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Add code for not working scanline interupt (for future dubbel buffer)

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hugova 2025-05-02 20:46:27 +02:00
parent 1a8d4593ed
commit a5044d6e4c
2 changed files with 79 additions and 3 deletions
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3
wip-hugo/STARTUP.s
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@ -86,9 +86,6 @@
;;https://codebase64.org/doku.php?id=base:nmi_lock_without_kernal
;; write to $FFFA/$FFFB possible (and needed) if BASIC ROM is disabled
LDA #$00
STA $CCCC
LDA #<NMI_routine
STA $FFFA
LDA #>NMI_routine

79
wip-hugo/dubbel_buffer/raster_irqs.s Normal file
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@ -0,0 +1,79 @@
.scope raster_irq
;;https://codebase64.org/doku.php?id=base:introduction_to_raster_irqs
sei ;disable maskable IRQs
lda #$7f
sta $dc0d ;disable timer interrupts which can be generated by the two CIA chips
sta $dd0d ;the kernal uses such an interrupt to flash the cursor and scan the keyboard, so we better
;stop it.
lda $dc0d ;by reading this two registers we negate any pending CIA irqs.
lda $dd0d ;if we don't do this, a pending CIA irq might occur after we finish setting up our irq.
;we don't want that to happen.
lda #$01 ;this is how to tell the VICII to generate a raster interrupt
sta $d01a
lda #$0FF ;this is how to tell at which rasterline we want the irq to be triggered
sta $d012
lda #$1b ;as there are more than 256 rasterlines, the topmost bit of $d011 serves as
sta $d011 ;the 9th bit for the rasterline we want our irq to be triggered.
;here we simply set up a character screen, leaving the topmost bit 0.
lda #$35 ;we turn off the BASIC and KERNAL rom here
sta $01 ;the cpu now sees RAM everywhere except at $d000-$e000, where still the registers of
;SID/VICII/etc are visible
lda #<irq ;this is how we set up
sta $fffe ;the address of our interrupt code
lda #>irq
sta $ffff
cli ;enable maskable interrupts again
jmp irq_end
irq:
;Being all kernal irq handlers switched off we have to do more work by ourselves.
;When an interrupt happens the CPU will stop what its doing, store the status and return address
;into the stack, and then jump to the interrupt routine. It will not store other registers, and if
;we destroy the value of A/X/Y in the interrupt routine, then when returning from the interrupt to
;what the CPU was doing will lead to unpredictable results (most probably a crash). So we better
;store those registers, and restore their original value before reentering the code the CPU was
;interrupted running.
;If you won't change the value of a register you are safe to not to store / restore its value.
;However, it's easy to screw up code like that with later modifying it to use another register too
;and forgetting about storing its state.
;The method shown here to store the registers is the most orthodox and most failsafe.
sei
pha ;store register A in stack
txa
pha ;store register X in stack
tya
pha ;store register Y in stack
lda #$ff ;this is the orthodox and safe way of clearing the interrupt condition of the VICII.
sta $d019 ;if you don't do this the interrupt condition will be present all the time and you end
;up having the CPU running the interrupt code all the time, as when it exists the
;interrupt, the interrupt request from the VICII will be there again regardless of the
;rasterline counter.
;it's pretty safe to use inc $d019 (or any other rmw instruction) for brevity, they
;will only fail on hardware like c65 or supercpu. c64dtv is ok with this though.
pla
tay ;restore register Y from stack (remember stack is FIFO: First In First Out)
pla
tax ;restore register X from stack
pla ;restore register A from stack
clc
rti ;Return From Interrupt, this will load into the Program Counter register the address
;where the CPU was when the interrupt condition arised which will make the CPU continue
;the code it was interrupted at also restores the status register of the CPU
irq_end:
.endscope