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180 lines
6.0 KiB
Plaintext
180 lines
6.0 KiB
Plaintext
; ribos2.p65 - p65 assembly source for RIBOS2:
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; Demonstration of the VIC-II raster interrupt on the Commodore 64:
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; Alter the border colour in the middle part of the screen only,
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; Simplified (KERNAL IRQ vector) version.
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; By Chris Pressey, Cat's Eye Technologies.
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; This work has been placed in the public domain.
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; ----- BEGIN ribos2.p65 -----
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; This is a simplified version of ribos.p65 which uses the Commodore 64
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; KERNAL's support for interrupt handling. Whereas ribos.p65 could run
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; with the KERNAL completely disabled, ribos2.p65 relies on it.
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; I'll assume you've read through ribos.p65 at least once, and won't
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; say much about the code that's shared between the two programs.
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; Again, page references are from the 'Commodore 64 Programmer's
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; Reference Guide'.
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.org 0
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.word $C000
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.org $C000
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; ----- Constants -----
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; The CIA #1 chip.
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.alias cia1 $dc00 ; pp. 328-331
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.alias intr_ctrl cia1+$d ; "CIA Interrupt Control Register
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; (Read IRQs/Write Mask)"
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; The VIC-II chip.
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.alias vic $d000 ; Appendix G:
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.alias vic_ctrl vic+$11 ; "Y SCROLL MODE"
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.alias vic_raster vic+$12 ; "RASTER"
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.alias vic_intr vic+$19 ; "Interrupt Request's" (sic)
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.alias vic_intr_enable vic+$1a ; "Interrupt Request MASKS"
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.alias border_color vic+$20 ; "BORDER COLOR"
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; The address at which the IRQ vector is stored.
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.alias cinv $0314 ; p. 319, "Vector: Hardware
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; IRQ Interrupt"
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; ----- Main Routine -----
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; This routine is intended to be called by the user (by, e.g., SYS 49152).
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; It installs the raster interrupt handler and returns to the caller.
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; Key to installing the interrupt handler is altering the IRQ service
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; vector. As I learned from a careful reading of Sheldon Leemon's
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; "Mapping the Commodore 64", if we wish to leave the KERNAL intact and
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; operational, it gives us an easy way to do that. Whenever it handles
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; an IRQ, it has to decide whether the IRQ was generated by a BRK
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; instruction, or some external device issuing an interrupt request. In
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; either case, it jumps indirectly through its IRQ-handling vector. We
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; can simply modify this vector (at $314) to point to our routine. In
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; fact, this is the "CINV" vector, which may already be familiar to you
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; if you have done any modest amount of C64 machine language programming;
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; it is normally called every 1/60 of a second due to the interrupt
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; request generated by CIA#1 Timer B. Here we will simply be using it
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; to detect when a raster interrupt has occurred, as well.
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; First, disable interrupts before changing interrupt vectors.
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sei
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; We obtain the address of the current IRQ service routine in CINV
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; and save it in the variable 'saved_irq_vec'.
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lda cinv
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sta saved_irq_vec
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lda cinv+1
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sta saved_irq_vec+1
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; We then store the address of our IRQ service routine in its place.
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lda #<our_service_routine
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sta cinv
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lda #>our_service_routine
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sta cinv+1
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; Now we must specify the raster line at which the interrupt gets called,
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; setting the ninth bit to zero.
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lda scanline
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sta vic_raster
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lda vic_ctrl
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and #%01111111
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sta vic_ctrl
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; Then we enable the raster interrupt on the VIC-II chip.
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lda #$01
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sta vic_intr_enable
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; We read the interrupt control port of CIA #1 for good measure.
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lda intr_ctrl
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; And we re-enable interrupts to resume normal operation -- plus our jazz.
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cli
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; Finally, we return to the caller.
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rts
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; ----- Raster Interrupt Service Routine ------
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our_service_routine:
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; First, we check to see if the current interrupt was caused by the raster.
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lda vic_intr
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sta vic_intr
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and #$01
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cmp #$01
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beq we_handle_it
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; If the interrupt was not caused by the raster, we continue execution as
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; normal, with the existing interrupt service routine.
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jmp (saved_irq_vec)
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we_handle_it:
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; If we got here, the interrupt was caused by the raster, so we do our thing.
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lda border_color
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eor #$ff
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sta border_color
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; Now, we make the interrupt trigger on the other scan line next time.
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lda scanline
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eor #$ff
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sta scanline
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sta vic_raster
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; Return to normal operation. If we simply continue with the standard
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; interrupt service routine by jumping through saved_irq_req, we will
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; confuse it a bit, as it expects to be called 60 times per second, and
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; continuing it here would make it occur more frequently. The result
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; would be the cursor blinking more frequently and the time of day clock
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; running fast.
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; So, we issue a plain return from interrupt (RTI) here. But first, we
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; must make sure that the state of the system is back to the way it was
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; when the interrupt service routine was called. Since it can be called
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; from anywhere, and since the code that was interrupted likely cares
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; deeply about the values in its registers, the KERNAL routine which
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; dispatches through CINV first carefully saves the contents of the
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; registers on the stack. We must be equally careful about restoring
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; those values before switching back to that interrupted code.
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pla
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tay
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pla
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tax
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pla
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rti
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; ----- Variables -----
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; 'scanline' stores the raster line that we want the interrupt to trigger
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; on; it gets loaded into the VIC-II's 'vic_raster' register.
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scanline: .byte %01010101
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; We also reserve space to store the address of the interrupt service
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; routine that we are replacing in the IRQ vector, so that we can transfer
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; control to it at the end of our routine.
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.space saved_irq_vec 2
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; ----- END of ribos2.p65 -----
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