; Tiny Xdraw ; repeatedly draws an image from an Apple II shape table ; can arbitrarily point to any memory location as a source of these ; some look amazing but depend on random machine state ; to be deterministic you should probably stick to ; $E7-$F0 (the program itself) ; $D000-$FFFF (the ROMs) ; shapetables are a bit complicated to explain here, but they are a ; series of bytes ending with a $00 ; (note if you point to a zero, it will be interpreted as an ; action not an end) ; each byte specifies up to 3 actions, DRAW + UP DOWN LEFT RIGHT or ; NODRAW + UP DOWN LEFT RIGHT ; It is vector scaling with SCALE we hardcode to $20 and rotation ; which gets set to 0 after the first iteration, (which is ; why the first shape has arbitrary rotation and gets left) ; we are xdrawing so it will XOR with the current pixels on the screen ; NUP=0 UP=4 zz yyy xxx , does xxx yyy zz ; NRT=1 RT=5 ; NDN=2 DN=6 ; NLT=3 LT=7 ; zero page locations HGR_SHAPE = $1A HGR_SHAPE2 = $1B HGR_BITS = $1C GBASL = $26 GBASH = $27 A5H = $45 XREG = $46 YREG = $47 ; C0-CF should be clear ; D0-DF?? D0-D5 = HGR scratch? HGR_DX = $D0 ; HGLIN HGR_DX2 = $D1 ; HGLIN HGR_DY = $D2 ; HGLIN HGR_QUADRANT = $D3 HGR_E = $D4 HGR_E2 = $D5 HGR_X = $E0 HGR_X2 = $E1 HGR_Y = $E2 HGR_COLOR = $E4 HGR_HORIZ = $E5 HGR_SCALE = $E7 HGR_SHAPE_TABLE = $E8 HGR_SHAPE_TABLE2= $E9 HGR_COLLISIONS = $EA HGR_ROTATION = $F9 FRAME = $FC XPOS = $FD YPOS = $FF ; ROM calls HGR2 = $F3D8 HGR = $F3E2 HPOSN = $F411 XDRAW0 = $F65D XDRAW1 = $F661 RESTORE = $FF3F .zeropage .globalzp rot_smc tiny_xdraw: jsr HGR2 ; Hi-res, full screen ; 3 ; Y=0, A=0 after this call ; we load at $E7 which is HGR_SCALE, so HGR_SCALE gets ; the value of the above JSR instruction ($20) ; A and Y are 0 here. ; X is left behind by the boot process? txa jsr HPOSN ; set screen position to X= (y,x) Y=(a) ; saves X,Y,A to zero page ; after Y= orig X/7 ; A and X are ?? tiny_loop: ; values for shape table ; Y X ; 00 E7 = neat ; 00 EB = OK ; 00 EF = good ; F0 01 = cool, let's go with it ldx #$01 ; point to bottom byte of shape address ldy #$f0 ; point to top byte of shape address ; ROT in A ; this will be 0 2nd time through loop, arbitrary otherwise ; lda #0 ; ROT=0 jsr XDRAW0 ; XDRAW 1 AT X,Y ; Both A and X are 0 at exit ; Z flag set on exit ; Y varies beq tiny_loop ; bra