Homebrew:Test Controls

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Running Test Controls.

Program to test the buttons and controllers of your Channel F console.


Binary file and source code download:
Test Controls binary and source (zip 7kB)


Code:

;            Input Test program 
;               written by 
;            Fredric Blåholtz 
;                 2007
;
; dasm game.asm -f3 -ogame.bin  to compile

	processor f8

;===========================================================================
; Colors
;===========================================================================
red		=	$40
blue		=	$80
green		=	$00
bkg		=	$C0
clear		=	$FF
	

;===========================================================================
; Configuration
;===========================================================================

game_size		=	2			; game size in kilobytes


;===========================================================================
; Program Entry
;===========================================================================

;---------------------------------------------------------------------------
; Cartridge Initalization
;---------------------------------------------------------------------------

	org	$800

	.byte	$55, $FB					; valid cart indicator, unused byte

	li	blue
	lr	2, A
	li	$ff
	lr	3, A
	lr	4, A
	li	104
	lr	5, A
	li	60
	lr	6, A

;---------------;
; fillscreen Function ;
;---------------;
; this function blits a graphic based on parameters set in r1-r6,
; and the graphic data pointed to by DC0, onto the screen
;
; originally from cart 26, modified and annotated
; uses r1-r9, K, Q
;
; r1 = color 1 (off)
; r2 = color 2 (on)
; r3 = x position
; r4 = y position
; r5 = width
; r6 = height (and vertical counter)
;
; r7 = horizontal counter
; r8 = graphics byte
; r9 = bit counter
;
; DC = pointer to graphics

fillscreen:
	; adjust the x coordinate
	lis	4
	as	3
	lr	3, A
	; adjust the y coordinate
	lis	4
	as	4
	lr	4, A

	lis	1
	lr	9, A						; load #1 into r9 so it'll be reset when we start
	lr	A, 4						; load the y offset
	com							; invert it
fillscreen.row:
	outs	5						; load accumulator into port 5 (row)

	; check vertical counter
	ds	6						; decrease r6 (vertical counter)
	bnc	fillscreen.exit					; if it rolls over exit

	; load the width into the horizontal counter
	lr	A, 5
	lr	7, A

	lr	A, 3						; load the x position
	com							; complement it
fillscreen.column:
	outs	4						; use the accumulator as our initial column
	; check to see if this byte is finished
	ds	9						; decrease r9 (bit counter)
	bnz	fillscreen.drawBit			; if we aren't done with this byte, branch

fillscreen.getByte:
	; get the next graphics byte and set related registers
	lis	8
	lr	9, A						; load #8 into r9 (bit counter)

fillscreen.drawBit:
	; check color to use
	lr	A, 2						; load color 1
	bc	fillscreen.savePixel			; if this bit is on, draw the color
	lr	A, 1						; load color 2
fillscreen.savePixel:
	inc
	bc	fillscreen.checkColumn			; branch if the color is "clear"
	outs	1						; output A in p1 (color)

fillscreen.transferData:
	; transfer the pixel data
	li	$60
	outs	0
	li	$40
	outs	0

	; and delay a little bit

	lis	2
fillscreen.savePixelDelay:
	ai	$ff
	bnz	fillscreen.savePixelDelay

fillscreen.checkColumn:
	ds	7						; decrease r7 (horizontal counter)
	bz	fillscreen.checkRow					; if it's 0, branch

	ins	4						; get p4 (column)
	ai	$ff						; add 1 (complemented)
	br	fillscreen.column					; branch

fillscreen.checkRow:
	ins	5						; get p5 (row)
	ai	$ff						; add 1 (complemented)
	br	fillscreen.row					; branch

fillscreen.exit:


	; set screen to blue, grey background

	dci	gfx.palette.parameters
	pi	blitGraphic


	; plot text



	dci	text_buttons
	lis	7			; store word length in r10
	lr	10, A
	li	clear		; 0 color
	lr	1, A		
	li	bkg		; 1 color
	lr	2, A
	li	30		; x
	lr	3, A
	lr	11, A		; backup
text_buttons_get_char:
	li	34		; y
	lr	4, A
	lis	8		; width
	lr	5, A	
	lis	5		; height
	lr	6, A
	li	64
	com	
	inc			; -64 in A
	am
	lr	7, A
	xdc
	dci	bitmaps

text_buttons_loop:
	bz	text_buttons_blit_char
	lis	5
	adc
	ds	7
	br	text_buttons_loop

text_buttons_blit_char:
	pi	blit		; plots character
	xdc	
	ds	10
	bz	text_buttons_end
	
	li	6		; add offset to blit x-register
	as	11
	lr	11, A
	lr	3, A
	br	text_buttons_get_char

text_buttons_end:



	dci	text_right
	li	87		; x
	lr	3, A
text_right_get_char:
	li	32		; y
	lr	4, A
	lis	8		; width
	lr	5, A	
	lis	5		; height
	lr	6, A
	li	64
	com	
	inc			; -64 in A
	am
	lr	7, A
	xdc
	dci	bitmaps

text_right_loop:
	bz	text_right_blit_char
	lis	5
	adc
	ds	7
	br	text_right_loop

text_right_blit_char:
	pi	blit		; plots character

text_right_end:



	dci	text_left
	li	9		; x
	lr	3, A
text_left_get_char:
	li	32		; y
	lr	4, A
	lis	8		; width
	lr	5, A	
	lis	5		; height
	lr	6, A
	li	64
	com	
	inc			; -64 in A
	am
	lr	7, A
	xdc
	dci	bitmaps

text_left_loop:
	bz	text_left_blit_char
	lis	5
	adc
	ds	7
	br	text_left_loop

text_left_blit_char:
	pi	blit		; plots character

text_left_end:


	dci	text_control
	lis	13			; store word length in r10
	lr	10, A
	li	12		; x
	lr	3, A
	lr	11, A		; backup
text_control_get_char:
	li	3		; y
	lr	4, A
	lis	8		; width
	lr	5, A	
	lis	5		; height
	lr	6, A
	li	64
	com	
	inc			; -64 in A
	am
	lr	7, A
	xdc
	dci	bitmaps

text_control_loop:
	bz	text_control_blit_char
	lis	5
	adc
	ds	7
	br	text_control_loop

text_control_blit_char:
	pi	blit		; plots character
	xdc	
	ds	10
	bz	text_control_end
	
	li	6		; add offset to blit x-register
	as	11
	lr	11, A
	lr	3, A
	br	text_control_get_char

text_control_end:




	dci	bitmap_numbers
	lis	4			; store word length in r10
	lr	10, A
	li	23		; x
	lr	3, A
	lr	11, A		; backup
text_numbers_get_char:
	li	47		; y
	lr	4, A
	lis	8		; width
	lr	5, A	
	lis	5		; height
	lr	6, A

text_numbers_blit_char:
	pi	blit		; plots character
	ds	10
	bz	text_numbers_end
	
	li	16		; add offset to blit x-register
	as	11
	lr	11, A
	lr	3, A
	br	text_numbers_get_char

text_numbers_end:






	; continously draw any I/O green, mark errors with red

	; check right controller

big_loop:

	clr
	outs	0
	outs	1					; check right hand controller
	ins	1
	com						; re-invert controller data
	lr	10, A					; back-up in r10


	dci	gfx.block4.parameters		; r.hc right
	lr	A, 10
	ni	%00000001
	bnz	rhcright1
	pi	blitGraphic
	br	rhcleft
rhcright1:
	pi	greenGraphic
rhcleft:
	dci	gfx.block3.parameters		; r.hc left
	lr	A, 10
	ni	%00000010
	bnz	rhcleft1
	pi	blitGraphic
	br	rhcbackward
rhcleft1:
	pi	greenGraphic
rhcbackward:
	dci	gfx.block8.parameters		; r.hc backward
	lr	A, 10
	ni	%00000100
	bnz	rhcbackward1
	pi	blitGraphic
	br	rhcforward
rhcbackward1:
	pi	greenGraphic
rhcforward:
	dci	gfx.block7.parameters		; r.hc forward
	lr	A, 10
	ni	%00001000
	bnz	rhcforward1
	pi	blitGraphic
	br	rhcccw
rhcforward1:
	pi	greenGraphic
rhcccw:
	dci	gfx.cclockwise2.parameters	; r.hc ccw
	lr	A, 10
	ni	%00010000
	bnz	rhcccw1
	pi	blitGraphic
	br	rhccw
rhcccw1:
	pi	greenGraphic
rhccw:
	dci	gfx.clockwise2.parameters	; r.hc cw
	lr	A, 10
	ni	%00100000
	bnz	rhccw1
	pi	blitGraphic
	br	rhcup
rhccw1:
	pi	greenGraphic
rhcup:
	dci	gfx.up2.parameters		; r.hc up
	lr	A, 10
	ni	%01000000
	bnz	rhcup1
	pi	blitGraphic
	br	rhcdown
rhcup1:
	pi	greenGraphic
rhcdown:
	dci	gfx.down2.parameters		; r.hc down
	lr	A, 10
	ni	%10000000
	bnz	rhcdown1
	pi	blitGraphic
	br	errorcheckright
rhcdown1:
	pi	greenGraphic



errorcheckright:
	; error check
	lr	A, 10
	ni	%00000011
	ci	%00000011
	bnz	rhcfandb
	dci	gfx.block4.parameters		; r.hc right
	pi	redGraphic
	dci	gfx.block3.parameters		; r.hc left
	pi	redGraphic

rhcfandb:
	lr	A, 10
	ni	%00001100
	ci	%00001100
	bnz	rhccwandccw
	dci	gfx.block8.parameters		; r.hc backward
	pi	redGraphic
	dci	gfx.block7.parameters		; r.hc forward
	pi	redGraphic

rhccwandccw:
	lr	A, 10
	ni	%00110000
	ci	%00110000
	bnz	rhcupanddown
	dci	gfx.cclockwise2.parameters	; r.hc ccw
	pi	redGraphic
	dci	gfx.clockwise2.parameters	; r.hc cw
	pi	redGraphic

rhcupanddown:
	lr	A, 10
	ni	%11000000
	ci	%11000000
	bnz	thelefthandcontroller
	dci	gfx.up2.parameters		; r.hc up
	pi	redGraphic
	dci	gfx.down2.parameters		; r.hc down
	pi	redGraphic



	; check the left controller


thelefthandcontroller:

	clr
	outs	0
	outs	4					; check left hand controller
	ins	4
	com
	lr	10, A					; backup in r10

	dci	gfx.block2.parameters		; l.hc right
	lr	A, 10
	ni	%00000001
	bnz	lhcright1
	pi	blitGraphic
	br	lhcleft
lhcright1:
	pi	greenGraphic
lhcleft:
	dci	gfx.block.parameters		; l.hc left
	lr	A, 10
	ni	%00000010
	bnz	lhcleft1
	pi	blitGraphic
	br	lhcbackward
lhcleft1:
	pi	greenGraphic
lhcbackward:
	dci	gfx.block6.parameters		; l.hc backward
	lr	A, 10
	ni	%00000100
	bnz	lhcbackward1
	pi	blitGraphic
	br	lhcforward
lhcbackward1:
	pi	greenGraphic
lhcforward:
	dci	gfx.block5.parameters		; l.hc forward
	lr	A, 10
	ni	%00001000
	bnz	lhcforward1
	pi	blitGraphic
	br	lhcccw
lhcforward1:
	pi	greenGraphic
lhcccw:
	dci	gfx.cclockwise.parameters	; l.hc ccw
	lr	A, 10
	ni	%00010000
	bnz	lhcccw1
	pi	blitGraphic
	br	lhccw
lhcccw1:
	pi	greenGraphic
lhccw:
	dci	gfx.clockwise.parameters	; l.hc cw
	lr	A, 10
	ni	%00100000
	bnz	lhccw1
	pi	blitGraphic
	br	lhcup
lhccw1:
	pi	greenGraphic
lhcup:
	dci	gfx.up.parameters			; l.hc up
	lr	A, 10
	ni	%01000000
	bnz	lhcup1
	pi	blitGraphic
	br	lhcdown
lhcup1:
	pi	greenGraphic
lhcdown:
	dci	gfx.down.parameters		; l.hc down
	lr	A, 10
	ni	%10000000
	bnz	lhcdown1
	pi	blitGraphic
	br	errorcheckleft
lhcdown1:
	pi	greenGraphic



errorcheckleft:
	; error check
	lr	A, 10
	ni	%00000011
	ci	%00000011
	bnz	lhcfandb
	dci	gfx.block2.parameters		; l.hc right
	pi	redGraphic
	dci	gfx.block.parameters		; l.hc left
	pi	redGraphic

lhcfandb:
	lr	A, 10
	ni	%00001100
	ci	%00001100
	bnz	lhccwandccw
	dci	gfx.block6.parameters		; l.hc backward
	pi	redGraphic
	dci	gfx.block5.parameters		; l.hc forward
	pi	redGraphic

lhccwandccw:
	lr	A, 10
	ni	%00110000
	ci	%00110000
	bnz	lhcupanddown
	dci	gfx.cclockwise.parameters	; l.hc ccw
	pi	redGraphic
	dci	gfx.clockwise.parameters	; l.hc cw
	pi	redGraphic

lhcupanddown:
	lr	A, 10
	ni	%11000000
	ci	%11000000
	bnz	thebuttons
	dci	gfx.up.parameters			; l.hc up
	pi	redGraphic
	dci	gfx.down.parameters		; l.hc down
	pi	redGraphic








thebuttons:

	ins	0				; get button input from port 0
	com					; invert 
	lr	10, A

	dci	gfx.button1.parameters
	lr	A, 10
	ni	%00000001
	bnz	button1on
	pi	blitGraphic
	br	button2
button1on:
	pi	greenGraphic
button2:
	dci	gfx.button2.parameters
	lr	A, 10
	ni	%00000010
	bnz	button2on
	pi	blitGraphic
	br	button3
button2on:
	pi	greenGraphic
button3:
	dci	gfx.button3.parameters
	lr	A, 10
	ni	%00000100
	bnz	button3on
	pi	blitGraphic
	br	button4
button3on:
	pi	greenGraphic
button4:
	dci	gfx.button4.parameters
	lr	A, 10
	ni	%00001000
	bnz	button4on
	pi	blitGraphic
	br	end_of_IO_test
button4on:
	pi	greenGraphic



end_of_IO_test:
	jmp	big_loop

;===========================================================================
; Data 
;===========================================================================



;---------------------------------------------------------------------------

gfx.palette.parameters:
	.byte	bkg			; color 1
	.byte	green			; color 2
	.byte	121			; x position
	.byte	0			; y position
	.byte	2			; width
	.byte	58			; height
	.word	gfx.palette.data	; address for the graphics

gfx.palette.data:

	.byte %01010111, %11111111, %01010101, %01010101, %01010101, %01010101, %01010101
	.byte %01010101, %11111111, %11111101, %01010101, %01010111, %11111111, %01010101
	.byte %01010101

;---------------------------------------------------------------------------

gfx.block.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	10			; x position
	.byte	20			; y position
	.byte	7			; width
	.byte	3			; height
	.word	gfx.block.data	; address for the graphics

gfx.block.data:

	.byte $ff,$ff,$ff

gfx.block2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	31			; x position
	.byte	20			; y position
	.byte	7			; width
	.byte	3			; height
	.word	gfx.block.data	; address for the graphics

gfx.block3.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	63			; x position
	.byte	20			; y position
	.byte	7			; width
	.byte	3			; height
	.word	gfx.block.data	; address for the graphics

gfx.block4.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	84			; x position
	.byte	20			; y position
	.byte	7			; width
	.byte	3			; height
	.word	gfx.block.data	; address for the graphics





gfx.block5.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	22			; x position
	.byte	11			; y position
	.byte	4			; width
	.byte	5			; height
	.word	gfx.block5.data	; address for the graphics

gfx.block5.data:

	.byte $ff,$ff,$ff,$ff

gfx.block6.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	22			; x position
	.byte	27			; y position
	.byte	4			; width
	.byte	5			; height
	.word	gfx.block5.data	; address for the graphics

gfx.block7.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	75			; x position
	.byte	11			; y position
	.byte	4			; width
	.byte	5			; height
	.word	gfx.block5.data	; address for the graphics

gfx.block8.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	75			; x position
	.byte	27			; y position
	.byte	4			; width
	.byte	5			; height
	.word	gfx.block5.data	; address for the graphics


gfx.clockwise.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	28			; x position
	.byte	11			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.clockwise.data	; address for the graphics

gfx.clockwise.data:
	.byte %01000000,%11110000,%01111000,%00011101,%00000111,%00011111
	
	
gfx.clockwise2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	81			; x position
	.byte	11			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.clockwise.data	; address for the graphics



gfx.cclockwise.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	12			; x position
	.byte	11			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.cclockwise.data	; address for the graphics

gfx.cclockwise.data:
	.byte %00000010,%00001111,%00011110,%10111000,%11100000,%11111000	

gfx.cclockwise2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	65			; x position
	.byte	11			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.cclockwise.data	; address for the graphics

gfx.up.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	22			; x position
	.byte	20			; y position
	.byte	4			; width
	.byte	3			; height
	.word	gfx.up.data	; address for the graphics

gfx.up.data:
	.byte %01101111,%01100000

gfx.up2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	75			; x position
	.byte	20			; y position
	.byte	4			; width
	.byte	3			; height
	.word	gfx.up.data	; address for the graphics


gfx.down.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	19			; x position
	.byte	18			; y position
	.byte	10			; width
	.byte	7			; height
	.word	gfx.down.data		; address for the graphics

gfx.down.data:
	.byte %00011110,%00011000,%01100100,%00001011,%00000011
	.byte %01000000,%10011000,%01100001,%11100000

;0001111000
;0110000110
;0100000010
;1100000011
;0100000010
;0110000110
;0001111000


gfx.down2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	72			; x position
	.byte	18			; y position
	.byte	10			; width
	.byte	7			; height
	.word	gfx.down.data		; address for the graphics



gfx.button1.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	21			; x position
	.byte	40			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.button1.data	; address for the graphics

gfx.button1.data:

	.byte $ff,$ff,$ff,$ff,$ff,$ff

gfx.button2.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	37			; x position
	.byte	40			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.button1.data	; address for the graphics

gfx.button3.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	53			; x position
	.byte	40			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.button1.data	; address for the graphics

gfx.button4.parameters:
	.byte	clear			; color 1
	.byte	bkg			; color 2
	.byte	70			; x position
	.byte	40			; y position
	.byte	8			; width
	.byte	6			; height
	.word	gfx.button1.data	; address for the graphics	


text_buttons:
	.byte "BUTTONS"
text_left:
	.byte "L"
text_right:
	.byte "R"
text_control:
	.byte "TEST@CONTROLS"

	



bitmaps:	;5x5 character bitmaps	offset 
	db	$00,$00,$00,$00,$00	; space
	db	$F8,$88,$F8,$88,$88	; "A"
	db	$F8,$48,$78,$48,$F8	; "B"
	db	$F8,$80,$80,$80,$F8	; "C"
	db	$F8,$48,$48,$48,$F8	; "D"
	db	$F8,$80,$E0,$80,$F8	; "E"
	db	$F8,$80,$E0,$80,$80	; "F"
	db	$F8,$80,$98,$88,$F8	; "G"
	db	$88,$88,$F8,$88,$88	; "H"
	db	$F8,$20,$20,$20,$F8	; "I"
	db	$F8,$20,$20,$A0,$E0	; "J"
	db	$90,$A0,$C0,$A0,$90	; "K"
	db	$80,$80,$80,$80,$F8	; "L"
	db	$88,$D8,$A8,$88,$88	; "M"
	db	$88,$C8,$A8,$98,$88	; "N"
	db	$F8,$88,$88,$88,$F8	; "O"
	db	$F8,$88,$F8,$80,$80	; "P"
	db	$F8,$88,$88,$90,$E8	; "Q"
	db	$F8,$88,$F8,$90,$88	; "R"
	db	$F8,$80,$F8,$08,$F8	; "S"
	db	$F8,$20,$20,$20,$20	; "T"
	db	$88,$88,$88,$88,$F8	; "U"
	db	$88,$88,$88,$50,$20	; "V"
	db	$88,$88,$A8,$D8,$88	; "W"
	db	$88,$50,$20,$50,$88	; "X"
	db	$88,$88,$F8,$20,$20	; "Y"
	db	$F8,$10,$20,$40,$F8	; "Z"
bitmap_numbers:
	db	$20,$60,$20,$20,$70	; "1"
	db	$F8,$08,$F8,$80,$F8	; "2"
	db	$F8,$08,$38,$08,$F8	; "3"
	db	$88,$88,$F8,$08,$08	; "4"


;===========================================================================
; Includes 
;===========================================================================

	include	"drawing.inc"

;===========================================================================
; Signature 
;===========================================================================

	; signature
	org [$800 + [game_size * $400] - $10]

signature:

	.byte	"·Blåholtz·  2007"


Code for drawing.inc:

;===================;
; Drawing Functions ;
;===================;

;---------------;
; Plot Function ;
;---------------;

; plot out a single point on the screen
; uses three registers as "arguments"
; r1 = color
; r2 = x (to screen) (0-101)
; r3 = y (to screen) (0-57)

plot:
	; set the color using r1
	lr	A, 1
	outs	1

	; set the column using r2
	lis	4
	as	2						; fix the x coordinate
	com
	outs	4

	; set the row using r3
	lis	4
	as	3						; fix the y coordinate
	com
	outs	5

	; transfer data to the screen memory
	lis	$6
	sl	4
	outs	0
	lis	$5
	sl	4
	outs	0

	; delay until it's fully updated
	lis	6
plot.delay:	
	ai	$ff
	bnz	plot.delay

	pop							; return from the subroutine

; takes graphic parameters from ROM, stores them in r1-r6, 
; changes the DC and calls the blit function with the parameters

blitGraphic:
	; load six bytes from the parameters into r0-r5
	lisu	0
	lisl	1
blitGraphic.getParams:
	lm   
	lr	I, A						; store byte and decrease ISAR
	br7	blitGraphic.getParams				; not finished with the registers, loop

	; load the graphics address
	lm
	lr	Qu, A						; into Q
	lm
	lr	Ql, A
	lr	DC, Q						; load it into the DC

	; call the blit function
	jmp	blit

;---------------;
; Blit Function ;
;---------------;
; this function blits a graphic based on parameters set in r1-r6,
; and the graphic data pointed to by DC0, onto the screen
;
; originally from cart 26, modified and annotated
; uses r1-r9, K, Q
;
; r1 = color 1 (off)
; r2 = color 2 (on)
; r3 = x position
; r4 = y position
; r5 = width
; r6 = height (and vertical counter)
;
; r7 = horizontal counter
; r8 = graphics byte
; r9 = bit counter
;
; DC = pointer to graphics

blit:
	; adjust the x coordinate
	lis	4
	as	3
	lr	3, A
	; adjust the y coordinate
	lis	4
	as	4
	lr	4, A

	lis	1
	lr	9, A						; load #1 into r9 so it'll be reset when we start
	lr	A, 4						; load the y offset
	com							; invert it
blit.row:
	outs	5						; load accumulator into port 5 (row)

	; check vertical counter
	ds	6						; decrease r6 (vertical counter)
	bnc	blit.exit					; if it rolls over exit

	; load the width into the horizontal counter
	lr	A, 5
	lr	7, A

	lr	A, 3						; load the x position
	com							; complement it
blit.column:
	outs	4						; use the accumulator as our initial column
	; check to see if this byte is finished
	ds	9						; decrease r9 (bit counter)
	bnz	blit.drawBit					; if we aren't done with this byte, branch

blit.getByte:
	; get the next graphics byte and set related registers
	lis	8
	lr	9, A						; load #8 into r9 (bit counter)
	lm
	lr	8, A						; load a graphics byte into r8

blit.drawBit:
	; shift graphics byte
	lr	A, 8						; load r8 (graphics byte)
	as	8						; shift left one (with carry)
	lr	8, A						; save it

	; check color to use
	lr	A, 2						; load color 1
	bc	blit.savePixel					; if this bit is on, draw the color
	lr	A, 1						; load color 2
blit.savePixel:
	inc
	bc	blit.checkColumn				; branch if the color is "clear"
	outs	1						; output A in p1 (color)

blit.transferData:
	; transfer the pixel data
	li	$60
	outs	0
	li	$40
	outs	0


	; and delay a little bit
; =============================================================================
; 
; The original delay was 35.5 cycles:
;
;	Acumulator was $C0
;
;blit.savePixelDelay:
; 	ai	$60
;	bnz	blit.savePixelDelay				; small delay
;
;
;	 9 cycle delay works on old NTSC system
;	 8 is to little.  (tested by e5frog)
;
;
;	jmp	blit.savePixelDelay				; 5.5 cycles
;blit.savePixelDelay:
;	br	blit.checkColumn				; 3.5 cycles
;
;
;	 Old PAL system works faster and requires longer delay
;        12.5 cycles is sufficient, 12 is too little


	lis	2
blit.savePixelDelay:
	ai	$ff
	bnz	blit.savePixelDelay

blit.checkColumn:
	ds	7						; decrease r7 (horizontal counter)
	bz	blit.checkRow					; if it's 0, branch

	ins	4						; get p4 (column)
	ai	$ff						; add 1 (complemented)
	br	blit.column					; branch

blit.checkRow:
	ins	5						; get p5 (row)
	ai	$ff						; add 1 (complemented)
	br	blit.row					; branch

blit.exit:
	; return from the subroutine
	pop



greenGraphic:
	; load six bytes from the parameters into r0-r5
	lisu	0
	lisl	1

	lm   
	lr	I, A						; store byte and decrease ISAR
	lm
	li	green
	lr	I, A

	br	blitGraphic.getParams


redGraphic:
	; load six bytes from the parameters into r0-r5
	lisu	0
	lisl	1

	lm   
	lr	I, A						; store byte and decrease ISAR
	lm
	li	red
	lr	I, A
	br	blitGraphic.getParams