; IL65 integer math library for 6502 ; (floating point math is done via the C-64's BASIC ROM routines) ; ; some more interesting routines can be found here: ; http://6502org.wikidot.com/software-math ; http://codebase64.org/doku.php?id=base:6502_6510_maths ; ; Written by Irmen de Jong (irmen@razorvine.net) - license: GNU GPL 3.0 ; ; ; indent format: TABS, size=8 ~ math { ; note: the following ZP scratch registers must be the same as in c64lib memory .byte SCRATCH_ZP1 = $02 ; scratch register #1 in ZP memory .byte SCRATCH_ZP2 = $03 ; scratch register #2 in ZP memory .word SCRATCH_ZPWORD1 = $fb ; scratch word in ZP ($fb/$fc) memory .word SCRATCH_ZPWORD2 = $fd ; scratch word in ZP ($fd/$fe) sub multiply_bytes (byte1: X, byte2: Y) -> (A, X?) { ; ---- multiply 2 bytes, result as byte in A (signed or unsigned) %asm { stx SCRATCH_ZP1 sty SCRATCH_ZP2 ldx #8 - asl a asl SCRATCH_ZP1 bcc + clc adc SCRATCH_ZP2 + dex bne - rts } } sub multiply_bytes_16 (byte1: X, byte2: Y) -> (A?, XY) { ; ---- multiply 2 bytes, result as word in X/Y (unsigned) %asm { lda #0 _m_with_add stx SCRATCH_ZP1 sty SCRATCH_ZP2 ldx #8 lsr SCRATCH_ZP1 - bcc + clc adc SCRATCH_ZP2 + ror a ror SCRATCH_ZP1 dex bne - tay ldx SCRATCH_ZP1 rts } } sub multiply_bytes_addA_16 (byte1: X, byte2: Y, add: A) -> (A?, XY) { ; ---- multiply 2 bytes and add A, result as word in X/Y (unsigned) %asm { jmp multiply_bytes_16._m_with_add } } var .wordarray(2) multiply_words_product sub multiply_words (number: XY) -> (?) { ; ---- multiply two 16-bit words into a 32-bit result ; input: X/Y = first 16-bit number, SCRATCH_ZPWORD1 in ZP = second 16-bit number ; output: multiply_words_product 32-bits product, LSB order (low-to-high) %asm { stx SCRATCH_ZPWORD2 sty SCRATCH_ZPWORD2+1 mult16 lda #$00 sta multiply_words_product+2 ; clear upper bits of product sta multiply_words_product+3 ldx #16 ; for all 16 bits... - lsr SCRATCH_ZPWORD1+1 ; divide multiplier by 2 ror SCRATCH_ZPWORD1 bcc + lda multiply_words_product+2 ; get upper half of product and add multiplicand clc adc SCRATCH_ZPWORD2 sta multiply_words_product+2 lda multiply_words_product+3 adc SCRATCH_ZPWORD2+1 + ror a ; rotate partial product sta multiply_words_product+3 ror multiply_words_product+2 ror multiply_words_product+1 ror multiply_words_product dex bne - rts } } sub divmod_bytes (number: X, divisor: Y) -> (X, A) { ; ---- divide X by Y, result quotient in X, remainder in A (unsigned) ; division by zero will result in quotient = 255 and remainder = original number %asm { stx SCRATCH_ZP1 sty SCRATCH_ZP2 lda #0 ldx #8 asl SCRATCH_ZP1 - rol a cmp SCRATCH_ZP2 bcc + sbc SCRATCH_ZP2 + rol SCRATCH_ZP1 dex bne - ldx SCRATCH_ZP1 rts } } sub divmod_words (divisor: XY) -> (A?, XY) { ; ---- divide two words (16 bit each) into 16 bit results ; input: SCRATCH_ZPWORD1 in ZP: 16 bit number, X/Y: 16 bit divisor ; output: SCRATCH_ZPWORD1 in ZP: 16 bit result, X/Y: 16 bit remainder ; division by zero will result in quotient = 65535 and remainder = divident %asm { remainder = SCRATCH_ZP1 stx SCRATCH_ZPWORD2 sty SCRATCH_ZPWORD2+1 lda #0 ;preset remainder to 0 sta remainder sta remainder+1 ldx #16 ;repeat for each bit: ... - asl SCRATCH_ZPWORD1 ;number lb & hb*2, msb -> Carry rol SCRATCH_ZPWORD1+1 rol remainder ;remainder lb & hb * 2 + msb from carry rol remainder+1 lda remainder sec sbc SCRATCH_ZPWORD2 ;substract divisor to see if it fits in tay ;lb result -> Y, for we may need it later lda remainder+1 sbc SCRATCH_ZPWORD2+1 bcc + ;if carry=0 then divisor didn't fit in yet sta remainder+1 ;else save substraction result as new remainder, sty remainder inc SCRATCH_ZPWORD1 ;and INCrement result cause divisor fit in 1 times + dex bne - lda remainder ; copy remainder to ZPWORD2 result register sta SCRATCH_ZPWORD2 lda remainder+1 sta SCRATCH_ZPWORD2+1 ldx SCRATCH_ZPWORD1 ; load division result in X/Y ldy SCRATCH_ZPWORD1+1 rts } } sub randbyte () -> (A) { ; ---- 8-bit pseudo random number generator into A %asm { lda _seed beq + asl a beq ++ ;if the input was $80, skip the EOR bcc ++ + eor _magic ; #$1d ; could be self-modifying code to set new magic + sta _seed rts _seed .byte $3a _magic .byte $1d _magiceors .byte $1d, $2b, $2d, $4d, $5f, $63, $65, $69 .byte $71, $87, $8d, $a9, $c3, $cf, $e7, $f5 ;returns - this comment avoids compiler warning } } sub randword () -> (XY) { ; ---- 16 bit pseudo random number generator into XY %asm { lda _seed beq _lowZero ; $0000 and $8000 are special values to test for ; Do a normal shift asl _seed lda _seed+1 rol a bcc _noEor _doEor ; high byte is in A eor _magic+1 ; #>magic ; could be self-modifying code to set new magic sta _seed+1 lda _seed eor _magic ; #