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/* pdp10_mdfp.c: PDP-10 multiply/divide and floating point simulator
Copyright (c) 1993-2001, Robert M Supnik
Permission is hereby granted, free of charge, to any person obtaining a
copy of this software and associated documentation files (the "Software"),
to deal in the Software without restriction, including without limitation
the rights to use, copy, modify, merge, publish, distribute, sublicense,
and/or sell copies of the Software, and to permit persons to whom the
Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
Except as contained in this notice, the name of Robert M Supnik shall not
be used in advertising or otherwise to promote the sale, use or other dealings
in this Software without prior written authorization from Robert M Supnik.
Instructions handled in this module:
imul integer multiply
idiv integer divide
mul multiply
div divide
dmul double precision multiply
ddiv double precision divide
fad(r) floating add (and round)
fsb(r) floating subtract (and round)
fmp(r) floating multiply (and round)
fdv(r) floating divide and round
fsc floating scale
fix(r) floating to fixed (and round)
fltr fixed to floating and round
dfad double precision floating add/subtract
dfmp double precision floating multiply
dfdv double precision floating divide
The PDP-10 stores double (quad) precision integers in sequential
AC's or memory locations. Integers are stored in 2's complement
form. Only the sign of the high order word matters; the signs
in low order words are ignored on input and set to the sign of
the result on output. Quad precision integers exist only in the
AC's as the result of a DMUL or the dividend of a DDIV.
0 00000000011111111112222222222333333
0 12345678901234567890123456789012345
+-+-----------------------------------+
|S| high order integer | AC(n), A
+-+-----------------------------------+
|S| low order integer | AC(n + 1), A + 1
+-+-----------------------------------+
|S| low order integer | AC(n + 2)
+-+-----------------------------------+
|S| low order integer | AC(n + 3)
+-+-----------------------------------+
The PDP-10 supports two floating point formats: single and double
precision. In both, the exponent is 8 bits, stored in excess
128 notation. The fraction is expected to be normalized. A
single precision floating point number has 27 bits of fraction;
a double precision number has 62 bits of fraction (the sign
bit of the second word is ignored and is set to zero).
In a negative floating point number, the exponent is stored in
one's complement form, the fraction in two's complement form.
0 00000000 011111111112222222222333333
0 12345678 901234567890123456789012345
+-+--------+---------------------------+
|S|exponent| high order fraction | AC(n), A
+-+--------+---------------------------+
|0| low order fraction | AC(n + 1), A + 1
+-+------------------------------------+
Note that treatment of the sign is different for double precision
integers and double precision floating point. DMOVN (implemented
as an inline macro) follows floating point conventions.
The original PDP-10 CPU (KA10) used a different format for double
precision numbers and included certain instructions to make
software support easier. These instructions were phased out in
the KL10 and KS10 and are treated as MUUO's.
The KL10 added extended precision (11-bit exponent) floating point
format (so-called G floating). These instructions were not
implemented in the KS10 and are treated as MUUO's.
31-Aug-01 RMS Changed int64 to t_int64 for Windoze
10-Aug-01 RMS Removed register in declarations
*/
#include "pdp10_defs.h"
#include <setjmp.h>
struct ufp { /* unpacked fp number */
int32 sign; /* sign */
int32 exp; /* exponent */
t_uint64 fhi; /* fraction high */
t_uint64 flo; }; /* for double prec */
typedef struct ufp UFP;
#define MSK32 0xFFFFFFFF
#define FIT27 (DMASK - 0x07FFFFFF)
#define FIT32 (DMASK - MSK32)
#define SFRC TRUE /* frac 2's comp */
#define AFRC FALSE /* frac abs value */
/* In packed floating point number */
#define FP_BIAS 0200 /* exponent bias */
#define FP_N_FHI 27 /* # of hi frac bits */
#define FP_V_FHI 0 /* must be zero */
#define FP_M_FHI 0000777777777
#define FP_N_EXP 8 /* # of exp bits */
#define FP_V_EXP (FP_V_FHI + FP_N_FHI)
#define FP_M_EXP 0377
#define FP_V_SIGN (FP_V_EXP + FP_N_EXP) /* sign */
#define FP_N_FLO 35 /* # of lo frac bits */
#define FP_V_FLO 0 /* must be zero */
#define FP_M_FLO 0377777777777
#define GET_FPSIGN(x) ((int32) (((x) >> FP_V_SIGN) & 1))
#define GET_FPEXP(x) ((int32) (((x) >> FP_V_EXP) & FP_M_EXP))
#define GET_FPHI(x) ((x) & FP_M_FHI)
#define GET_FPLO(x) ((x) & FP_M_FLO)
/* In unpacked floating point number */
#define FP_N_GUARD 1 /* # of guard bits */
#define FP_V_UFLO FP_N_GUARD /* <35:1> */
#define FP_V_URNDD (FP_V_UFLO - 1) /* dp round bit */
#define FP_V_UFHI (FP_V_UFLO + FP_N_FLO) /* <62:36> */
#define FP_V_URNDS (FP_V_UFHI - 1) /* sp round bit */
#define FP_V_UCRY (FP_V_UFHI + FP_N_FHI) /* <63> */
#define FP_V_UNORM (FP_V_UCRY - 1) /* normalized bit */
#define FP_UFHI 0x7FFFFFF000000000
#define FP_UFLO 0x0000000FFFFFFFFE
#define FP_UFRAC 0x7FFFFFFFFFFFFFFE
#define FP_URNDD 0x0000000000000001
#define FP_URNDS 0x0000000800000000
#define FP_UNORM 0x4000000000000000
#define FP_UCRY 0x8000000000000000
#define FP_ONES 0xFFFFFFFFFFFFFFFF
#define UNEG(x) ((~x) + 1)
#define DUNEG(x) x.flo = UNEG (x.flo); x.fhi = ~x.fhi + (x.flo == 0)
extern d10 *ac_cur; /* current AC block */
extern int32 flags; /* flags */
void mul (d10 a, d10 b, d10 *rs);
void funpack (d10 h, d10 l, UFP *r, t_bool sgn);
void fnorm (UFP *r, t_int64 rnd);
d10 fpack (UFP *r, d10 *lo, t_bool fdvneg);
/* Integer multiply - checked against KS-10 ucode */
d10 imul (d10 a, d10 b)
{
d10 rs[2];
if ((a == SIGN) && (b == SIGN)) { /* KS10 hack */
SETF (F_AOV | F_T1); /* -2**35 squared */
return SIGN; }
mul (a, b, rs); /* mpy, dprec result */
if (rs[0] && (rs[0] != ONES)) { /* high not all sign? */
rs[1] = TSTS (a ^ b)? SETS (rs[1]): CLRS (rs[1]); /* set sign */
SETF (F_AOV | F_T1); } /* overflow */
return rs[1];
}
/* Integer divide, return quotient, remainder - checked against KS10 ucode
The KS10 does not recognize -2^35/-1 as an error. Instead, it produces
2^35 (that is, -2^35) as the incorrect result.
*/
t_bool idiv (d10 a, d10 b, d10 *rs)
{
d10 dvd = ABS (a); /* make ops positive */
d10 dvr = ABS (b);
if (dvr == 0) { /* divide by 0? */
SETF (F_DCK | F_AOV | F_T1); /* set flags, return */
return FALSE; }
rs[0] = dvd / dvr; /* get quotient */
rs[1] = dvd % dvr; /* get remainder */
if (TSTS (a ^ b)) rs[0] = NEG (rs[0]); /* sign of result */
if (TSTS (a)) rs[1] = NEG (rs[1]); /* sign of remainder */
return TRUE;
}
/* Multiply, return double precision result - checked against KS10 ucode */
void mul (d10 s1, d10 s2, d10 *rs)
{
t_uint64 a = ABS (s1);
t_uint64 b = ABS (s2);
t_uint64 t, u, r;
if ((a == 0) || (b == 0)) { /* operand = 0? */
rs[0] = rs[1] = 0; /* result 0 */
return; }
if ((a & FIT32) || (b & FIT32)) { /* fit in 64b? */
t = a >> 18; /* no, split in half */
a = a & RMASK; /* "dp" multiply */
u = b >> 18;
b = b & RMASK;
r = (a * b) + (((a * u) + (b * t)) << 18); /* low is only 35b */
rs[0] = ((t * u) << 1) + (r >> 35); /* so lsh hi 1 */
rs[1] = r & MMASK; }
else { r = a * b; /* fits, native mpy */
rs[0] = r >> 35; /* split at bit 35 */
rs[1] = r & MMASK; }
if (TSTS (s1 ^ s2)) { MKDNEG (rs); } /* result -? */
else if (TSTS (rs[0])) { /* result +, 2**70? */
SETF (F_AOV | F_T1); /* overflow */
rs[1] = SETS (rs[1]); } /* consistent - */
return;
}
/* Divide, return quotient and remainder - checked against KS10 ucode
Note that the initial divide check catches the case -2^70/-2^35;
thus, the quotient can have at most 35 bits.
*/
t_bool divi (int32 ac, d10 b, d10 *rs)
{
int32 p1 = ADDAC (ac, 1);
d10 dvr = ABS (b); /* make divr positive */
t_int64 t;
int32 i;
d10 dvd[2];
dvd[0] = AC(ac); /* divd high */
dvd[1] = CLRS (AC(p1)); /* divd lo, clr sgn */
if (TSTS (AC(ac))) { DMOVN (dvd); } /* make divd positive */
if (dvd[0] >= dvr) { /* divide fail? */
SETF (F_AOV | F_DCK | F_T1); /* set flags, return */
return FALSE; }
if (dvd[0] & FIT27) { /* fit in 63b? */
for (i = 0, rs[0] = 0; i < 35; i++) { /* 35 quotient bits */
dvd[0] = (dvd[0] << 1) | ((dvd[1] >> 34) & 1);
dvd[1] = (dvd[1] << 1) & MMASK; /* shift dividend */
rs[0] = rs[0] << 1; /* shift quotient */
if (dvd[0] >= dvr) { /* subtract work? */
dvd[0] = dvd[0] - dvr; /* quo bit is 1 */
rs[0] = rs[0] + 1; } }
rs[1] = dvd[0]; } /* store remainder */
else { t = (dvd[0] << 35) | dvd[1]; /* concatenate */
rs[0] = t / dvr; /* quotient */
rs[1] = t % dvr; } /* remainder */
if (TSTS (AC(ac) ^ b)) rs[0] = NEG (rs[0]); /* sign of result */
if (TSTS (AC(ac))) rs[1] = NEG (rs[1]); /* sign of remainder */
return TRUE;
}
/* Double precision multiply. This is done the old fashioned way. Cross
product multiplies would be a lot faster but would require more code.
*/
void dmul (int32 ac, d10 *mpy)
{
int32 p1 = ADDAC (ac, 1);
int32 p2 = ADDAC (ac, 2);
int32 p3 = ADDAC (ac, 3);
int32 i;
d10 mpc[2], sign;
mpc[0] = AC(ac); /* mplcnd hi */
mpc[1] = CLRS (AC(p1)); /* mplcnd lo, clr sgn */
sign = mpc[0] ^ mpy[0]; /* sign of result */
if (TSTS (mpc[0])) { DMOVN (mpc); } /* get abs (mpcnd) */
if (TSTS (mpy[0])) { DMOVN (mpy); } /* get abs (mpyer) */
else mpy[1] = CLRS (mpy[1]); /* clear mpy lo sign */
AC(ac) = AC(p1) = AC(p2) = AC(p3) = 0; /* clear AC's */
if (((mpy[0] | mpy[1]) == 0) || ((mpc[0] | mpc[1]) == 0)) return;
for (i = 0; i < 71; i++) { /* 71 mpyer bits */
if (i) { /* shift res, mpy */
AC(p3) = (AC(p3) >> 1) | ((AC(p2) & 1) << 34);
AC(p2) = (AC(p2) >> 1) | ((AC(p1) & 1) << 34);
AC(p1) = (AC(p1) >> 1) | ((AC(ac) & 1) << 34);
AC(ac) = AC(ac) >> 1;
mpy[1] = (mpy[1] >> 1) | ((mpy[0] & 1) << 34);
mpy[0] = mpy[0] >> 1; }
if (mpy[1] & 1) { /* if mpy lo bit = 1 */
AC(p1) = AC(p1) + mpc[1];
AC(ac) = AC(ac) + mpc[0] + (TSTS (AC(p1) != 0));
AC(p1) = CLRS (AC(p1)); } }
if (TSTS (sign)) { /* result minus? */
AC(p3) = (-AC(p3)) & MMASK; /* quad negate */
AC(p2) = (~AC(p2) + (AC(p3) == 0)) & MMASK;
AC(p1) = (~AC(p1) + (AC(p2) == 0)) & MMASK;
AC(ac) = (~AC(ac) + (AC(p1) == 0)) & DMASK; }
else if (TSTS (AC(ac))) SETF (F_AOV | F_T1); /* wrong sign */
if (TSTS (AC(ac))) { /* if result - */
AC(p1) = SETS (AC(p1)); /* make signs consistent */
AC(p2) = SETS (AC(p2));
AC(p3) = SETS (AC(p3)); }
return;
}
/* Double precision divide - checked against KS10 ucode */
void ddiv (int32 ac, d10 *dvr)
{
int32 i, cryin;
d10 sign, qu[2], dvd[4];
dvd[0] = AC(ac); /* save dividend */
for (i = 1; i < 4; i++) dvd[i] = CLRS (AC(ADDAC (ac, i)));
sign = AC(ac) ^ dvr[0]; /* sign of result */
if (TSTS (AC(ac))) { /* get abs (dividend) */
for (i = 3, cryin = 1; i > 0; i--) { /* negate quad */
dvd[i] = (~dvd[i] + cryin) & MMASK; /* comp + carry in */
if (dvd[i]) cryin = 0; } /* next carry in */
dvd[0] = (~dvd[0] + cryin) & DMASK; }
if (TSTS (dvr[0])) { DMOVN (dvr); } /* get abs (divisor) */
else dvr[1] = CLRS (dvr[1]);
if (DCMPGE (dvd, dvr)) { /* will divide work? */
SETF (F_AOV | F_DCK | F_T1); /* no, set flags */
return; }
qu[0] = qu[1] = 0; /* clear quotient */
for (i = 0; i < 70; i++) { /* 70 quotient bits */
dvd[0] = ((dvd[0] << 1) | ((dvd[1] >> 34) & 1)) & DMASK;;
dvd[1] = ((dvd[1] << 1) | ((dvd[2] >> 34) & 1)) & MMASK;
dvd[2] = ((dvd[2] << 1) | ((dvd[3] >> 34) & 1)) & MMASK;
dvd[3] = (dvd[3] << 1) & MMASK; /* shift dividend */
qu[0] = (qu[0] << 1) | ((qu[1] >> 34) & 1); /* shift quotient */
qu[1] = (qu[1] << 1) & MMASK;
if (DCMPGE (dvd, dvr)) { /* subtract work? */
dvd[0] = dvd[0] - dvr[0] - (dvd[1] < dvr[1]);
dvd[1] = (dvd[1] - dvr[1]) & MMASK; /* do subtract */
qu[1] = qu[1] + 1; } } /* set quotient bit */
if (TSTS (sign) && (qu[0] | qu[1])) { MKDNEG (qu); }
if (TSTS (AC(ac)) && (dvd[0] | dvd[1])) { MKDNEG (dvd); }
AC(ac) = qu[0]; /* quotient */
AC(ADDAC(ac, 1)) = qu[1];
AC(ADDAC(ac, 2)) = dvd[0]; /* remainder */
AC(ADDAC(ac, 3)) = dvd[1];
return;
}
/* Single precision floating add - checked against KS10 ucode
The KS10 shifts the smaller operand regardless of the exponent diff.
This code will not shift more than 63 places; shifts beyond that
cannot change the value of the smaller operand.
If the signs of the operands are the same, the result sign is the
same as the source sign; the sign of the result fraction is actually
part of the data. If the signs of the operands are different, the
result sign is determined by the fraction sign.
*/
d10 fad (d10 op1, d10 op2, t_bool rnd, int32 inv)
{
int32 ediff;
UFP a, b, t;
if (inv) op2 = NEG (op2); /* subtract? -b */
if (op1 == 0) funpack (op2, 0, &a, AFRC); /* a = 0? result is b */
else if (op2 == 0) funpack (op1, 0, &a, AFRC); /* b = 0? result is a */
else { funpack (op1, 0, &a, SFRC); /* unpack operands */
funpack (op2, 0, &b, SFRC); /* fracs are 2's comp */
ediff = a.exp - b.exp; /* get exp diff */
if (ediff < 0) { /* a < b? switch */
t = a;
a = b;
b = t;
ediff = -ediff; }
if (ediff > 63) ediff = 63; /* cap diff at 63 */
if (ediff) b.fhi = (t_int64) b.fhi >> ediff; /* shift b (signed) */
a.fhi = a.fhi + b.fhi; /* add fractions */
if (a.sign ^ b.sign) { /* add or subtract? */
if (a.fhi & FP_UCRY) { /* subtract, frac -? */
a.fhi = UNEG (a.fhi); /* complement result */
a.sign = 1; } /* result is - */
else a.sign = 0; } /* result is + */
else { if (a.sign) a.fhi = UNEG (a.fhi); /* add, src -? comp */
if (a.fhi & FP_UCRY) { /* check for carry */
a.fhi = a.fhi >> 1; /* flo won't be used */
a.exp = a.exp + 1; } } }
fnorm (&a, (rnd? FP_URNDS: 0)); /* normalize, round */
return fpack (&a, NULL, FALSE);
}
/* Single precision floating multiply. Because the fractions are 27b,
a 64b multiply can be used for the fraction multiply. The 27b
fractions are positioned 0'frac'0000, resulting in 00'hifrac'0..0.
The extra 0 is accounted for by biasing the result exponent.
*/
#define FP_V_SPM (FP_V_UFHI - (32 - FP_N_FHI - 1))
d10 fmp (d10 op1, d10 op2, t_bool rnd)
{
UFP a, b;
funpack (op1, 0, &a, AFRC); /* unpack operands */
funpack (op2, 0, &b, AFRC); /* fracs are abs val */
if ((a.fhi == 0) || (b.fhi == 0)) return 0; /* either 0? */
a.sign = a.sign ^ b.sign; /* result sign */
a.exp = a.exp + b.exp - FP_BIAS + 1; /* result exponent */
a.fhi = (a.fhi >> FP_V_SPM) * (b.fhi >> FP_V_SPM); /* high 27b of result */
fnorm (&a, (rnd? FP_URNDS: 0)); /* normalize, round */
return fpack (&a, NULL, FALSE);
}
/* Single precision floating divide. Because the fractions are 27b, a
64b divide can be used for the fraction divide. Note that 28b-29b
of fraction are developed; the code will do one special normalize to
make sure that the 28th bit is not lost. Also note the special
treatment of negative quotients with non-zero remainders; this
implements the note on p2-23 of the Processor Reference Manual.
*/
t_bool fdv (d10 op1, d10 op2, d10 *rs, t_bool rnd)
{
UFP a, b;
t_uint64 savhi;
t_bool rem = FALSE;
funpack (op1, 0, &a, AFRC); /* unpack operands */
funpack (op2, 0, &b, AFRC); /* fracs are abs val */
if (a.fhi >= 2 * b.fhi) { /* will divide work? */
SETF (F_AOV | F_DCK | F_FOV | F_T1);
return FALSE; }
if (savhi = a.fhi) { /* dvd = 0? quo = 0 */
a.sign = a.sign ^ b.sign; /* result sign */
a.exp = a.exp - b.exp + FP_BIAS + 1; /* result exponent */
a.fhi = a.fhi / (b.fhi >> (FP_N_FHI + 1)); /* do divide */
if (a.sign && (savhi != (a.fhi * (b.fhi >> (FP_N_FHI + 1)))))
rem = TRUE; /* KL/KS hack */
a.fhi = a.fhi << (FP_V_UNORM - FP_N_FHI - 1); /* put quo in place */
if ((a.fhi & FP_UNORM) == 0) { /* normalize 1b */
a.fhi = a.fhi << 1; /* before masking */
a.exp = a.exp - 1; }
a.fhi = a.fhi & (FP_UFHI | FP_URNDS); } /* mask quo to 28b */
fnorm (&a, (rnd? FP_URNDS: 0)); /* normalize, round */
*rs = fpack (&a, NULL, rem); /* pack result */
return TRUE;
}
/* Single precision floating scale. */
d10 fsc (d10 val, a10 ea)
{
int32 sc = LIT8 (ea);
UFP a;
if (val == 0) return 0;
funpack (val, 0, &a, AFRC); /* unpack operand */
if (ea & RSIGN) a.exp = a.exp - sc; /* adjust exponent */
else a.exp = a.exp + sc;
fnorm (&a, 0); /* renormalize */
return fpack (&a, NULL, FALSE); /* pack result */
}
/* Float integer operand and round */
d10 fltr (d10 mb)
{
UFP a;
d10 val = ABS (mb);
a.sign = GET_FPSIGN (mb); /* get sign */
a.exp = FP_BIAS + 36; /* initial exponent */
a.fhi = val << (FP_V_UNORM - 35); /* left justify op */
a.flo = 0;
fnorm (&a, FP_URNDS); /* normalize, round */
return fpack (&a, NULL, FALSE); /* pack result */
}
/* Fix and truncate/round floating operand */
void fix (int32 ac, d10 mb, t_bool rnd)
{
int32 sc;
t_uint64 so;
UFP a;
funpack (mb, 0, &a, AFRC); /* unpack operand */
if (a.exp > (FP_BIAS + FP_N_FHI + FP_N_EXP)) SETF (F_AOV | F_T1);
else if (a.exp < (FP_BIAS - 1)) AC(ac) = 0;
else { sc = FP_V_UNORM - (a.exp - FP_BIAS) + 1;
AC(ac) = a.fhi >> sc;
if (rnd) {
so = a.fhi << (64 - sc);
if (so >= (0x8000000000000000 + a.sign)) AC(ac) = AC(ac) + 1; }
if (a.sign) AC(ac) = NEG (AC(ac)); }
return;
}
/* Double precision floating add/subtract
Since a.flo is 0, adding b.flo is just a copy - this is incorporated into
the denormalization step. If there's no denormalization, bflo is zero too.
*/
void dfad (int32 ac, d10 *rs, int32 inv)
{
int32 p1 = ADDAC (ac, 1);
int32 ediff;
UFP a, b, t;
if (inv) { DMOVN (rs); } /* subtract? -b */
if ((AC(ac) | AC(p1)) == 0) funpack (rs[0], rs[1], &a, AFRC);
/* a == 0? sum = b */
else if ((rs[0] | rs[1]) == 0) funpack (AC(ac), AC(p1), &a, AFRC);
/* b == 0? sum = a */
else {
funpack (AC(ac), AC(p1), &a, SFRC); /* unpack operands */
funpack (rs[0], rs[1], &b, SFRC);
ediff = a.exp - b.exp; /* get exp diff */
if (ediff < 0) { /* a < b? switch */
t = a;
a = b;
b = t;
ediff = -ediff; }
if (ediff > 127) ediff = 127; /* cap diff at 127 */
if (ediff > 63) { /* diff > 63? */
a.flo = (t_int64) b.fhi >> (ediff - 64); /* b hi to a lo */
b.fhi = b.sign? FP_ONES: 0; } /* hi = all sign */
else if (ediff) { /* diff <= 63 */
a.flo = (b.flo >> ediff) | (b.fhi << (64 - ediff));
b.fhi = (t_int64) b.fhi >> ediff; } /* shift b (signed) */
a.fhi = a.fhi + b.fhi; /* do add */
if (a.sign ^ b.sign) { /* add or subtract? */
if (a.fhi & FP_UCRY) { /* subtract, frac -? */
DUNEG (a); /* complement result */
a.sign = 1; } /* result is - */
else a.sign = 0; } /* result is + */
else { if (a.sign) { DUNEG (a); }; /* add, src -? comp */
if (a.fhi & FP_UCRY) { /* check for carry */
a.fhi = a.fhi >> 1; /* flo won't be used */
a.exp = a.exp + 1; } } }
fnorm (&a, FP_URNDD); /* normalize, round */
AC(ac) = fpack (&a, &AC(p1), FALSE); /* pack result */
return;
}
/* Double precision floating multiply
The 62b fractions are multiplied, with cross products, to produce a
124b fraction with two leading and two trailing 0's. Because the
product has 2 leading 0's, instead of the normal 1, an extra
normalization step is needed. Accordingly, the exponent calculation
increments the result exponent, to compensate for normalization.
*/
void dfmp (int32 ac, d10 *rs)
{
int32 p1 = ADDAC (ac, 1);
t_uint64 xh, xl, yh, yl, mid;
UFP a, b;
funpack (AC(ac), AC(p1), &a, AFRC); /* unpack operands */
funpack (rs[0], rs[1], &b, AFRC);
if ((a.fhi == 0) || (b.fhi == 0)) { /* either 0? result 0 */
AC(ac) = AC(p1) = 0;
return; }
a.sign = a.sign ^ b.sign; /* result sign */
a.exp = a.exp + b.exp - FP_BIAS + 1; /* result exponent */
xh = a.fhi >> 32; /* split 62b fracs */
xl = a.fhi & MSK32; /* into 32b halves */
yh = b.fhi >> 32;
yl = b.fhi & MSK32;
a.fhi = xh * yh; /* hi xproduct */
a.flo = xl * yl; /* low xproduct */
mid = (xh * yl) + (yh * xl); /* fits in 64b */
a.flo = a.flo + (mid << 32); /* add mid lo to lo */
a.fhi = a.fhi + ((mid >> 32) & MSK32) + (a.flo < (mid << 32));
fnorm (&a, FP_URNDD); /* normalize, round */
AC(ac) = fpack (&a, &AC(p1), FALSE); /* pack result */
return;
}
/* Double precision floating divide
This algorithm develops a full 62 bits of quotient, plus one rounding
bit, in the low order 63b of a 64b number. To do this, we must assure
that the initial divide step generates a 1. If it would fail, shift
the dividend left and decrement the result exponent accordingly.
*/
void dfdv (int32 ac, d10 *rs)
{
int32 p1 = ADDAC (ac, 1);
int32 i;
t_uint64 qu = 0;
UFP a, b;
funpack (AC(ac), AC(p1), &a, AFRC); /* unpack operands */
funpack (rs[0], rs[1], &b, AFRC);
if (a.fhi >= 2 * b.fhi) { /* will divide work? */
SETF (F_AOV | F_DCK | F_FOV | F_T1);
return; }
if (a.fhi) { /* dvd = 0? quo = 0 */
a.sign = a.sign ^ b.sign; /* result sign */
a.exp = a.exp - b.exp + FP_BIAS + 1; /* result exponent */
if (a.fhi < b.fhi) { /* make sure initial */
a.fhi = a.fhi << 1; /* divide step will work */
a.exp = a.exp - 1; }
for (i = 0; i < 63; i++) { /* 63b of quotient */
qu = qu << 1; /* shift quotient */
if (a.fhi >= b.fhi) { /* will div work? */
a.fhi = a.fhi - b.fhi; /* sub, quo = 1 */
qu = qu + 1; }
a.fhi = a.fhi << 1; } /* shift dividend */
a.fhi = qu; }
fnorm (&a, FP_URNDD); /* normalize, round */
AC(ac) = fpack (&a, &AC(p1), FALSE); /* pack result */
return;
}
/* Unpack floating point operand */
void funpack (d10 h, d10 l, UFP *r, t_bool sgn)
{
d10 fphi, fplo;
r -> sign = GET_FPSIGN (h);
r -> exp = GET_FPEXP (h);
fphi = GET_FPHI (h);
fplo = GET_FPLO (l);
r -> fhi = (fphi << FP_V_UFHI) | (fplo << FP_V_UFLO);
r -> flo = 0;
if (r -> sign) {
r -> exp = r -> exp ^ FP_M_EXP;
if (sgn) r -> fhi = r -> fhi | FP_UCRY; /* ext sign */
else { if (r -> fhi) r -> fhi = UNEG (r -> fhi) & FP_UFRAC;
else { r -> exp = r -> exp + 1;
r -> fhi = FP_UNORM; } } }
return;
}
/* Normalize and optionally round floating point operand */
void fnorm (UFP *a, t_int64 rnd)
{
int32 i;
static t_uint64 normmask[6] = {
0x6000000000000000, 0x7800000000000000, 0x7F80000000000000,
0x7FFF800000000000, 0x7FFFFFFF80000000, 0x7FFFFFFFFFFFFFFF };
static int32 normtab[7] = { 1, 2, 4, 8, 16, 32, 63 };
if ((a -> fhi | a -> flo) == 0) { /* if fraction = 0 */
a -> sign = a -> exp = 0; /* result is 0 */
return; }
while ((a -> fhi & FP_UNORM) == 0) { /* normalized? */
for (i = 0; i < 6; i++) {
if (a -> fhi & normmask[i]) break; }
a -> fhi = (a -> fhi << normtab[i]) | (a -> flo >> (64 - normtab[i]));
a -> flo = a -> flo << normtab[i];
a -> exp = a -> exp - normtab[i]; }
if (rnd) { /* rounding? */
a -> fhi = a -> fhi + rnd; /* add round const */
if (a -> fhi & FP_UCRY) { /* if carry out, */
a -> fhi = a -> fhi >> 1; /* renormalize */
a -> exp = a -> exp + 1; } }
return;
}
/* Pack floating point result */
d10 fpack (UFP *r, d10 *lo, t_bool fdvneg)
{
d10 val[2];
if (r -> exp < 0) SETF (F_AOV | F_FOV | F_FXU | F_T1);
else if (r -> exp > FP_M_EXP) SETF (F_AOV | F_FOV | F_T1);
val[0] = (((((d10) r -> exp) & FP_M_EXP) << FP_V_EXP) |
((r -> fhi & FP_UFHI) >> FP_V_UFHI)) & DMASK;
if (lo) val[1] = ((r -> fhi & FP_UFLO) >> FP_V_UFLO) & MMASK;
else val[1] = 0;
if (r -> sign) { /* negate? */
if (fdvneg) { /* fdvr special? */
val[1] = ~val[1] & MMASK; /* 1's comp */
val[0] = ~val[0] & DMASK; }
else { DMOVN (val); } } /* 2's comp */
if (lo) *lo = val[1];
return val[0];
}