freebsd-nq/lib/libc/sparc64/fpu/fpu_implode.c
Warner Losh fbbd9655e5 Renumber copyright clause 4
Renumber cluase 4 to 3, per what everybody else did when BSD granted
them permission to remove clause 3. My insistance on keeping the same
numbering for legal reasons is too pedantic, so give up on that point.

Submitted by:	Jan Schaumann <jschauma@stevens.edu>
Pull Request:	https://github.com/freebsd/freebsd/pull/96
2017-02-28 23:42:47 +00:00

543 lines
14 KiB
C

/*
* Copyright (c) 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* This software was developed by the Computer Systems Engineering group
* at Lawrence Berkeley Laboratory under DARPA contract BG 91-66 and
* contributed to Berkeley.
*
* All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Lawrence Berkeley Laboratory.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* @(#)fpu_implode.c 8.1 (Berkeley) 6/11/93
* $NetBSD: fpu_implode.c,v 1.8 2001/08/26 05:44:46 eeh Exp $
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* FPU subroutines: `implode' internal format numbers into the machine's
* `packed binary' format.
*/
#include <sys/param.h>
#ifdef FPU_DEBUG
#include <stdio.h>
#endif
#include <machine/frame.h>
#include <machine/fp.h>
#include <machine/fsr.h>
#include <machine/ieee.h>
#include <machine/instr.h>
#include "fpu_arith.h"
#include "fpu_emu.h"
#include "fpu_extern.h"
#include "__sparc_utrap_private.h"
static int fpround(struct fpemu *, struct fpn *);
static int toinf(struct fpemu *, int);
/*
* Round a number (algorithm from Motorola MC68882 manual, modified for
* our internal format). Set inexact exception if rounding is required.
* Return true iff we rounded up.
*
* After rounding, we discard the guard and round bits by shifting right
* 2 bits (a la fpu_shr(), but we do not bother with fp->fp_sticky).
* This saves effort later.
*
* Note that we may leave the value 2.0 in fp->fp_mant; it is the caller's
* responsibility to fix this if necessary.
*/
static int
fpround(struct fpemu *fe, struct fpn *fp)
{
u_int m0, m1, m2, m3;
int gr, s;
m0 = fp->fp_mant[0];
m1 = fp->fp_mant[1];
m2 = fp->fp_mant[2];
m3 = fp->fp_mant[3];
gr = m3 & 3;
s = fp->fp_sticky;
/* mant >>= FP_NG */
m3 = (m3 >> FP_NG) | (m2 << (32 - FP_NG));
m2 = (m2 >> FP_NG) | (m1 << (32 - FP_NG));
m1 = (m1 >> FP_NG) | (m0 << (32 - FP_NG));
m0 >>= FP_NG;
if ((gr | s) == 0) /* result is exact: no rounding needed */
goto rounddown;
fe->fe_cx |= FSR_NX; /* inexact */
/* Go to rounddown to round down; break to round up. */
switch (FSR_GET_RD(fe->fe_fsr)) {
case FSR_RD_N:
default:
/*
* Round only if guard is set (gr & 2). If guard is set,
* but round & sticky both clear, then we want to round
* but have a tie, so round to even, i.e., add 1 iff odd.
*/
if ((gr & 2) == 0)
goto rounddown;
if ((gr & 1) || fp->fp_sticky || (m3 & 1))
break;
goto rounddown;
case FSR_RD_Z:
/* Round towards zero, i.e., down. */
goto rounddown;
case FSR_RD_NINF:
/* Round towards -Inf: up if negative, down if positive. */
if (fp->fp_sign)
break;
goto rounddown;
case FSR_RD_PINF:
/* Round towards +Inf: up if positive, down otherwise. */
if (!fp->fp_sign)
break;
goto rounddown;
}
/* Bump low bit of mantissa, with carry. */
FPU_ADDS(m3, m3, 1);
FPU_ADDCS(m2, m2, 0);
FPU_ADDCS(m1, m1, 0);
FPU_ADDC(m0, m0, 0);
fp->fp_mant[0] = m0;
fp->fp_mant[1] = m1;
fp->fp_mant[2] = m2;
fp->fp_mant[3] = m3;
return (1);
rounddown:
fp->fp_mant[0] = m0;
fp->fp_mant[1] = m1;
fp->fp_mant[2] = m2;
fp->fp_mant[3] = m3;
return (0);
}
/*
* For overflow: return true if overflow is to go to +/-Inf, according
* to the sign of the overflowing result. If false, overflow is to go
* to the largest magnitude value instead.
*/
static int
toinf(struct fpemu *fe, int sign)
{
int inf;
/* look at rounding direction */
switch (FSR_GET_RD(fe->fe_fsr)) {
default:
case FSR_RD_N: /* the nearest value is always Inf */
inf = 1;
break;
case FSR_RD_Z: /* toward 0 => never towards Inf */
inf = 0;
break;
case FSR_RD_PINF: /* toward +Inf iff positive */
inf = sign == 0;
break;
case FSR_RD_NINF: /* toward -Inf iff negative */
inf = sign;
break;
}
return (inf);
}
/*
* fpn -> int (int value returned as return value).
*
* N.B.: this conversion always rounds towards zero (this is a peculiarity
* of the SPARC instruction set).
*/
u_int
__fpu_ftoi(fe, fp)
struct fpemu *fe;
struct fpn *fp;
{
u_int i;
int sign, exp;
sign = fp->fp_sign;
switch (fp->fp_class) {
case FPC_ZERO:
return (0);
case FPC_NUM:
/*
* If exp >= 2^32, overflow. Otherwise shift value right
* into last mantissa word (this will not exceed 0xffffffff),
* shifting any guard and round bits out into the sticky
* bit. Then ``round'' towards zero, i.e., just set an
* inexact exception if sticky is set (see round()).
* If the result is > 0x80000000, or is positive and equals
* 0x80000000, overflow; otherwise the last fraction word
* is the result.
*/
if ((exp = fp->fp_exp) >= 32)
break;
/* NB: the following includes exp < 0 cases */
if (__fpu_shr(fp, FP_NMANT - 1 - exp) != 0)
fe->fe_cx |= FSR_NX;
i = fp->fp_mant[3];
if (i >= ((u_int)0x80000000 + sign))
break;
return (sign ? -i : i);
default: /* Inf, qNaN, sNaN */
break;
}
/* overflow: replace any inexact exception with invalid */
fe->fe_cx = (fe->fe_cx & ~FSR_NX) | FSR_NV;
return (0x7fffffff + sign);
}
/*
* fpn -> extended int (high bits of int value returned as return value).
*
* N.B.: this conversion always rounds towards zero (this is a peculiarity
* of the SPARC instruction set).
*/
u_int
__fpu_ftox(fe, fp, res)
struct fpemu *fe;
struct fpn *fp;
u_int *res;
{
u_int64_t i;
int sign, exp;
sign = fp->fp_sign;
switch (fp->fp_class) {
case FPC_ZERO:
i = 0;
goto done;
case FPC_NUM:
/*
* If exp >= 2^64, overflow. Otherwise shift value
* right into last mantissa word (this will not exceed
* 0xffffffffffffffff), shifting any guard and round
* bits out into the sticky bit. Then ``round'' towards
* zero, i.e., just set an inexact exception if sticky
* is set (see round()).
* If the result is > 0x8000000000000000, or is positive
* and equals 0x8000000000000000, overflow; otherwise
* the last fraction word is the result.
*/
if ((exp = fp->fp_exp) >= 64)
break;
/* NB: the following includes exp < 0 cases */
if (__fpu_shr(fp, FP_NMANT - 1 - exp) != 0)
fe->fe_cx |= FSR_NX;
i = ((u_int64_t)fp->fp_mant[2]<<32)|fp->fp_mant[3];
if (i >= ((u_int64_t)0x8000000000000000LL + sign))
break;
if (sign)
i = -i;
goto done;
default: /* Inf, qNaN, sNaN */
break;
}
/* overflow: replace any inexact exception with invalid */
fe->fe_cx = (fe->fe_cx & ~FSR_NX) | FSR_NV;
i = 0x7fffffffffffffffLL + sign;
done:
res[1] = i & 0xffffffff;
return (i >> 32);
}
/*
* fpn -> single (32 bit single returned as return value).
* We assume <= 29 bits in a single-precision fraction (1.f part).
*/
u_int
__fpu_ftos(fe, fp)
struct fpemu *fe;
struct fpn *fp;
{
u_int sign = fp->fp_sign << 31;
int exp;
#define SNG_EXP(e) ((e) << SNG_FRACBITS) /* makes e an exponent */
#define SNG_MASK (SNG_EXP(1) - 1) /* mask for fraction */
/* Take care of non-numbers first. */
if (ISNAN(fp)) {
/*
* Preserve upper bits of NaN, per SPARC V8 appendix N.
* Note that fp->fp_mant[0] has the quiet bit set,
* even if it is classified as a signalling NaN.
*/
(void) __fpu_shr(fp, FP_NMANT - 1 - SNG_FRACBITS);
exp = SNG_EXP_INFNAN;
goto done;
}
if (ISINF(fp))
return (sign | SNG_EXP(SNG_EXP_INFNAN));
if (ISZERO(fp))
return (sign);
/*
* Normals (including subnormals). Drop all the fraction bits
* (including the explicit ``implied'' 1 bit) down into the
* single-precision range. If the number is subnormal, move
* the ``implied'' 1 into the explicit range as well, and shift
* right to introduce leading zeroes. Rounding then acts
* differently for normals and subnormals: the largest subnormal
* may round to the smallest normal (1.0 x 2^minexp), or may
* remain subnormal. A number that is subnormal before rounding
* will signal an underflow if the result is inexact or if underflow
* traps are enabled.
*
* Rounding a normal, on the other hand, always produces another
* normal (although either way the result might be too big for
* single precision, and cause an overflow). If rounding a
* normal produces 2.0 in the fraction, we need not adjust that
* fraction at all, since both 1.0 and 2.0 are zero under the
* fraction mask.
*
* Note that the guard and round bits vanish from the number after
* rounding.
*/
if ((exp = fp->fp_exp + SNG_EXP_BIAS) <= 0) { /* subnormal */
/* -NG for g,r; -SNG_FRACBITS-exp for fraction */
(void) __fpu_shr(fp, FP_NMANT - FP_NG - SNG_FRACBITS - exp);
if (fpround(fe, fp) && fp->fp_mant[3] == SNG_EXP(1)) {
fe->fe_cx |= FSR_UF;
return (sign | SNG_EXP(1) | 0);
}
if ((fe->fe_cx & FSR_NX) ||
(fe->fe_fsr & (FSR_UF << FSR_TEM_SHIFT)))
fe->fe_cx |= FSR_UF;
return (sign | SNG_EXP(0) | fp->fp_mant[3]);
}
/* -FP_NG for g,r; -1 for implied 1; -SNG_FRACBITS for fraction */
(void) __fpu_shr(fp, FP_NMANT - FP_NG - 1 - SNG_FRACBITS);
#ifdef DIAGNOSTIC
if ((fp->fp_mant[3] & SNG_EXP(1 << FP_NG)) == 0)
__utrap_panic("fpu_ftos");
#endif
if (fpround(fe, fp) && fp->fp_mant[3] == SNG_EXP(2))
exp++;
if (exp >= SNG_EXP_INFNAN) {
/* overflow to inf or to max single */
fe->fe_cx |= FSR_OF | FSR_NX;
if (toinf(fe, sign))
return (sign | SNG_EXP(SNG_EXP_INFNAN));
return (sign | SNG_EXP(SNG_EXP_INFNAN - 1) | SNG_MASK);
}
done:
/* phew, made it */
return (sign | SNG_EXP(exp) | (fp->fp_mant[3] & SNG_MASK));
}
/*
* fpn -> double (32 bit high-order result returned; 32-bit low order result
* left in res[1]). Assumes <= 61 bits in double precision fraction.
*
* This code mimics fpu_ftos; see it for comments.
*/
u_int
__fpu_ftod(fe, fp, res)
struct fpemu *fe;
struct fpn *fp;
u_int *res;
{
u_int sign = fp->fp_sign << 31;
int exp;
#define DBL_EXP(e) ((e) << (DBL_FRACBITS & 31))
#define DBL_MASK (DBL_EXP(1) - 1)
if (ISNAN(fp)) {
(void) __fpu_shr(fp, FP_NMANT - 1 - DBL_FRACBITS);
exp = DBL_EXP_INFNAN;
goto done;
}
if (ISINF(fp)) {
sign |= DBL_EXP(DBL_EXP_INFNAN);
goto zero;
}
if (ISZERO(fp)) {
zero: res[1] = 0;
return (sign);
}
if ((exp = fp->fp_exp + DBL_EXP_BIAS) <= 0) {
(void) __fpu_shr(fp, FP_NMANT - FP_NG - DBL_FRACBITS - exp);
if (fpround(fe, fp) && fp->fp_mant[2] == DBL_EXP(1)) {
fe->fe_cx |= FSR_UF;
res[1] = 0;
return (sign | DBL_EXP(1) | 0);
}
if ((fe->fe_cx & FSR_NX) ||
(fe->fe_fsr & (FSR_UF << FSR_TEM_SHIFT)))
fe->fe_cx |= FSR_UF;
exp = 0;
goto done;
}
(void) __fpu_shr(fp, FP_NMANT - FP_NG - 1 - DBL_FRACBITS);
if (fpround(fe, fp) && fp->fp_mant[2] == DBL_EXP(2))
exp++;
if (exp >= DBL_EXP_INFNAN) {
fe->fe_cx |= FSR_OF | FSR_NX;
if (toinf(fe, sign)) {
res[1] = 0;
return (sign | DBL_EXP(DBL_EXP_INFNAN) | 0);
}
res[1] = ~0;
return (sign | DBL_EXP(DBL_EXP_INFNAN - 1) | DBL_MASK);
}
done:
res[1] = fp->fp_mant[3];
return (sign | DBL_EXP(exp) | (fp->fp_mant[2] & DBL_MASK));
}
/*
* fpn -> extended (32 bit high-order result returned; low-order fraction
* words left in res[1]..res[3]). Like ftod, which is like ftos ... but
* our internal format *is* extended precision, plus 2 bits for guard/round,
* so we can avoid a small bit of work.
*/
u_int
__fpu_ftoq(fe, fp, res)
struct fpemu *fe;
struct fpn *fp;
u_int *res;
{
u_int sign = fp->fp_sign << 31;
int exp;
#define EXT_EXP(e) ((e) << (EXT_FRACBITS & 31))
#define EXT_MASK (EXT_EXP(1) - 1)
if (ISNAN(fp)) {
(void) __fpu_shr(fp, 2); /* since we are not rounding */
exp = EXT_EXP_INFNAN;
goto done;
}
if (ISINF(fp)) {
sign |= EXT_EXP(EXT_EXP_INFNAN);
goto zero;
}
if (ISZERO(fp)) {
zero: res[1] = res[2] = res[3] = 0;
return (sign);
}
if ((exp = fp->fp_exp + EXT_EXP_BIAS) <= 0) {
(void) __fpu_shr(fp, FP_NMANT - FP_NG - EXT_FRACBITS - exp);
if (fpround(fe, fp) && fp->fp_mant[0] == EXT_EXP(1)) {
fe->fe_cx |= FSR_UF;
res[1] = res[2] = res[3] = 0;
return (sign | EXT_EXP(1) | 0);
}
if ((fe->fe_cx & FSR_NX) ||
(fe->fe_fsr & (FSR_UF << FSR_TEM_SHIFT)))
fe->fe_cx |= FSR_UF;
exp = 0;
goto done;
}
/* Since internal == extended, no need to shift here. */
if (fpround(fe, fp) && fp->fp_mant[0] == EXT_EXP(2))
exp++;
if (exp >= EXT_EXP_INFNAN) {
fe->fe_cx |= FSR_OF | FSR_NX;
if (toinf(fe, sign)) {
res[1] = res[2] = res[3] = 0;
return (sign | EXT_EXP(EXT_EXP_INFNAN) | 0);
}
res[1] = res[2] = res[3] = ~0;
return (sign | EXT_EXP(EXT_EXP_INFNAN - 1) | EXT_MASK);
}
done:
res[1] = fp->fp_mant[1];
res[2] = fp->fp_mant[2];
res[3] = fp->fp_mant[3];
return (sign | EXT_EXP(exp) | (fp->fp_mant[0] & EXT_MASK));
}
/*
* Implode an fpn, writing the result into the given space.
*/
void
__fpu_implode(fe, fp, type, space)
struct fpemu *fe;
struct fpn *fp;
int type;
u_int *space;
{
switch (type) {
case FTYPE_LNG:
space[0] = __fpu_ftox(fe, fp, space);
break;
case FTYPE_INT:
space[0] = __fpu_ftoi(fe, fp);
break;
case FTYPE_SNG:
space[0] = __fpu_ftos(fe, fp);
break;
case FTYPE_DBL:
space[0] = __fpu_ftod(fe, fp, space);
break;
case FTYPE_EXT:
/* funky rounding precision options ?? */
space[0] = __fpu_ftoq(fe, fp, space);
break;
default:
__utrap_panic("fpu_implode");
}
DPRINTF(FPE_REG, ("fpu_implode: %x %x %x %x\n",
space[0], space[1], space[2], space[3]));
}