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NetBSD/sys/arch/pc532/fpu/ieee_subnormal.c

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/* $NetBSD: ieee_subnormal.c,v 1.1 1996/04/04 06:36:30 phil Exp $ */
/*
* IEEE floating point support for NS32081 and NS32381 fpus.
* Copyright (c) 1995 Ian Dall
* All Rights Reserved.
*
* Permission to use, copy, modify and distribute this software and its
* documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* IAN DALL ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" CONDITION.
* IAN DALL DISCLAIMS ANY LIABILITY OF ANY KIND FOR ANY DAMAGES
* WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
*/
/*
* File: ieee_subnormal.c
* Author: Ian Dall
* Date: November 1995
*
* Handle operations which generated underflow traps. Subnormal
* (denormalized numbers) are generated as required.
*
* HISTORY
* 14-Dec-95 Ian Dall (Ian.Dall@dsto.defence.gov.au)
* First release.
*
*/
#include "ieee_internal.h"
#include <machine/psl.h>
/* Return bit pos numbered from lsb 0 to 31. Returns 31 if no bit is set */
static int find_msb(unsigned int t) {
static const int b_mask[] = {
0xffff0000,
0xff00ff00,
0xf0f0f0f0,
0xcccccccc,
0xaaaaaaaa };
int i;
int pos = 31;
int bit_incr = 16; /* Half no of bits in int */
for (i = 0; i < 5; i++, bit_incr /= 2) {
if(t & b_mask[i]) {
t &= b_mask[i];
}
else {
pos -= bit_incr;
t &= ~b_mask[i];
}
}
return pos;
}
static int leading_zeros(union t_conv *data)
{
unsigned int t;
if ((t = data->d_bits.mantissa)) {
return 19 - find_msb(t);
}
else if ((t = data->d_bits.mantissa2)) {
return 51 - find_msb(t);
}
else
return 52;
}
static void lshift_mantissa(union t_conv *data, int n)
{
unsigned long t[2];
t[1] = data->d_bits.mantissa;
t[0] = data->d_bits.mantissa2;
*(unsigned long long *) t <<= n;
data->d_bits.mantissa = t[1];
data->d_bits.mantissa2 = t[0];
}
static void rshift_mantissa(union t_conv *data, int n)
{
unsigned long t[2];
t[1] = data->d_bits.mantissa | 0x100000;
t[0] = data->d_bits.mantissa2;
*(unsigned long long *) t >>= n;
data->d_bits.mantissa = t[1];
data->d_bits.mantissa2 = t[0];
}
/* After this, the data is a normal double and the returned value is
* such that:
* union t_conv t;
* t = *data;
* norm = normalize(&t);
* 2**norm * t.d == data->d;
*
* Assume data is not already normalized.
*/
int ieee_normalize(union t_conv *data)
{
int norm;
if(data->d_bits.exp != 0)
return 0;
norm = leading_zeros(data) + 1; /* plus one for the implied bit */
data->d_bits.exp = 1;
lshift_mantissa(data, norm);
return -norm;
}
/* Divide by 2**n producing a denormalized no if necessary */
static void denormalize(union t_conv *data, int n)
{
int exp = data->d_bits.exp;
if(exp > n)
exp -= n;
else if (exp <= n) {
rshift_mantissa(data, n - exp + 1); /* plus 1 for the implied bit */
exp = 0;
}
data->d_bits.exp = exp;
}
static int scale_and_check(union t_conv *d, int scale)
{
int exp;
exp = d->d_bits.exp - scale;
if(exp >= 0x7ff) {
/* Overflow */
d->d_bits.exp = 0x7ff;
d->d_bits.mantissa = 0;
d->d_bits.mantissa2 = 0; /* XXX sig */
return FPC_TT_OVFL;
}
if(exp <= 0) {
/* Underflow */
denormalize(d, scale); /* XXX sig */
return FPC_TT_UNDFL;
}
d->d_bits.exp = exp;
return FPC_TT_NONE;
}
/* Add two doubles, not caring if one or both is a de-norm.
* Strategy: First scale and normalize operands so the addition
* can't overflow or underflow, then do a normal floating point
* addition, then scale back and possibly denormalize.
*/
int ieee_add(double data1, double *data2)
{
union t_conv d1 = (union t_conv) data1;
union t_conv *d2 = (union t_conv *) data2;
int scale;
int norm1 = ieee_normalize(&d1);
int norm2 = ieee_normalize(d2);
int exp1 = d1.d_bits.exp + norm1;
int exp2 = d2->d_bits.exp + norm2;
if(exp1 > exp2) {
scale = EXP_DBIAS - exp1;
exp1 = EXP_DBIAS;
exp2 += scale;
}
else {
scale = EXP_DBIAS - exp2;
exp2 = EXP_DBIAS;
exp1 += scale;
}
if(exp1 > 0) {
d1.d_bits.exp = exp1;
if (exp2 > 0) {
d2->d_bits.exp = exp2;
d2->d += d1.d;
}
else {
d2->d = d1.d;
}
}
else {
d2->d_bits.exp = exp2;
}
return scale_and_check(d2, scale);
}
/* Multiply two doubles, not caring if one or both is a de-norm.
* Strategy: First scale and normalize operands so the multiplication
* can't overflow or underflow, then do a normal floating point
* addition, then scale back and possibly denormalize.
*/
int ieee_mul(double data1, double *data2)
{
union t_conv d1 = (union t_conv) data1;
union t_conv *d2 = (union t_conv *) data2;
int scale;
int norm1 = ieee_normalize(&d1);
int norm2 = ieee_normalize(d2);
int exp1 = d1.d_bits.exp + norm1;
int exp2 = d2->d_bits.exp + norm2;
d1.d_bits.exp = EXP_DBIAS; /* Add EXP_DBIAS - exp1 */
d2->d_bits.exp = EXP_DBIAS;
d2->d *= d1.d;
scale = EXP_DBIAS - exp1 + EXP_DBIAS - exp2;
return scale_and_check(d2, scale);
}
/* Divide d2 by d1, not caring if one or both is a de-norm.
* Strategy: First scale and normalize operands so the division
* can't overflow or underflow, then do a normal floating point
* division, then scale back and possibly denormalize.
*/
int ieee_div(double data1, double *data2)
{
union t_conv d1 = (union t_conv) data1;
union t_conv *d2 = (union t_conv *) data2;
int scale;
int norm1 = ieee_normalize(&d1);
int norm2 = ieee_normalize(d2);
int exp1 = d1.d_bits.exp + norm1;
int exp2 = d2->d_bits.exp + norm2;
d1.d_bits.exp = EXP_DBIAS; /* Add EXP_DBIAS - exp1 */
d2->d_bits.exp = EXP_DBIAS;
d2->d /= d1.d;
scale = exp1 - exp2;
return scale_and_check(d2, scale);
}
/* Add mul-add three doubles d1 * d2 + d3 -> d3, not caring if any a de-norm.
* Strategy: First scale and normalize operands so the operations
* can't overflow or underflow, then do a normal floating point operation
* addition, then scale back and possibly denormalize.
*/
int ieee_dot(double data1, double data2, double *data3)
{
union t_conv d1 = (union t_conv) data1;
union t_conv d2 = (union t_conv) data2;
union t_conv *d3 = (union t_conv *) data3;
int scale;
int norm1 = ieee_normalize(&d1);
int norm2 = ieee_normalize(&d2);
int norm3 = ieee_normalize(d3);
int exp1 = d1.d_bits.exp + norm1;
int exp2 = d2.d_bits.exp + norm2;
int exp3 = d3->d_bits.exp + norm3;
int exp_prod = exp1 + exp2;
if(exp_prod > exp3) {
scale = EXP_DBIAS + EXP_DBIAS - exp_prod;
exp1 = EXP_DBIAS; /* Add EXP_DBIAS - exp1 */
exp2 = EXP_DBIAS;
exp3 += scale;
}
else {
scale = EXP_DBIAS - exp3;
exp3 = EXP_DBIAS;
exp1 = (exp_prod + scale)/2;
exp2 = exp_prod + scale - exp1;
}
if(exp1 > 0 && exp2 > 0) {
d1.d_bits.exp = exp1;
d2.d_bits.exp = exp2;
if(exp3 > 0) {
d3->d_bits.exp = exp3;
d3->d += d1.d * d2.d;
}
else {
d3->d = d1.d * d2.d;
}
}
else {
d3->d_bits.exp = exp3;
}
return scale_and_check(d3, scale);
}
/* Compare the magnitude of two ops.
* return: 1 |op1| > |op2|
* -1 |op1| < |op2|
* 0 |op1| == |op2|
*/
static int u_cmp(double data1, double data2)
{
union t_conv d1 = (union t_conv) data1;
union t_conv d2 = (union t_conv) data2;
int exp1 = d1.d_bits.exp;
int exp2 = d2.d_bits.exp;
if (exp1 > exp2)
return 1;
else if (exp1 < exp2)
return -1;
else if (d1.d_bits.mantissa > d2.d_bits.mantissa)
return 1;
else if (d1.d_bits.mantissa < d2.d_bits.mantissa)
return -1;
else if (d1.d_bits.mantissa2 > d2.d_bits.mantissa2)
return 1;
else if (d1.d_bits.mantissa2 < d2.d_bits.mantissa2)
return -1;
else
return 0;
}
void ieee_cmp(double data1, double data2, state *state)
{
union t_conv d1 = (union t_conv) data1;
union t_conv d2 = (union t_conv) data2;
int sign1 = d1.d_bits.sign;
int sign2 = d2.d_bits.sign;
state->PSR &= ~(PSR_N | PSR_Z | PSR_L);
switch(sign2 * 2 + sign1) {
case 2: /* op2 is negative op1 is positive */
state->PSR |= PSR_N;
break;
case 1: /* op2 is positive op1 is negative */
break;
case 0: /* Both ops same sign */
case 3:
{
int cmp = u_cmp(d1.d, d2.d);
if(sign1)
cmp *= -1;
if(cmp > 0)
state->PSR |= PSR_N;
else if (cmp == 0)
state->PSR |= PSR_Z;
}
break;
}
return;
}
int ieee_scalb(double data1, double *data2)
{
union t_conv d1 = (union t_conv) data1;
union t_conv *d2 = (union t_conv *) data2;
int exp2 = d2->d_bits.exp - EXP_DBIAS;
int n;
if (exp2 > 16) {
*d2 = infty;
d2->d_bits.sign = d1.d_bits.sign;
return FPC_TT_OVFL;
}
else if (exp2 < -16) {
d2->d = 0.0;
d2->d_bits.sign = d1.d_bits.sign;
return FPC_TT_OVFL;
}
n = d2->d;
*d2 = d1;
return scale_and_check(d2, n);
}
/* With no trap, hardware produces zero, which is fast but not
* strictly correct. We should always have the hardware trap bit set
* and generate denormalized numbers by simulation unless the user
* indicates via the FPC_UNDE flag they want to handle it. */
int ieee_undfl(struct operand *op1, struct operand *op2,
struct operand *f0_op, int xopcode, state *state)
{
unsigned int fsr = state->FSR;
int user_trap = FPC_TT_NONE;
DP(1, "Underflow trap: xopcode = 0x%x\n", xopcode);
if (fsr & FPC_UNDE) {
user_trap = FPC_TT_UNDFL;
}
else {
user_trap = FPC_TT_NONE;
/* Calculate correct denormal output. The easiest way is to
* prescale the operands so they won't underflow, then use the
* hardware operation, then post scale.
*/
/* The exact sematics are a bit tricky. Apparently, we should only
* set flag if we underflowed *and* there was loss of precision
* For now, just set the flag always XXX
*/
fsr |= FPC_UF;
switch(xopcode) {
case NEGF:
op1->data.d_bits.sign ^= 1;
/* Fall through */
case MOVF:
case MOVLF:
case MOVFL:
op2->data = op1->data;
break;
case CMPF:
ieee_cmp(op1->data.d, op2->data.d, state);
break;
case SUBF:
op1->data.d_bits.sign ^= 1;
/* Fall through */
case ADDF:
user_trap = ieee_add(op1->data.d, &op2->data.d);
break;
case MULF:
user_trap = ieee_mul(op1->data.d, &op2->data.d);
break;
case DIVF:
user_trap = ieee_div(op1->data.d, &op2->data.d);
break;
case ROUNDFI:
case TRUNCFI:
case FLOORFI:
op2->data.i = 0;
break;
case SCALBF:
user_trap = ieee_scalb(op1->data.d, &op2->data.d);
break;
case LOGBF:
op2->data.d = 0.0;
break;
case DOTF:
user_trap = ieee_dot(op1->data.d, op2->data.d, &f0_op->data.d);
break;
case POLYF:
{
union t_conv t = op2->data;
user_trap = ieee_dot(f0_op->data.d, op1->data.d, &t.d);
f0_op->data = t;
}
break;
}
}
state->FSR = fsr;
return user_trap;
}
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