ATR: chpt.10: System Interrupts

From: Doug Wokoun (aa384)
Date: 12/25/89-06:02:56 AM Z


From: aa384 (Doug Wokoun)
Subject: ATR: chpt.10: System Interrupts
Date: Mon Dec 25 06:02:56 1989

 
                                  CHAPTER 10
     
     
                               SYSTEM INTERRUPTS
     
     
     There are four types of interrupts which can occur with the 6502
     microprocessor:
     
                                6502 interrupts
     
     
          1.   chip reset
          2.   IRQ, interrupt request (maskable)
          3.   MNI (non-maskable interrupt)
          4.   software interrupt (BRK instruction)
     
     CHIP RESET
     
     On the 400/800 the chip reset occurs only upon power-up and causes the
     computer to do a cold start.  On later models, pressing [SYSTEM RESET]
     will cause a chip reset but the computer then does a warm start.  On
     the 400/800, the [SYSTEM RESET] key generates a NMI interrupt.
     
     COLD START
     
     This is a synopsis of the cold start routine.
     
     1
     The warm start flag [$0008] is set to 0 (false)
     
     2
     If a cartridge slot contains a diagnostic cartridge, control is handed
     to the cartridge.
     
     3
     The end of RAM is determined by trying to complement the first byte of
     each 4K block of memory.
     
     4
     Hardware registers at $D000 - $D4FF (except $D100 - $D1FF) are
     cleared.
     
     5
     RAM is cleared from $0008 to the top of ram.
     
     6
     The user program jump vector, DOSVEC [$000A] is set to point to the
     black board mode (Atari logo display mode in XL/XE models).
     
     7
     The screen margins are set to 2 and 39
    
     8
     Interrupt vectors are initialized.
     
     9
     Bottom of free RAM pointer, MEMLO [$02E7], is set to point to $0700.
     
     10
     Resident CIO handlers are initialized.
     
     11
     If the [START] key is pressed the cassette boot request flag, CKEY
     [$004A], is set.
     
     12
     The CIO device table is initialized.
     
     13
     If a cartridge is present it is initialized.
     
     14
     Channel 0 is opened to the screen editor.  The top-of-free-RAM
     pointer, MEMTOP [$02E5], is set to point below the screen region.  The
     computer then waits for the screen to be established before
     continuing.
     
     15
     If the cassette boot flag is set the cassette is booted.
     
     16
     If there is no cartridge present or a cartridge doesn't prevent it,
     the disk is booted.
     
     17
     The cold start flag is reset.
     
     18
     If there is a cartridge present, the computer jumps to the cartridge's
     run vector.
     
     19
     If there is no cartridge present the computer jumps through the vector
     DOSVEC [$000A (10)].  DOSVEC will point to either a booted program,
     the memo pad routine (400/800) or the logo display routine (XL/XE).
     
     WARM START
     
     
     1
     The warm start flag is set to $7F (true).
     
     2
     cold start steps 2 - 4 are executed.
     
     3
     RAM is cleared from $0010 - $007F and $0200 - $03FF.
     
     4
     Cold start steps 7 - 14 are executed.
     
     5
     If cassette booted software is present the computer JSRs through
     CASINI [$0002].
     
     6
     If disk booted software is present the computer JSRs through DOSINI
     [$000C (12)].
     
     
     The difference between cold start and warm start is the condition of
     the warm start flag, WARMST, [$0008].  If this flag is 0 a complete
     cold start is executed.  If the flag is anything other than 0 then
     only the warm start part of the warm start/cold start code is
     executed.
     
     NON-MASKABLE INTERRUPTS (NMI)
     
     NMI interrupts are generated by the following conditions:
     
     
     1.   Display list interrupt, generated by the ANTIC chip.
     2.   TV vertical blank interrupt, generated by the ANTIC
          chip.
     3.   [SYSTEM RESET] key (400/800).
     
     
     When an NMI interrupt occurs, the hardware register NMIST [$D40F] is
     examined to determine what type of interrupt occurred.  The computer
     is then directed through the proper ram vector to service the
     interrupt.
     
     DISPLAY LIST INTERRUPTS (DLIs)
     
     The computer makes no use of DLIs.  The ram vector points to an RTI
     instruction.
     
     
     VERTICAL BLANK INTERRUPTS (VBIs)
     
     There are two stages to the VBI service routine.  The second stage is
     only done if a critical function was not interrupted.
     
     
     Stage 1 (VBI)
     
     
     The real time clock, RTCLOK [$0012 - $0014], is incremented.

     The attract mode variables are processed.
     
     System timer 1 is decremented.   If it goes to zero the computer JSRs
     through system time-out vector 1.
     
     
     
     Stage 2 (VBI)
     
     
     The hardware registers are loaded with the data in their shadow
     registers.
     
     System timer 2 is decremented.   If it goes to zero the computer JSRs
     through the system time-out vector 2.
     
     System timers 3, 4, and 5 are decremented.   If a timer goes to zero
     the computer sets system timer flags 3, 4, and/or 5.
     
     If auto-repeat is active, the auto-repeat process is done.
     
     The keyboard debounce timer is decremented if not 0.
     
     Information at the controller port registers is read, processed and
     placed in the proper shadow registers.
     
     
     [SYSTEM RESET] INTERRUPT
     
     If a [SYSTEM RESET] interrupt is generated on the 400/800 the computer
     jumps to the warm start routine.
                                                                           


     INTERRUPT REQUESTS (maskable interrupts (IRQs))
     
     When an IRQ interrupt occurs the hardware register IRQST [$D20E], the
     PIA status registers, PACTL [$D302] and PBCTL [$D303] are examined to
     determine what caused the interrupt.
     
     For each interrupt, the 6502 accumulator is pushed to the stack.  The
     computer is then directed to the proper ram vector to service the
     interrupt.
     
     SOFTWARE INTERRUPT (BRK instruction)
     
     The operating system doesn't use software interrupts.  The software
     interrupt vector points to a PLA followed by an RTI.
     
     
                               Interrupt vectors
     
     Label  address type function
     
     VDSLST $0200   NMI  DLI  Points to an RTI
     VVBLKI $0222   NMI  stage 1 VBI
     VVBLKD $0224   NMI  return-from-interrupt routine
     CDTMA1 $0226   NMI  time-out 1 (used by SIO)
     CDTMA2 $0228   NMI  time-out 2 (not used by OS)
     VPRCED $0202   IRQ  not used (points to PLA,RTI)
     VINTER $0204   IRQ  not used (PLA,RTI)
     VKEYBD $0208   IRQ  keyboard interrupt
     VSERIN $020A   IRQ  used by Serial I/O routine
     VSEROR $020C   IRQ  used by SIO
     VSEROC $020E   IRQ  used by SIO
     VTIMR1 $0210   IRQ  not used by OS (PLA,RTI)
     VTIMR2 $0212   IRQ  not used by OS (PLA,RTI)
     VTIMR4 $0214   IRQ  ?
     VIMIRQ $0216   IRQ  main IRQ code
     VBREAK $0206   BRK  unused by OS (PLA,RTI)
     
     
     SYSTEM TIMERS
     
     The following timers are updated during vertical blank (VBI) as noted
     above.  If a timer is decremented to 0 the computer jumps through it's
     associated vector or sets it's associated flag.
     
     
     Label  address  flag/vector
     
     RTCLOK $0012    3 byte clock ($0012 = MSB)
     CDTMV1 $0218    CDTMA1 $0226  vector (SIO time-out)
     CDTMV2 $021A    CDTMA2 $0228  vector
     CDTMV3 $021C    CDTMF3 $022A  flag
     CDTMV4 $021E    CDTMF4 $022C  flag
     CDTMV5 $0220    CDTMF5 $022E  flag

     
     HARDWARE INTERRUPT CONTROL
     
     There are two registers on the antic chip which control interrupts. 
     These registers can be used to disable interrupts if necessary.  There
     are also two associated interrupt status registers.
     
     The IRQ enable and status registers use the same address.  The result
     is that reading the register does not reveal the enabled interrupts
     but the interrupts pending.  IRQ interrupt enable data should usually
     be written to the OS shadow first.  Reading the OS shadow tells which
     interrupts are enabled.
     
                         Non maskable interrupt enable
     
     
     NMIEN  $D40E
     
                7 6 5 4 3 2 1 0
               -----------------
               | | | not used  |
               -----------------
     
      bit 7  1 = DLI enabled
          6  1 = VBI enabled
     
     
                         Non maskable interrupt status
     
     
     NMIST  $D40F
     
                7 6 5 4 3 2 1 0
               -----------------
               | | | | not used|
               -----------------
     
      bit 7  1 = DLI pending
          6  1 = VBI pending
          5  1 = [SYSTEM RESET] key pending
     
     
                           Interrupt request enable
     
     
     
     IRQEN  $D20E
     
                7 6 5 4 3 2 1 0
               -----------------
               | | | | | | | | |
               -----------------
     


      bit 7  1 = [BREAK] key interrupt enable
          6  1 = keyboard interrupt enable
          5  1 = serial input interrupt enable
          4  1 = serial output interrupt enable
          3  1 = serial output-finished interrupt enable
          2  1 = timer 4 interrupt enable
          1  1 = timer 2 interrupt enable
          0  1 = timer 1 interrupt enable
     
      IRQEN has a shadow register, POKMSK [$0010 (A)].
     
     
                           Interrupt request status
     
     
     
     IRQST  $D20E
     
                7 6 5 4 3 2 1 0
               -----------------
               | | | | | | | | |
               -----------------
     
      bit 7  1 = [BREAK] key interrupt pending
          6  1 = keyboard interrupt pending
          5  1 = serial input interrupt pending
          4  1 = serial output interrupt pending
          3  1 = serial output-finished interrupt pending
          2  1 = timer 4 interrupt pending
          1  1 = timer 2 interrupt pending
          0  1 = timer 1 interrupt pending
     
     
     WAIT FOR HORIZONTAL SYNC
     
     Writing any number to WSYNC [$D40A (54282)] will cause the computer to
     stop and wait for the next TV horizontal sync.
     
     It is wise to use DLIs one TV line before needed then writing to
     WSYNC.  This will keep other interrupts from causing DLIs to be
     serviced late.  This can cause a DLI to change something in the middle
     of a scan line.
     
     
                   Useful database variables and OS equates
     
     
     POKMSK $0010       (16): IRQEN shadow
     IRQEN  $D20E    (53774): enables IRQs when written to
     IRQST  $D20E    (53774); gives IRQs waiting when read
     PACTL  $D302    (54018): bit 7 (read) peripheral A interrupt status
                              bit 0 (write) peripheral A interrupt enable
     PBCTL  $D303    (54019): bit 7 (read) peripheral B interrupt status
                              bit 0 (write) peripheral B interrupt enable
     WSYNC  $D40A    (54282): wait for horizontal sync
     NMIEN  $D40E    (54286): NMI enable
     NMIST  $D40F    (54287): NMI status
                                                                           
-- 
-- 


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