A list of small routines that can help you. Feel free to add your own.
Directly polls the hardware for battery status. Thanks to Steve Riekeberg.
;Name: BatteryStatus ;Description: Returns if the batteries are good, or low and need changing. ;Inputs: None ;Outputs: Non-Zero = Good Batteries Zero = Batteries Low ;Destroys: A GetBatteryStatus: in a, (2) and 01h ret
Alternatively, save a byte and 3cc and have the output in the c flag (c means good, nc bad):
GetBatteryStatus: in a,(2) \ rra \ ret
Original: Adm. Wiggin. New: Zeda. Checks if coordinates is inside a designated box.
#define x 10 #define y 10 #define width 10 #define height 20 check: ;Input: a,b = x,y ;Output: c if the coords are in the box, nc if not. ;destorys af ;25cc or 47cc, 11 bytes ;compare too: 33cc~75cc, 20 bytes sub x sub width ret nc ld a,b sub y sub height ret
Displays a string centered on the screen (small font). Thanks to WikiGuru.
;input:hl points to string ;output: string displayed centered on screen ;destroyed: all registers ;other remarks: (penrow) must be set before calling this sub-routine ; first byte of string must be the length of the string centertxt: bcall(_SStringLength) ld a,96 ;width of screen sub b ;subtract width of string rra ;divide by 2 to be centered ld (pencol),a ld b,(hl) inc hl bcall(_VPutSN) ret ;to call: ... ld hl,0 ld (penrow),hl ld hl,txtTest call centertxt ... txtTest: .db 11,"Sample Text"
Used for direct input. See here to learn more about direct input. Thanks to Steve Riekeberg.
;Name: DirectInput ;Inputs: A = Key Group ;Outputs: A = Key Code; Zero If None ;Destroys: A, B DirectInput: ld b,a ld a,$ff ;Reset the keypad out (1),a ld a,b out (1),a in a,(1) ret
Checks if h>b, l>c, h<d, and l<e. Thanks to kermmartian and DarkerLine.
;----------Hot spot detection----------- ;inputs: b,c (first x and y cor) ; d,e (last x and y cor) ; h,l (current x,y) ;output: "c" flag [either true (set) or false (reset)] hdetect: ld a,h cp b ccf ret nc cp d ret nc ld a,l cp c ccf ret nc cp e ret
Turns the calculator "off" and waits for user to press on. Note: Pulling batteries out will result in Ram Clear. Thanks to Taricorp.
;no inputs ld a,02h out (10h),a ;Turn off LCD ld a,08h out (3),a call LCD_Delay ld a,36h out (4),a ld a,01h out (3),a halt ;It halts until ON is pressed ld a,0Bh out (3),a ld a,03h out (10h),a ;Turn the LCD back on res onKey,(iy+keyFlags)
Find Next App
This routine is useful if you want to manually search through the installed apps on a calculator.
FindNextApp: ;Inputs: ; B is the base page of the app. ;Outputs: ; c flag set if the field was found ; nc means the app header subfield was not found ; B is the number of pages of the app ; A is the page of the next app ; H is the input page number ; L is the page number of the currently swapped in page in bank 1 ; ;Comments: ; This code must run in RAM in a,(6) ld c,a push bc ;b is the app page, c is the current page ld a,b out (6),a call FindNumPages pop hl ;h is the app page, l is the current page ld b,a ld a,l out (6),a ld a,h ret nc sub b scf ret FindNumPages: ;Outputs: ; c flag set if the field was found ; nc means the app header subfield was not found ; A is the number of app pages ; B is 0 ; (HL) is the number of app pages ld hl,4000h ld bc,128 ld a,c or a FNPLoop: cpir ret po ret nz inc a cp (hl) jr z,$+6 dec a jp FNPLoop inc l ld a,(hl) scf ret
When reading through data in MemBank1, this routine is particularly useful as it adjusts the flash pages accordingly, as well as the pointer HL. If HL does not point to data in MemBank1 (4000h~7FFFh) then HL will simply be incremented, which is useful if the data might be in RAM or flash.
incFPtr: ;15cc or 24cc or 69cc, avg: ~15.03845cc inc l \ ret nz incptr: inc h \ ret po ld h,a in a,(6) \ inc a \ out (6),a ld a,h ld h,40h ret
It destroys no registers and is very efficient. However, if you are really in need of speed, such as with a ReadArc routine, you can try something like this (conditionally calling the routine):
inc l \ call z,incptr
This code is not as efficient as it could be, but it works. it sorts a bunch of bytes to be in ascending order:
SortA: ;Inputs: ; BC is the size ; HL is where the data is located ;Takes at least n iterations, at most n(n+1)/2 ld d,h ld e,l SortALoop: push bc push de ld a,(hl) call SwapBytes SortLoop1: jp po,NextSort cp (hl) cpi jr c,SortLoop1 dec hl call z,SwapBytes jr c,SortLoop1 EndSwap: pop de jr SortALoop+1 NextSort: pop hl pop bc dec hl add hl,bc or a sbc hl,de ret c ret z ld b,h ld c,l inc bc ex de,hl jp SortA+1 SwapBytes: inc bc push af ld a,(de) ldi dec hl ld (hl),a inc hl pop af scf ret
This routine will set the calculator to 15MHz mode if possible:
Set15MHz: ;Ouputs: ; Sets the calculator to 15MHz if possible ; z flag set if the calc is at 6MHz, nz if at 15MHz in a,(2) sbc a,a and 3 out (20h),a ret
This is pretty tiny (3 bytes) so it isn't worth making it a subroutine. In other words, just use it inline:
xor a out (20h),a