cc65/libsrc/cbm610/crt0.s

;
; Startup code for cc65 (CBM 600/700 version)
;
; This must be the *first* file on the linker command line
;

	.export	     	_exit
	.exportzp       crtc, sid, IPCcia, cia, acia, tpi1, tpi2, ktab1
	.exportzp       ktab2, ktab3, ktab4, time, RecvBuf, SendBuf

	.import		initlib, donelib
	.import	     	push0, _main
	.import	       	__BSS_RUN__, __BSS_SIZE__
	.import		irq, nmi
       	.import	       	k_irq, k_nmi, k_plot, k_udtim, k_scnkey

	.include     	"zeropage.inc"
	.include    	"cbm610.inc"


; ------------------------------------------------------------------------
; BASIC header and a small BASIC program. Since it is not possible to start
; programs in other banks using SYS, the BASIC program will write a small
; machine code program into memory at $100 and start that machine code
; program. The machine code program will then start the machine language
; code in bank 1, which will initialize the system by copying stuff from
; the system bank, and start the application.
;
; Here's the basic program that's in the following lines:
;
; 10 for i=0 to 4
; 20 read j
; 30 poke 256+i,j
; 40 next i
; 50 sys 256
; 60 data 120,169,1,133,0
;
; The machine program in the data lines is:
;
; sei
; lda 	  #$01
; sta     $00	       	<-- Switch to bank 1 after this command
;
; Initialization is not only complex because of the jumping from one bank
; into another. but also because we want to save memory, and because of
; this, we will use the system memory ($00-$3FF) for initialization stuff
; that is overwritten later.
;

.code

; To make things more simple, make the code of this module absolute.

   	.org	$0001
Head:	.byte	$03,$00,$11,$00,$0a,$00,$81,$20,$49,$b2,$30,$20,$a4,$20,$34,$00
   	.byte	$19,$00,$14,$00,$87,$20,$4a,$00,$27,$00,$1e,$00,$97,$20,$32,$35
   	.byte	$36,$aa,$49,$2c,$4a,$00,$2f,$00,$28,$00,$82,$20,$49,$00,$39,$00
   	.byte	$32,$00,$9e,$20,$32,$35,$36,$00,$4f,$00,$3c,$00,$83,$20,$31,$32
   	.byte	$30,$2c,$31,$36,$39,$2c,$31,$2c,$31,$33,$33,$2c,$30,$00,$00,$00

; Since we need some vectors to access stuff in the system bank for our own,
; we will include them here, starting from $60:

      	.res	$60-*

crtc:  		.word  	$d800
sid:		.word  	$da00
IPCcia:		.word  	$db00
cia:   		.word  	$dc00
acia:  		.word  	$dd00
tpi1:		.word  	$de00
tpi2:  		.word  	$df00
ktab1:		.word  	$ea29
ktab2:	       	.word  	$ea89
ktab3:		.word	$eae9
ktab4:		.word  	$eb49
time:		.dword 	$0000
RecvBuf:	.word	$0100		; RS232 received buffer
SendBuf:	.word	$0200		; RS232 send buffer


; The code in the target bank when switching back will be put at the bottom
; of the stack. We will jump here to switch segments. The range $F2..$FF is
; not used by any kernal routine.

      	.res	$F8-*
Back:	ldx	spsave
   	txs
   	lda    	IndReg
   	sta	ExecReg

; The following code is a copy of the code that is poked in the system bank
; memory by the basic header program, it's only for documentation and not
; actually used here:

     	sei
     	lda	#$01
     	sta	ExecReg

; This is the actual starting point of our code after switching banks for
; startup. Beware: The following code will get overwritten as soon as we
; use the stack (since it's in page 1)!

      	tsx
       	stx	spsave 		; Save the system stackpointer
	ldx	#$FF
	txs	       		; Set up our own stack

; Set the interrupt, NMI and other vectors

      	ldy	#vectable_size
L0:   	lda	vectable-1,y
      	sta	$FF80,y
      	dey
       	bne    	L0

; Switch the indirect segment to the system bank

      	lda	#$0F
      	sta	IndReg

; Copy the kernal zero page ($90-$F2) from the system bank

   	lda  	#$90
   	sta	ptr1
	lda	#$00
   	sta	ptr1+1
   	ldy	#$62-1
L1:	lda	(ptr1),y
   	sta	$90,y
   	dey
   	bpl 	L1

; Copy the page 3 vectors in place

	ldy	#$00
L2:	lda	p3vectable,y
  	sta	$300,y
   	iny
  	cpy	#p3vectable_size
       	bne	L2

; Copy the rest of page 3 from the system bank

      	lda	#$00
      	sta	ptr1
	lda	#$03
	sta	ptr1+1
L3:	lda	(ptr1),y
   	sta	$300,y
   	iny
   	bne	L3

; Set the indirect segment to bank we're executing in

	lda	ExecReg
	sta	IndReg

; Zero the BSS segment. We will do that here instead calling the routine
; in the common library, since we have the memory anyway, and this way,
; it's reused later.

   	lda	#<__BSS_RUN__
   	sta	ptr1
	lda	#>__BSS_RUN__
   	sta	ptr1+1
	lda	#0
	tay

; Clear full pages

   	ldx	#>__BSS_SIZE__
   	beq	Z2
Z1:	sta	(ptr1),y
   	iny
   	bne	Z1
   	inc	ptr1+1			; Next page
   	dex
   	bne	Z1

; Clear the remaining page

Z2:	ldx	#<__BSS_SIZE__
   	beq	Z4
Z3:	sta	(ptr1),y
   	iny
   	dex
   	bne	Z3
Z4:

; Setup the C stack

	lda   	#<$FF81
	sta	sp
       	lda	#>$FF81
	sta	sp+1

; We expect to be in page 2 now

.if 	(* < $1FD)
	jmp	$200
   	.res	$200-*
.endif
.if	(* < $200)
     	.res	$200-*,$EA
.endif
.if    	(* >= $2F0)
.error	"Code range invalid"
.endif

; This code is in page 2, so we may now start calling subroutines safely,
; since the code we execute is no longer in the stack page.
; Call module constructors

	jsr	initlib

; Create the (empty) command line for the program

       	jsr    	push0 	       	; argc
       	jsr	push0	       	; argv

; Execute the program code

	jmp	Start

; ------------------------------------------------------------------------
; Additional data that we need for initialization and that's overwritten
; later

vectable:
      	jmp	$0000		; CINT
      	jmp	$0000		; IOINIT
      	jmp	$0000		; RAMTAS
      	jmp	$0000	      	; RESTOR
      	jmp	$0000	      	; VECTOR
      	jmp	$0000	      	; SETMSG
      	jmp	$0000  	      	; SECOND
      	jmp	$0000	      	; TKSA
      	jmp	$0000	      	; MEMTOP
      	jmp	$0000	      	; MEMBOT
      	jmp	k_scnkey	; SCNKEY
      	jmp	$0000	      	; SETTMO
      	jmp	$0000	      	; ACPTR
      	jmp	$0000	      	; CIOUT
      	jmp	$0000  	      	; UNTLK
      	jmp	$0000	      	; UNLSN
      	jmp	$0000	      	; LISTEN
      	jmp	$0000	      	; TALK
   	jmp	$0000	      	; READST
       	jmp    	k_setlfs	; SETLFS
       	jmp    	k_setnam 	; SETNAM
     	jmp	$0000	      	; OPEN
	jmp	$0000 	      	; CLOSE
	jmp	$0000	      	; CHKIN
	jmp	$0000	      	; CKOUT
	jmp	$0000	      	; CLRCH
	jmp	$0000	      	; BASIN
      	jmp	$0000	      	; BSOUT
	jmp	$0000	      	; LOAD
	jmp	$0000	      	; SAVE
	jmp	k_settim	; SETTIM
       	jmp    	k_rdtim		; RDTIM
	jmp	$0000	      	; STOP
   	jmp	$0000	      	; GETIN
	jmp	$0000	      	; CLALL
	jmp	k_udtim		; UDTIM
   	jmp	k_screen  	; SCREEN
	jmp	k_plot		; PLOT
	jmp	k_iobase	; IOBASE
   	sta	ExecReg
	rts
	.byte  	$01 	      	; Filler
       	.word	nmi
       	.word	0     	      	; Reset - not used
       	.word	irq
vectable_size	= * - vectable

p3vectable:
	.word	k_irq		; IRQ user vector
	.word	k_brk		; BRK user vector
	.word	k_nmi		; NMI user vector
p3vectable_size	= * - p3vectable


; ------------------------------------------------------------------------
; This is the program code after setup. It starts at $400

   	.res	$400-*

Start:

; Enable interrupts

      	cli

; Call the user code

       	ldy	#4    	       	; Argument size
       	jsr    	_main 		; call the users code

; Call module destructors. This is also the _exit entry.

_exit:	jsr	donelib		; Run module destructors

; Clear the start of the zero page, since it will be interpreted as a
; (garbage) BASIC program otherwise. This is also the default entry for
; the break vector.

k_brk:	sei
      	lda	#$00
      	ldx	#$3E
Clear:	sta	$02,x
      	dex
      	bne	Clear

; Setup the welcome code at the stack bottom in the system bank. Use
; the F4/F5 vector to access the system bank

      	lda	#$0F
      	sta	IndReg
      	ldy    	#$00
       	sty	$F4
      	iny
      	sty	$F5
   	ldy	#reset_size-1
@L1:	lda	reset,y
   	sta	($F4),y
   	dey
   	bne	@L1
   	jmp	Back

; ------------------------------------------------------------------------
; Code that is copied into the system bank at $100 when switching back

reset:	cli
	jmp	$8000		   	; BASIC cold start
reset_size = * - reset

; ------------------------------------------------------------------------
; Code for a few simpler kernal calls goes here

k_iobase:
	ldx	cia
	ldy	cia+1
	rts

k_screen:
   	ldx	#80		; Columns
	ldy	#25		; Lines
	rts

k_setlfs:
        sta     LogicalAdr
        stx     FirstAdr
        sty     SecondAdr
        rts

k_setnam:
        sta     FileNameLen
        lda     $00,x
        sta     FileNameAdrLo
        lda     $01,x
        sta     FileNameAdrHi
        lda     $02,x
        sta     FileNameAdrSeg
        rts

k_rdtim:
	sei
	lda	time+0
   	ldx	time+1
	ldy	time+2
	cli
	rts

k_settim:
	sei
	sta	time+0
   	stx	time+1
	sty	time+2
	cli
	rts

; -------------------------------------------------------------------------
; Data area - switch back to relocatable mode

	.reloc

.data
spsave:	.res	1