gas/flonum-mult.c - third_party/binutils-gdb - Git at Google

 /* flonum_mult.c - multiply two flonums
    Copyright (C) 1987-2016 Free Software Foundation, Inc.

    This file is part of GAS, the GNU Assembler.

    GAS 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 3, or (at your option)
    any later version.

    GAS 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 GAS; see the file COPYING.  If not, write to the Free
    Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
    02110-1301, USA.  */

 #include "ansidecl.h"
 #include "flonum.h"

 /*	plan for a . b => p(roduct)

 	+-------+-------+-/   /-+-------+-------+
 	| a	| a	|  ...	| a	| a	|
 	|  A	|  A-1	|	|  1	|  0	|
 	+-------+-------+-/   /-+-------+-------+

 	+-------+-------+-/   /-+-------+-------+
 	| b	| b	|  ...	| b	| b	|
 	|  B	|  B-1	|	|  1	|  0	|
 	+-------+-------+-/   /-+-------+-------+

 	+-------+-------+-/   /-+-------+-/   /-+-------+-------+
 	| p	| p	|  ...	| p	|  ...	| p	| p	|
 	|  A+B+1|  A+B	|	|  N	|	|  1	|  0	|
 	+-------+-------+-/   /-+-------+-/   /-+-------+-------+

 	/^\
 	(carry) a .b	   ...	    |	   ...	 a .b	 a .b
 	A  B 		    |		  0  1	  0  0
 	|
 	...	    |	   ...	 a .b
 	|		  1  0
 	|
 	|	   ...
 	|
 	|
 	|
 	|		  ___
 	|		  \
 	+-----  P  =   >  a .b
 	N	  /__  i  j

 	N = 0 ... A+B

 	for all i,j where i+j=N
 	[i,j integers > 0]

 	a[], b[], p[] may not intersect.
 	Zero length factors signify 0 significant bits: treat as 0.0.
 	0.0 factors do the right thing.
 	Zero length product OK.

 	I chose the ForTran accent "foo[bar]" instead of the C accent "*garply"
 	because I felt the ForTran way was more intuitive. The C way would
 	probably yield better code on most C compilers. Dean Elsner.
 	(C style also gives deeper insight [to me] ... oh well ...)  */

 void
 flonum_multip (const FLONUM_TYPE *a, const FLONUM_TYPE *b,
 	       FLONUM_TYPE *product)
 {
   int size_of_a;		/* 0 origin  */
   int size_of_b;		/* 0 origin  */
   int size_of_product;		/* 0 origin  */
   int size_of_sum;		/* 0 origin  */
   int extra_product_positions;	/* 1 origin  */
   unsigned long work;
   unsigned long carry;
   long exponent;
   LITTLENUM_TYPE *q;
   long significant;		/* TRUE when we emit a non-0 littlenum  */
   /* ForTran accent follows.  */
   int P;			/* Scan product low-order -> high.  */
   int N;			/* As in sum above.  */
   int A;			/* Which [] of a?  */
   int B;			/* Which [] of b?  */

   if ((a->sign != '-' && a->sign != '+')
       || (b->sign != '-' && b->sign != '+'))
     {
       /* Got to fail somehow.  Any suggestions?  */
       product->sign = 0;
       return;
     }
   product->sign = (a->sign == b->sign) ? '+' : '-';
   size_of_a = a->leader - a->low;
   size_of_b = b->leader - b->low;
   exponent = a->exponent + b->exponent;
   size_of_product = product->high - product->low;
   size_of_sum = size_of_a + size_of_b;
   extra_product_positions = size_of_product - size_of_sum;
   if (extra_product_positions < 0)
     {
       P = extra_product_positions;	/* P < 0  */
       exponent -= extra_product_positions;	/* Increases exponent.  */
     }
   else
     {
       P = 0;
     }
   carry = 0;
   significant = 0;
   for (N = 0; N <= size_of_sum; N++)
     {
       work = carry;
       carry = 0;
       for (A = 0; A <= N; A++)
 	{
 	  B = N - A;
 	  if (A <= size_of_a && B <= size_of_b && B >= 0)
 	    {
 #ifdef TRACE
 	      printf ("a:low[%d.]=%04x b:low[%d.]=%04x work_before=%08x\n",
 		      A, a->low[A], B, b->low[B], work);
 #endif
 	      /* Watch out for sign extension!  Without the casts, on
 		 the DEC Alpha, the multiplication result is *signed*
 		 int, which gets sign-extended to convert to the
 		 unsigned long!  */
 	      work += (unsigned long) a->low[A] * (unsigned long) b->low[B];
 	      carry += work >> LITTLENUM_NUMBER_OF_BITS;
 	      work &= LITTLENUM_MASK;
 #ifdef TRACE
 	      printf ("work=%08x carry=%04x\n", work, carry);
 #endif
 	    }
 	}
       significant |= work;
       if (significant || P < 0)
 	{
 	  if (P >= 0)
 	    {
 	      product->low[P] = work;
 #ifdef TRACE
 	      printf ("P=%d. work[p]:=%04x\n", P, work);
 #endif
 	    }
 	  P++;
 	}
       else
 	{
 	  extra_product_positions++;
 	  exponent++;
 	}
     }
   /* [P]-> position # size_of_sum + 1.
      This is where 'carry' should go.  */
 #ifdef TRACE
   printf ("final carry =%04x\n", carry);
 #endif
   if (carry)
     {
       if (extra_product_positions > 0)
 	product->low[P] = carry;
       else
 	{
 	  /* No room at high order for carry littlenum.  */
 	  /* Shift right 1 to make room for most significant littlenum.  */
 	  exponent++;
 	  P--;
 	  for (q = product->low + P; q >= product->low; q--)
 	    {
 	      work = *q;
 	      *q = carry;
 	      carry = work;
 	    }
 	}
     }
   else
     P--;
   product->leader = product->low + P;
   product->exponent = exponent;
 }
	/* flonum_mult.c - multiply two flonums
	Copyright (C) 1987-2016 Free Software Foundation, Inc.

	This file is part of GAS, the GNU Assembler.

	GAS 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 3, or (at your option)
	any later version.

	GAS 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 GAS; see the file COPYING. If not, write to the Free
	Software Foundation, 51 Franklin Street - Fifth Floor, Boston, MA
	02110-1301, USA. */

	#include "ansidecl.h"
	#include "flonum.h"

	/* plan for a . b => p(roduct)

	+-------+-------+-/ /-+-------+-------+
	\| a \| a \| ... \| a \| a \|
	\| A \| A-1 \| \| 1 \| 0 \|
	+-------+-------+-/ /-+-------+-------+

	+-------+-------+-/ /-+-------+-------+
	\| b \| b \| ... \| b \| b \|
	\| B \| B-1 \| \| 1 \| 0 \|
	+-------+-------+-/ /-+-------+-------+

	+-------+-------+-/ /-+-------+-/ /-+-------+-------+
	\| p \| p \| ... \| p \| ... \| p \| p \|
	\| A+B+1\| A+B \| \| N \| \| 1 \| 0 \|
	+-------+-------+-/ /-+-------+-/ /-+-------+-------+

	/^\
	(carry) a .b ... \| ... a .b a .b
	A B \| 0 1 0 0
	\|
	... \| ... a .b
	\| 1 0
	\|
	\| ...
	\|
	\|
	\|
	\| ___
	\| \
	+----- P = > a .b
	N /__ i j

	N = 0 ... A+B

	for all i,j where i+j=N
	[i,j integers > 0]

	a[], b[], p[] may not intersect.
	Zero length factors signify 0 significant bits: treat as 0.0.
	0.0 factors do the right thing.
	Zero length product OK.

	I chose the ForTran accent "foo[bar]" instead of the C accent "*garply"
	because I felt the ForTran way was more intuitive. The C way would
	probably yield better code on most C compilers. Dean Elsner.
	(C style also gives deeper insight [to me] ... oh well ...) */

	void
	flonum_multip (const FLONUM_TYPE a, const FLONUM_TYPE b,
	FLONUM_TYPE *product)
	{
	int size_of_a; /* 0 origin */
	int size_of_b; /* 0 origin */
	int size_of_product; /* 0 origin */
	int size_of_sum; /* 0 origin */
	int extra_product_positions; /* 1 origin */
	unsigned long work;
	unsigned long carry;
	long exponent;
	LITTLENUM_TYPE *q;
	long significant; /* TRUE when we emit a non-0 littlenum */
	/* ForTran accent follows. */
	int P; /* Scan product low-order -> high. */
	int N; /* As in sum above. */
	int A; /* Which [] of a? */
	int B; /* Which [] of b? */

	if ((a->sign != '-' && a->sign != '+')
	\|\| (b->sign != '-' && b->sign != '+'))
	{
	/* Got to fail somehow. Any suggestions? */
	product->sign = 0;
	return;
	}
	product->sign = (a->sign == b->sign) ? '+' : '-';
	size_of_a = a->leader - a->low;
	size_of_b = b->leader - b->low;
	exponent = a->exponent + b->exponent;
	size_of_product = product->high - product->low;
	size_of_sum = size_of_a + size_of_b;
	extra_product_positions = size_of_product - size_of_sum;
	if (extra_product_positions < 0)
	{
	P = extra_product_positions; /* P < 0 */
	exponent -= extra_product_positions; /* Increases exponent. */
	}
	else
	{
	P = 0;
	}
	carry = 0;
	significant = 0;
	for (N = 0; N <= size_of_sum; N++)
	{
	work = carry;
	carry = 0;
	for (A = 0; A <= N; A++)
	{
	B = N - A;
	if (A <= size_of_a && B <= size_of_b && B >= 0)
	{
	#ifdef TRACE
	printf ("a:low[%d.]=%04x b:low[%d.]=%04x work_before=%08x\n",
	A, a->low[A], B, b->low[B], work);
	#endif
	/* Watch out for sign extension! Without the casts, on
	the DEC Alpha, the multiplication result is signed
	int, which gets sign-extended to convert to the
	unsigned long! */
	work += (unsigned long) a->low[A] * (unsigned long) b->low[B];
	carry += work >> LITTLENUM_NUMBER_OF_BITS;
	work &= LITTLENUM_MASK;
	#ifdef TRACE
	printf ("work=%08x carry=%04x\n", work, carry);
	#endif
	}
	}
	significant \|= work;
	if (significant \|\| P < 0)
	{
	if (P >= 0)
	{
	product->low[P] = work;
	#ifdef TRACE
	printf ("P=%d. work[p]:=%04x\n", P, work);
	#endif
	}
	P++;
	}
	else
	{
	extra_product_positions++;
	exponent++;
	}
	}
	/* [P]-> position # size_of_sum + 1.
	This is where 'carry' should go. */
	#ifdef TRACE
	printf ("final carry =%04x\n", carry);
	#endif
	if (carry)
	{
	if (extra_product_positions > 0)
	product->low[P] = carry;
	else
	{
	/* No room at high order for carry littlenum. */
	/* Shift right 1 to make room for most significant littlenum. */
	exponent++;
	P--;
	for (q = product->low + P; q >= product->low; q--)
	{
	work = *q;
	*q = carry;
	carry = work;
	}
	}
	}
	else
	P--;
	product->leader = product->low + P;
	product->exponent = exponent;
	}