[unix-history] / gnu / usr.bin / as / flonum-mult.c

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

This file is part of Gas, the GNU Assembler.

The GNU assembler is distributed in the hope that it will be
useful, but WITHOUT ANY WARRANTY.  No author or distributor
accepts responsibility to anyone for the consequences of using it
or for whether it serves any particular purpose or works at all,
unless he says so in writing.  Refer to the GNU Assembler General
Public License for full details.

Everyone is granted permission to copy, modify and redistribute
the GNU Assembler, but only under the conditions described in the
GNU Assembler General Public License.  A copy of this license is
supposed to have been given to you along with the GNU Assembler
so you can know your rights and responsibilities.  It should be
in a file named COPYING.  Among other things, the copyright
notice and this notice must be preserved on all copies.  */

#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 ...)
*/
\f
void
flonum_multip (a, b, product)
     FLONUM_TYPE *	a,
		 *	b,
		 *	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 int	work;
  unsigned long int	carry;
  long int		exponent;
  LITTLENUM_TYPE *	q;
  long int		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
	      work += a -> low [A]   *   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;
}

/* end: flonum_multip.c */
Commit	Line	Data
7b374118 NW	1	/* flonum_multip.c - multiply two flonums
	2	Copyright (C) 1987 Free Software Foundation, Inc.
	3
	4	This file is part of Gas, the GNU Assembler.
	5
	6	The GNU assembler is distributed in the hope that it will be
	7	useful, but WITHOUT ANY WARRANTY. No author or distributor
	8	accepts responsibility to anyone for the consequences of using it
	9	or for whether it serves any particular purpose or works at all,
	10	unless he says so in writing. Refer to the GNU Assembler General
	11	Public License for full details.
	12
	13	Everyone is granted permission to copy, modify and redistribute
	14	the GNU Assembler, but only under the conditions described in the
	15	GNU Assembler General Public License. A copy of this license is
	16	supposed to have been given to you along with the GNU Assembler
	17	so you can know your rights and responsibilities. It should be
	18	in a file named COPYING. Among other things, the copyright
	19	notice and this notice must be preserved on all copies. */
	20
	21	#include "flonum.h"
	22
	23	/* plan for a . b => p(roduct)
	24
	25
	26	+-------+-------+-/ /-+-------+-------+
	27	\| a \| a \| ... \| a \| a \|
	28	\| A \| A-1 \| \| 1 \| 0 \|
	29	+-------+-------+-/ /-+-------+-------+
	30
	31
	32	+-------+-------+-/ /-+-------+-------+
	33	\| b \| b \| ... \| b \| b \|
	34	\| B \| B-1 \| \| 1 \| 0 \|
	35	+-------+-------+-/ /-+-------+-------+
	36
	37
	38	+-------+-------+-/ /-+-------+-/ /-+-------+-------+
	39	\| p \| p \| ... \| p \| ... \| p \| p \|
	40	\| A+B+1\| A+B \| \| N \| \| 1 \| 0 \|
	41	+-------+-------+-/ /-+-------+-/ /-+-------+-------+
	42
	43	/^\
	44	(carry) a .b ... \| ... a .b a .b
	45	A B \| 0 1 0 0
	46	\|
	47	... \| ... a .b
	48	\| 1 0
	49	\|
	50	\| ...
	51	\|
	52	\|
	53	\|
	54	\| ___
	55	\| \
	56	+----- P = > a .b
	57	N /__ i j
	58
	59	N = 0 ... A+B
	60
	61	for all i,j where i+j=N
	62	[i,j integers > 0]
	63
	64	a[], b[], p[] may not intersect.
65	Zero length factors signify 0 significant bits: treat as 0.0.
66	0.0 factors do the right thing.
67	Zero length product OK.
68
69	I chose the ForTran accent "foo[bar]" instead of the C accent "*garply"
70	because I felt the ForTran way was more intuitive. The C way would
71	probably yield better code on most C compilers. Dean Elsner.
72	(C style also gives deeper insight [to me] ... oh well ...)
73	*/
74	\f
75	void
76	flonum_multip (a, b, product)
77	FLONUM_TYPE * a,
78	* b,
79	* product;
80	{
81	int size_of_a; /* 0 origin */
82	int size_of_b; /* 0 origin */
83	int size_of_product; /* 0 origin */
84	int size_of_sum; /* 0 origin */
85	int extra_product_positions;/* 1 origin */
86	unsigned long int work;
87	unsigned long int carry;
88	long int exponent;
89	LITTLENUM_TYPE * q;
90	long int significant; /* TRUE when we emit a non-0 littlenum */
91	/* ForTran accent follows. */
92	int P; /* Scan product low-order -> high. */
93	int N; /* As in sum above. */
94	int A; /* Which [] of a? */
95	int B; /* Which [] of b? */
96
97	if((a->sign!='-' && a->sign!='+') \|\| (b->sign!='-' && b->sign!='+')) {
98	/* ...
99	Got to fail somehow. Any suggestions? */
100	product->sign=0;
101	return;
102	}
103	product -> sign = (a->sign == b->sign) ? '+' : '-';
104	size_of_a = a -> leader - a -> low;
105	size_of_b = b -> leader - b -> low;
106	exponent = a -> exponent + b -> exponent;
107	size_of_product = product -> high - product -> low;
108	size_of_sum = size_of_a + size_of_b;
109	extra_product_positions = size_of_product - size_of_sum;
110	if (extra_product_positions < 0)
111	{
112	P = extra_product_positions; /* P < 0 */
113	exponent -= extra_product_positions; /* Increases exponent. */
114	}
115	else
116	{
117	P = 0;
118	}
119	carry = 0;
120	significant = 0;
121	for (N = 0;
122	N <= size_of_sum;
123	N++)
124	{
125	work = carry;
126	carry = 0;
127	for (A = 0;
128	A <= N;
129	A ++)
130	{
131	B = N - A;
132	if (A <= size_of_a && B <= size_of_b && B >= 0)
133	{
134	#ifdef TRACE
135	printf("a:low[%d.]=%04x b:low[%d.]=%04x work_before=%08x\n", A, a->low[A], B, b->low[B], work);
136	#endif
137	work += a -> low [A] * b -> low [B];
138	carry += work >> LITTLENUM_NUMBER_OF_BITS;
139	work &= LITTLENUM_MASK;
140	#ifdef TRACE
141	printf("work=%08x carry=%04x\n", work, carry);
142	#endif
143	}
144	}
145	significant \|= work;
146	if (significant \|\| P<0)
147	{
148	if (P >= 0)
149	{
150	product -> low [P] = work;
151	#ifdef TRACE
152	printf("P=%d. work[p]:=%04x\n", P, work);
153	#endif
154	}
155	P ++;
156	}
157	else
158	{
159	extra_product_positions ++;
160	exponent ++;
161	}
162	}
163	/*
164	* [P]-> position # size_of_sum + 1.
165	* This is where 'carry' should go.
166	*/
167	#ifdef TRACE
168	printf("final carry =%04x\n", carry);
169	#endif
170	if (carry)
171	{
172	if (extra_product_positions > 0)
173	{
174	product -> low [P] = carry;
175	}
176	else
177	{
178	/* No room at high order for carry littlenum. */
179	/* Shift right 1 to make room for most significant littlenum. */
180	exponent ++;
181	P --;
182	for (q = product -> low + P;
183	q >= product -> low;
184	q --)
185	{
186	work = * q;
187	* q = carry;
188	carry = work;
189	}
190	}
191	}
192	else
193	{
194	P --;
195	}
196	product -> leader = product -> low + P;
197	product -> exponent = exponent;
198	}
199
200	/* end: flonum_multip.c */