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bigint.c
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bigint.c
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/*** bigint.c ***/
/* This is a very crude large integer package. The purpose is to teach, not to
be efficient. See freelip or miracl for very efficient code or check out the
commercial packages like Macsyma, Maple or the other similar products. The basis
of these routines come from J.W. Crenshaw and several articles in his "Programmers
Toolbox" in Embedded Systems Programming magazine from Dec. 1996 thru Sept. 1997
*/
#include <stdio.h>
#include "bigint.h"
/* clear all bits in a large integer storage block. */
void bi_int_null( a)
BIGINT *a;
{
INDEX i;
INTLOOP (i) a->hw[i] = 0;
}
/* copy one BIGINT block to another */
void bi_int_copy( a, b)
BIGINT *a, *b;
{
INDEX i;
INTLOOP (i) b->hw[i] = a->hw[i];
}
/* for use in the far distant future, convert a packed field to a large
integer. Does a simple expansion. The large integer is 4 times bigger
to accomodate multiplication (once!).
*/
void bi_field_to_int( a, b)
FIELD2N *a;
BIGINT *b;
{
INDEX i, j;
bi_int_null( b);
for (i=NUMWORD; i>=0; i--)
{
j = INTMAX - ((NUMWORD - i)<<1);
b->hw[j] = a->e[i] & LOMASK;
j--;
b->hw[j] = (a->e[i] & HIMASK) >> HALFSIZE;
}
}
/* Pack a BIGINT variable back into a FIELD2N size one. */
void bi_int_to_field( a, b)
BIGINT *a;
FIELD2N *b;
{
INDEX i, j;
SUMLOOP(i)
{
j = (i + MAXLONG) << 1;
b->e[i] = a->hw[j+1] | (a->hw[j] << HALFSIZE);
}
}
/* Negate a BIGINT in place. Each half word is complemented, then we add 1 */
void bi_int_neg( a)
BIGINT *a;
{
INDEX i;
INTLOOP(i) a->hw[i] = ~a->hw[i] & LOMASK;
INTLOOP(i)
{
a->hw[i]++;
if (a->hw[i] & LOMASK) break;
a->hw[i] &= LOMASK;
}
}
/* add two BIGINTS to get a third. c = a + b
Unlike the polynomial or ONB math, c can be one of a or b
*/
void bi_int_add( a, b, c)
BIGINT *a, *b, *c;
{
INDEX i;
ELEMENT ec;
ec = 0;
INTLOOP (i)
{
/* add previous carry bit to each term */
ec = a->hw[i] + b->hw[i] + (ec >> HALFSIZE);
c->hw[i] = ec & LOMASK;
}
}
/* subtract two BIGINTS, c = a - b == a + (-b).
as in addition, c can point to a or b and still works
*/
void bi_int_sub( a, b, c)
BIGINT *a, *b, *c;
{
BIGINT negb;
bi_int_copy( b, &negb);
bi_int_neg( &negb);
bi_int_add( a, &negb, c);
}
/* multiply two BIGINTs to get a third.
Do NOT attempt to do 2 multiplies in a row without a division in between.
You may get an overflow and there is no provision in this code to return
an error condition for that. See more advanced packages for correct way
to do this. c can *not* be one of a or b, it must be a separate storage
location.
*/
void bi_int_mul( a, b, c)
BIGINT *a, *b, *c;
{
ELEMENT ea, eb, mul;
INDEX i, j, k;
BIGINT sum;
bi_int_null(c);
for ( i = INTMAX; i > INTMAX/2; i--)
{
ea = a->hw[i];
bi_int_null( &sum);
for ( j = INTMAX; j > INTMAX/2; j--)
{
eb = b->hw[j];
k = i + j - INTMAX;
mul = ea * eb + sum.hw[k];
sum.hw[k] = mul & LOMASK;
sum.hw[k-1] = mul >> HALFSIZE;
}
bi_int_add( &sum, c, c);
}
}
/* unsigned divide. Input full sized numerator (top),
half sized denominator (bottom).
Output half sized quotient and half sized remainder.
Exceptionally crude but works ok for basics, error
conditions return zero results.
*/
void bi_int_div( top, bottom, quotient, remainder)
BIGINT *top, *bottom, *quotient, *remainder;
{
BIGINT d, e;
ELEMENT mask;
INDEX l, m, n, i, j;
/* first step, initialize counters to most significant
bit position in top and bottom.
*/
bi_int_copy( top, &d);
bi_int_copy( bottom, &e);
l = (INTMAX + 1) * HALFSIZE;
for( i=0; i<=INTMAX; i++)
{
if (!d.hw[i]) l -= HALFSIZE;
else break;
}
mask = 1L << (HALFSIZE-1);
for ( j=0; j<HALFSIZE; j++)
{
if ( !(d.hw[i] & mask))
{
l--;
mask >>= 1;
}
else break;
}
/* same thing for bottom, compute msb position */
m = (INTMAX + 1) * HALFSIZE;
for( i=0; i<=INTMAX; i++)
{
if (!e.hw[i]) m -= HALFSIZE;
else break;
}
mask = 1L << (HALFSIZE-1);
for ( j=0; j<HALFSIZE; j++)
{
if ( !(e.hw[i] & mask))
{
m--;
mask >>= 1;
}
else break;
}
/* check for error inputs, does not check for zero, so is
actually incorrect.
*/
if (!m) /* x/1 = x */
{
bi_int_copy( top, quotient);
bi_int_null( remainder);
}
if (!l | (l<m)) /* 1/x = 0 */
{
bi_int_null( quotient);
bi_int_copy( bottom, remainder);
}
/* next step, shift bottom over to align msb with top msb */
n = l - m;
i = n;
while ( i > HALFSIZE )
{
for (j=0; j<INTMAX; j++) e.hw[j] = e.hw[j+1];
i -= HALFSIZE;
e.hw[INTMAX] = 0;
}
mask = 0;
while ( i > 0 )
{
INTLOOP (j)
{
e.hw[j] = (e.hw[j] << 1) | mask;
mask = e.hw[j] & CARRY ? 1 : 0;
e.hw[j] &= LOMASK;
}
i--;
}
/* main division loop. check to see if we can subtract shifted bottom
from what's left on top. If we can, set that bit in quotient and do
subtract. if we can't, just shift bottom right and repeat until only
remainder is left.
*/
bi_int_null( quotient);
while ( n>=0)
{
i = INTMAX - l/HALFSIZE;
j = INTMAX - n/HALFSIZE;
while ( (d.hw[i] == e.hw[i]) && ( i<INTMAX) ) i++;
if ( d.hw[i] >= e.hw[i] )
{
bi_int_sub( &d, &e, &d);
mask = 1L << ( n%HALFSIZE );
quotient->hw[j] |= mask;
}
INTLOOP(j)
{
if (j) mask = ( e.hw[j-1] & 1) ? CARRY : 0;
else mask = 0;
e.hw[j] = (e.hw[j] | mask) >> 1;
}
n--;
l--;
}
bi_int_copy ( &d, remainder);
}
/* Convert ascii string of decimal digits into BIGINT binary.
Ignores out of range characters. This is very crude, 'a' = '1',
so watch out for input errors!
*/
void bi_ascii_to_bigint( instring, outhex)
char *instring;
BIGINT *outhex;
{
ELEMENT ch;
BIGINT ten, digit, temp;
INDEX i=0;
bi_int_null( &ten); /* create decimal multiplier */
ten.hw[INTMAX] = 0xA;
bi_int_null( &digit);
bi_int_null( outhex);
while (ch = *instring++)
{
digit.hw[INTMAX] = ch & 0xF;
bi_int_mul( outhex, &ten, &temp);
if (digit.hw[INTMAX] > 9) continue;
bi_int_add( &temp, &digit, outhex);
}
}
/* Convert binary BIGINT to ascii string. Assumes destination has
enough characters to hold result. This is 4*HALFSIZE*MAXLONG bits
= Log(2)*4*HALFSIZE*MAXLONG = 1.20412*HALFSIZE*MAXLONG characters
or about 5/4*HALFSIZE*MAXLONG chars. Works backwards and blank
fills destination string.
*/
void bi_bigint_to_ascii( inhex, outstring)
BIGINT *inhex;
char *outstring;
{
BIGINT top, ten, quotient, remainder;
ELEMENT check;
INDEX i;
bi_int_copy( inhex, &top);
bi_int_null( &ten); /* create constant 10 */
ten.hw[INTMAX] = 0xA;
for (i=0; i<MAXSTRING; i++) *outstring++ = ' '; /* blank fill and null string */
outstring--;
*outstring-- = 0;
check = 1;
while (check)
{
bi_int_div( &top, &ten, "ient, &remainder);
*outstring-- = remainder.hw[INTMAX] | '0';
check = 0;
INTLOOP(i) check |= quotient.hw[i];
bi_int_copy( "ient, &top);
}
}