fis-gtm/sr_port/eb_muldiv.c

/****************************************************************
 *								*
 *	Copyright 2001 Sanchez Computer Associates, Inc.	*
 *								*
 *	This source code contains the intellectual property	*
 *	of its copyright holder(s), and is made available	*
 *	under a license.  If you do not know the terms of	*
 *	the license, please stop and do not read further.	*
 *								*
 ****************************************************************/

/*	eb_muldiv - emulate extended precision (18-digit) multiplication and division */

#include "mdef.h"

#include "arit.h"
#include "eb_muldiv.h"

#define FLO_HI		1e9
#define FLO_LO		1e8
#define FLO_BIAS	1e3

#define DFLOAT2MINT(X,DF) (X[1] = DF, X[0] = (DF - (double)X[1])*FLO_HI)

#define RADIX		10000


/*	eb_int_mul - multiply two GT.M INT's
 *
 *	input
 *		v1, u1 - GT.M INT's
 *
 *	output
 *		if the product will fit into a GT.M INT format:
 *			function result = FALSE => no promotion necessary
 *			p[] = INT product of (v1*m1)
 *		else (implies overflow out of INT format):
 *			function result = TRUE => promotion to extended precision necessary
 *			p[] = undefined
 */

bool	eb_int_mul (int4 v1, int4 u1, int4 p[])
{
	double	pf;
	int4	tp[2], promote;

	promote = TRUE;	/* promote if overflow or too many significant fractional digits */
	pf = (double)u1*(double)v1/FLO_BIAS;
	if ((pf < FLO_HI)  &&  (pf > -FLO_HI))
	{
		DFLOAT2MINT(tp, pf);
		if (tp[0] == 0)	/* don't need extra precision */
		{
			promote = FALSE;
			p[0] = tp[0];  p[1] = tp[1];
		}
	}
	return promote;
}


/*	eb_mul - multiply two GT.M extended precision numeric values
 *
 *	input
 *		v[], u[] - GT.M extended precision numeric value mantissas
 *
 *	output
 *		function result = scale factor of result
 *		p[] = GT.M extended precision mantissa of (u*v)
 */

int4	eb_mul (int4 v[], int4 u[], int4 p[])	/* p = u*v */
{
	short	i, j;
	int4	acc, carry, m1[5], m2[5], prod[9], scale;

	/* Throughout, larger index => more significance. */

	for (i = 0 ;  i < 9 ;  i++)
		prod[i] = 0;

	/* Break up 2-4-(3/1)-4-4 */

	m1[0] = v[0] % RADIX;
	m2[0] = u[0] % RADIX;

	m1[1] = (v[0]/RADIX) % RADIX;
	m2[1] = (u[0]/RADIX) % RADIX;

	m1[2] = (v[1] % (RADIX/10))*10 + v[0]/(RADIX*RADIX);
	m2[2] = (u[1] % (RADIX/10))*10 + u[0]/(RADIX*RADIX);

	m1[3] = (v[1]/(RADIX/10)) % RADIX;
	m2[3] = (u[1]/(RADIX/10)) % RADIX;

	m1[4] = v[1]/((RADIX/10)*RADIX);
	m2[4] = u[1]/((RADIX/10)*RADIX);

	for (j = 0 ;  j <= 4 ;  j++)
	{
		if (m2[j] != 0)
		{
			for (i = 0, carry = 0 ;  i <= 4 ;  i++)
			{
				acc = m1[i]*m2[j] + prod[i+j] + carry;
				prod[i+j] = acc % RADIX;
				carry     = acc / RADIX;
			}
			if ( 9 > i+j)
				prod[i+j] = carry;
			else
				if (0 != carry)
					assert(FALSE);
		}
	}

	if (prod[8] >= RADIX/10)
	{
		/* Assemble back 4-4-1/3-4-2 */
		scale = 0;	/* no scaling needed */
		p[0] = ((prod[6]%1000)*RADIX + prod[5])*(RADIX/ 100) + (prod[4]/ 100);
		p[1] = ( prod[8]      *RADIX + prod[7])*(RADIX/1000) + (prod[6]/1000);
	}
	else /* prod[8] < RADIX/10  [means not normalized] */
	{
		/* Assemble back 3-4-2/2-4-3 */
		scale = -1;	/* to compensate for normalization */
		p[0] = ((prod[6]%100)*RADIX + prod[5])*(RADIX/ 10) + (prod[4]/ 10);
		p[1] = ( prod[8]     *RADIX + prod[7])*(RADIX/100) + (prod[6]/100);
	}

	return scale;
}


/*	eb_mvint_div - divide to GT.M INT's
 *
 *	input
 *		v, u	- INT's to be divided
 *
 *	output
 *		if the quotient will fit into a GT.M INT:
 *			function value = FALSE => no promotion necessary
 *			q[] = INT quotient of (v/u)
 *		else (implies overflow out of GT.M INT forat):
 *			function value = TRUE => promotion to extended precision necessary
 *			q[] = undefined
 */

bool	eb_mvint_div (int4 v, int4 u, int4 q[])
{
	double	qf;
	int4	tq[2], promote;

	promote = TRUE;	/* promote if overflow or too many significant fractional digits */
	qf = (double)v*FLO_BIAS/(double)u;
	if ((qf < FLO_HI)  &&  (qf > -FLO_HI))
	{
		DFLOAT2MINT(tq, qf);
		if (tq[0] == 0)	/* don't need extra word of precision */
		{
			promote = FALSE;
			q[0] = tq[0];  q[1] = tq[1];
		}
	}
	return promote;
}


/*	eb_int_div - integer division of two GT.M INT's
 *
 *	input
 *		v1, u1 - GT.M INT's to be divided
 *
 *	output
 *		if result fits into a GT.M INT:
 *			function value = FALSE => no promotion necessary
 *			q[] = INT result of (v1\u1)
 *		else (implies some sort of overflow):
 *			function result = TRUE => promotion to extended precision necessary
 *			q[] = undefined
 */

bool	eb_int_div (int4 v1, int4 u1, int4 q[])
{
	double	qf;
	qf= (double)v1*FLO_BIAS/(double)u1;
	if (qf < FLO_HI  &&  qf > -FLO_HI)
	{
		DFLOAT2MINT(q,qf);
		q[1]= (q[1]/MV_BIAS)*MV_BIAS;
		return FALSE;
	}
	else
	{
		return TRUE;
	}
}


/*	eb_div - divide two GT.M extended precision numeric values
 *
 *	input
 *		x[], y[] - GT.M extended precision numeric value mantissas
 *
 *	output
 *		function result = scale factor of result
 *		q[] = GT.M extended precision mantissa of (y/x)
 */

int4	eb_div (int4 x[], int4 y[], int4 q[])	/* q = y/x */
{
	int4	borrow, carry, i, j, scale, prod, qx[5], xx[5], yx[10];

	for (i = 0 ;  i < 5 ;  i++)
		yx[i] = 0;
	if (x[1] < y[1]  ||  (x[1] == y[1]  &&  x[0] <= y[0]))	/* i.e., if x <= y */
	{
		/* Break y apart 3-4-2/2-4-3 */
		scale = 1;
		yx[5] = (y[0]%(RADIX/10))*10;
		yx[6] = (y[0]/(RADIX/10))%RADIX;
		yx[7] = (y[1]%(RADIX/100))*(RADIX/100) + y[0]/((RADIX/10)*RADIX);
		yx[8] = (y[1]/(RADIX/100))%RADIX;
		yx[9] =  y[1]/((RADIX/100)*RADIX);
	}
	else
	{
		/* Break y apart 4-4-1/3-4-2 */
		scale = 0;
		yx[5] = (y[0]%(RADIX/100))*100;
		yx[6] = (y[0]/(RADIX/100))%RADIX;
		yx[7] = (y[1]%(RADIX/1000))*(RADIX/10) + y[0]/((RADIX/100)*RADIX);
		yx[8] = (y[1]/(RADIX/1000))%RADIX;
		yx[9] =  y[1]/((RADIX/1000)*RADIX);
	}
	/* Break x apart 4-4-1/3-4-2 */
	xx[0] = (x[0]%(RADIX/100))*100;
	xx[1] = (x[0]/(RADIX/100))%RADIX;
	xx[2] = (x[1]%(RADIX/1000))*(RADIX/10) + x[0]/((RADIX/100)*RADIX);
	xx[3] = (x[1]/(RADIX/1000))%RADIX;
	xx[4] =  x[1]/((RADIX/1000)*RADIX);

	assert (yx[9] <= xx[4]);
	for (i = 4 ;  i >= 0 ;  i--)
	{
		qx[i] = (yx[i+5]*RADIX + yx[i+4]) / xx[4];
		if (qx[i] != 0)
		{
			/* Multiply x by qx[i] and subtract from remainder. */
			for (j = 0, borrow = 0 ;  j <= 4 ;  j++)
			{
				prod = qx[i]*xx[j] + borrow;
				borrow = prod/RADIX;
				yx[i+j] -= (prod%RADIX);
				if (yx[i+j] < 0)
				{
					yx[i+j] += RADIX;
					borrow ++;
				}
			}
			yx[i+5] -= borrow;

			while (yx[i+5] < 0)
			{
				qx[i] --;	/* estimate too high */
				for (j = 0, carry = 0 ;  j <= 4 ;  j++)
				{
					yx[i+j] += (xx[j] + carry);
					carry = yx[i+j]/RADIX;
					yx[i+j] %= RADIX;
				}
				yx[i+5] += carry;
			}
		}
		assert (0 <= qx[i]  &&  qx[i] < RADIX);	/* make sure in range */
		assert (yx[i+5] == 0);		/* check that remainder doesn't overflow */
	}

	/* Assemble q 4-4-1/3-4-2 */
	q[0] = ((qx[2]%1000)*RADIX + qx[1])*100 + (qx[0]/ 100);
	q[1] = ( qx[4]      *RADIX + qx[3])* 10 + (qx[2]/1000);

	assert (   (FLO_LO <= q[1]  &&  q[1] < FLO_HI)
		|| (q[1] == 0  &&  q[0] == 0  &&  y[1] == 0  &&  y[0] == 0) );

	return scale;
}


/*	eb_int_mod - INT modulus of two GT.M INT's
 *
 *	input
 *		v1, u1 - GT.M INT's
 *
 *	output
 *		p[] = INT value of (v1 mod u1) == (v1 - (u1*floor(v1/u1)))
 */

void	eb_int_mod (int4 v1, int4 u1, int4 p[])
{
	int4	quo, rat, neg;

	if (u1 == 0  ||  v1 == 0)
	{
		p[1]= 0;
	}
	else
	{
		quo = v1/u1;
		rat = v1 != quo*u1;
		neg = (v1 < 0  &&  u1 > 0) || (v1 > 0  && u1 < 0);
		p[1] = v1 - u1*(quo - (neg && rat));
	}
	return;
}
ENH: Initial import from sourceforge. These source tree was directly imported from http://sourceforge.net/projects/fis-gtm/files/GT.M-x86-Linux-src/V5.4-002B/ by extracting the file: gtm_V54002B_linux_i686_src.tar.gz 2012-02-05 11:35:58 -05:00			`/****************************************************************`
			`* *`
			`* Copyright 2001 Sanchez Computer Associates, Inc. *`
			`* *`
			`* This source code contains the intellectual property *`
			`* of its copyright holder(s), and is made available *`
			`* under a license. If you do not know the terms of *`
			`* the license, please stop and do not read further. *`
			`* *`
			`****************************************************************/`

			`/* eb_muldiv - emulate extended precision (18-digit) multiplication and division */`

			`#include "mdef.h"`

			`#include "arit.h"`
			`#include "eb_muldiv.h"`

			`#define FLO_HI 1e9`
			`#define FLO_LO 1e8`
			`#define FLO_BIAS 1e3`

			`#define DFLOAT2MINT(X,DF) (X[1] = DF, X[0] = (DF - (double)X[1])*FLO_HI)`

			`#define RADIX 10000`


			`/* eb_int_mul - multiply two GT.M INT's`
			`*`
			`* input`
			`* v1, u1 - GT.M INT's`
			`*`
			`* output`
			`* if the product will fit into a GT.M INT format:`
			`* function result = FALSE => no promotion necessary`
			`* p[] = INT product of (v1*m1)`
			`* else (implies overflow out of INT format):`
			`* function result = TRUE => promotion to extended precision necessary`
			`* p[] = undefined`
			`*/`

			`bool eb_int_mul (int4 v1, int4 u1, int4 p[])`
			`{`
			`double pf;`
			`int4 tp[2], promote;`

			`promote = TRUE; /* promote if overflow or too many significant fractional digits */`
			`pf = (double)u1*(double)v1/FLO_BIAS;`
			`if ((pf < FLO_HI) && (pf > -FLO_HI))`
			`{`
			`DFLOAT2MINT(tp, pf);`
			`if (tp[0] == 0) /* don't need extra precision */`
			`{`
			`promote = FALSE;`
			`p[0] = tp[0]; p[1] = tp[1];`
			`}`
			`}`
			`return promote;`
			`}`


			`/* eb_mul - multiply two GT.M extended precision numeric values`
			`*`
			`* input`
			`* v[], u[] - GT.M extended precision numeric value mantissas`
			`*`
			`* output`
			`* function result = scale factor of result`
			`* p[] = GT.M extended precision mantissa of (u*v)`
			`*/`

			`int4 eb_mul (int4 v[], int4 u[], int4 p[]) /* p = uv /`
			`{`
			`short i, j;`
			`int4 acc, carry, m1[5], m2[5], prod[9], scale;`

			`/* Throughout, larger index => more significance. */`

			`for (i = 0 ; i < 9 ; i++)`
			`prod[i] = 0;`

			`/* Break up 2-4-(3/1)-4-4 */`

			`m1[0] = v[0] % RADIX;`
			`m2[0] = u[0] % RADIX;`

			`m1[1] = (v[0]/RADIX) % RADIX;`
			`m2[1] = (u[0]/RADIX) % RADIX;`

			`m1[2] = (v[1] % (RADIX/10))10 + v[0]/(RADIXRADIX);`
			`m2[2] = (u[1] % (RADIX/10))10 + u[0]/(RADIXRADIX);`

			`m1[3] = (v[1]/(RADIX/10)) % RADIX;`
			`m2[3] = (u[1]/(RADIX/10)) % RADIX;`

			`m1[4] = v[1]/((RADIX/10)*RADIX);`
			`m2[4] = u[1]/((RADIX/10)*RADIX);`

			`for (j = 0 ; j <= 4 ; j++)`
			`{`
			`if (m2[j] != 0)`
			`{`
			`for (i = 0, carry = 0 ; i <= 4 ; i++)`
			`{`
			`acc = m1[i]*m2[j] + prod[i+j] + carry;`
			`prod[i+j] = acc % RADIX;`
			`carry = acc / RADIX;`
			`}`
			`if ( 9 > i+j)`
			`prod[i+j] = carry;`
			`else`
			`if (0 != carry)`
			`assert(FALSE);`
			`}`
			`}`

			`if (prod[8] >= RADIX/10)`
			`{`
			`/* Assemble back 4-4-1/3-4-2 */`
			`scale = 0; /* no scaling needed */`
			`p[0] = ((prod[6]%1000)RADIX + prod[5])(RADIX/ 100) + (prod[4]/ 100);`
			`p[1] = ( prod[8] RADIX + prod[7])(RADIX/1000) + (prod[6]/1000);`
			`}`
			`else /* prod[8] < RADIX/10 [means not normalized] */`
			`{`
			`/* Assemble back 3-4-2/2-4-3 */`
			`scale = -1; /* to compensate for normalization */`
			`p[0] = ((prod[6]%100)RADIX + prod[5])(RADIX/ 10) + (prod[4]/ 10);`
			`p[1] = ( prod[8] RADIX + prod[7])(RADIX/100) + (prod[6]/100);`
			`}`

			`return scale;`
			`}`


			`/* eb_mvint_div - divide to GT.M INT's`
			`*`
			`* input`
			`* v, u - INT's to be divided`
			`*`
			`* output`
			`* if the quotient will fit into a GT.M INT:`
			`* function value = FALSE => no promotion necessary`
			`* q[] = INT quotient of (v/u)`
			`* else (implies overflow out of GT.M INT forat):`
			`* function value = TRUE => promotion to extended precision necessary`
			`* q[] = undefined`
			`*/`

			`bool eb_mvint_div (int4 v, int4 u, int4 q[])`
			`{`
			`double qf;`
			`int4 tq[2], promote;`

			`promote = TRUE; /* promote if overflow or too many significant fractional digits */`
			`qf = (double)v*FLO_BIAS/(double)u;`
			`if ((qf < FLO_HI) && (qf > -FLO_HI))`
			`{`
			`DFLOAT2MINT(tq, qf);`
			`if (tq[0] == 0) /* don't need extra word of precision */`
			`{`
			`promote = FALSE;`
			`q[0] = tq[0]; q[1] = tq[1];`
			`}`
			`}`
			`return promote;`
			`}`


			`/* eb_int_div - integer division of two GT.M INT's`
			`*`
			`* input`
			`* v1, u1 - GT.M INT's to be divided`
			`*`
			`* output`
			`* if result fits into a GT.M INT:`
			`* function value = FALSE => no promotion necessary`
			`* q[] = INT result of (v1\u1)`
			`* else (implies some sort of overflow):`
			`* function result = TRUE => promotion to extended precision necessary`
			`* q[] = undefined`
			`*/`

			`bool eb_int_div (int4 v1, int4 u1, int4 q[])`
			`{`
			`double qf;`
			`qf= (double)v1*FLO_BIAS/(double)u1;`
			`if (qf < FLO_HI && qf > -FLO_HI)`
			`{`
			`DFLOAT2MINT(q,qf);`
			`q[1]= (q[1]/MV_BIAS)*MV_BIAS;`
			`return FALSE;`
			`}`
			`else`
			`{`
			`return TRUE;`
			`}`
			`}`


			`/* eb_div - divide two GT.M extended precision numeric values`
			`*`
			`* input`
			`* x[], y[] - GT.M extended precision numeric value mantissas`
			`*`
			`* output`
			`* function result = scale factor of result`
			`* q[] = GT.M extended precision mantissa of (y/x)`
			`*/`

			`int4 eb_div (int4 x[], int4 y[], int4 q[]) /* q = y/x */`
			`{`
			`int4 borrow, carry, i, j, scale, prod, qx[5], xx[5], yx[10];`

			`for (i = 0 ; i < 5 ; i++)`
			`yx[i] = 0;`
			`if (x[1] < y[1] \|\| (x[1] == y[1] && x[0] <= y[0])) /* i.e., if x <= y */`
			`{`
			`/* Break y apart 3-4-2/2-4-3 */`
			`scale = 1;`
			`yx[5] = (y[0]%(RADIX/10))*10;`
			`yx[6] = (y[0]/(RADIX/10))%RADIX;`
			`yx[7] = (y[1]%(RADIX/100))(RADIX/100) + y[0]/((RADIX/10)RADIX);`
			`yx[8] = (y[1]/(RADIX/100))%RADIX;`
			`yx[9] = y[1]/((RADIX/100)*RADIX);`
			`}`
			`else`
			`{`
			`/* Break y apart 4-4-1/3-4-2 */`
			`scale = 0;`
			`yx[5] = (y[0]%(RADIX/100))*100;`
			`yx[6] = (y[0]/(RADIX/100))%RADIX;`
			`yx[7] = (y[1]%(RADIX/1000))(RADIX/10) + y[0]/((RADIX/100)RADIX);`
			`yx[8] = (y[1]/(RADIX/1000))%RADIX;`
			`yx[9] = y[1]/((RADIX/1000)*RADIX);`
			`}`
			`/* Break x apart 4-4-1/3-4-2 */`
			`xx[0] = (x[0]%(RADIX/100))*100;`
			`xx[1] = (x[0]/(RADIX/100))%RADIX;`
			`xx[2] = (x[1]%(RADIX/1000))(RADIX/10) + x[0]/((RADIX/100)RADIX);`
			`xx[3] = (x[1]/(RADIX/1000))%RADIX;`
			`xx[4] = x[1]/((RADIX/1000)*RADIX);`

			`assert (yx[9] <= xx[4]);`
			`for (i = 4 ; i >= 0 ; i--)`
			`{`
			`qx[i] = (yx[i+5]*RADIX + yx[i+4]) / xx[4];`
			`if (qx[i] != 0)`
			`{`
			`/* Multiply x by qx[i] and subtract from remainder. */`
			`for (j = 0, borrow = 0 ; j <= 4 ; j++)`
			`{`
			`prod = qx[i]*xx[j] + borrow;`
			`borrow = prod/RADIX;`
			`yx[i+j] -= (prod%RADIX);`
			`if (yx[i+j] < 0)`
			`{`
			`yx[i+j] += RADIX;`
			`borrow ++;`
			`}`
			`}`
			`yx[i+5] -= borrow;`

			`while (yx[i+5] < 0)`
			`{`
			`qx[i] --; /* estimate too high */`
			`for (j = 0, carry = 0 ; j <= 4 ; j++)`
			`{`
			`yx[i+j] += (xx[j] + carry);`
			`carry = yx[i+j]/RADIX;`
			`yx[i+j] %= RADIX;`
			`}`
			`yx[i+5] += carry;`
			`}`
			`}`
			`assert (0 <= qx[i] && qx[i] < RADIX); /* make sure in range */`
			`assert (yx[i+5] == 0); /* check that remainder doesn't overflow */`
			`}`

			`/* Assemble q 4-4-1/3-4-2 */`
			`q[0] = ((qx[2]%1000)RADIX + qx[1])100 + (qx[0]/ 100);`
			`q[1] = ( qx[4] RADIX + qx[3]) 10 + (qx[2]/1000);`

			`assert ( (FLO_LO <= q[1] && q[1] < FLO_HI)`
			`\|\| (q[1] == 0 && q[0] == 0 && y[1] == 0 && y[0] == 0) );`

			`return scale;`
			`}`


			`/* eb_int_mod - INT modulus of two GT.M INT's`
			`*`
			`* input`
			`* v1, u1 - GT.M INT's`
			`*`
			`* output`
			`* p[] = INT value of (v1 mod u1) == (v1 - (u1*floor(v1/u1)))`
			`*/`

			`void eb_int_mod (int4 v1, int4 u1, int4 p[])`
			`{`
			`int4 quo, rat, neg;`

			`if (u1 == 0 \|\| v1 == 0)`
			`{`
			`p[1]= 0;`
			`}`
			`else`
			`{`
			`quo = v1/u1;`
			`rat = v1 != quo*u1;`
			`neg = (v1 < 0 && u1 > 0) \|\| (v1 > 0 && u1 < 0);`
			`p[1] = v1 - u1*(quo - (neg && rat));`
			`}`
			`return;`
			`}`