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mytb.asm
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mytb.asm
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;=====================================================
; Bob's Tiny BASIC
;
; While working on the Corsham Technologies KIM Clone
; project, I wanted to include a TINY BASIC since that
; was a highly desirable feature of early computers.
;
; Rather than negotiating copyright issues for
; existing BASICs, I decided to just write one from
; scratch.
;
; 10/07/2017
;
; This implements a stripped down Tiny BASIC
; interpreter using the Interpretive Language (IL)
; method as described in the first few issues of
; Dr Dobb's Journal. The IL interpreter can be used
; to write various languages simply by changing the
; IL code rather than the interpreter itself.
;
; 10/15/2021 v0.4 - Bob Applegate
; * Fxed major bug in findLine that
; caused corrupted lines, crashes, etc.
; * If no parameter given to RND, assume
; 32766.
; * No more error 5 when a program
; reaches the end without an END.
;
; www.corshamtech.com
; bob@corshamtech.com
;
;=====================================================
;
; Create TRUE and FALSE values for conditionals.
;
FALSE equ 0
TRUE equ ~FALSE
;
;---------------------------------------------------------
; One of these must be set to indicate which environment
; Tiny BASIC will be running in. Here are the current
; environments:
;
; KIM - This is a bare KIM-1. You'll need to add a few
; more K of RAM.
;
; XKIM - The Corsham Technologies xKIM extended monitor,
; which enhances, without replacing, the standard KIM
; monitor. It gives access to routines to save/load files
; to a micro SD card.
;
; CTMON65 is a from-scratch monitor written for the
; Corsham Tech SS-50 6502 CPU board, but the monitor can
; easily be ported to other systems. It has support for
; using a micro SD card for file storage/retrieval.
;
KIM equ FALSE ;Basic KIM-1, no extensions
XKIM equ TRUE ;Corsham Tech xKIM monitor
CTMON65 equ FALSE ;Corsham Tech CTMON65
;
; If set, include disk functions.
;
DISK_ACCESS equ TRUE
;
; If ILTRACE is set then dump out the address of every
; IL opcode before executing it.
;
ILTRACE equ FALSE
;
; If FIXED is set, put the IL code and the user
; program space at fixed locations in memory. This is
; meant only for debugging.
;
FIXED equ FALSE
;
; Sets the arithmetic stack depth. This is *TINY*
; BASIC, so keep this small!
;
STACKSIZE equ 8 ;number of entries
;
; Common ASCII constants
;
BEL equ $07
BS equ $08
TAB equ $09
LF equ $0A
CR equ $0D
QUOTE equ $22
SPACE equ ' '
COMMA equ ','
SEMICOLON equ ';'
;
; These are error codes
;
ERR_NONE equ 0
ERR_EXPR equ 1 ;expression error
ERR_UNDER equ 2 ;stack underflow
ERR_OVER equ 3 ;stack overflow
ERR_EXTRA_STUFF equ 4 ;Stuff at end of line
ERR_SYNTAX equ 5 ;various syntax errors
ERR_DIVIDE_ZERO equ 6 ;divide by zero
ERR_READ_FAIL equ 7 ;error loading file
ERR_WRITE_FAIL equ 8 ;error saving file
ERR_NO_FILENAME equ 9
;
;=====================================================
; Zero page storage.
;
bss
org $0040
ILTrace ds 1 ;non-zero means tracing
variables ds 26*2 ;2 bytes, A-Z
variablesEnd equ *
ILPC ds 2 ;IL program counter
dpl ds 2
tempIL ds 2
tempIlY ds 1
offset ds 1
lineLength ds 1
;
; CURPTR is a pointer to curent BASIC line being
; executed. Always points to start of line, CUROFF
; is the offset to the current character.
;
CURPTR ds 2
CUROFF ds 1
;
; R0 and R1 are used for arithmetic operations and
; general use.
;
R0 ds 2 ;arithmetic register 0
R1 ds 2 ;arithmetic register 1
;
; This is zero if in immediate mode, or non-zero
; if currently running a program. Any input from
; the main loop clears this, and the XFER IL
; statement will set it.
;
RunMode ds 1
;
; Used for line insertion/removal.
;
FROM ds 2
;
;=====================================================
;
code
org $0200
;
; Cold start is at $0200. Warm start is at $0203.
;
TBasicCold jmp cold2 ;jump around vectors
warm jmp warm2
;
; These are the user-supplied vectors to I/O routines.
; If you want, you can just patch these in the binary
; file, but it would be better to change the source
; code.
;
if KIM
OUTCH jmp $1ea0 ;output char in A
GETCH jmp $1e5a ;get char in A (blocks)
CRLF jmp $1e2f ;print CR/LF
OUTHEX jmp $1e3b ;print A as hex
MONITOR jmp $1c4f ;return to monitor
endif
if XKIM
include "xkim.inc"
code
OUTCH jmp $1ea0
GETCH jmp xkGETCH
CRLF jmp $1e2f ;print CR/LF
OUTHEX jmp xkPRTBYT
MONITOR jmp extKIM
puts equ putsil
BUFFER_SIZE equ 132
endif
if CTMON65
include "ctmon65.inc"
code
OUTCH jmp cout
GETCH jmp cin
CRLF jmp crlf
OUTHEX jmp HexA
MONITOR jmp WARM
puts equ putsil
endif
;
cold2 jsr puts
db CR,LF
db "Bob's Tiny BASIC v0.3"
db CR,LF
db "https://github.com/CorshamTech/6502-Tiny-BASIC"
db CR,LF,0
;
lda #IL&$ff
sta ILPC
lda #IL>>8
sta ILPC+1
;
lda #ProgramStart&$ff ;user prog
sta PROGRAMEND
lda #ProgramStart>>8
sta PROGRAMEND+1
;
; Initialize the pseudo-random number sequence...
;
lda #$5a
sta rtemp1
lda #%10011101
sta random
lda #%01011011
sta random+1
;
jmp coldtwo
;
; This is the warm start entry point
;
warm2 jsr CRLF
lda errGoto
sta ILPC
lda errGoto+1
sta ILPC+1
;
; And continue with both starts here
;
coldtwo jsr SetOutConsole
;
; The ILTrace flag is now run-time settable.
;
lda #ILTRACE&$ff
sta ILTrace
;
lda #0
sta RunMode
sta LINBUF
lda #LINBUF&$ff
sta CURPTR
lda #LINBUF>>8
sta CURPTR+1 ;fall through...
;
;=====================================================
; This is the top of the IL interpreter. This fetches
; and executes the instruction currently pointed to
; by ILPC and adjusts ILPC to point to the next
; instruction to execute.
;
NextIL lda ILTrace
beq NextIL2
jsr dbgLine
NextIL2 ldy CUROFF
jsr SkipSpaces
sty CUROFF
;
jsr getILByte
;
; When the handler is called, these are the conditions
; of several important items:
;
; (ILPC) will point to the byte AFTER the IL
; opcode being executed.
;
; (CURPTR),CUROFF will point to the start of the
; next word in the input buffer. Ie, the next word
; in the user program.
;
asl a
cmp #ILTBLend-ILTBL+2
bcc ILgood
;
; This handles an illegal IL opcode. This is serious
; and there's no way to recover.
;
ILbad jsr puts
db CR,LF
db "Illegal IL "
db 0
;
; Well this is awkward, we need to back up the IL
; by one since it no longer points to the current
; opcode.
;
jsr decIL
;
ldy #0
lda (ILPC),y
jsr OUTHEX
jsr puts
db " at ",0
lda ILPC+1
jsr OUTHEX
lda ILPC
jsr OUTHEX
jsr CRLF
jmp MONITOR
;
; Just jump to the address (ILPC),y. Have to do
; some goofy stuff.
;
ILgood tay ;move index into Y
lda ILTBL,y
sta dpl
lda ILTBL+1,y
sta dpl+1
jmp (dpl) ;go to handler
;
;=====================================================
; This is the IL jump table. The IL opcode is
; mulitplied by two, then looked-up in this table.
; There is absolutely nothing special about the order
; of entries here... they all decode at exactly the
; same speed. However the entry number must match the
; values in IL.inc.
;
ILTBL dw iXINIT ;0
dw iDONE ;1
dw iPRS ;2
dw iPRN ;3
dw iSPC ;4
dw iNLINE ;5
dw iNXT ;6
dw iXFER ;7
dw iSAV ;8
dw iRSTR ;9
dw iCMPR ;10
dw iINNUM ;11
dw iFIN ;12
dw iERR ;13
dw iADD ;14
dw iSUB ;15
dw iNEG ;16
dw iMUL ;17
dw iDIV ;18
dw iSTORE ;19
dw iIND ;20
dw iLST ;21
dw iINIT ;22
dw iGETLINE
dw iINSRT ;24
dw iRTN ;25
dw MONITOR ;26
dw iLIT ;27
dw iCALL ;28
dw iJMP ;29
dw iVINIT ;30
dw iERRGOTO
dw iTST ;32
dw iTSTV ;33
dw iTSTL ;34
dw iTSTN ;35
dw iFREE ;36
dw iRANDOM ;37
dw iABS ;38
;
; Disk functions. There must be pointers
; to functions even if no disk is supported.
; Makes things easier in IL.inc.
;
if DISK_ACCESS
dw iOPENREAD
dw iOPENWRITE
dw iDCLOSE ;41
dw iDGETLINE ;Life, universe, everything
dw iDLIST ;43
else
dw NextIL ;39
dw NextIL ;40
dw NextIL ;41
dw NextIL ;42
dw NextIL ;43
endif
;
ILTBLend equ *
;
;=====================================================
;=====================================================
;=====================================================
; This marks the start of the handlers for IL opcodes.
;=====================================================
;=====================================================
;=====================================================
;
;
iINIT lda #0 ;clear IL stack pointer
sta retStackPtr
;
lda #ProgramStart&$ff ;user prog
sta CURPTR
sta PROGRAMEND
lda #ProgramStart>>8
sta CURPTR+1
sta PROGRAMEND+1
;
; fall into XINIT...
;
;=====================================================
; This initializes for the start of the next line of
; BASIC text.
;
iXINIT lda #0
sta mathStackPtr ;clear math stack
goodExit jmp NextIL
;
;=====================================================
; Verify there is nothing else on this input line.
; If there is, generate an error.
;
iDONE ldy CUROFF
jsr SkipSpaces
lda (CURPTR),y
beq doneadv
ldx #ERR_EXTRA_STUFF
lda #0
jmp iErr2
;
; Advance to the next line
;
doneadv
; jsr FindNext2
jmp NextIL
;
;=====================================================
; Print the string until a closing quote
;
iPRS ldy CUROFF
;
; Odd logic here. The main loop skipped any leading
; whitespace inside the quoted text, so move back to
; the quote, then move forward again.
;
lda #'"' ;pre-load with char to find
iPRS3 dey ;move back one
cmp (CURPTR),y ;quote?
bne iPRS3
iny
sty CUROFF
;
iPRS2 lda (CURPTR),y
beq PRSend2 ;end of line!
cmp #'"'
beq PRSend
jsr OUTCH
inc CUROFF
ldy CUROFF
bne iPRS2
PRSend iny ;skip closing quote
sty CUROFF
PRSend2 jmp NextIL
;
;=====================================================
; Pop the top off the stack and print it as a signed
; decimal number.
;
iPRN jsr popR0
jsr PrintDecimal
jmp NextIL
;
;=====================================================
; Space to next zone. Currently the code does not
; keep track of which column the output is on, so
; just print a tab.
;
iSPC lda #TAB
jsr OUTCH
jmp NextIL
;
;=====================================================
; If in immediate mode, jump to the address following
; the NXT instruction. Else move to the next line of
; user code and continue.
;
iNXT lda RunMode
bne iNxtRun ;in run mode
;
; Get address and jump to it.
;
jmp iJMP
;
iNxtRun jsr FindNextLine
jsr AtEnd
bne iNxtRun2 ;not at end
;
; At the end of the program. Pretend an END statement
; was found.
;
iFINv jmp iFIN
;
iNxtRun2 jsr getILWord ;ignore next word
jmp NextIL
;
;=====================================================
; XFER takes the number on top of the stack and looks
; for that line in the program, or the next line
; higher. Ie, if it's 1 but there is no line 1, then
; find the next one after that.
;
iXFER jsr popR0
jsr findLine
iXFER2 jsr AtEnd ;at end of user program?
beq iFINv
ldy #2 ;point to start of text
sty CUROFF
lda #$ff
sta RunMode
;
; Transfer IL to STMT. I don't like having this
; hard-coded; fix it.
;
lda #STMT&$ff
sta ILPC
lda #STMT>>8
sta ILPC+1
jmp NextIL
;
; Run
;
iXferok
lda #$ff
sta RunMode ;we're running
;
; Need a more elegant way to do this
;
lda #STMT&$ff
sta ILPC
lda #STMT>>8
sta ILPC+1
jmp NextIL
;
;=====================================================
; Save the pointer to the next line to the call stack.
;
iSAV
jmp ILbad
;
;=====================================================
; Pop the next line from the call stack.
;
iRSTR
jmp ILbad
;
;=====================================================
; Compare items on stack. Okay, so on input there are
; three things on the stack
;
; EXPR2 <- Top of stack
; OP <- relational operator, next on stack
; EXPR1 <- last item on stack
;
; Comparison is: EXPR1 <operator> EXPR2
;
; Operator is one of...
;
; 2 is =
; 1 is <
; 3 is <=
; 5 is <>
; 4 is >
; 6 is >=
;
; Those are bit-mapped:
;
; xxxxxGEL
;
; G = Greater than
; E = Equal
; L = Less than
;
; If the comparison is false, do a NXT, ie, move to the
; next line and continue. If true, continue executing
; on this line.
;
REL_LT equ %001
REL_EQUAL equ %010
REL_GT equ %100
;
iCMPR jsr popR1
jsr popMQ ;operator in MQ
jsr popR0
;
; See if they are equal or not
;
lda R0
cmp R1
bne iCMPRnoteq ;try not equal
lda R0+1
cmp R1+1
bne iCMPRnoteq
;
; Equal, set the flag in MQ+1
;
lda #REL_EQUAL
bne iCMPcom
;
; See if EXPR1 (R0) < EXPR2 (R1)
; See www.6502.org/tutorials/compare_beyond.html
;
iCMPRnoteq lda R0
cmp R1
lda R0+1
sbc R1+1
bvc iCMPR_2
eor #$80
iCMPR_2 bmi iCMPlt
lda #REL_GT
bne iCMPcom
iCMPlt lda #REL_LT ;R0 < R1
iCMPcom ora MQ+1
;
; Now compare the end result with what the caller
; was looking for.
;
and MQ
beq iCMPno ;no match
jmp NextIL
;
; R0 > R1
;
iCMPgt lda #REL_GT
bne iCMPcom
;
; Not a match, so jump to the next line of code.
;
iCMPno jsr FindNextLine
jmp iXFER2
;
;=====================================================
; Get a line of text from the user, convert to a
; number, leave on top of stack.
;
iINNUM lda CUROFF ;save state before GetLine
pha
lda CURPTR+1
pha
lda CURPTR
pha
;
lda #'?'
jsr GetLine
jsr getDecimal
jsr pushR0 ;put onto stack
;
pla
sta CURPTR
pla
sta CURPTR+1
pla
sta CUROFF
;
jmp NextIL
;
;=====================================================
; Stop the currently running program. Actually very
; simple to do... clear the RunMode flag, then set the
; ILPC to the standard handler and continue running.
;
iFIN lda #0
sta RunMode
;
lda errGoto
sta ILPC
lda errGoto+1
sta ILPC+1
jmp NextIL
;
;=====================================================
; Handle the ERR opcode. Following the instruction is
; a 16 bit error number. Print an error message, and
; if we're in run mode, print the line number. Stop
; program execution and return to the initial state.
;
iERR jsr getILWord ;get err code
;
; Enter here with the error code in X (LSB) and A (MSB).
;
iErr2 stx R0
sta R0+1
;
jsr puts
db "Error ",0
jsr PrintDecimal
;
lda RunMode ;running?
beq iERR2 ;nope
jsr puts
db " at line ",0
ldy #0
lda (CURPTR),y
sta R0
iny
lda (CURPTR),y
sta R0+1
jsr PrintDecimal
;
iERR2 jsr CRLF
lda #0
sta RunMode ;fall through...
;
;=====================================================
; Reset the IL to be back at the idle loop. Does not
; clear variables so the user can see what state
; the program is in.
;
ResetIL lda #0
sta retStackPtr
lda errGoto
sta ILPC
lda errGoto+1
sta ILPC+1
jmp NextIL
;
;=====================================================
; Pop two items off stack, add them, then place the
; result back onto the stack.
;
iADD jsr popR0
jsr popR1
clc
lda R0
adc R1
sta R0
lda R0+1
adc R1+1
sta R0+1
jmp pushR0nextIl
;
;=====================================================
; Pop two items off the stack. Subtract the top of
; stack from the lower entry.
;
iSUB jsr popR1
jsr popR0
sec
lda R0
sbc R1
sta R0
lda R0+1
sbc R1+1
sta R0+1
jmp pushR0nextIl
;
;=====================================================
; Negate the top of stack.
;
iNEG jsr popR0
lda R0
eor #$ff
sta R0
lda R0+1
eor #$ff
sta R0+1
inc R0
bne iNEG2
inc R0+1
iNEG2 jmp pushR0nextIl
;
;=====================================================
; Multiply top two items on the stack, put the results
; on top. This uses the algorithm documented on page
; 115 of "Microprocessor Programming for Computer
; Hobbyists" by Neill Graham.
;
iMUL jsr popR0 ;AC
jsr popR1 ;OP
;
lda R0
sta MQ
lda R0+1
sta MQ+1
lda #0 ;clear result
sta R0
sta R0+1
;
ldx #16 ;number of bits in value
multloop asl R0
rol R0+1
asl MQ
rol MQ+1
bcc multno ;skip add if no carry
;
; Add R1 back into R0
;
clc
lda R0
adc R1
sta R0
lda R0+1
adc R1+1
sta R0+1
;
multno dex ;did all bits yet?
bne multloop
;
pushR0nextIl jsr pushR0 ;OP
jmp NextIL
;
;=====================================================
; Divide the top of stack into the next to top item.
; Leave results on stack. Taken from:
; http://codebase64.org/doku.php?id=base:16bit_division_16-bit_result
;
; MQ = R0 / R1
; Remainder is in R0
;
iDIV jsr popR1
jsr popR0
;
; Check for divide by zero
;
lda R1
ora R1+1
beq divby0
;
jsr SaveSigns
lda #0 ;preset remainder to 0
sta MQ
sta MQ+1
ldx #16 ;repeat for each bit: ...
divloop asl R0 ;dividend lb & hb*2, msb -> Carry
rol R0+1
rol MQ ;remainder lb & hb * 2 + msb from carry
rol MQ+1
lda MQ
sec
sbc R1 ;substract divisor to see if it fits in
tay ;lb result -> Y, for we may need it later
lda MQ+1
sbc R1+1
bcc skip ;if carry=0 then divisor didn't fit in yet
sta MQ+1 ;else save substraction result as new remainder,
sty MQ
inc R0 ;and INCrement result cause divisor fit in 1 times
skip dex
bne divloop
jsr RestoreSigns
jmp pushR0nextIl
;
; Indicate divide-by-zero error
;
divby0 ldx #ERR_DIVIDE_ZERO
lda #0
jmp iErr2
;
;=====================================================
; This pops the top two items off the stack. The top
; item is a data value and the other is an index into
; the variable table. Save the value into that entry.
;
iSTORE jsr popR0 ;data
jsr popR1 ;index
ldx R1 ;get index
lda R0
sta variables,x
lda R0+1
sta variables+1,x
jmp NextIL
;
;=====================================================
; Replaces the top of stack with the variable whose
; index it represents.
;
iIND jsr popR1
ldx R1 ;get index
lda variables,x
sta R0
lda variables+1,x
sta R0+1
jmp pushR0nextIl
;
;=====================================================
; List the current BASIC program in memory. Uses R0,
; tempIly, and dpl.
;
iLST jsr SetOutConsole
iLST2 lda #ProgramStart&$ff
sta dpl
lda #ProgramStart>>8
sta dpl+1
;
; dpl/dph point to the current line. See if we're at
; the end of the program.
;
iLSTloop lda dpl
cmp PROGRAMEND
bne iLstNotEnd
lda dpl+1
cmp PROGRAMEND+1
beq iLstdone
;
iLstNotEnd ldy #0
lda (dpl),y ;line number LSB
sta R0
iny
lda (dpl),y ;line number MSB
sta R0+1
iny
sty tempIlY
jsr PrintDecimal
lda #SPACE
jsr VOUTCH
ldy tempIlY
iLSTl2 lda (dpl),y
beq iLST3 ;end of this line
sty tempIlY
jsr VOUTCH
ldy tempIlY
iny
bne iLSTl2 ;do next char
;
; End of this line. Print CR/LF, then move to the
; next line.
;
iLST3 iny
clc
tya
adc dpl
sta dpl
lda dpl+1
adc #0
sta dpl+1
;
; Have to manually do CR/LF so it uses the vectored
; output function.
;
lda #CR
jsr VOUTCH
lda #LF
jsr VOUTCH
jmp iLSTloop ;do next line
;
iLstdone jsr SetOutConsole
jmp NextIL
;
;=====================================================
; Get a line of text into LINBUF. Terminate with a
; null byte.
;
iGETLINE lda #'>' ;prompt character
jsr GetLine
;
lda #0
sta RunMode
jmp NextIL
;
;=====================================================
; This is called when the input buffer contains a line
; typed in by the user that starts with a line number.
; Insert the line into the program or delete the line
; if there is nothing after the line number,
;
iINSRT ldy #0
jsr getDecimal ;convert line #
jsr SkipSpaces
sty offset ;save for now
;
; Now find the line OR the next higher line OR the
; end of the program.
;
jsr findLine
;
; If the line exists, it needs to be removed.
;
bne insert2 ;jump if not found
;
; Get length of line to be removed
;
jsr getCURPTRLength ;results in Y
sty lineLength
;
; Compute the new end of the program first.
;
sec
lda PROGRAMEND
sbc lineLength
sta PROGRAMEND
lda PROGRAMEND+1
sbc #0
sta PROGRAMEND+1
;
; Copy CURPTR into R1 for working
;
lda CURPTR
sta R1
lda CURPTR+1
sta R1+1
;
; See if we're at the end.
;
InsDelChk lda R1
cmp PROGRAMEND
bne InsDelLoop
lda R1+1
cmp PROGRAMEND+1
beq insert2
;
; Move one byte, move to next location.
;
InsDelLoop ldy lineLength