kernel-aes67/arch/parisc/math-emu/fcnvff.c
Linus Torvalds 1da177e4c3 Linux-2.6.12-rc2
Initial git repository build. I'm not bothering with the full history,
even though we have it. We can create a separate "historical" git
archive of that later if we want to, and in the meantime it's about
3.2GB when imported into git - space that would just make the early
git days unnecessarily complicated, when we don't have a lot of good
infrastructure for it.

Let it rip!
2005-04-16 15:20:36 -07:00

310 lines
9.2 KiB
C

/*
* Linux/PA-RISC Project (http://www.parisc-linux.org/)
*
* Floating-point emulation code
* Copyright (C) 2001 Hewlett-Packard (Paul Bame) <bame@debian.org>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
/*
* BEGIN_DESC
*
* File:
* @(#) pa/spmath/fcnvff.c $Revision: 1.1 $
*
* Purpose:
* Single Floating-point to Double Floating-point
* Double Floating-point to Single Floating-point
*
* External Interfaces:
* dbl_to_sgl_fcnvff(srcptr,nullptr,dstptr,status)
* sgl_to_dbl_fcnvff(srcptr,nullptr,dstptr,status)
*
* Internal Interfaces:
*
* Theory:
* <<please update with a overview of the operation of this file>>
*
* END_DESC
*/
#include "float.h"
#include "sgl_float.h"
#include "dbl_float.h"
#include "cnv_float.h"
/*
* Single Floating-point to Double Floating-point
*/
/*ARGSUSED*/
int
sgl_to_dbl_fcnvff(
sgl_floating_point *srcptr,
unsigned int *nullptr,
dbl_floating_point *dstptr,
unsigned int *status)
{
register unsigned int src, resultp1, resultp2;
register int src_exponent;
src = *srcptr;
src_exponent = Sgl_exponent(src);
Dbl_allp1(resultp1) = Sgl_all(src); /* set sign of result */
/*
* Test for NaN or infinity
*/
if (src_exponent == SGL_INFINITY_EXPONENT) {
/*
* determine if NaN or infinity
*/
if (Sgl_iszero_mantissa(src)) {
/*
* is infinity; want to return double infinity
*/
Dbl_setinfinity_exponentmantissa(resultp1,resultp2);
Dbl_copytoptr(resultp1,resultp2,dstptr);
return(NOEXCEPTION);
}
else {
/*
* is NaN; signaling or quiet?
*/
if (Sgl_isone_signaling(src)) {
/* trap if INVALIDTRAP enabled */
if (Is_invalidtrap_enabled())
return(INVALIDEXCEPTION);
/* make NaN quiet */
else {
Set_invalidflag();
Sgl_set_quiet(src);
}
}
/*
* NaN is quiet, return as double NaN
*/
Dbl_setinfinity_exponent(resultp1);
Sgl_to_dbl_mantissa(src,resultp1,resultp2);
Dbl_copytoptr(resultp1,resultp2,dstptr);
return(NOEXCEPTION);
}
}
/*
* Test for zero or denormalized
*/
if (src_exponent == 0) {
/*
* determine if zero or denormalized
*/
if (Sgl_isnotzero_mantissa(src)) {
/*
* is denormalized; want to normalize
*/
Sgl_clear_signexponent(src);
Sgl_leftshiftby1(src);
Sgl_normalize(src,src_exponent);
Sgl_to_dbl_exponent(src_exponent,resultp1);
Sgl_to_dbl_mantissa(src,resultp1,resultp2);
}
else {
Dbl_setzero_exponentmantissa(resultp1,resultp2);
}
Dbl_copytoptr(resultp1,resultp2,dstptr);
return(NOEXCEPTION);
}
/*
* No special cases, just complete the conversion
*/
Sgl_to_dbl_exponent(src_exponent, resultp1);
Sgl_to_dbl_mantissa(Sgl_mantissa(src), resultp1,resultp2);
Dbl_copytoptr(resultp1,resultp2,dstptr);
return(NOEXCEPTION);
}
/*
* Double Floating-point to Single Floating-point
*/
/*ARGSUSED*/
int
dbl_to_sgl_fcnvff(
dbl_floating_point *srcptr,
unsigned int *nullptr,
sgl_floating_point *dstptr,
unsigned int *status)
{
register unsigned int srcp1, srcp2, result;
register int src_exponent, dest_exponent, dest_mantissa;
register boolean inexact = FALSE, guardbit = FALSE, stickybit = FALSE;
register boolean lsb_odd = FALSE;
boolean is_tiny;
Dbl_copyfromptr(srcptr,srcp1,srcp2);
src_exponent = Dbl_exponent(srcp1);
Sgl_all(result) = Dbl_allp1(srcp1); /* set sign of result */
/*
* Test for NaN or infinity
*/
if (src_exponent == DBL_INFINITY_EXPONENT) {
/*
* determine if NaN or infinity
*/
if (Dbl_iszero_mantissa(srcp1,srcp2)) {
/*
* is infinity; want to return single infinity
*/
Sgl_setinfinity_exponentmantissa(result);
*dstptr = result;
return(NOEXCEPTION);
}
/*
* is NaN; signaling or quiet?
*/
if (Dbl_isone_signaling(srcp1)) {
/* trap if INVALIDTRAP enabled */
if (Is_invalidtrap_enabled()) return(INVALIDEXCEPTION);
else {
Set_invalidflag();
/* make NaN quiet */
Dbl_set_quiet(srcp1);
}
}
/*
* NaN is quiet, return as single NaN
*/
Sgl_setinfinity_exponent(result);
Sgl_set_mantissa(result,Dallp1(srcp1)<<3 | Dallp2(srcp2)>>29);
if (Sgl_iszero_mantissa(result)) Sgl_set_quiet(result);
*dstptr = result;
return(NOEXCEPTION);
}
/*
* Generate result
*/
Dbl_to_sgl_exponent(src_exponent,dest_exponent);
if (dest_exponent > 0) {
Dbl_to_sgl_mantissa(srcp1,srcp2,dest_mantissa,inexact,guardbit,
stickybit,lsb_odd);
}
else {
if (Dbl_iszero_exponentmantissa(srcp1,srcp2)){
Sgl_setzero_exponentmantissa(result);
*dstptr = result;
return(NOEXCEPTION);
}
if (Is_underflowtrap_enabled()) {
Dbl_to_sgl_mantissa(srcp1,srcp2,dest_mantissa,inexact,
guardbit,stickybit,lsb_odd);
}
else {
/* compute result, determine inexact info,
* and set Underflowflag if appropriate
*/
Dbl_to_sgl_denormalized(srcp1,srcp2,dest_exponent,
dest_mantissa,inexact,guardbit,stickybit,lsb_odd,
is_tiny);
}
}
/*
* Now round result if not exact
*/
if (inexact) {
switch (Rounding_mode()) {
case ROUNDPLUS:
if (Sgl_iszero_sign(result)) dest_mantissa++;
break;
case ROUNDMINUS:
if (Sgl_isone_sign(result)) dest_mantissa++;
break;
case ROUNDNEAREST:
if (guardbit) {
if (stickybit || lsb_odd) dest_mantissa++;
}
}
}
Sgl_set_exponentmantissa(result,dest_mantissa);
/*
* check for mantissa overflow after rounding
*/
if ((dest_exponent>0 || Is_underflowtrap_enabled()) &&
Sgl_isone_hidden(result)) dest_exponent++;
/*
* Test for overflow
*/
if (dest_exponent >= SGL_INFINITY_EXPONENT) {
/* trap if OVERFLOWTRAP enabled */
if (Is_overflowtrap_enabled()) {
/*
* Check for gross overflow
*/
if (dest_exponent >= SGL_INFINITY_EXPONENT+SGL_WRAP)
return(UNIMPLEMENTEDEXCEPTION);
/*
* Adjust bias of result
*/
Sgl_setwrapped_exponent(result,dest_exponent,ovfl);
*dstptr = result;
if (inexact)
if (Is_inexacttrap_enabled())
return(OVERFLOWEXCEPTION|INEXACTEXCEPTION);
else Set_inexactflag();
return(OVERFLOWEXCEPTION);
}
Set_overflowflag();
inexact = TRUE;
/* set result to infinity or largest number */
Sgl_setoverflow(result);
}
/*
* Test for underflow
*/
else if (dest_exponent <= 0) {
/* trap if UNDERFLOWTRAP enabled */
if (Is_underflowtrap_enabled()) {
/*
* Check for gross underflow
*/
if (dest_exponent <= -(SGL_WRAP))
return(UNIMPLEMENTEDEXCEPTION);
/*
* Adjust bias of result
*/
Sgl_setwrapped_exponent(result,dest_exponent,unfl);
*dstptr = result;
if (inexact)
if (Is_inexacttrap_enabled())
return(UNDERFLOWEXCEPTION|INEXACTEXCEPTION);
else Set_inexactflag();
return(UNDERFLOWEXCEPTION);
}
/*
* result is denormalized or signed zero
*/
if (inexact && is_tiny) Set_underflowflag();
}
else Sgl_set_exponent(result,dest_exponent);
*dstptr = result;
/*
* Trap if inexact trap is enabled
*/
if (inexact)
if (Is_inexacttrap_enabled()) return(INEXACTEXCEPTION);
else Set_inexactflag();
return(NOEXCEPTION);
}