4.3BSD-Reno/src/sys/tahoemath/Kdivd.s
/* Kdivd.s 1.3 86/01/05 */
#include "../tahoemath/fp.h"
#include "../tahoemath/Kfp.h"
#include "../tahoe/SYS.h"
#define HIDDEN 23 # here we count from 0 not from 1 as in fp.h
.text
ENTRY(Kdivd, R9|R8|R7|R6|R5|R4|R3|R2)
clrl r3 # r3 - sign: 0 for positive,1 for negative.
movl 4(fp),r0
jgeq 1f
movl $1,r3
1: movl 12(fp),r2
jgeq 2f
bbc $0,r3,1f # seconed operand is negative.
clrl r3 # if first was negative, make result positive.
jmp 2f
1: movl $1,r3 # if first was positive, make result negative.
2: andl2 $EXPMASK,r0 # compute first 'pure'exponent.
jeql retz
shrl $EXPSHIFT,r0,r0
subl2 $BIAS,r0
andl2 $EXPMASK,r2 # compute seconed 'pure'exponent.
jeql retz2
shrl $EXPSHIFT,r2,r2
subl2 $BIAS,r2
subl3 r2,r0,r2 # subtruct the exponents.
addl2 $BIAS,r2
jleq underf
# normalization can make the exp. smaller.
#
# We have the sign in r3,the exponent in r2,now is the time to
# perform the division...
#
# fetch dividend. (r4,r5)
andl3 $(0!(EXPMASK | SIGNBIT)),4(fp),r4
orl2 $(0!CLEARHID),r4
movl 8(fp),r5
# fetch divisor : (r6,r7)
andl3 $(0!(EXPMASK | SIGNBIT)),12(fp),r6
orl2 $(0!CLEARHID),r6
movl 16(fp),r7
movl $0,r0 # init r0,r1 to be zeros
movl $0,r1
movl $(0!CLEARHID),r8# r8 first bit to set (if).
shll $1,r8,r8 # to have one more bit,because we might
# have to shift left to normelize.
movl $0,r9
2:
subl2 r7,r5
sbwc r6,r4
jgeq 1f
addl2 r7,r5
adwc r6,r4
shlq $1,r4,r4
shrq $1,r8,r8
jeql over
jmp 2b
1:
orl2 r8,r0
orl2 r9,r1
shlq $1,r4,r4
shrq $1,r8,r8
jneq 2b
over:
pushl 20(fp)
callf $8,_Kfnorm
sign:
1: bbc $0,r3,done
orl2 $SIGNBIT,r0
done: ret
retz:
clrl r0
clrl r1
ret
retz2: bbc $31,12(fp),z_div
clrl r0
clrl r1
ret
underf:
orl2 $HFS_UNDF,*20(fp)
ret
z_div:
orl2 $HFS_DIVZ,*20(fp)
ret