IS_ZERO(dest))
462 		return;
463 
464 	/* first truncate the lower bits */
465 	oldmant = dest->mant;
466 	switch (dest->exp) {
467 	case 0 ... 0x3ffe:
468 		dest->mant.m64 = 0;
469 		break;
470 	case 0x3fff ... 0x401e:
471 		dest->mant.m32[0] &= 0xffffffffU << (0x401e - dest->exp);
472 		dest->mant.m32[1] = 0;
473 		if (oldmant.m64 == dest->mant.m64)
474 			return;
475 		break;
476 	case 0x401f ... 0x403e:
477 		dest->mant.m32[1] &= 0xffffffffU << (0x403e - dest->exp);
478 		if (oldmant.m32[1] == dest->mant.m32[1])
479 			return;
480 		break;
481 	default:
482 		return;
483 	}
484 	fp_set_sr(FPSR_EXC_INEX2);
485 
486 	/* We might want to normalize upwards here... however, since
487 	   we know that this is only called on the output of fp_fdiv,
488 	   or with the input to fp_fint or fp_fintrz, and the inputs
489 	   to all these functions are either normal or denormalized
490 	   (no subnormals allowed!), there's really no need.
491 
492 	   In the case of fp_fdiv, observe that 0x80000000 / 0xffff =
493 	   0xffff8000, and the same holds for 128-bit / 64-bit. (i.e. the
494 	   smallest possible normal dividend and the largest possible normal
495 	   divisor will still produce a normal quotient, therefore, (normal
496 	   << 64) / normal is normal in all cases) */
497 
498 	switch (mode) {
499 	case FPCR_ROUND_RN:
500 		switch (dest->exp) {
501 		case 0 ... 0x3ffd:
502 			return;
503 		case 0x3ffe:
504 			/* As noted above, the input is always normal, so the
505 			   guard bit (bit 63) is always set.  therefore, the
506 			   only case in which we will NOT round to 1.0 is when
507 			   the input is exactly 0.5. */
508 			if (oldmant.m64 == (1ULL << 63))
509 				return;
510 			break;
511 		case 0x3fff ... 0x401d:
512 			mask = 1 << (0x401d - dest->exp);
513 			if (!(oldmant.m32[0] & mask))
514 				return;
515 			if (oldmant.m32[0] & (mask << 1))
516 				break;
517 			if (!(oldmant.m32[0] << (dest->exp - 0x3ffd)) &&
518 					!oldmant.m32[1])
519 				return;
520 			break;
521 		case 0x401e:
522 			if (oldmant.m32[1] & 0x80000000)
523 				return;
524 			if (oldmant.m32[0] & 1)
525 				break;
526 			if (!(oldmant.m32[1] << 1))
527 				return;
528 			break;
529 		case 0x401f ... 0x403d:
530 			mask = 1 << (0x403d - dest->exp);
531 			if (!(oldmant.m32[1] & mask))
532 				return;
533 			if (oldmant.m32[1] & (mask << 1))
534 				break;
535 			if (!(oldmant.m32[1] << (dest->exp - 0x401d)))
536 				return;
537 			break;
538 		default:
539 			return;
540 		}
541 		break;
542 	case FPCR_ROUND_RZ:
543 		return;
544 	default:
545 		if (dest->sign ^ (mode - FPCR_ROUND_RM))
546 			break;
547 		return;
548 	}
549 
550 	switch (dest->exp) {
551 	case 0 ... 0x3ffe:
552 		dest->exp = 0x3fff;
553 		dest->mant.m64 = 1ULL << 63;
554 		break;
555 	case 0x3fff ... 0x401e:
556 		mask = 1 << (0x401e - dest->exp);
557 		if (dest->mant.m32[0] += mask)
558 			break;
559 		dest->mant.m32[0] = 0x80000000;
560 		dest->exp++;
561 		break;
562 	case 0x401f ... 0x403e:
563 		mask = 1 << (0x403e - dest->exp);
564 		if (dest->mant.m32[1] += mask)
565 			break;
566 		if (dest->mant.m32[0] += 1)
567                         break;
568 		dest->mant.m32[0] = 0x80000000;
569                 dest->exp++;
570 		break;
571 	}
572 }
573 
574 /* modrem_kernel: Implementation of the FREM and FMOD instructions
575    (which are exactly the same, except for the rounding used on the
576    intermediate value) */
577 
578 static struct fp_ext *
579 modrem_kernel(struct fp_ext *dest, struct fp_ext *src, int mode)
580 {
581 	struct fp_ext tmp;
582 
583 	fp_dyadic_check(dest, src);
584 
585 	/* Infinities and zeros */
586 	if (IS_INF(dest) || IS_ZERO(src)) {
587 		fp_set_nan(dest);
588 		return dest;
589 	}
590 	if (IS_ZERO(dest) || IS_INF(src))
591 		return dest;
592 
593 	/* FIXME: there is almost certainly a smarter way to do this */
594 	fp_copy_ext(&tmp, dest);
595 	fp_fdiv(&tmp, src);		/* NOTE: src might be modified */
596 	fp_roundint(&tmp, mode);
597 	fp_fmul(&tmp, src);
598 	fp_fsub(dest, &tmp);
599 
600 	/* set the quotient byte */
601 	fp_set_quotient((dest->mant.m64 & 0x7f) | (dest->sign << 7));
602 	return dest;
603 }
604 
605 /* fp_fmod: Implements the kernel of the FMOD instruction.
606 
607    Again, the argument order is backwards.  The result, as defined in
608    the Motorola manuals, is:
609 
610    fmod(src,dest) = (dest - (src * floor(dest / src))) */
611 
612 struct fp_ext *
613 fp_fmod(struct fp_ext *dest, struct fp_ext *src)
614 {
615 	dprint(PINSTR, "fmod\n");
616 	return modrem_kernel(dest, src, FPCR_ROUND_RZ);
617 }
618 
619 /* fp_frem: Implements the kernel of the FREM instruction.
620 
621    frem(src,dest) = (dest - (src * round(dest / src)))
622  */
623 
624 struct fp_ext *
625 fp_frem(struct fp_ext *dest, struct fp_ext *src)
626 {
627 	dprint(PINSTR, "frem\n");
628 	return modrem_kernel(dest, src, FPCR_ROUND_RN);
629 }
630 
631 struct fp_ext *
632 fp_fint(struct fp_ext *dest, struct fp_ext *src)
633 {
634 	dprint(PINSTR, "fint\n");
635 
636 	fp_copy_ext(dest, src);
637 
638 	fp_roundint(dest, FPDATA->rnd);
639 
640 	return dest;
641 }
642 
643 struct fp_ext *
644 fp_fintrz(struct fp_ext *dest, struct fp_ext *src)
645 {
646 	dprint(PINSTR, "fintrz\n");
647 
648 	fp_copy_ext(dest, src);
649 
650 	fp_roundint(dest, FPCR_ROUND_RZ);
651 
652 	return dest;
653 }
654 
655 struct fp_ext *
656 fp_fscale(struct fp_ext *dest, struct fp_ext *src)
657 {
658 	int scale, oldround;
659 
660 	dprint(PINSTR, "fscale\n");
661 
662 	fp_dyadic_check(dest, src);
663 
664 	/* Infinities */
665 	if (IS_INF(src)) {
666 		fp_set_nan(dest);
667 		return dest;
668 	}
669 	if (IS_INF(dest))
670 		return dest;
671 
672 	/* zeroes */
673 	if (IS_ZERO(src) || IS_ZERO(dest))
674 		return dest;
675 
676 	/* Source exponent out of range */
677 	if (src->exp >= 0x400c) {
678 		fp_set_ovrflw(dest);
679 		return dest;
680 	}
681 
682 	/* src must be rounded with round to zero. */
683 	oldround = FPDATA->rnd;
684 	FPDATA->rnd = FPCR_ROUND_RZ;
685 	scale = fp_conv_ext2long(src);
686 	FPDATA->rnd = oldround;
687 
688 	/* new exponent */
689 	scale += dest->exp;
690 
691 	if (scale >= 0x7fff) {
692 		fp_set_ovrflw(dest);
693 	} else if (scale <= 0) {
694 		fp_set_sr(FPSR_EXC_UNFL);
695 		fp_denormalize(dest, -scale);
696 	} else
697 		dest->exp = scale;
698 
699 	return dest;
700 }
701 
702