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-=-=-=-=-=-=-

      ====================================================================
	DR  6502    AER 201S Engineering Design 6502 Execution Simulator
      ====================================================================

      Supplementary Notes                                   By: M.J.Malone


		       Advanced 6502 Assembly Code Examples
		       ====================================

	   The remainder of this file will be in a  format  acceptable  to
      TASM  for direct assembly.  Note there may be errors in the code, it
      is not intended that it be cut up and included  in  students  files.
      It   is   meant   only   as  an  example  of  addressing  modes  and
      instructions.  The first example is  a  prime  number  finder.   The
      second  example  is  a set of subroutines to maintain a multitasking
      system.


;==============================================================================
;             Advanced Coding Examples for the Students of AER201S
;==============================================================================
;
;
.ORG $E000
	   SEI             ; INITIALIZING THE STACK POINTER
	   LDX #$FF
	   TXS
;
	   LDX #$00
	   LDY #$00
Delay      DEX
	   BNE Delay
	   DEY
	   BNE Delay
;
;=============================================================================
;    Prime Number Finder
;=============================================================================
;  This Prime Number Finder uses the sieve method to find the primes up to 255
;  and then uses those primes to find the primes up to 65535.  Note that this
;  is of course not THE most efficient way to find primes but it makes a good
;  demonstration.
;  It would be neat to stack this code up against a casually written/optimized
;  compiled C prime number finder on a raging 386.  I have a feeling there will
;  be less than a factor of ten difference on execution speed.  You may be
;  surprised just how fast the 6502 is on simple problems.
;
Test_num = $00             ;  Test Number to Eliminate non-primes
Array    = $00             ;  Base Address for the array of primes
;
;
	   lda #$01
	   sta $a003
	   lda #$01
	   sta $a001       ;  Turns on an LED on bit zero of port A of VIA 1
			   ;  to let you know it has started looking for primes
;
 
 
 
 
 
 
 
 
 
                                                            page 2 
 
	   ldx #$01        ;  Initialize the array of numbers
Init_Loop  txa
	   sta Array,x
	   inx
	   bne Init_loop
;
	   lda #$02        ; Initialize the Test_num = 2
	   sta Test_num
	   lda #$04        ; Put the square of 2 in the accumulator
			   ;   as the first non-prime
;
;  Start Setting the Multiples of the Test_num to zero
Start_num
Got_Mult   tax
	   stz Array,x     ; Set multiples of Test_num to zero since they
	   clc             ; are not prime.
	   adc Test_num    ; Calculate the next multiple
	   bcs Next_num    ; Until the Multiples are outside the array
	   jmp Got_Mult
;
Next_num   inc Test_num    ; Go on to the next Test_num
	   ldx Test_num
	   cpx #$10        ; Until Test_num => sqrt(largest number)
	   beq More_Primes
	   lda Array,x
	   beq Next_num    ; Don't use Test_num if Test_num is not prime
	   txa
;    Got a valid new Test_num, now find its square because all non-primes
;       multiples less than its square are eliminated already
	   dex
	   clc
Square     adc Test_num
	   dex
	   bne Square
;    OK Got the square of Test_num in the accumulator
;       lets start checking
	   jmp Start_num
;
;
More_Primes
;
;   Ok now we have all the primes up to 255 in the memory locations $01-$FF
;     Lets repack them more neatly into an array with no spaces to make our
;     life easier
;
	   ldx #$00          ; .X is a pointer into the loose array
	   ldy #$01          ; .Y is a pointer into the packed array
Repack     inx
	   beq Done_packing
	   lda Array,x
	   beq Repack
	   sta Array,y
	   iny
	   jmp Repack
;
 
 
 
 
 
 
 
 
 
                                                            page 3 
 
Prime_Ptr = $F0              ; This is a points into the list of primes greater
			     ;  than $FF and less that $10000
;
Poss_Prime = $F2             ; Possible prime
Temp       = $F4             ; A Temporary Number used to find modulus
Shift      = $F6             ; Number of Places that .A is shifted
TempArg    = $F7             ; A temporary number; argument of modulus
 
;
Done_packing
	   lda #$00          ; Store a $00 at the end of the array of short
	   sta Array,y       ; primes so we know when we have reached the end
	   lda #$00
	   sta Prime_ptr     ; Set the Prime Pointer (for primes >$FF)
	   lda #$02          ; pointing into $0200. The found primes will be
	   sta Prime_ptr+1   ; recorded sequentially from there on.
;
	   lda #$01          ; Start with $0101 as the first possible prime
	   sta Poss_Prime
	   sta Poss_Prime+1
;
Next_PP    ldy #$02
Next_AP    lda Array,y
	   beq Prime
	   jsr Mod
	   beq Next_Poss_prime     ; it was a multiple of Array,y
				   ; and therefore not prime
	   iny
	   jmp Next_AP
;
Prime      ldx #$00
	   lda Poss_prime       ; Store prime away in the array of primes
	   sta (Prime_ptr,x)
	   inx
	   lda Poss_prime+1
	   sta (Prime_ptr,x)
	   clc
	   lda Prime_ptr        ; Increment the pointer in the array of primes
	   adc #$02
	   sta Prime_ptr
	   lda Prime_ptr+1
	   adc #$00
	   sta Prime_ptr+1
;
Next_Poss_prime
	   clc                  ; Increment Poss_Prime to look at the next
	   lda Poss_Prime       ; number
	   adc #$01
	   sta Poss_Prime
	   lda Poss_Prime+1
	   adc #$00
	   sta Poss_Prime+1
	   bcc Next_PP          ; Carry will be set when we reach $10000
;
;   Ends when it has found all the primes up to 65535
;
;
 
 
 
 
 
 
 
                                                            page 4 
 
	   lda #$00
	   sta $a001       ; Turns off the LED after the code finishes
;
DONE       JMP DONE        ; Endless loop at end to halt execution
;
;
;
; --------------------------------------------------------------------------
; Find the Modulus Remainder of Poss_Prime and number in A
; --------------------------------------------------------------------------
; Input Regs: .A Number being divided into the Possible Prime
;             Poss_Prime contains the number being tested for primeness
; Output  Regs:  .A  Modulo remainder
;
Mod           ldx Poss_Prime      ; Transfer Poss_Prime to Temp
	      stx Temp
	      ldx Poss_Prime+1
	      stx Temp+1
	      ldx #$00            ; Set the bit shifting counter to #$00
	      stx Shift
;
;  Compare A to the upper byte of Temp
;
Compare       sec                 ; Compare to see if the .A is greater than
	      cmp Temp+1          ; (equal to) the high byte of Temp
	      bcs A_Bigger
;
;  If the accumulator is smaller than the upper byte of Temp then shift it
;  until it is bigger or it overflows the highest bit
;
	      clc
	      rol a
	      bcc Not_off_end
;
;  It has overflowed the highest bit, unroll it by one position
;
	      ror a
	      sta TempArg
	      jmp Start_Mod
;
;  Not overflowed yet, go and compare it to Temp+1 again
;
Not_off_end   inc Shift
	      jmp Compare
;
;  If the accumulator is bigger and it has been shifted then unshift by one
;  bit
;
A_Bigger      ldx Shift
	      cpx #$00
	      sta TempArg
	      beq Start_Mod
	      clc
	      ror a
	      dec Shift
	      sta TempArg
;
 
 
 
 
 
 
 
                                                            page 5 
 
;  If the accumulator was smaller than the highest byte of Temp it now
;     has been shifted to strip off the high bit at least
;  If the accumulator was larger than the highest byte then proceed with the
;     regular modulus shift and subtracts
;
Start_Mod     lda Temp+1
	      sec
	      cmp TempArg
	      bcc Dont_Subt
;
;  Subtract as a stage of division
;
	      sbc TempArg
	      sta Temp+1
;
Dont_Subt
;
;  We would now like to shift the TempArg relative the Temp
;    1) Shift is greater than zero - accumulator was shifted - unshift it
;    2) Shift Temp - if shift reaches -8 then we are out of Temp and
;       what we have left is the modulus --RTS
;
	      lda Shift
	      bmi Sh_Temp     ; Case 2
	      beq Sh_Temp
;   Case 1
	      clc
	      ror TempArg
	      dec Shift
	      jmp Start_Mod
;
Sh_Temp       cmp #$f8
	      bne Continue
	      lda Temp+1       ;  This is the Modulus
	      rts
 
Continue      dec Shift
	      clc
	      rol Temp
	      rol Temp+1
	      jmp Start_Mod
;
.ORG $FFFC
.WORD $E000
.END
;
;
;
;==============================================================================
;******************************************************************************
;==============================================================================
;
;
 
 
 
 
 
 
 
 
 
 
 
                                                            page 6 
 
;=============================================================================
;  The Multitasking 6502  -  See you 6502 do several things at once
;=============================================================================
;  This relies on the assumption that there is a source of IRQ's out there
;  that is repetitive and each task is allotted time between each IRQ.
;  Process 1 is started automatically by the RESET signal.
;  Any process can extend its life for a while (if it is doing something
;  important) by setting the SEI and then CLI after the important section.
;
;
;
.ORG $E000
	   SEI             ; INITIALIZING THE STACK POINTER
	   LDX #$FF
	   TXS
;
	   LDX #$00
	   LDY #$00
Delay      DEX
	   BNE Delay
	   DEY
	   BNE Delay
;
;  Each Process has a reserved space in memory starting with process 1 at
;  $0200-$03FF, process 2 at $0400-$05FF.  With this model, an 8K RAM can
;  support 15 such processes provided none of the RAM outside zero page and
;  stack is used during the execution of a particular process.
;
M_box    = $F0    ; A Mailbox used to communicate between processes
Com1     = $F8    ; User Communications Channel to other processes
Com2     = $F9
Temp     = $FA    ; A temporary variable used during SWAPS and SPAWNS
Proc_Ptr = $FB    ; Pointer to the reserved space of the current process
Proc     = $FC    ; Current process number
Proc_N   = $FE    ; Actual Number for active Processes
Proc_M   = $FF    ; Maximum Number of Processes that have been concurrent
;
; A Process Record Consists of:
;    Offset        Purpose
;    ------        -------
;      00          Priority
;      01          Priority Counter
;      02          Accumulator
;      03          X Register
;      04          Y Register
;      05          Stack Pointer
;
;      10-FF       Zero Page Memory from $00-$EF
;     100-1FF      System Stack Space
;
	   lda #$01           ; Initialize the start up process as 1
	   sta Proc
	   sta Proc_N         ; Set the number of processes to 1
	   sta $0200          ; Set the priority of process 1 to 1
	   lda #$00
	   sta $0201          ; Set the priority counter of process 1 to 0
 
 
 
 
 
 
 
 
                                                            page 7 
 
	   lda #$00
	   sta Proc_Ptr       ; Initialize the process pointer to point to
	   lda #$02           ; Process 1 reserved space $0200-$03FF
	   sta Proc_Ptr+1
	   JMP Start_Code
;
;===========================================================================
;  IRQ Subroutine to Swap Tasks
;===========================================================================
;
IRQ_VECT   sta Temp           ; Store .A Temporarily
;
;  If there is only one active process currently then just return
;
	   lda Proc_N
	   cmp #$01
	   bne Cont_Swap1
	   lda Temp
	   rti
;
;  Continue there is more than one Process
;
Cont_Swap1 tya
	   pha
;
;   Check process priority counter.  If it equals the priority of the process
;     then attempt to swap in another process
;
	   ldy #$00
	   lda (Proc_Ptr),y   ; Load Priority Number
	   beq Swap_In        ; If 'killed' process then just swap in another
	   iny
	   inc (Proc_Ptr),y   ; Increment Priority Counter
	   cmp (Proc_Ptr),y
	   beq Cont_Swap2
;
;   Not done this Process, Return
;
	   pla
	   tay
	   lda Temp
	   rti
;
;   Other Processes available and this one is done:  S W A P   O U T
;
Cont_Swap2 pla
	   ldy #$04
	   sta (Proc_Ptr),y   ; Save .Y
	   dey
	   txa
	   sta (Proc_Ptr),y   ; Save .X
	   dey
	   lda Temp
	   sta (Proc_Ptr),y   ; Save .A
	   ldy #$05
	   tsx
	   txa
	   sta (Proc_Ptr),y   ; Save .SP
 
 
 
 
 
 
                                                            page 8 
 
;
;   Swap Zero Page ($00-$EF) to (Proc_Ptr + $10-$FF)
;
	   ldy #$00
	   lda #$10
	   sta Proc_Ptr
Out_Zero   lda $00,y
	   sta (Proc_Ptr),y
	   iny
	   cpy #$f0
	   bne Out_Zero
;
;   Swap System Stack
;
	   lda #$00
	   sta Proc_Ptr
	   inc Proc_Ptr+1
	   tsx
	   txa
	   tay
Out_Stack  iny
	   beq Swap_In
	   lda $0100,y
	   sta (Proc_Ptr),y
	   jmp Out_Stack
;
;
;   Look for the next process to swap in
;
Swap_In
Another    lda Proc         ; Looking for another process to Swap in
	   cmp Proc_M
	   bne Not_End
;
;  Go back to Process #1
;
	   lda #$01
	   sta Proc
	   lda #$02
	   sta Proc_Ptr+1
	   jmp Check_Proc
;
;  Go to the next Process
;
Not_End    clc
	   lda Proc_Ptr+1
	   adc #$02
	   sta Proc_Ptr+1
	   inc Proc
;
;  Check this Process if Non-Active, go try another
;
	   ldy #$00
	   lda (Proc_Ptr),y
	   beq Another
;
 
 
 
 
 
 
 
 
                                                            page 9 
 
;  Found an Acceptable Process:  S W A P   I N
;
;
;   Get the Stack Pointer
;
	   ldy #$05
	   lda (Proc_Ptr),y  ; Restore .SP
	   tax
	   txs
;
;   Swap In Zero Page ($00-$EF) to (Proc_Ptr + $10-$FF)
;
	   ldy #$00
	   lda #$10
	   sta Proc_Ptr
In_Zero    lda (Proc_Ptr),y
	   sta $00,y
	   iny
	   cpy #$f0
	   bne In_Zero
;
;   Swap System Stack
;
	   lda #$00
	   sta Proc_Ptr
	   inc Proc_Ptr+1
	   tsx
	   txa
	   tay
In_Stack   iny
	   beq Restore_Regs
	   lda (Proc_Ptr),y
	   sta $0100,y
	   jmp In_Stack
;
;    Restore all of the system registers
;
Restore_Regs
	   lda #$00
	   sta Proc_Ptr
	   dec Proc_Ptr+1
	   ldy #$01          ; Set Priority Counter to 0
	   sta (Proc_Ptr),y
	   iny
	   lda (Proc_Ptr),y  ; Temporarily store .A
	   sta Temp
	   iny
	   lda (Proc_Ptr),y  ; Restore .X
	   tax
	   iny
	   lda (Proc_Ptr),y  ; Restore .Y
	   tay
	   lda Temp          ; Restore .A
	   rti
;--------------------- Done the Swap ----------------------
;
;
;
 
 
 
 
 
 
                                                            page 10 
 
;==========================================================
; Spawn a New Process
;==========================================================
; PHA    Process PCH
; PHA    Process PCL
; PHA    Process Priority
; JSR    Spawn High
;        Spawn Low
;
;
Spawn    lda Proc_Ptr+1   ; Store Current Process Pointer
	 sta Temp
	 lda Proc         ; Store Current Process Number
	 pha
	 lda #$01         ; Set Process Pointer and Number to 1
	 sta Proc
	 lda #$02
	 sta Proc_Ptr+1
;
Free_Check                 ;   See if there is an old process number no longer
	 ldy #$00          ;   in use
	 lda (Proc_Ptr),y
	 beq Got_Free
	 inc Proc
	 clc
	 lda Proc_Ptr+1
	 adc #$02
	 sta Proc_Ptr+1
	 lda Proc_M
	 sec
	 cmp Proc
	 bcs Free_Check
	 inc Proc_M       ; Have to create an extra Process
	 inc Proc_N
;
;  Ok we are clear, Create this Process
;
Got_Free tsx              ; Get the current stack pointer
	 txa
	 clc
	 adc #$05
	 tax              ; Set x to point at Priority
;
	 ldy #$00
	 lda $0100,x      ; Transfer Priority to Process Space
	 sta (Proc_Ptr),y
;
	 ldy #$05         ; Set .sp = #$FC
	 lda #$FC
	 sta (Proc_Ptr),y
;
	 ldy #$02         ; Set the accumulator to 1 to indicate: START
	 lda #$01         ; to the new process
	 sta (Proc_Ptr),y
;
	 inc Proc_Ptr+1   ; To point into stack swap space for this process
;
 
 
 
 
 
 
 
                                                            page 11 
 
	 lda #$00         ; Processor Status Register, for this process
	 ldy #$FD
	 sta (Proc_Ptr),y
;
	 inx
	 lda $0100,x      ; Load PCL
	 iny
	 sta (Proc_Ptr),y ; Put into (swapped) Stack
;
	 inx
	 lda $0100,x      ; Load PCH
	 iny
	 sta (Proc_Ptr),y ; Put into (swapped) Stack
;
	 lda Temp         ; Set Pointer back to original (Spawner) process
	 sta Proc_Ptr+1
;
	 lda Proc         ; Take Spawned Process number and put in Temp
	 sta Temp
;
	 pla              ; Restore Spawned Process number
	 sta Proc
;
	 pla              ; Pull 'Spawn' return address from stack
	 tax
	 pla
	 tay
;
	 pla              ; Pull Spawn data out of the stack
	 pla
	 pla
;
	 tya              ; Push the Return Address back to the stack
	 pha
	 txa
	 pha
	 lda Temp         ; Return Spawned Process Number
	 rts
;-------------- Done Spawn -----------------
;
;
;
;=============================================================
;  Kill a Process
;=============================================================
;
; Input Registers : NONE
; Output Registers: NEVER RETURNS IF KILL IS SUCCESSFUL
;
Kill     lda Proc_N
	 cmp #$01          ; Can't Clear Last Process
	 bne Ok_More
	 rts
Ok_More  ldy #$00          ; OK Kill the Process, put a 0 in Priority
	 tya
	 sta (Proc_Ptr)
;
 
 
 
 
 
 
 
                                                            page 12 
 
	 dec Proc_N        ; One Less Process
;
	 lda Proc          ; If we are clearing 'Maximum' Process then
	 cmp Proc_M        ; then reduce maximum
	 beq Reduce_Max
	 jmp Swap_In       ; Otherwise Go swap another in
;
Reduce_Max
	 dec Proc
	 dec Proc_M
	 dec Proc_Ptr+1
	 dec Proc_Ptr+1
	 lda (Proc_ptr),y
	 beq Reduce_Max
	 jmp Swap_In
;---------------------- Done Clear a Process ---------------------------
;
;
;
;
;=======================================================================
; An Example Spawnable Process
;=======================================================================
; Input Registers:  .A  =  #$00   Means that we just want the address of
;   (JSR Child)                   this process so that the process swapper
;                                 will know where to start.
;
; (RTI to CHILD1)   .A  =  #$01   Means that the process swapper has signalled
;                                 this process to actually start
;
Child    jsr Child1
Child1   cmp #$00
	 bne Go_For_It
;
;  Process was called to get its start up address
;
	 pla            ;  Grab Child1 start up address
	 clc
	 adc #$01       ;  Remember that an RTS return address points at the
	 tax            ;  last byte of the JSR statement.
	 pla            ;  RTI return addresses point to the first byte of the
	 adc #$00       ;  next instruction to be executed
	 tay
;
	 pla            ;  Save Return Address to program calling Child
	 sta Temp
	 pla
	 sta Proc_Ptr
;
	 tya            ;  Push Child1  RTI  address
	 pha
	 txa
	 pha
;
	 lda Proc_Ptr   ;  This Pushes the calling program's return address
	 pha            ;  back into the stack
	 lda Temp
	 pha
;
 
 
 
 
 
                                                            page 13 
 
	 lda #$00       ; Returns Proc_Ptr(low) to #$00 after its use as a
	 sta Proc_Ptr   ; Temporary variable
	 rts
;
;  Spawned Process actually starts:
;   Note that PLA's are not required to get rid of the JSR Child1 start up
;   address since the RTI address pushed in points to Child1  NOT  Child
Go_For_It
 
  Body of the spawned process
 
;
;
;=======================================================================
;  An Example of a Kill of the present Process
;=======================================================================
;
     { User Code  }
;
	 sei
	 jsr Kill     ;  This should kill the process unless it is the
		      ;  only process
	 cli
;
;   This is the only process
;
     { More user code }
;
;
;
;=======================================================================
; Start of User Code
;=======================================================================
Start_Code
{ Your first process goes here }
;
;
;  Example Spawn of Process   'Child'
;
	 sei             ;  Prevent swap attempts during process creation
	 lda #$00
	 jsr Child       ;  Request Address for Child1
;
	 lda #Priority
	 pha             ;  Push Priority into the stack
;
	 jsr Spawn       ;  Ask the Process Swapper to set 'Child1' up in
			 ;  the swap schedule
	 rol a
	 sta Ptr+1       ;  Set pointer to the Child process zero page
	 lda #$10        ;  reserved area
	 sta Ptr
;
 
 
 
 
 
 
 
 
 
 
 
                                                            page 14 
 
;  The  Spawn  call returns the process number.  If there is some initial data
;  or a pointer that this process would like to pass to 'Child1' then the
;  address of its ZERO PAGE reserved data space is pointed to by  '(Ptr),y'.
;  Once the data has been transferred:
;
	 cli             ;  Re-enable swap attempts
;
;
;
;============================================================================
;  Example of Taking full control of execution temporarily
;============================================================================
;
	 sei             ; Disable swaps
  { User Code }
	 cli             ; Re-enable swaps
;
;
;
;============================================================================
;  Example of taking full control by Killing all other processes
;============================================================================
;
Ptr    = $00
K_Proc = $02
;
	 sei               ; Disable swaps
;
	 lda #$00          ; Set Pointer to $0200
	 sta Ptr
	 lda #$02
	 sta Ptr+1
;
	 lda #$01          ; Set Kill Process counter to 1
	 sta K_Proc
;
Top      lda Proc
	 cmp K_Proc
	 beq Don_t_Kill
	 ldy #$00
	 tya
	 sta (Ptr),y
;
Don_t_Kill
	 cmp Proc_M
	 beq Done_Kill
	 inc Ptr+1
	 inc Ptr+1
	 inc K_Proc
	 jmp Top
;
 
 
 
 
 
 
 
 
 
 
 
 
 
                                                            page 15 
 
Done_Kill
	 lda #$01
	 sta Proc_N
	 lda Proc
	 sta Proc_M
	 cli         ; Note that this is optional, if we know that there
		     ; are no other processes we could prevent swap decisions
		     ; by not clearing the IRQ mask.
;
   { More code that will not be swapped out }
;
;
;
.ORG $FFFC
.WORD $E000
.WORD IRQ_VECT
.END
;
; -------------------- Done Multitasking example -------------------------
 
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