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MATH2.ASM
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MATH2.ASM
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SUBTTL $FIDIG ADD TEXT DIGIT TO CURRENT ACCUMULATED NUMBER
;***************************************************************
;
; $FIDIG CONVERTS DIGIT POINTED TO BY (BX) TO BINARY
; VALUE AND ADDS TO NUMBER ACCUMULATED. AT THE
; APPROPRIATE TIMES CONVERSION WILL TAKE
; PLACE TO THE NEXT HIERARCHY OF NUMBERS,I.E.
; INTEGER-SINGLE PRECISION-DOUBLE PRECISION.
; CALLING SEQUENCE: CALL $FIDIG
; WITH (BX) POINTING TO NUMBER IN THE
; TEXT BUFFER. NUMBER IS ACCUMULATED IN THE FAC.
;
;****************************************************************
;******************************************************************
;AS $FIDIG IS ENTERED CF=1 AND (DI) WILL HOLD PLACES TO THE RIGHT OF
;DECIMAL POINT (IF DECIMAL POINT HAS OCCURRED).(CX) WILL BE EITHER
;ALL BITS SET OR ALL BITS CLEARED. ALL BITS SET INDICATES A DECIMAL
;POINT HAS NOT BEEN SEEN YET AND (CX)=0 INDICATES D. P. SEEN
;******************************************************************
$FIDIG: ADC DI,CX ;(DI) INCREMENTED ONLY IF D.P. SEEN
PUSH BX ;MUST NOW SAVE ALL NECESSARY REGS.
PUSH DI
PUSH CX
SUB AL,LOW "0" ;SUBTRACT OUT ASCII BIAS
PUSH AX ;SAVE ON STACK
CALL $GETYP ;SET CONDITION CODES
POP AX ;RECALL DIGIT
CBW ;ZERO AH
JNS FI05 ;MUST BE S.P. OR D.P. ALREADY
MOV BX,WORD PTR $FACLO ;FETCH THE INTEGER ALREADY ACCUM.
CMP BX,3277D ;IS IT ALREADY TOO BIG TO ADD
;ANOTHER DIGIT TO?
JNB FFI10 ;IF SO GO MAKE S.P. FIRST
MOV CX,BX ;SAVE ORIGINAL (BX)
SHL BX,1 ;(BX)=(BX)*2
SHL BX,1 ;(BX)=(BX)*4
ADD BX,CX ;(BX)=(BX)*5
SHL BX,1 ;(BX)=(BX)*10
ADD BX,AX ;ADD IN THE DIGIT
JS FFI10 ;IF SF=1 WE HAVE 32768 OR 32769
MOV WORD PTR $FACLO,BX ;STORE IN $FAC
JMP SHORT FI50
FI05: ;TO GET HERE NUMBER WAS ALREADY S.P. OR D.P.
PUSH AX ;SAVE THE NUMBER
JB FFFI20 ;IT'S CURRENTLY SINGLE PRECISION
JMP SHORT FI40 ;DOUBLE PRECISION
FFI10: ;TO GET HERE NUMBER WAS PREVIOUSLY AN INTEGER BUT HAS
;GROWN TOO LARGE - MUST MAKE IT SINGLE PRECISION
PUSH AX ;SAVE THE NUMBER
CALL $CSI ;CONVERT INTEGER TO S.P.
JMP SHORT FI30 ;MUL BY 10 AND ADD IN DIGIT
FFFI20: ;TO GET HERE NUMBER WAS ALREADY SINGLE PRECISION
;MUST CHECK TO SEE IF ACCURACY MIGHT BE LOST IF WE
;MULTIPLY OUR FAC BY 10,I.E. FAC MUST BE SMALLER
;THAN 1000000.
MOV WORD PTR $DBUFF+4,22000
MOV WORD PTR $DBUFF+6,112164
MOV BX,OFFSET $DBUFF+6
CALL $COMPM ;COMPARE TO $FAC
JNS FI35 ;GO DO D.P. IF TOO LARGE FOR S.P.
FI30: CALL $MUL10 ;MULTIPLY $FAC BY 10
POP DX ;RECALL DIGIT
PUSH WORD PTR $FACLO
PUSH WORD PTR $FAC-1 ;FAC PUSHED ON STACK
CALL $FLT ;CONVERT INTEGER TO S.P.
POP BX ;RECALL FAC
POP DX
CALL $FADDS ;ADD IN THE NEW DIGIT
JMP SHORT FI50 ;GET STACK RIGHT AND RETURN
FI35: ;TO GET HERE WE ALREADY HAVE 7 DIGITS AND WOULD
;HAVE A LOSS OF ACCURACY IF WE CONTINUED IN S.P. SO WE
;NEED TO CONVERT TO D.P. MULTIPLY BY 10 AND ADD IN THE DIG.
CALL $CDS ;CONVERT THE SINGLE TO D.P.
FI40: CALL $MUL10 ;MULTIPLY BY 10
CALL $MOVAF ;MOVE $FAC TO $ARG
POP DX ;RECALL DIGIT
CALL $FLT ;CONVERT TO S.P.
CALL $CDS ;CONVERT TO D.P.
CALL $FADDD ;ADD IN THE OLD ACCUMULATED VALUE
FI50: POP CX ;GET DECIMAL POINT FLAG BACK
POP DI ;GET NO. DIGITS TO RIGHT OF DECIMAL PT.
POP BX ;GET TEXT POINTER BACK
RET ;COMPLETE
SUBTTL $FINEX EXPONENT INPUT ROUTINE
;*************************************************************
;
; $FINEX THE PURPOSE OF THIS ROUTINE IS TO DETERMINE
; THE INPUT EXPONENT BASE 10 AND LEAVE IN (DX).
; ADDITIONALLY IF A MINUS "-" SIGN IS ENCOUNTERED
; $FINEX WILL SET ALL BITS OF (SI). OTHERWISE ALL
; BITS OF (SI) WILL BE CLEARED.
; CALLING SEQUENCE: CALL $FINEX
; WITH THE SIGNIFICANT DIGITS OF THE NUMBER IN
; THE FAC.
;
;***************************************************************
$FINEX: LAHF ;SAVE STATUS
CMP BYTE PTR $VALTP,LOW 10 ;SEE IF ALREADY D.P.
JNZ EXA
SAHF ;GET STACK RIGHT
JMP EXB
EXA: SAHF ;RESTORE CODES
PUSH BX ;SAVE IMPORTANT REGISTERS
PUSH DI ;PRECISION ACCORDING TO ZF. IF
CALL $FINFC ;ZF=1 S.P.:ZF=0 THEN D.P.
POP DI ;RECALL DIGITS TO RIGHT OF D.P.
POP BX ;RECALL TEXT POINTER
EXB: XOR SI,SI ;IN CASE EXPONENT IS POSITIVE
MOV DX,SI ;WILL BUILD EXPONENT IN DX
CALL $CHRGT ;GET FIRST CHARACTER OF EXPONENT
JB FX20 ;NO SIGN SO DEFAULT POS.
CMP AL,LOW "-" ;NEGATIVE EXPONENT
JNZ FX00 ;IF NOT MUST BE POSITIVE
NOT SI ;NEGATIVE EXPONENT
JMP SHORT FX10 ;GO GET NEXT CHARACTER
FX00: CMP AL,LOW "+"
JZ FX10
;ILLEGAL CHARACTER MUST LEAVE
RET ;(BX) POINTING HERE
FX10: CALL $CHRGT ;GET NEXT CHARACTER
JB FX20 ;IF DIGIT PROCESS AS EXPONENT
RET ;OTHERWISE RETURN
FX20: CMP DX,3276D ;OVERFLOW IF THIS DOESN'T GET CF=1
JB FX30 ;NO-USE THIS DIGIT
MOV DX,32767D ;TO ASSURE OVERFLOW
JMP SHORT FX10
FX30: PUSH AX ;SAVE NEW DIGIT
MOV AX,10D ;MUST MULTIPLY DX BY 10
MUL DX ;ANSWER NOW IN AX
POP DX ;RECALL DIGIT TO DX
SUB DL,LOW 60 ;SUBTRACT OUT ASCII BIAS
XOR DH,DH ;TO BE SURE AX HAS CORRECT NO.
ADD DX,AX ;ADD TO DX
JMP SHORT FX10
SUBTTL FINFC INPUT FORCE ROUTINES FOR "#","%","!"
;*********************************************************
;
; FINFC THIS MODULE CONTAINS THE ROUTINES $FINI,
; $FIND, AND $FINS FOR FORCING THE INPUT TO
; INTEGER, DOUBLE PRECISION OR SINGLE PRECISION
; RESPECTIVELY IN RESPONSE TO AN INPUT "$","#", OR
; "!". ADDITIONALLY THIS MODULE CONTAINS
; THE UTILITY ROUTINES $FI,$FS,$FD,$CSI,$CSD,$CDS
; FOR FORCING INTEGER,SINGLE,DOUBLE,CONVERTING
; INTEGER TO SINGLE,CONVERTING DOUBLE TO SINGLE, AND
; CONVERTING SINGLE TO DOUBLE, RESPECTIVELY
; CALLING SEQUENCE: CALL $FINI
; OR CALL $FIND
; OR CALL $FINS
; OR CALL $FS
; OR CALL $FD
; OR CALL $FI
; OR CALL $CSI
; OR CALL $CSD
; OR CALL $CDS
; WITH THE FAC CONTAINING THE CURRENT ACCUMULATED
; NUMBER.
;
;***********************************************************
$FIND: ;FORCE INPUT TO DOUBLE PRECISION
OR AL,LOW 1 ;TO SIGNAL DOUBLE PRECISION
$FINS: ;FORCE INPUT TO SINGLE PRECISION (caller has set Z flag)
PUSH BX ;SAVE TEXT POINTER
PUSH DI ;SAVE NO DIGITS AFTER DECIMAL POINT
JNZ FC10 ;Force to double for $FIND callers.
CALL $FS ;Force to single for $FINS callers.
JMP SHORT FC20 ;Skip over $FD call.
FC10: CALL $FD ;FORCE FAC TO DOUBLE PREC.
FC20: POP DI ;RECALL NO DIGITS TO RT. OF DEC PT
POP BX ;RECALL TEXT POINTER
XOR SI,SI ;SINCE THIS IS A FORCED
MOV DX,SI ;NO. EXPONENT IS ZERO
CALL $FINE ;DO IMPLIED EXPONENT FIX-UP
FC30: INC BX ;Point past the force character and
RET ;return.
$FINI: CALL $GETYP ;SET COND CODES ACCORDING TO TYPE
JS FC30
JMP $SNERR ;CAN'T MAKE INTEGER IF NOT ALREADY
$FINFC: JZ $FD ;IF ZF=1 THEN DOUBLE PRECISION
FRCSNG:
$FS: ;FORCE SINGLE PRECISION
CALL $GETYP ;SET COND CODES ACC. TO TYPE
JPO FC200 ;IF ALREADY S.P. RETURN
JNZ FS10
JMP $TMERR ;CAN'T FORCE A STRING
FS10:
JNS $CSD ;IF NOT INTEGER FORCE DOUBLE TO S.P.
CALL $CSI ;FORCE INTEGER TO SINGLE
JMP SHORT FC200
$CSD: ;CONVERT DOUBLE TO SINGLE PRECISION
MOV AL,LOW 4 ;SINGLE PREC DESIGNATION
MOV BYTE PTR $VALTP,AL
MOV BL,BYTE PTR $FAC-1 ;FETCH HIGH MANTISSA BITS
MOV BYTE PTR $FAC+1,BL ;MOVE SIGN TO $FAC+1
MOV DX,WORD PTR $FAC-3 ;FETCH REST OF MANTISSA
MOV AH,BYTE PTR $FAC-4 ;FETCH OVERFLOW BITS
OR AH,LOW 100 ;WANT ROUND-UP IF HIGH BIT SET
OR BL,LOW 200 ;PUT IN UNDERSTOOD 1
JMP $ROUNM ;GO ROUND THE NUMBER
FRCDBL:
$FD: ;FORCE TO DOUBLE PRECISION
CALL $GETYP ;DETERMINE CURRENT TYPE
JNB FC200 ;IF ALREADY DOUBLE EXIT
JNZ FD10
JMP $TMERR
FD10:
JNS $CDS ;IF NOT INTEGER PROCEED
CALL $CSI ;CONVERT INTEGER TO SINGLE PREC.
$CDS: MOV AL,LOW 10 ;DOUBLE PREC. INDICATOR
MOV BYTE PTR $VALTP,AL ;SET TYPE TO D.P.
XOR AX,AX ;MUST ZERO OVERFLOW BYTES
MOV WORD PTR $DFACL,AX
MOV WORD PTR $DFACL+2,AX
RET
$CSI: PUSH DX ;SAVE (DX)
PUSH SI ;SAVE (SI)
MOV DX,WORD PTR $FACLO ;FETCH THE INTEGER
CALL $FLT ;FLOAT THE INTEGER AND STORE IN FAC
POP SI ;GET REGISTERS RIGHT
POP DX
FC200: RET
FRCINT:
$FI: ;FORCE INTEGER
CALL $GETYP ;SEE WHAT WE'RE IN FOR
JNS FI10 ;IF NOT INTEGER ALREADY - JUMP
MOV BX,WORD PTR $FACLO
RET
FI10:
JNZ FFI20
JMP $TMERR ;IF STRING - ERROR
FFI20:
$CINC: ;Single precision, operand in FAC
$CIND: ;Double precision uses same routine
PUSH AX
PUSH CX
MOV AX,WORD PTR $FACM1 ;Get exponent
MOV CX,WORD PTR $FACLO ;Get mantissa
CINT:
XOR BX,BX ;Set up zero result
SUB AH,LOW 200O ;Take bias out of exponent
JB CXRET ;Return zero if no integer part
MOV BH,AL ;Highest byte of mantissa
MOV BL,CH
XCHG AX,CX
MOV CL,LOW 16D
SUB CL,CH ;Number of bits to shift mantissa right
MOV AH,BH ;Save sign
JB OVERFLOW ;If negative shift, it won't fit in 16 bits
JZ OVCHK ;Only -32768 has 16 bits - go check for it
OR BH,LOW 200O ;Set implied bit
SHR BX,CL ;Position the integer
ADC BX,0 ;Perform rounding
JO POSBOVER
OR AH,AH ;Check sign now
JNS CXRET
NEG BX
CXRET:
POP CX
POP AX
MOV WORD PTR $FACLO,BX ;Result in both FAC and BX
VALINT:
$VALNT: MOV BYTE PTR $VALTP,LOW 2
RET
POSBOVER: ;Here for either -32768 or overflow
OR AH,AH ;If signed then -32768
JS CXRET
JMP SHORT OVERFLOW
OVCHK:
;Come here if no shift is needed on the number, i.e., it requires a full
;16 bits. Only -32768 (8000H) is allowed.
CMP BX,100000O ;The 1 is sign bit (negative), not implied bit
JNZ OVERFLOW
TEST AL,LOW 200O ;Should we be rounding up?
JZ CXRET ;If so, that causes overflow
OVERFLOW:
JMP $OVERR
SUBTTL $FLT CONVERT INTEGER IN (DX) TO REAL AND STORE IN FAC
;****************************************************************
; $FLT CONVERTS THE SIGNED INTEGER IN (DX) TO A REAL
; (FLOATING POINT ) NUMBER AND STORES IT IN THE FAC
; AND SETS $VALTP=4
;*****************************************************************
$FLT: XOR BX,BX ;CLEAR HIGH MANTISSA BYTE (BL)
XOR AH,AH ;CLEAR OVERFLOW BYTE
MOV SI,OFFSET $FAC+1 ;FETCH $FAC ADDRESS TO (SI)
MOV BYTE PTR -1[SI],LOW 220 ;SET EXPONENT TO 16
MOV BYTE PTR 0[SI],LOW 0 ;SET SIGN POSITIVE
OR DX,DX ;SETS SF=1 IF NEGATIVE NO.
JNS FLT10 ;IF POSITIVE PROCEED
NEG DX ;NEED POSTIVE MAGNITUDE
MOV BYTE PTR 0[SI],LOW 200 ;SET SIGN TO NEGATIVE
FLT10: MOV BL,DH ;WILL MOVE (DX) TO (BLDH)
MOV DH,DL ;
MOV DL,BH ;SET (DL)=0
MOV BYTE PTR $VALTP,LOW 4 ;SET TYPE TO S.P.
JMP $NORMS ;GO NORMALIZE
SUBTTL $FMULD DOUBLE PRECISION MULTIPLICATION
;**************************************************************
;
; $FMULD THIS ROUTINE FORMS THE DOUBLE PRECISION PRODUCT
; ($FAC):=($FAC)*($ARG)
; THE TECHNIQUE USED IS DESCRIBED IN KNUTH, VOL II
; P.233 AND IS CALLED ALGORITHM "M"
; CALLING SEQUENCE: CALL $FMULD
; WITH THE MULTIPLIER AND MULTIPLICAND IN THE
; $FAC AND $ARG
;
;**************************************************************
DMULT:
$FMULD: ;DOUBLE PRECISION MULT., (FAC)=(FAC)*(ARG)
MOV AL,BYTE PTR $FAC ;WILL FIRST SEE IF FAC IS ZERO
OR AL,AL ;AND IF SO JUST RETURN
JZ FMD10
MOV AL,BYTE PTR $ARG ;WILL NOW SEE IF ARG IS ZERO AND
OR AL,AL ;IF SO SET FAC TO ZERO AND RETURN
JNZ FMD20 ;IF NOT ZERO PROCEED TO MULTIPLY
JMP $DZERO ;ZERO THE FAC
FMD10: RET
FMD20:
MOV BX,WORD PTR $ARG-1 ;FETCH SIGN AND EXP. TO BX
CALL $AEXPS ;ADD THE EXPONENTS
PUSH WORD PTR $FAC ;EXPONENT,SIGN
MOV WORD PTR $ARG-1,BX ;REPLACE UNPACKED MANTISSA
;PUT THE SIGN OF THE PRODUCT IN
;FAC+1
CALL $SETDB ;MOVE THE FAC TO $DBUFF SO PRODUCT
;CAN BE FORMED IN THE FAC, AND ZERO
;THE FAC AND RETURNS WITH (AX)=0
MOV SI,AX ;J
MOV WORD PTR $FAC,AX
MOV BX,OFFSET $DBUFF ;
MOV WORD PTR $ARG,AX
MOV BP,OFFSET $ARGLO ;POINT TO MULTIPLICAND BASE
M1: MOV AX,WORD PTR 0[BX+SI] ;FETCH MULTIPLIER V(J)
OR AX,AX ;SEE IF ZERO
JZ M4D ;IF ZERO W(J)=0
MOV DI,0 ;I
MOV CX,DI ;K
M4: MOV AX,WORD PTR 0[BX+SI] ;FETCH MULTIPLIER V(J)
MUL WORD PTR 0[BP+DI] ;FORM PRODUCT V(J)*U(J) IN (DXAX)
PUSH BX ;SAVE PTR. TO MULTIPLIER BASE
MOV BX,SI ;
ADD BX,DI ;I+J
ADD BX,OFFSET $DFACL-10 ;W(I+J) ADDRESS IN BX
ADD AX,WORD PTR 0[BX] ;(DXAX)=U(I)*V(J)+W(I+J)
JNB M4A
INC DX
M4A: ADD AX,CX ;T=U(I)*V(J)+W(I+J)+K
JNB M4B
INC DX
M4B: MOV WORD PTR 0[BX],AX ;W(I+J)= T MOD 2^16
MOV CX,DX ;K=INT(T/2^16)
POP BX ;RECALL PTR TO MULTIPLIER BASE
CMP DI,6 ;FINISHED INNER LOOP?
JZ M4C ;IF SO JUMP AND SET W(J)
INC DI
INC DI
JMP SHORT M4
M4C: MOV AX,CX ;(AX)=K
M4D: PUSH BX ;SAVE PTR TO MULTIPLIER BASE
MOV BX,OFFSET $DFACL
MOV WORD PTR 0[BX+SI],AX ;W(J)=K OR 0 (0 IF V(J) WERE 0)
POP BX ;RECALL PTR TO MULTIPLIER BASE
CMP SI,6 ;FINISHED OUTER LOOP?
JZ M5
INC SI
INC SI
JMP SHORT M1
M5: ;MULTIPLICATION COMPLETE AND IN FAC
MOV SI,OFFSET $DFACL-2 ;WILL NOW SET ST
STD ;WANT NON-ZERO BYTE ASAP SO PROB.
;SEEMS HIGHER OF GETTING ONE IF
;(SI) IS DECREMENTED
MOV CX,7 ;7-BYTE CHECK
M5AA: LODSB ;FETCH NEXT BYTE
OR AL,AL
LOOPZ M5AA
JZ M5AB ;DON'T NEED TO SET ST
OR BYTE PTR $DFACL-1,LOW 40 ;"OR" IN ST BIT
M5AB:
MOV AL,BYTE PTR $FAC-1 ;SEE IF WE NEED TO INC EXPONENT
OR AL,AL
POP WORD PTR $FAC ;RESTORE EXPONENT,SIGN
JS M6
MOV BX,OFFSET $DFACL-1 ;MUST SHIFT 1 BIT LEFT
MOV CX,4
M5A: RCL WORD PTR 0[BX],1
INC BX
INC BX
LOOP M5A
M5B: JMP $ROUND ;NOW ROUND
M6: INC BYTE PTR $FAC ;INCREMENT EXPONENT
JNZ M5B
JMP $OVFLS ;OVERFLOW!
SUBTTL $FMULS SINGLE PRECISION 8086 MULTIPLICATION
;**********************************************************
; $FMULS FMULS MULTIPLIES THE SINGLE PRECISION
; FLOATING POINT QUANTITIES (BXDX) AND (FAC)
; AND RETURNS THE PRODUCT IN THE (FAC). ONLY
; SEGMENT REGISTERS ARE PRESERVED.
;***********************************************************
$FMULS: ;(FAC)=(BXDX)*(FAC)
CALL $SIGNS ;ZF=1 WILL BE SET IF (FAC)=0
JZ FMS00 ;JUST RETURN IF (FAC)=0
OR BH,BH ;IF EXPONENT OF (BXDX) IS ZERO
JNZ FMS05 ;PROCEED IF NON-ZERO
FMS00: JMP $ZERO ;THE NUMBER IS ZERO.
FMS05:
CALL $AEXPS ;ADD THE S.P. EXPONENTS
;***************************************************************
;WILL NOW PROCEED TO MULTIPLY THE MANTISSAS. THE MULTIPLICATION
;WILL UTILIZE THE 16 BIT MUL INSTRUCTION AND THUS WILL TAKE
;PLACE AS PARTIAL PRODUCTS SINCE WE HAVE 24 BIT MANTISSAS TO
;MULTIPLY.
;***************************************************************
MOV CX,WORD PTR $FAC-1 ;(CH)=($FAC):(CL)=($FAC-1)
XOR CH,CH ;(CX) CONTAINS HIGH MANTISSA BITS
MOV AX,WORD PTR $FAC-3 ;(AX) CONTAINS LOW MANTISSA BITS OF FAC
MOV BH,CH ;SET (BH)=0 AS WELL
;*************************************************************
;AT THIS POINT WE HAVE THE FAC MANTISSA IN (CLAX) AND THE
;(BXDX) MANTISSA IN (BLDX). THE UNDERSTOOD LEADING MANTISSA
;BIT WAS INSTALLED BY $AEXPS AND THE SIGN OF THE PRODUCT
;WAS STORED IN FAC+1
;THE PRODUCT WILL BE FORMED IN (BXCX) BY PARTIAL PRODUCTS.
;FIRST THE NECESSARY ELEMENTS WILL BE PUSHED ON THE STACK
;THEN UTILIZED IN REVERSE ORDER(THAT'S THE BEST WAY TO
;GET THE THEM OFF THE LIFO STACK -TURKEY!)
;************************************************************
MOV SI,BX
MOV DI,CX
MOV BP,DX
PUSH CX ;HIGH FAC MANTISSA BITS
PUSH AX ;LOW FAC MANTISSA BITS
MUL DX ;32 BIT PRODUCT FORMED(ONLY NEED
MOV CX,DX ;MOST 16 SIGNIFICANT BITS)
POP AX ;LOW FAC MANTISSA BITS
MUL BX ;TIMES HIGH MANTISSA BITS OF (BLDX)
ADD CX,AX ;ADD TO PREVIOUS CALCULATION
JNB FMS10 ;IF CARRY NOT PRODUCED PROCEED
INC DX
FMS10: MOV BX,DX ;PROBABLY ONLY 8 BITS HERE
POP DX ;HIGH FAC MANTISSA BITS
MOV AX,BP ;LOW 16 MANTISSA BITS OF (BLDX)
MUL DX ;
ADD CX,AX ;ADD IN LOW ORDER BITS
JNB FMS20 ;JUMP IF CARRY NOT PRODUCED
INC DX ;
FMS20: ADD BX,DX ;CAN'T PRODUCE CARRY HERE
MOV DX,DI ;HIGH FAC MANTISSA BITS
MOV AX,SI ;HIGH FAC MANTISSA BITS
MUL DL ;(AX) HAS ENTIRE PRODUCT
ADD BX,AX ;ADD IT IN
JNB FMS30 ;IF NO CARRY PROCEED
RCR BX,1 ;MOVE EVERYTHING RIGHT
RCR CX,1 ;
INC BYTE PTR $FAC ;MUST NOW CHECK FOR OVERFLOW
JNZ FMS30 ;PROCEED IF NON-ZERO
JMP $OVFLS
FMS30: ;PRODUCT FORMED, MUST NOW GET MANTISSA IN (BLDXAH) FOR ROUNS
;PRODUCT IS CURRENTLY IN (BXCX)
OR BH,BH ;MUST BE SURE PRODUCT LEFT JUSTIFIED
JNS FMS35 ;IN (BXCX)
INC BYTE PTR $FAC ;NEED TO INCREMENT EXP.
JNZ FMS37 ;IF NOT OVERFLOW PROCEED
JMP $OVFLS ;OVERFLOW JUMP
FMS35:
RCL CX,1
RCL BX,1
FMS37:
MOV DL,CH
MOV DH,BL
MOV BL,BH
MOV AH,CL ;OVERFLOW BYTE
JMP $ROUNS ;GO ROUND
RET
SUBTTL $FOTAN ROUTINE TO PUT IN DECIMAL POINT AND LEADING ZEROS
;*****************************************************************
;
; $FOTAN THIS ROUTINE IS CALLED BY THE FREE FORMAT OUTPUT
; CODE TO OUTPUT DECIMAL POINT AND LEADING ZEROS.
; $FOTED THIS ROUTINE IS CALLED BY BOTH THE FREE FORMAT
; OUTPUT ROUTINE AND THE PRINT USING CODE TO OUTPUT
; THE DECIMAL POINT WHEN NECESSARY AND TO PUT IN
; COMMAS "," AFTER EACH THREE DIGITS IF THIS OPTION
; IS INVOKED.
; CALLING SEQUENCE: CALL $FOTAN
; CALL $FOTED
; WITH $FMTCX CONTAINING NUMBER PLACES PRIOR TO
; DECIMAL POINT(NEGATIVELY) IN UPPER BYTE AND
; NO PLACES BEFORE NEXT COMMA IN LOW BYTE
;
;*******************************************************************
$FOTAN:
DEC CH ;IF NEGATIVE THEN LEADING ZEROS
JNS FTD05 ;
MOV WORD PTR $DPADR,BX ;SAVE DECIMAL POINT COUNT
MOV BYTE PTR 0[BX],LOW "." ;MOVE IN DECIMAL POINT
FTN10: INC BX ;POINT TO NEXT OUTPUT POSITION
MOV BYTE PTR 0[BX],LOW "0" ;PUT IN LEADING ZERO
INC CH ;WILL INCREMENT CH UNTIL ZERO
JNZ FTN10 ;PUT IN LEADING ZEROS UNTIL CH ZERO
INC BX ;POINT TO NEXT BUFFER POSITION
XOR CX,CX ;ZERO OUT DECIMAL POINT AND COMMA CTS.
JMP SHORT FTD20 ;GET STACK RIGHT AND RETURN
$FOTED:
DEC CH ;SEE IF TIME FOR D.P.
FTD05: JNZ FTD10 ;IF NOT D.P. TIME SEE IF COMMA TIME
MOV BYTE PTR 0[BX],LOW "." ;PUT IN D.P.
MOV WORD PTR $DPADR,BX ;SAVE ADDR OF DECIMAL POINT
INC BX ;INCREMENT PAST D.P.
XOR CX,CX ;ZERO COUNTS & SET ZF=1
JMP SHORT FTD20 ;GET STACK RIGHT AND RETURN
FTD10: DEC CL ;IF ZERO TIME FOR COMMA
JNZ FTD20
MOV BYTE PTR 0[BX],LOW 54O ;COMMA
INC BX ;POINT TO NEXT BUFFER POSITION
MOV CL,LOW 3 ;
FTD20: MOV WORD PTR $FMTCX,CX ;UPDATE D.P.&COMMA COUNTS
RET
SUBTTL $FOTCV CONVERT FAC TO ASCII DIGITS
;************************************************************
;
; $FOTCV CONVERSION OF SINGLE OR DOUBLE PRECISION
; NUMBER TO ASCII DIGITS.IF DOUBLE PRECISION
; 10 DIGITS WILL BE CONVERTED WITH DOUBLE
; PRECISION POWER OF TEN INTEGERS, 3 DIGITS
; WITH SINGLE PRECISION POWER OF TEN INTEGERS
; AND 3 DIGITS WITH INTEGER POWERS OF TEN
; CALLING SEQUENCE: CALL $FOTCV
; WITH THE NUMBER TO BE CONVERTED HAVING PREVIOUSLY
; BEEN OPERATED ON BY $FOTNV TO BRACKET THE
; NUMBER AND HAVE ALL DIGITS IN THE INTEGER PORTION
; OF THE FAC. AND THE CORRESPONDING EXPONENT WILL
; BE SAVED ON THE STACK AND CONVERTED LATER.
;
;**************************************************************
$FOTCV: CALL $GETYP ;SET CONDITION CODES FOR VALTYP
JPO FCV40 ;IF SINGLE PRECISION GO PROCESS
PUSH CX ;SAVE DIGIT AND COMMA COUNT
PUSH BX ;SAVE BUFFR PTR.
MOV SI,OFFSET $DFACL ;WILL MOVE FAC TO ARG
MOV DI,OFFSET $ARGLO
MOV CX,4
CLD
REP MOVSW
CALL $DINT ;WILL SEE IF FAC ALREADY INTEGER
PUSH BX ;NEED TO CALL VCOMP WITH BX=ARG-1
MOV BX,OFFSET $ARG-1
CALL $VCOMP ;DO COMPARE
POP BX ;GET BUFFER POINTER BACK
MOV SI,OFFSET $ARGLO ;WILL MOVIE ARG TO FAC
MOV DI,OFFSET $DFACL
MOV CX,4
CLD
REP MOVSW
JZ FCV05 ;DON'T ADD .5 IF NO DIFF.
CALL $DADDH ;ADD .5 TO NUMBER
FCV05: MOV CL,BYTE PTR $FAC ;SHIFT COUNT IN (CL)
SUB CL,LOW 270
NEG CL ;MAKE SHIFT COUNT POSITIVE
CLC ;TO TELL DINT NOT TO NORMALIZE
CALL $FTDNT ;MAKE SURE ITS STILL INTEGER
POP BX ;RECALL BUFFER PTR.
POP CX ;RECALL DIGIT AND COMMA COUNT
MOV SI,OFFSET $FODTB ;DOUBLE PRECISION OUTPUT INTEGERS
MOV AL,LOW 9D ;9 DIGITS TO BE CONVERTED WITH D.P.
FCV10: CALL $FOTED ;SEE IF DECIMAL POINT NEEDED
PUSH AX ;SAVE DIGIT COUNT
MOV AL,LOW OFFSET "0"-1 ;WILL FORM DIGIT IN (AL)
PUSH AX
FCV20: POP AX ;RECALL DIGIT
INC AL ;INCREMENT TO NEXT DIGIT
PUSH AX ;SAVE DIGIT
CALL DSUBI ;SUBTRACT POWER OF TEN
JNB FCV20
CALL DADDI ;ADD POWER 10 BACK IN
;AND ADVANCE SI TO NEXT POWER 10
POP AX ;GET DIGIT BACK
MOV BYTE PTR 0[BX],AL ;PUT IN ASCII DIGIT
INC BX ;POINT TO NEXT BUFFER POSITION
POP AX ;GET DIGIT COUNT
DEC AL ;SEE IF 10 DIGITS FORMED
JNZ FCV10 ;IF NOT CONTINUE THE ALGORITHM
PUSH CX ;SAVE DECIMAL POINT COUNT
MOV SI,OFFSET $DFACL ;WILL MOVE INTO FAC
MOV DI,OFFSET $FACLO
MOV CX,2
CLD
REP MOVSW
POP CX ;RECALL DECIMAL POINT COUNT
JMP SHORT FCV50 ;GO DO THE REST OF THE DIGITS
FCV40:
;**************************************************************
;CODE BELOW WORKS WITH SINGLE PRECISION NUMBERS
;***************************************************************
PUSH BX ;SAVE BUFFER PTR
PUSH CX ;SAVE DIGIT AND COMMA COUNTS
CALL $PUSHF ;SAVE $FAC ON STACK
CALL $INT ;WILL SEE IF INTEGER CURRENTLY
POP DX ;RECALL FAC
POP BX
CALL $FCOMP ;COMPARE IF EQUAL DON'T ADD .5
JZ FCV45
MOV WORD PTR $FAC-1,BX ;MOVE BACK TO FAC
MOV WORD PTR $FACLO,DX
CALL $FADDH ;ADD .5 TO NUMBER
FCV45: MOV AL,LOW 1 ;FLAG TO QINT WE HAVE A POS. NO.
CALL $QINT ;GET INTEGER INTO (BLDX)
MOV WORD PTR $FAC-1,BX
MOV WORD PTR $FACLO,DX ;MOVE TO FAC
POP CX ;RECALL DIGIT AND COMMA COUNTS
POP BX ;RECALL BUFFER PTR
FCV50:
MOV AL,LOW 3 ;WILL CONVERT 3 DIGITS IN THIS CODE
MOV DX,OFFSET $FOSTB ;Print S.P. numbers with 7 digits
FCV60: CALL $FOTED ;SEE IF NEED A DECIMAL POINT OR COMMA
PUSH AX ;SAVE DIGIT COUNT
PUSH BX ;SAVE BUFFER POINTER
PUSH DX ;SAVE POWER OF TEN POINTER
CALL $MOVRF ;FETCH INTEGER
POP BP ;FETCH POWER TEN POINTER
MOV AL,LOW OFFSET "0"-1 ;WILL BUILD DIGIT IN (AL)
PUSH AX ;SAVE DIGIT
FCV70: POP AX ;RECALL DIGIT
INC AL ;GO TO NEXT DIGIT
PUSH AX
CALL $RSUBM ;SUBTRACT NO. POINTED TO BY (BP)
;FROM (BLDX)
JNB FCV70 ;CONTINUE UNTIL CF=1
;POWER TEN TABLE IN CODE SEGMENT
ADD DX,WORD PTR CS:0[BP] ;ADD WORD PORTION
ADC BL,BYTE PTR CS:2[BP]
;SINCE WE SUBTRACTED ONE TOO MANY
INC BP ;INCREMENT TO NEXT POWER OF TEN
INC BP
INC BP
CALL $MOVFR ;SAVE (BLDX) IN FAC
POP AX ;RECALL DIGIT
XCHG DX,BP ;SAVE POWER TEN PTR. IN DX
POP BX ;RECALL BUFFER POINTER
MOV BYTE PTR 0[BX],AL ;SEND OUT DIGIT
INC BX ;INCREMENT TO NEXT BUFFER POSITION
POP AX ;RECALL DIGIT COUNT
DEC AL ;SEE IF FINISHED
JNZ FCV60 ;IF NOT CONTINUE
INC DX ;NEED TO INCREMENT PAST 1ST
INC DX ;INTEGER SO THAT FOTCI WILL
MOV BP,DX ;FOTCI IS EXPECTING POINTER IN BP
MOV AH,LOW 4 ;CONVERT ONLY 4 DIGITS
JMP $FCI4
;INTEGER ARITHMETIC
DSUBI: ;SUBTRACT 7 BYTE INTEGER POINTED TO BY (SI) FROM $DFACL
PUSH CX ;FIRST SAVE CX,SI,DI
PUSH SI
MOV CX,7 ;7 BYTES
MOV DI,OFFSET $DFACL
CLC ;CF=0
CLD ;SO LODC WILL INCREMENT
DSUBI1: ;NEED NO. FROM CODE SEGMENT
LODS BYTE PTR ?CSLAB ;FETCH BYTE TO AL
SBB BYTE PTR 0[DI],AL ;SUBTRACT
INC DI
LOOP DSUBI1
POP SI
POP CX
RET
DADDI: ;ADD 7 BYTE INTEGER POINTED TO BY (SI) FROM $DFACL
PUSH CX ;SAVE CX,SI,DI
MOV CX,7
MOV DI,OFFSET $DFACL
CLC
CLD ;SO LODC WILL INCREMENT SI
DADDI1: ;WANT NO. FETCHED FROM CODE SEGMENT
LODS BYTE PTR ?CSLAB ;FETCH NEXT BYTE TO ADD
ADC BYTE PTR 0[DI],AL ;ADD IT IN
INC DI
LOOP DADDI1
POP CX
RET
SUBTTL $FOTNV BRACKET FAC SO PRINTABLE DIGITS IN INTEGER PART
;****************************************************************
;
; $FOTNV THIS ROUTINE MULTIPLIES THE FAC BY APPROPRIATE
; VALUES SO THAT THE PRINTABLE DIGITS (7 FOR SINGLE
; PRECISION, 16 FOR DOUBLE PRECISION) ARE IN THE
; INTEGER PART OF THE FAC . IT RETURNS THE COMPLEMENT-
; ING EXPONENT IN (AL).
; CALLING SEQUENCE: CALL $FOTNV
; WITH THE FAC CONTAINING THE DESIRED VALUE TO PRINT
; REGISTERS (BX) AND (CX) WILL RETAIN THEIR VALUES
;
;*****************************************************************
$FOTNV:
PUSH BX ;WON'T ALTER (BX) OR (CX)
PUSH CX
XOR DI,DI ;INITIALIZE EXPONENT
PUSH DI ;SAVE EXPONENT
FNV10: MOV BX,OFFSET $FOTB ;ADDRESS OF BRACKET CONTROL TABLE
MOV AL,BYTE PTR $FAC ;FETCH THE EXPONENT
;MUST FETCH FROM CODE SEGMENT
XLAT BYTE PTR ?CSLAB ;GET MULTIPLIER
OR AL,AL ;IF ZERO - DONE
JZ FNV20
POP DI ;RECALL EXPONENT
CBW ;CONVERT AL TO WORD
SUB DI,AX ;GET EXPONENT CORRECT
PUSH DI ;SAVE EXPONENT
MOV DX,AX ;DX:=exponent for MDPTEN.
CALL MDPTEN ;Multiply or divide by power of ten.
JMP SHORT FNV10 ;See if need to do it again.
FNV20: MOV BX,OFFSET $DP06+4 ;LOWER BOUND
CALL $MOVBS ;MOVE OUT TO "DS" AREA
CALL $COMPM ;ONE MORE MULT. POSSIBLE
;$COMPM WILL SET CF=1 IF $DP06
;IS LARGER, CF=0 FOR EQ OR GT
JNB FNV30 ;JUMP IF NOT NEEDED
CALL $MUL10 ;MULTIPLY BY TEN
POP DI ;RECALL EXPONENT
DEC DI ;ACCOUNT FOR MULTIPLY BY 10.
PUSH DI
FNV30: CALL $GETYP ;SET CONDITION CODES FOR TYPE
JB FNV40 ;done if single precision
MOV BX,OFFSET $DP09 ;MUST MULTIPLY BY 10^9
CALL $MOVAC ;MOVE 10^9 TO $ARG
CALL $FMULD ;PERFORM MULTIPLICATION
POP AX ;RECALL EXPONENT
SUB AL,LOW 11 ;SUBTRACT 9
PUSH AX ;Resave the exponent.
MOV BX,OFFSET HIDBL ;Is the number too big? (Will it
CALL $MOVBF ;overflow when $FOTCV adds .5 to it?)
CALL $DCMPM
JNA FNV40 ;No.
FNV44: CALL $DIV10 ;Yes, divide by ten and fix up the
;the decimal exponent.
POP AX ;restore the exponent
INC AL ;adjust for $DIV10
PUSH AX
FNV40: POP AX ;recall exponent
FNV50: POP CX ;restore registers
POP BX
OR AL,AL ;SET CONDITION CODES ACCORDING TO EXP
RET
;
; The largest double precision value that .5 can be added to without
; overflow occuring.
;
HIDBL: DB 375,377,3,277,311,33,16,266 ;9999999999999999.
SUBTTL $FOUT CONTROL OUTPUT CONVERSION
;***************************************************************
;
; $FOUT THIS ROUTINE PROVIDES TOP-LEVEL CONTROL OF THE
; FREE FORMAT OUTPUT FUNCTION.
; CALLING SEQUENCE: CALL $FOUT
;
;****************************************************************
S: MOV BX,OFFSET $FBUFF+1 ;FETCH BUFFER POINTER
MOV BYTE PTR 0[BX],LOW " " ;MOVE IN SPACE FOR POSSIBLE SIGN
PUSH BX ;SAVE BUFFER POINTER
CALL $SIGNS ;DETERMINE SIGN OF NUMBER
POP BX ;RECALL BUFFER POINTER
PUSHF ;SAVE FLAGS FOR LATER
JNS FO20 ;JUMP IF POSITIVE
MOV BYTE PTR 0[BX],LOW "-" ;PUT IN MINUS SGN
PUSH BX ;SAVE TEXT POINTER
CALL $VNEG ;NEGATE NO. SO WE WORK ONLY WITH
POP BX ;RECALL TEXT POINTER
OR AL,LOW 1 ;POS. NOS. AND SET ZF=0
FO20: INC BX ;POINT TO NEXT BUFFER POSITION
MOV BYTE PTR 0[BX],LOW "0" ;PUT IN ZERO IN CASE NO IS ZERO
POPF ;RECALL FLAGS
RET
FOUT:
$FOUT: ;FREE-FORMAT ENTRY POINT
CALL S ;DO SIGN FIX-UP
JNZ $FOUT2 ;IF NON-ZERO PROCEED
INC BX ;POINT TO NEXT OUTPUT BUFFER POS.
MOV BYTE PTR 0[BX],LOW 0 ;INDICATE END OF NUMBER
MOV BX,OFFSET $FBUFF+1 ;POINT (BX) TO START POSITION
RET
$FOUT2: CALL $GETYP ;GET TYPE NO.
JNS FO50 ;GO FORMAT SINGLE OR DOUBLE PREC.
MOV CX,OFFSET 7*400 ;default 7 digits prior to dp.
XOR AX,AX ;CLEAR COMMA COUNT
MOV WORD PTR $FMTAX,AX
MOV WORD PTR $FMTCX,CX
CALL $FOTCI ;CONVERT INTEGER TO ASCII
JMP $FOTZS ;DO LEADING ZERO SUPPRESSION
FO50: JMP $FOFMT ;SINGLE OR DOUBLE PREC. OUTPUT
SUBTTL $INT CONVERT PRESENT NO. TO INTEGER BY TRUNCATION
;***********************************************************
;
; $INT SINGLE PRECISION INT ROUTINE
; $DINT DOUBLE PRECISION INT ROUTINE
; $QINT CONVERT TO INT AND LEAVE IN (BLDX)
; $FTDNT FOUT ENTRY TO CONVERT TO INT AND LEAVE RT.ADJUSTED
; $SHRD SHIFT DOUBLE PRECISION MANTISSA RIGHT
;
;**********************************************************
;**********************************************************
;THE INT TECHNIQUE IS PRETTY STRAIGHT FORWARD EXCEPT
;FOR NEGATIVE NON-INTEGERS. THE RUB WITH THESE NOS. IS THAT
;IF THEY HAVE ANY FRACTIONAL BITS THE ANSWER IS TO
;BE THE NEXT LOWER VALUE INTEGER. FOR EXAMPLE : INT(-1.1) SHOULD
;RETURN -2 WHEREAS INT(1.1) SHOULD RETURN 1. THE TRICK USED TO
;EFFECT THIS IS TO SUBTRACT 1 FROM NEGATIVE NON-INTEGER MANTISSAS
;PRIOR TO SHIFTING OUT FRACTIONAL BITS THEN ADD 1 BACK TO THE
;MANTISSA ONCE FRACTIONAL BITS HAVE BEEN SHIFTED OUT. WITH THE
;FOLLOWING EXAMPLE (IN BINARY) WATCH HOW THIS TECHNIQUE WORKS:
;FIND INT(10011.011)
; (1) SINCE THIS IS A POSITIVE NO WE JUST SHIFT OUT
; THE FRACTIONAL BITS AND NORMALIZE
;FIND INT(-10011.011)
; (1) SUBTRACT ONE FROM THE MANTISSA YIELDING -10011.010
; (2) SHIFT OUT THE FRACTIONAL BITS YIELDING -10011.
; (3) ADD 1 TO MANTISSA YIELDING -10100 THE CORRECT VALUE
;FIND INT(-10011.000)
; (1) SUBTRACT ONE FROM MANTISSA YIELDING -10010.111
; (2) SHIFT OUT THE FRACTIONAL BITS YIELDING -10010.
; (3) ADD 1 TO MANTISSA YIELDING -10011. THE CORRECT VALUE
;******************************************************************
$DINT: ;DOUBLE PRECISION INT FUNCTION
MOV CL,BYTE PTR $FAC ;CL:=exponent.
SUB CL,LOW 270 ;Is there a fractional part?
JNB DNT20 ;RETURN IF NO FRACTIONAL BITS
NEG CL ;CL NOW POSITIVE
$FTDNT: PUSHF ;FOUT ENTRY POINT. THIS IS SEPARATE
;ENTRY POINT BECAUSE FOUT WISHES
;TO HAVE INTEGER RIGHT ADJUSTED
;IN THE MANTISSA BITS. WE WILL DO
;THE NECESSARY SHIFTS AND RETURN
;PRIOR TO NORMALIZATION IF CALLED
;BY FOUT (SIGNIFIED BY CF=0)
TEST BYTE PTR $FAC,LOW 377O ;Is the exponent zero?
JNE DINTNZ ;No, proceed.
POPF ;Yes, if the exponent is zero the
RET ;number is zero. Don't operate on
;the possible garbage in the mantissa.
DINTNZ: MOV BX,OFFSET $FAC-2
MOV AL,BYTE PTR 1[BX] ;FETCH SIGN BYTE
MOV BYTE PTR 3[BX],AL ;AND PUT IN $FAC+1 FOR $NORMD
OR AL,AL ;SEE IF NEGATIVE
PUSHF
OR AL,LOW 200 ;RESTORE HIDDEN 1
MOV BYTE PTR 1[BX],AL ;AND REPLACE
MOV BYTE PTR 2[BX],LOW 270 ;SET EXPONENT FOR POST SHIFT VALUE
POPF ;RECALL SF
PUSHF
JNS DNT10 ;IF POSITIVE PROCEED
;*****************************************************************
;NEGATIVE NO. MUST DO THE FANCY FOOTWORK DESCRIBED ABOVE
;*****************************************************************
CALL DINTA ;SUBTRACT 1 FROM MANTISSA BITS
DNT10: XOR CH,CH ;(CX)=SHIFT COUNT
CALL $SHRD ;DOUBLE PRECISION SHIFT RIGHT
POPF ;RECALL SF
JNS DNT15 ;IF POSITIVE PROCEED
CALL ADD1D ;ADD 1 TO MANTISSA BITS
DNT15: MOV BYTE PTR $DFACL-1,LOW 0 ;ZERO THE OVERFLOW BYTE
POPF ;SEE IF CALLED BY FOUT (CF=0)
JNB DNT20 ;IF SO JUST RETURN
JMP $NORMD ;OTHERWISE NORMALIZE
DNT20: RET
$SHRD: ;SHIFT RIGHT DOUBLE PRECISION
SHRD10: PUSH CX ;SAVE OUTER LOOP VARIABLE (BITS TO
;BE SHIFTED RIGHT)
PUSH BX ;SAVE POINTER TO HIGH BYTE TO SHIFT
CLC ;CF=0
CALL $SHDR ;SHIFT 1 BIT RIGHT
POP BX
POP CX ;GET OUTER LOOP VARIABLE
LOOP SHRD10
RET
DINTA: PUSH BX
MOV BX,OFFSET $DFACL ;BEGINNING ADDRESS FOR SUBTRACT
DINA10: SUB WORD PTR 0[BX],1 ;NEED CF SO CAN'T USE DEC
JNB DINA20
INC BX
INC BX ;CAN DO WORD SUBTRACTS SINCE HIGH BIT
;OF MANTISSA IS SET (THUS PROTECTING
;THE EXPONENT FROM THE SUBTRACT)
JMP SHORT DINA10
DINA20: POP BX
RET
ADD1D: ;ADD 1 TO DOUBLE PRECISION MANTISSA BITS
PUSH BX ;
MOV BX,OFFSET $DFACL
ADD10: INC BYTE PTR 0[BX]
JNZ ADD20
INC BX ;POINT TO NEXT BYTE THERE WAS A CARRY
JMP SHORT ADD10
ADD20: POP BX
RET
INT:
$INT: ;SINGLE PRECISION INT FUNCTION
MOV CL,BYTE PTR $FAC ;FETCH EXPONENT
SUB CL,LOW 230 ;CALCULATE SHIFT COUNT
JNB INT20 ;ALREADY INTEGER PROCEED
NEG CL ;GET POSITIVE SHIFT COUNT
;
; Note - At this point the carry is set. This will be used
; to indicate that this is not a QINT call. Also note that
; if the exponent is zero the above subtraction did set the
; carry so the check for the zero exponent case below is
; guaranteed to be executed.
;
QINTX: ; $QINTX'S ENTRY POINT
MOV DX,WORD PTR $FACLO ;FETCH LOW MANTISSA BITS
MOV BX,WORD PTR $FAC-1 ;FETCH EXP,SIGN,HIGH MANTISSA BITS
INC BH ;Is the exponent zero? (Test for zero
DEC BH ;without affecting the carry.)
JNE QINTNZ ;No, proceed.
XOR BL,BL ;Yes, put zero into BL,DX for QINT
XOR DX,DX ;rather than work with the possible
RET ;garbage in the mantissa (an exponent
;of zero means the number is zero).
QINTNZ: PUSHF ;Save carry which if clear indicates
;this is a QINT call.
OR BL,BL ;SEE IF NEGATIVE
PUSHF ;SAVE
MOV BYTE PTR $FAC+1,BL ;SAVE SIGN FOR NORMS
MOV BYTE PTR $FAC,LOW 230 ;SET EXP FOR POST SHIFT
OR BL,LOW 200 ;RESTORE HIDDEN 1
POPF
PUSHF ;SAVE SIGN
JNS INT10 ;
SUB DX,1 ;CAN'T DO A 'DEC' BECAUSE NEED CF
SBB BL,LOW 0 ;DO APPROPRIATE SUBTRACT TO HIGH BYTE
INT10: XOR CH,CH ;CX HAS LOOP COUNT
OR CL,CL ;IF SHIFT COUNT ZERO MUST JUMP OVER
JZ INT12 ;RIGHT SHIFTS
INT11: SHR BL,1 ;SHIFT RIGHT INTO CF
RCR DX,1 ;ROTATE RIGHT
LOOP INT11 ;WILL DO (CX) RIGHT SHIFTS
INT12: POPF ;RECALL SIGN OF NO.
LAHF ;STORE FLAGS TEMPORARILY
JNS INT15 ;PROCEED IF POSITIVE
INC DX
JNZ INT15
INC BL
INT15:
POPF ;CF=0 IF CALLED BY QINT
JNB INT20 ;JUST RETURN IF QINT CALL
XOR AH,AH ;CLEAR OVERFLOW BYTE
JMP $NORMS ;NORMALIZE AND RETURN
INT20: SAHF ;MUST SEE IF NEGATIVE
NGBLDX: JNS INT30 ;IF NOT PROCEED AS NORMAL
NOT DX ;COMPLEMENT DX
NOT BL ;AND BL
ADD DX,1 ;NEED CF SET IF DX OVERFLOWS
ADC BL,LOW 0 ;2's COMPLEMENT NOW FORMED
INT30: RET
QINT:
$QINT: ;DO INT(FAC) AND LEAVE IN (BLDX)
MOV CL,LOW 230
SUB CL,BYTE PTR $FAC ;GET SHIFT COUNT TO CL
CLC ;CF=0
JMP SHORT QINTX ;LEAVE RIGHT ADJUSTED
SUBTTL $LOG SINGLE PRECISION NATURAL LOG FUNCTION
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