/*============================================================================
This C source file is part of the SoftPosit Posit Arithmetic Package
by S. H. Leong (Cerlane).
Copyright 2017, 2018 A*STAR. All rights reserved.
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.
=============================================================================*/
#include <math.h>
#ifdef SOFTPOSIT_QUAD
#include <quadmath.h>
#endif
#include "platform.h"
#include "internals.h"
#ifdef SOFTPOSIT_QUAD
void checkQuadExtraP32TwoBits(__float128 f32, __float128 temp, bool * bitsNPlusOne, bool * bitsMore ){
temp /= 2;
if (temp<=f32){
*bitsNPlusOne = 1;
f32-=temp;
}
if (f32>0)
*bitsMore = 1;
}
uint_fast32_t convertQuadFractionP32(__float128 f32, uint_fast16_t fracLength, bool * bitNPlusOne, bool * bitsMore ){
uint_fast32_t frac=0;
if(f32==0) return 0;
else if(f32==INFINITY) return 0x80000000;
f32 -= 1; //remove hidden bit
if (fracLength==0)
checkQuadExtraP32TwoBits(f32, 1.0, bitNPlusOne, bitsMore);
else{
__float128 temp = 1;
while (true){
temp /= 2;
if (temp<=f32){
f32-=temp;
fracLength--;
frac = (frac<<1) + 1; //shift in one
if (f32==0){
frac <<= (uint_fast32_t)fracLength;
break;
}
if (fracLength == 0){
checkQuadExtraP32TwoBits(f32, temp, bitNPlusOne, bitsMore);
break;
}
}
else{
frac <<= 1; //shift in a zero
fracLength--;
if (fracLength == 0){
checkQuadExtraP32TwoBits(f32, temp, bitNPlusOne, bitsMore);
break;
}
}
}
}
return frac;
}
posit32_t convertQuadToP32(__float128 f32){
union ui32_p32 uZ;
bool sign, regS;
uint_fast32_t reg, frac=0;
int_fast32_t exp=0;
bool bitNPlusOne=0, bitsMore=0;
(f32>=0) ? (sign=0) : (sign=1);
if (f32 == 0 ){
uZ.ui = 0;
return uZ.p;
}
else if(f32 == INFINITY || f32 == -INFINITY || f32 == NAN){
uZ.ui = 0x80000000;
return uZ.p;
}
else if (f32 == 1) {
uZ.ui = 0x40000000;
return uZ.p;
}
else if (f32 == -1){
uZ.ui = 0xC0000000;
return uZ.p;
}
else if (f32 >= 1.329227995784916e+36){
//maxpos
uZ.ui = 0x7FFFFFFF;
return uZ.p;
}
else if (f32 <= -1.329227995784916e+36){
// -maxpos
uZ.ui = 0x80000001;
return uZ.p;
}
else if(f32 <= 7.52316384526264e-37 && !sign){
//minpos
uZ.ui = 0x1;
return uZ.p;
}
else if(f32 >= -7.52316384526264e-37 && sign){
//-minpos
uZ.ui = 0xFFFFFFFF;
return uZ.p;
}
else if (f32>1 || f32<-1){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 1;
reg = 1; //because k = m-1; so need to add back 1
// minpos
if (f32 <= 7.52316384526264e-37){
uZ.ui = 1;
}
else{
//regime
while (f32>=16){
f32 *=0.0625; // f32/=16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int fracLength = 28-reg;
if (fracLength<0){
//remove hidden bit
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==29){
bitNPlusOne = exp&0x1;
exp>>=1; //taken care of by the pack algo
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){
bitsMore =1;
frac=0;
}
}
else
frac = convertQuadFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>30 ){
(regS) ? (uZ.ui= 0x7FFFFFFF): (uZ.ui=0x1);
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac));
uZ.ui += (bitNPlusOne & (uZ.ui&1)) | ( bitNPlusOne & bitsMore);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
/*if(sign)
uZ.ui = -uZ.ui;*/
}
}
else if (f32 < 1 || f32 > -1 ){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 0;
reg = 0;
while (f32<1){
f32 *= 16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
//only possible combination for reg=15 to reach here is 7FFF (maxpos) and FFFF (-minpos)
//but since it should be caught on top, so no need to handle
int fracLength = 28-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==29){
bitNPlusOne = exp&0x1;
exp>>=1; //taken care of by the pack algo
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertQuadFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>30 ){
(regS) ? (uZ.ui= 0x7FFFFFFF): (uZ.ui=0x1);
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac));
uZ.ui += (bitNPlusOne & (uZ.ui&1)) | ( bitNPlusOne & bitsMore);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
else {
//NaR - for NaN, INF and all other combinations
uZ.ui = 0x80000000;
}
return uZ.p;
}
posit_2_t convertQuadToPX2(__float128 f32, int x){
union ui32_pX2 uZ;
bool sign, regS;
uint_fast32_t reg, frac=0;
int_fast32_t exp=0;
bool bitNPlusOne=0, bitsMore=0;
(f32>=0) ? (sign=0) : (sign=1);
if (f32 == 0 ){
uZ.ui = 0;
return uZ.p;
}
else if(f32 == INFINITY || f32 == -INFINITY || f32 == NAN){
uZ.ui = 0x80000000;
return uZ.p;
}
else if (f32 == 1) {
uZ.ui = 0x40000000;
return uZ.p;
}
else if (f32 == -1){
uZ.ui = 0xC0000000;
return uZ.p;
}
/*else if (f32 >= 1.329227995784916e+36){
//maxpos
uZ.ui = 0x7FFFFFFF;
return uZ.p;
}
else if (f32 <= -1.329227995784916e+36){
// -maxpos
uZ.ui = 0x80000001;
return uZ.p;
}
else if(f32 <= 7.52316384526264e-37 && !sign){
//minpos
uZ.ui = 0x1;
return uZ.p;
}
else if(f32 >= -7.52316384526264e-37 && sign){
//-minpos
uZ.ui = 0xFFFFFFFF;
return uZ.p;
}*/
else if (f32>1 || f32<-1){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 1;
reg = 1; //because k = m-1; so need to add back 1
// minpos
if (x==32 && f32 <= 7.52316384526264e-37){
uZ.ui = 1;
}
else{
//regime
while (f32>=16){
f32 *=0.0625; // f32/=16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int fracLength = x-4-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==x-3){
bitNPlusOne = exp&0x1;
//exp>>=1; //taken care of by the pack algo
exp&=0x2;
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertQuadFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>(x-2) ){
uZ.ui=(regS) ? (0x7FFFFFFF & ((int32_t)0x80000000>>(x-1)) ): (0x1 << (32-x));
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac<<(32-x)));
//minpos
if (uZ.ui==0 && frac>0){
uZ.ui = 0x1 << (32-x);
}
if (bitNPlusOne)
uZ.ui += ( ((uZ.ui>>(32-x)) & 0x1) | bitsMore ) << (32-x);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
}
else if (f32 < 1 || f32 > -1 ){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 0;
reg = 0;
//regime
while (f32<1){
f32 *= 16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int fracLength = x-4-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==x-3){
bitNPlusOne = exp&0x1;
//exp>>=1; //taken care of by the pack algo
exp&=0x2;
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertQuadFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>(x-2) ){
uZ.ui=(regS) ? (0x7FFFFFFF & ((int32_t)0x80000000>>(x-1)) ): (0x1 << (32-x));
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac<<(32-x)));
//minpos
if (uZ.ui==0 && frac>0){
uZ.ui = 0x1 << (32-x);
}
if (bitNPlusOne){
uZ.ui += ( ((uZ.ui>>(32-x)) & 0x1) | bitsMore ) << (32-x);
}
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
else {
//NaR - for NaN, INF and all other combinations
uZ.ui = 0x80000000;
}
return uZ.p;
}
#endif
void checkExtraP32TwoBits(double f32, double temp, bool * bitsNPlusOne, bool * bitsMore ){
temp /= 2;
if (temp<=f32){
*bitsNPlusOne = 1;
f32-=temp;
}
if (f32>0)
*bitsMore = 1;
}
uint_fast32_t convertFractionP32(double f32, uint_fast16_t fracLength, bool * bitsNPlusOne, bool * bitsMore ){
uint_fast32_t frac=0;
if(f32==0) return 0;
else if(f32==INFINITY) return 0x80000000;
f32 -= 1; //remove hidden bit
if (fracLength==0)
checkExtraP32TwoBits(f32, 1.0, bitsNPlusOne, bitsMore);
else{
double temp = 1;
while (true){
temp /= 2;
if (temp<=f32){
f32-=temp;
fracLength--;
frac = (frac<<1) + 1; //shift in one
if (f32==0){
frac <<= (uint_fast16_t)fracLength;
break;
}
if (fracLength == 0){
checkExtraP32TwoBits(f32, temp, bitsNPlusOne, bitsMore);
break;
}
}
else{
frac <<= 1; //shift in a zero
fracLength--;
if (fracLength == 0){
checkExtraP32TwoBits(f32, temp, bitsNPlusOne, bitsMore);
break;
}
}
}
}
return frac;
}
posit32_t convertDoubleToP32(double f32){
union ui32_p32 uZ;
bool sign, regS;
uint_fast32_t reg, frac=0;
int_fast32_t exp=0;
bool bitNPlusOne=0, bitsMore=0;
(f32>=0) ? (sign=0) : (sign=1);
if (f32 == 0 ){
uZ.ui = 0;
return uZ.p;
}
else if(f32 == INFINITY || f32 == -INFINITY || f32 == NAN){
uZ.ui = 0x80000000;
return uZ.p;
}
else if (f32 == 1) {
uZ.ui = 0x40000000;
return uZ.p;
}
else if (f32 == -1){
uZ.ui = 0xC0000000;
return uZ.p;
}
else if (f32 >= 1.329227995784916e+36){
//maxpos
uZ.ui = 0x7FFFFFFF;
return uZ.p;
}
else if (f32 <= -1.329227995784916e+36){
// -maxpos
uZ.ui = 0x80000001;
return uZ.p;
}
else if(f32 <= 7.52316384526264e-37 && !sign){
//minpos
uZ.ui = 0x1;
return uZ.p;
}
else if(f32 >= -7.52316384526264e-37 && sign){
//-minpos
uZ.ui = 0xFFFFFFFF;
return uZ.p;
}
else if (f32>1 || f32<-1){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 1;
reg = 1; //because k = m-1; so need to add back 1
// minpos
if (f32 <= 7.52316384526264e-37){
uZ.ui = 1;
}
else{
//regime
while (f32>=16){
f32 *=0.0625; // f32/=16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int8_t fracLength = 28-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==29){
bitNPlusOne = exp&0x1;
exp>>=1; //taken care of by the pack algo
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>30 ){
(regS) ? (uZ.ui= 0x7FFFFFFF): (uZ.ui=0x1);
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac));
uZ.ui += (bitNPlusOne & (uZ.ui&1)) | ( bitNPlusOne & bitsMore);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
}
else if (f32 < 1 || f32 > -1 ){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 0;
reg = 0;
//regime
while (f32<1){
f32 *= 16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
//only possible combination for reg=15 to reach here is 7FFF (maxpos) and FFFF (-minpos)
//but since it should be caught on top, so no need to handle
int_fast8_t fracLength = 28-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==29){
bitNPlusOne = exp&0x1;
exp>>=1; //taken care of by the pack algo
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>30 ){
(regS) ? (uZ.ui= 0x7FFFFFFF): (uZ.ui=0x1);
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac));
uZ.ui += (bitNPlusOne & (uZ.ui&1)) | ( bitNPlusOne & bitsMore);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
else {
//NaR - for NaN, INF and all other combinations
uZ.ui = 0x80000000;
}
return uZ.p;
}
posit32_t convertFloatToP32(float a){
return convertDoubleToP32((double) a );
}
posit_2_t convertDoubleToPX2(double f32, int x){
union ui32_pX2 uZ;
bool sign, regS;
uint_fast32_t reg, frac=0;
int_fast32_t exp=0;
bool bitNPlusOne=0, bitsMore=0;
(f32>=0) ? (sign=0) : (sign=1);
if (f32 == 0 ){
uZ.ui = 0;
return uZ.p;
}
else if(f32 == INFINITY || f32 == -INFINITY || f32 == NAN){
uZ.ui = 0x80000000;
return uZ.p;
}
else if (f32 == 1) {
uZ.ui = 0x40000000;
return uZ.p;
}
else if (f32 == -1){
uZ.ui = 0xC0000000;
return uZ.p;
}
/*else if (f32 >= 1.329227995784916e+36){
//maxpos
uZ.ui = 0x7FFFFFFF;
return uZ.p;
}
else if (f32 <= -1.329227995784916e+36){
// -maxpos
uZ.ui = 0x80000001;
return uZ.p;
}
else if(f32 <= 7.52316384526264e-37 && !sign){
//minpos
uZ.ui = 0x1;
return uZ.p;
}
else if(f32 >= -7.52316384526264e-37 && sign){
//-minpos
uZ.ui = 0xFFFFFFFF;
return uZ.p;
}*/
else if (f32>1 || f32<-1){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 1;
reg = 1; //because k = m-1; so need to add back 1
// minpos
if (x==32 && f32 <= 7.52316384526264e-37){
uZ.ui = 1;
}
else{
//regime
while (f32>=16){
f32 *=0.0625; // f32/=16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int fracLength = x-4-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==x-3){
bitNPlusOne = exp&0x1;
//exp>>=1; //taken care of by the pack algo
exp&=0x2;
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>(x-2) ){
uZ.ui=(regS) ? (0x7FFFFFFF & ((int32_t)0x80000000>>(x-1)) ): (0x1 << (32-x));
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (x==32 && reg==29) exp>>=1;
else if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac<<(32-x)));
//minpos
if (uZ.ui==0 && frac>0){
uZ.ui = 0x1 << (32-x);
}
if (bitNPlusOne)
uZ.ui += ( ((uZ.ui>>(32-x)) & 0x1) | bitsMore ) << (32-x);
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
}
else if (f32 < 1 || f32 > -1 ){
if (sign){
//Make negative numbers positive for easier computation
f32 = -f32;
}
regS = 0;
reg = 0;
//regime
while (f32<1){
f32 *= 16;
reg++;
}
while (f32>=2){
f32*=0.5;
exp++;
}
int fracLength = x-4-reg;
if (fracLength<0){
//in both cases, reg=29 and 30, e is n+1 bit and frac are sticky bits
if(reg==x-3){
bitNPlusOne = exp&0x1;
//exp>>=1; //taken care of by the pack algo
exp&=0x2;
}
else{//reg=30
bitNPlusOne=exp>>1;
bitsMore=exp&0x1;
exp=0;
}
if (f32!=1){//because of hidden bit
bitsMore =1;
frac=0;
}
}
else
frac = convertFractionP32 (f32, fracLength, &bitNPlusOne, &bitsMore);
if (reg>(x-2) ){
uZ.ui=(regS) ? (0x7FFFFFFF & ((int32_t)0x80000000>>(x-1)) ): (0x1 << (32-x));
}
//rounding off fraction bits
else{
uint_fast32_t regime = 1;
if (regS) regime = ( (1<<reg)-1 ) <<1;
if (x==32 && reg==29) exp>>=1;
else if (reg<=28) exp<<= (28-reg);
uZ.ui = ((uint32_t) (regime) << (30-reg)) + ((uint32_t) exp ) + ((uint32_t)(frac<<(32-x)));
//minpos
if (uZ.ui==0 && frac>0){
uZ.ui = 0x1 << (32-x);
}
if (bitNPlusOne){
uZ.ui += ( ((uZ.ui>>(32-x)) & 0x1) | bitsMore ) << (32-x);
}
}
if (sign) uZ.ui = -uZ.ui & 0xFFFFFFFF;
}
else {
//NaR - for NaN, INF and all other combinations
uZ.ui = 0x80000000;
}
return uZ.p;
}