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C02/include/intlib.a02
2020-10-15 22:58:12 -04:00

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; C02 module intlib.h02 assembly language subroutines
; Requires
; external zero page words DSTPTR and SRCPTR
; and external locations TEMP0, TEMP1, TEMP2, and TEMP3
SUBROUTINE INTLIB
;iabs(n) - Get Integer ABSolute Value
;Args: Y,X = Integer to get Absolute Value Of
;Sets: TEMP1, TEMP2
;Affects: C, N, Z
;Returns: A = Absolute Value of Argument
IABS: CPY #$80 ;If Negative (High Bit Set)
BCC .RETURN ; Carry will Already be Set
JSR SAVRXY ; Copy LSB, MSB to TEMP1. TEMP2
LDA #0 ; Subtract LSB
SBC TEMP1 ; from 0
TAX ; and Copy to X Register
LDA #0 ; Subtract MSB
SBC TEMP2 ; from 0
TAY ; and Copy to Y Register
.RETURN RTS
;imax(i) - Get MAXimum of Two Integers
;Args: Y,X = Second Integer
;Uses: SRCPTR = First Integer
;Affects: N,Z,C
;Returns: Y,X = Larger of the Two Arguments
IMAX: CPY SRCPTR+1 ;If Y < SRCPTR MSB
BCC .GETSRC ; Return SRCPTR
CPX SRCPTR ;IF X >= SRCPTR LSB
BCS .RETURN ; Return Argument
.GETSRC JMP GETSRC ;Return Integer in SRCPTR
;imin(i) - Get MINimum of Two Integers
;Args: Y,X = Second Integer
;Uses: SRCPTR = First Integer
;Affects: N,Z,C
;Returns: Y,X = Larger of the Two Arguments
IMIN: CPY SRCPTR+1 ;If Y < SRCPTR+1
BCC .RETURN ; Return Argument
BNE .GETSRC ;If Y > SRCPTR+1 Return SRCPTR
CPX SRCPTR ;If X >= SRCPTR
BCS .GETSRC ; Return SRCPTR
RTS ;Return Argument
;iaddc(c,i) - Add Byte c to Integer i
IADDC: JSR SETSRC ;Save Integer and Clear Y
TAX ;Copy Byte to LSB and drop into IADD
;iadd(d) - ADD Integer d to from Integer g
;Args: Y,X = Addend
;Requires: setsrc(g) - Augend
;Sets: TEMP1,TEMP2 = Addend
;Affects: Z,C
;Returns: A = Carry
; Y,X = Sum
; N = Sign of Result
IADD: CLC ;Clear Carry for Addition
TXA ;Add Addend LSB
ADC SRCPTR ;to Augend LSB
TAX ;and Copy to X
TYA ;Add Addend MSB
ADC SRCPTR+1 ;to Augebd MSB
TAY ;and Copy to Y
LDA #0 ;Set Overflow to 0
ROL ; Rotate Carry (Same as Adding it)
RTS ; and Return
;isub(s) - SUBtract Integer s from Integer m
;Args: Y,X = Subtrahend
;Requires: setsrc(m) - Minuend
;Sets: TEMP1,TEMP2 = Subtrahend
;Affects: Z,C
;Returns: A = Carry
; Y,X = Difference
; N = Sign of Result
ISUB: JSR SAVRXY ;Store Subtrahend in TEMP1,TEMP2
SEC ;Set Carry for Subtraction
LDA SRCPTR ;Load Minuend LSB
SBC TEMP1 ;Subtract Subtrahend LSB
TAX ;Copy Difference LSB to X
LDA SRCPTR+1 ;Load Minuend MSB
SBC TEMP2 ;Subtract Subtrahend MSB
TAY ;Copy Difference MSB to Y
LDA #0 ;Set Overflow Byte to 0
SBC #0 ; Subtract Carry
RTS ; and Return
;imult(m) - MULTiply Two Integers
;Args: Y,X - Multiplier
;Requires: DSTPTR = Multiplicand
;Sets: TEMP0-TEMP3 = 32 Bit Product
;Destroys: SRCPTR
;Affects: A,C,Z,N
;Returns: A,Y,X = 24 Bit Product
IMULT: JSR SETSRC ;Save Multiplier
STY TEMP0+2 ;Clear Upper Bits of Product
STY TEMP0+3
LDX #16 ;Rotate Through 16 Bits
.MSHFTR LSR SRCPTR+1 ;Divide Multiplier by 2
ROR SRCPTR
BCC .MROTR ;If Shifted out Bit is 1
LDA TEMP0+2 ; Add Multiplicand
CLC ; to Upper Half of Product
ADC DSTPTR
STA TEMP0+2
LDA TEMP0+3
ADC DSTPTR+1
STA TEMP0+3
.MROTR ROR TEMP0+3
ROR TEMP0+2
ROR TEMP0+1
ROR TEMP0
DEX ;Decrement Counter
BNE .MSHFTR ;and Process Next Bit
LDX TEMP0
LDY TEMP1 ;Return Low 24 Bits of
LDA TEMP2 ;Product in A, Y, and X
RTS
;idiv(d) - Integer DIVide
;Args: Y,X - Divisor
;Requires: DSTPTR = Dividend
;Sets: SRCPTR = Divisor
; DSTPTR = Quotient
; TEMP1,TEMP2 = Remainder
;Affects: A,C,Z,N
;Returns: Y,X = 16 Bit Quotient
IDIV: JSR .IDIV ;Do Division and
JMP GETDST ;Return Quotient
;imod(d) - Integer MODulus
;Args: Y,X - Divisor
;Requires: DSTPTR = Dividend
;Sets: SRCPTR = Divisor
; DSTPTR = Quotient
; TEMP1,TEMP2 = Remainder
;Affects: A,C,Z,N
;Returns: Y,X = 16 Bit Remainder
IMOD: JSR .IDIV ;Do Division and
JMP RESRXY ;Return Remainder
.IDIV JSR SETSRC ;Save Divisor
STY TEMP1
STY TEMP1+1
LDX #16 ;repeat for each bit: ...
.IDLOOP ASL DSTPTR ;dividend lb & hb*2, msb -> Carry
ROL DSTPTR+1
ROL TEMP1 ;remainder lb & hb * 2 + msb from carry
ROL TEMP1+1
LDA TEMP1
SEC
SBC SRCPTR ;subtract divisor to see if it fits in
TAY ;lb result -> Y, for we may need it later
LDA TEMP1+1
SBC SRCPTR+1
BCC .IDSKIP ;if carry=0 then divisor didn't fit in yet
STA TEMP1+1 ;else save substraction result as new remainder,
STY TEMP1
INC DSTPTR ;and INCrement result cause divisor fit in 1 times
.IDSKIP DEX
BNE .IDLOOP
RTS
;ishftl(n,i) - Shift Integer i to the Left n Bits
;Sets: TEMP1, TEMP2 = LSB, MSB of Result
;Affects: A,Y,N,Z,C
;Returns: A = Bits Shifted out of Integer
; Y,X = Shifted Integer
ISHFTL: JSR SAVRXY ;Save X,Y in TEMP1,TEMP2
TAY ;Set Counter to Number of Bits
BEQ .RESRXY ;If Zero, Return
LDA #0 ;Clear Overflow
.LSLOOP ASL TEMP1 ;Shift LSB to Left
ROL TEMP2 ;Rotate MSB to Left
ROL ;Rotate Carry into A
DEY ;Decrement Counter
BNE .LSLOOP ; and Loop if Not 0
BEQ .RESRXY ;Return Shifted Integer
;ishftr(n,i) - Shift Integer i to the Right n Bits
;Sets: TEMP1, TEMP2 = LSB, MSB of Result
;Affects: A,Y,N,Z,C
;Returns: A = Bits Shifted out of Integer
; Y,X = Shifted Integer
ISHFTR: JSR SAVRXY ;Save X,Y in TEMP1,TEMP2
TAY ;Set Counter to Number of Bits
BEQ .RESRXY ;If Zero, Return
LDA #0 ;Clear Overflow
.RSLOOP LSR TEMP2 ;Shift MSB to Right
ROR TEMP1 ;Rotate LSB to Right
ROR ;Rotate Carry into A
DEY ;Decrement Counter
BNE .RSLOOP ; and Loop if Not 0
BEQ .RESRXY ;Load Shifted Integer and Return
;atoi(&s) - ASCII string TO Integer
;Args: Y,X = Address of String to Convert
;Sets: TEMP1, TEMP2 = Integer Value
;Affects: TEMP0
;Returns: A = Number of Digits
; Y,X = Integer Value
ATOI: JSR SETSRC ;Initialize Source String
STY TEMP1 ;Initialize Result
STY TEMP2
.AILOOP LDA (SRCPTR),Y ;Get Next Character
CMP #$30 ;If Less Than '0'
BCC .AIDONE ; Exit
CMP #$3A ;If Greater Than '9'
BCS .AIDONE ; Exit
AND #$0F ;Convert to Binary Nybble
STA TEMP0 ; and Save It
LDA TEMP1 ;Load Result
LDX TEMP2
ASL TEMP1 ;Multiply by 5 by
ROL TEMP2
ASL TEMP1 ; Multiplying by 4
ROL TEMP2
CLC ; And Adding Itself
ADC TEMP1
STA TEMP1
TXA
ADC TEMP2
STA TEMP2
ASL TEMP1 ;Multiply that by 2
ROL TEMP2
LDA TEMP0 ;Get Saved Nybble
CLC ;and Add to Result
ADC TEMP1 ;Add Saved Nybble
STA TEMP1 ; and Store Result
LDA #0
ADC TEMP2
STA TEMP2
INY ;Increment Index
BPL .AILOOP ; and Loop
.AIDONE TYA ;Return Number of Digits
.RESRXY JMP RESRXY ;and Integer Value
;itoa(n) - Integer TO ASCII string
;Args: Y,X = Integer Value to Convert
;Uses: DSTPTR = Destination String
;Affects: X
;Returns: A,Y = Length of String
ITOA: JSR CVIBCD ;Convert Integer to Packed BCD
LDY #0 ;Initialize Index into String
STY TEMP3
.ITOAA LDY #4 ;Set Initial Digit Number
.IAZERO JSR UPBCDI ;Unpack Digit Y
BNE .IASKIP ;If Zero
DEY ; Decrement Digit Number
BNE .IAZERO ; If Not Zero Loop
BEQ .IASKIP ; Else .IDSKIP Unpack
.IALOOP JSR UPBCDI ;Unpack Digit #Y
.IASKIP TAX ;Save Digit in X
TYA ;Push Digit Number into Stack
PHA
TXA ;and Restore Digit
LDY TEMP3 ;Get Index into String
ORA #$30 ;Convert Digit to ASCII
STA (DSTPTR),Y ;and Store in String
INC TEMP3 ;Increment Index into String
PLA ;Pull Digit Number off Stack
TAY
DEY ;Decrement Digit Number
BPL .IALOOP ;Loop if >= Zero
LDA #0 ;Terminate String
STA (DSTPTR),Y
TYA ;Return String Length
RTS
;upbcdi() - UnPack digits from BCD Integer
; Assumes that TEMP0, TEMP1, and TEMP2
; are in consecutive memory locations
;Args: Y = Digit Number to Unpack (0-5)
;Uses: TEMP0 = Low Byte
; TEMP1 = Middle Byte
; TEMP2 = High Nybble
;Affects: X,N,Z
;Returns: A = Unpacked Digit
UPBCDI: PHP
TYA ;Divide Digit Number by 2,
LSR ; Setting Carry
TAX ; if Digit Number is Odd
LDA TEMP0,X ;Load BCD Byte
BCC .UPSKIP ;If Digit Number is Odd
LSR ; Shift High Nybble to Low Nybble
LSR
LSR
LSR
.UPSKIP PLP
AND #$0F ;Strip Off High Nybble
RTS
;cvibcd(int) - ConVert Integer to packed Binary Coded Decimal
;Args: Y,X - Integer to Convert
;Sets: TEMP0 = Tens and Ones Digit
; TEMP1 = Thousands and Hundreds Digit
; TEMP2 = Ten-Thousands Digit
;Affects: A
CVIBCD: LDA #0 ;Clear BCD Bytes
STA TEMP0
STA TEMP1
STA TEMP2
PHP ;Save Status Register
SEI ;Disable Interrupts
SED ;Set Decimal Mode
TYA ;Push MSB onto Stack
PHA
TXA ;Push LSB onto Stack
PHA
TSX ;Copy Stack Pointer to X
LDY #16 ;Process 16 bits of Binary
.CVLOOP ASL $101,X ;Shift High Bit Into Carry
ROL $102,X
LDA TEMP0 ;Add 6 Digit BCD Number Itself
ADC TEMP0 ; Effectively Multiplying It by 2
STA TEMP0 ; and Adding in the Shifted Out Bit
LDA TEMP1
ADC TEMP1
STA TEMP1
LDA TEMP2
ADC TEMP2
STA TEMP2
DEY ;Decrement Counter and
BNE .CVLOOP ; Process Next Bit
PLA ;Restore X and Y Registers
PLA
PLP ;Restore Status Register
RTS
ENDSUBROUTINE