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collapseos/apps/forth/dict.asm

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; A dictionary entry has this structure:
; - 7b name (zero-padded)
; - 1b flags (bit 0: IMMEDIATE)
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; - 2b prev pointer
; - 2b code pointer
; - Parameter field (PF)
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;
; The code pointer point to "word routines". These routines expect to be called
; with IY pointing to the PF. They themselves are expected to end by jumping
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; to the address at the top of the Return Stack. They will usually do so with
; "jp exit".
; Execute a word containing native code at its PF address (PFA)
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nativeWord:
jp (iy)
; Execute a list of atoms, which usually ends with EXIT.
; IY points to that list.
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compiledWord:
push iy \ pop hl
inc hl
inc hl
; HL points to next Interpreter pointer.
call pushRS
ld l, (iy)
ld h, (iy+1)
push hl \ pop iy
; IY points to code link
jp executeCodeLink
; Pushes the PFA directly
cellWord:
push iy
jp exit
; Pushes the address in the first word of the PF
sysvarWord:
ld l, (iy)
ld h, (iy+1)
push hl
jp exit
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; The word was spawned from a definition word that has a DOES>. PFA+2 (right
; after the actual cell) is a link to the slot right after that DOES>.
; Therefore, what we need to do push the cell addr like a regular cell, then
; follow the link from the PFA, and then continue as a regular compiledWord.
doesWord:
push iy ; like a regular cell
ld l, (iy+2)
ld h, (iy+3)
push hl \ pop iy
jr compiledWord
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; The IF word checks the stack for zero. If it's non-zero, it does nothing and
; allow compiledWord to continue.
; If it's zero, it tracksback RS, advance it until it finds a ELSE, a THEN, or
; an EXIT (not supposed to happen unless the IF is misconstructed). Whether
; it's a ELSE or THEN, the same thing happens: we resume execution after the
; ELSE/THEN. If it's a EXIT, we simply execute it.
ifWord:
pop hl
ld a, h
or l
jp nz, exit ; non-zero, continue
; Zero, seek ELSE, THEN or EXIT. Continue to elseWord
; If a ELSE word is executed, it means that the preceding IF had a non-zero
; condition and continued execution. This means that upon encountering an ELSE,
; we must search for a THEN or an EXIT.
; To simplify implementation and share code with ifWord, we also match ELSE,
; which is only possible in malformed construct. Therefore "IF ELSE ELSE" is
; valid and interpreted as "IF ELSE THEN".
elseWord:
; to save processing, we test EXIT, ELSE and THEN in the order they
; appear, address-wise. This way, we don't need to push/pop HL: we can
; SUB the difference between the words and check for zeroes.
call popRS
; We need to save that IP somewhere. Let it be BC
ld b, h
ld c, l
.loop:
; Whether there's a match or not, we will resume the operation at IP+2,
; which means that we have to increase BC anyways. Let's do it now.
inc bc \ inc bc
call intoHL
or a ; clear carry
ld de, EXIT
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sbc hl, de
jp z, exit
; Not EXIT, let's continue with ELSE. No carry possible because EXIT
; is first word. No need to clear.
ld de, ELSE-EXIT
sbc hl, de
jr c, .nomatch ; A word between EXIT and ELSE. No match.
jr z, .match ; We have a ELSE
; Let's try with THEN. Again, no carry possible, C cond was handled.
ld de, THEN-ELSE
sbc hl, de
jr z, .match ; We have a THEN
.nomatch:
; Nothing matched, which means that we need to continue looking.
; BC is already IP+2
ld h, b
ld l, c
jr .loop
.match:
; Matched a ELSE or a THEN, which means we need to continue executing
; word from IP+2, which is already in BC.
push bc \ pop iy
jp compiledWord
; This word does nothing. It's never going to be executed unless the wordlist
; is misconstructed.
thenWord:
jp exit
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; This is not a word, but a number literal. This works a bit differently than
; others: PF means nothing and the actual number is placed next to the
; numberWord reference in the compiled word list. What we need to do to fetch
; that number is to play with the Return stack: We pop it, read the number, push
; it to the Parameter stack and then push an increase Interpreter Pointer back
; to RS.
numberWord:
call popRS
ld e, (hl)
inc hl
ld d, (hl)
inc hl
call pushRS
push de
jp exit
NUMBER:
.dw numberWord
; Similarly to numberWord, this is not a real word, but a string literal.
; Instead of being followed by a 2 bytes number, it's followed by a
; null-terminated string. This is not expected to be called in a regular
; context. Only words expecting those literals will look for them. This is why
; the litWord triggers abort.
litWord:
call popRS
call intoHL
call printstr ; let's print the word before abort.
ld hl, .msg
call printstr
jp abort
.msg:
.db "undefined word", 0
LIT:
.dw litWord
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; ( R:I -- )
.db ";"
.fill 7
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.dw 0
EXIT:
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.dw nativeWord
; When we call the EXIT word, we have to do a "double exit" because our current
; Interpreter pointer is pointing to the word *next* to our EXIT reference when,
; in fact, we want to continue processing the one above it.
call popRS
exit:
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; Before we continue: is SP within bounds?
call chkPS
; we're good
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call popRS
; We have a pointer to a word
push hl \ pop iy
jp compiledWord
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; ( R:I -- )
.db "QUIT"
.fill 4
.dw EXIT
QUIT:
.dw nativeWord
quit:
jp forthRdLine
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.db "ABORT"
.fill 3
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.dw QUIT
ABORT:
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.dw nativeWord
abort:
; Reinitialize PS (RS is reinitialized in forthInterpret
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ld sp, (INITIAL_SP)
jp forthRdLine
.db "BYE"
.fill 5
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.dw ABORT
BYE:
.dw nativeWord
; Goodbye Forth! Before we go, let's restore the stack
ld sp, (INITIAL_SP)
; unwind stack underflow buffer
pop af \ pop af \ pop af
; success
xor a
ret
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; ( c -- )
.db "EMIT"
.fill 4
.dw BYE
EMIT:
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.dw nativeWord
pop hl
ld a, l
call stdioPutC
jp exit
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; ( c port -- )
.db "PC!"
.fill 5
.dw EMIT
PSTORE:
.dw nativeWord
pop bc
pop hl
out (c), l
jp exit
; ( port -- c )
.db "PC@"
.fill 5
.dw PSTORE
PFETCH:
.dw nativeWord
pop bc
ld h, 0
in l, (c)
push hl
jp exit
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; ( addr -- )
.db "EXECUTE"
.db 0
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.dw PFETCH
EXECUTE:
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.dw nativeWord
pop iy ; is a wordref
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executeCodeLink:
ld l, (iy)
ld h, (iy+1)
; HL points to code pointer
inc iy
inc iy
; IY points to PFA
jp (hl) ; go!
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.db ":"
.fill 7
.dw EXECUTE
DEFINE:
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.dw nativeWord
call entryhead
ld de, compiledWord
ld (hl), e
inc hl
ld (hl), d
inc hl
; At this point, we've processed the name literal following the ':'.
; What's next? We have, in IP, a pointer to words that *have already
; been compiled by INTERPRET*. All those bytes will be copied as-is.
; All we need to do is to know how many bytes to copy. To do so, we
; skip compwords until EXIT is reached.
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ex de, hl ; DE is our dest
ld l, (ix)
ld h, (ix+1)
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.loop:
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call HLPointsNUMBER
jr nz, .notNUMBER
; is number
ld bc, 4
ldir
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jr .loop
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.notNUMBER:
call HLPointsLIT
jr nz, .notLIT
; is lit
ldi
ldi
call strcpyM
jr .loop
.notLIT:
; it's a word
call HLPointsIMMED
jr nz, .notIMMED
; Immediate word, we'll have to call it.
; Before we make our call, let's save our current HL/DE position
ld (HERE), de
ld e, (hl)
inc hl
ld d, (hl)
inc hl ; point to next word
push de \ pop iy ; prepare for executeCodeLink
ld (ix), l
ld (ix+1), h
; Push return address
ld hl, .retList
call pushRS
; Ready!
jp executeCodeLink
.notIMMED:
; a good old regular word. We have 2 bytes to copy. But before we do,
; let's check whether it's an EXIT. LDI doesn't affect Z, so we can
; make our jump later.
call HLPointsEXITQUIT
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ldi
ldi
jr nz, .loop
; HL has our new RS' TOS
ld (ix), l
ld (ix+1), h
ld (HERE), de ; update HERE
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jp exit
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; This label is pushed to RS when an IMMED word is called. When that word calls
; exit, this is where it returns. When we return, RS will need to be popped so
; that we stay on the proper RS level.
.retList:
.dw .retWord
.retWord:
.dw .retEntry
.retEntry:
call popRS ; unwind stack
; recall old HL / DE values
ld l, (ix)
ld h, (ix+1)
ld de, (HERE)
; continue!
jr .loop
.db "DOES>"
.fill 3
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.dw DEFINE
DOES:
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.dw nativeWord
; We run this when we're in an entry creation context. Many things we
; need to do.
; 1. Change the code link to doesWord
; 2. Leave 2 bytes for regular cell variable.
; 3. Get the Interpreter pointer from the stack and write this down to
; entry PFA+2.
; 3. exit. Because we've already popped RS, a regular exit will abort
; colon definition, so we're good.
ld iy, (CURRENT)
ld hl, doesWord
call wrCompHL
inc iy \ inc iy ; cell variable space
call popRS
call wrCompHL
ld (HERE), iy
jp exit
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.db "IMMEDIA"
.db 0
.dw DOES
IMMEDIATE:
.dw nativeWord
ld hl, (CURRENT)
dec hl
dec hl
dec hl
inc (hl)
jp exit
; ( n -- )
.db "LITERAL"
.db 1 ; IMMEDIATE
.dw IMMEDIATE
LITERAL:
.dw nativeWord
ld hl, (HERE)
ld de, NUMBER
ld (hl), e
inc hl
ld (hl), d
inc hl
pop de ; number from stack
ld (hl), e
inc hl
ld (hl), d
inc hl
ld (HERE), hl
jp exit
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; ( -- c )
.db "KEY"
.fill 5
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.dw LITERAL
KEY:
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.dw nativeWord
call stdioGetC
ld h, 0
ld l, a
push hl
jp exit
.db "INTERPR"
.db 0
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.dw KEY
INTERPRET:
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.dw nativeWord
interpret:
ld iy, COMPBUF
.loop:
call readword
jr nz, .end
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call compile
jr .loop
.end:
ld hl, QUIT
call wrCompHL
ld iy, COMPBUF
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jp compiledWord
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.db "CREATE"
.fill 2
.dw INTERPRET
CREATE:
.dw nativeWord
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call entryhead
jp nz, quit
ld de, cellWord
ld (hl), e
inc hl
ld (hl), d
inc hl
ld (HERE), hl
jp exit
.db "HERE"
.fill 4
.dw CREATE
HERE_: ; Caution: conflicts with actual variable name
.dw sysvarWord
.dw HERE
.db "CURRENT"
.db 0
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.dw HERE_
CURRENT_:
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.dw sysvarWord
.dw CURRENT
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; ( n -- )
.db "."
.fill 7
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.dw CURRENT_
DOT:
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.dw nativeWord
pop de
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; We check PS explicitly because it doesn't look nice to spew gibberish
; before aborting the stack underflow.
call chkPS
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call pad
call fmtDecimalS
call printstr
jp exit
; ( n a -- )
.db "!"
.fill 7
.dw DOT
STORE:
.dw nativeWord
pop iy
pop hl
ld (iy), l
ld (iy+1), h
jp exit
; ( a -- n )
.db "@"
.fill 7
.dw STORE
FETCH:
.dw nativeWord
pop hl
call intoHL
push hl
jp exit
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; ( -- a )
.db "LIT@"
.fill 4
.dw FETCH
LITFETCH:
.dw nativeWord
call readLITTOS
push hl
jp exit
; ( a b -- b a )
.db "SWAP"
.fill 4
.dw LITFETCH
SWAP:
.dw nativeWord
pop hl
ex (sp), hl
push hl
jp exit
; ( a -- a a )
.db "DUP"
.fill 5
.dw SWAP
DUP:
.dw nativeWord
pop hl
push hl
push hl
jp exit
; ( a b -- a b a )
.db "OVER"
.fill 4
.dw DUP
OVER:
.dw nativeWord
pop hl ; B
pop de ; A
push de
push hl
push de
jp exit
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; ( a b -- c ) A + B
.db "+"
.fill 7
.dw OVER
PLUS:
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.dw nativeWord
pop hl
pop de
add hl, de
push hl
jp exit
; ( a b -- c ) A - B
.db "-"
.fill 7
.dw PLUS
MINUS:
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.dw nativeWord
pop de ; B
pop hl ; A
or a ; reset carry
sbc hl, de
push hl
jp exit
; ( a b -- c ) A * B
.db "*"
.fill 7
.dw MINUS
MULT:
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.dw nativeWord
pop de
pop bc
call multDEBC
push hl
jp exit
; ( a b -- c ) A / B
.db "/"
.fill 7
.dw MULT
DIV:
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.dw nativeWord
pop de
pop hl
call divide
push bc
jp exit
; ( a1 a2 -- b )
.db "SCMP"
.fill 4
.dw DIV
SCMP:
.dw nativeWord
pop de
pop hl
call strcmp
call flagsToBC
push bc
jp exit
; ( n1 n2 -- f )
.db "CMP"
.fill 5
.dw SCMP
CMP:
.dw nativeWord
pop hl
pop de
or a ; clear carry
sbc hl, de
call flagsToBC
push bc
jp exit
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.db "IF"
.fill 6
.dw CMP
IF:
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.dw ifWord
.db "ELSE"
.fill 4
.dw IF
ELSE:
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.dw elseWord
.db "THEN"
.fill 4
.dw ELSE
THEN:
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.dw thenWord
.db "RECURSE"
.db 0
.dw THEN
RECURSE:
.dw nativeWord
call popRS
ld l, (ix)
ld h, (ix+1)
dec hl \ dec hl
push hl \ pop iy
jp compiledWord
; End of native words
; ( a -- )
; @ .
.db "?"
.fill 7
.dw RECURSE
FETCHDOT:
.dw compiledWord
.dw FETCH
.dw DOT
.dw EXIT
; ( n a -- )
; SWAP OVER @ + SWAP !
.db "+!"
.fill 6
.dw FETCHDOT
STOREINC:
.dw compiledWord
.dw SWAP
.dw OVER
.dw FETCH
.dw PLUS
.dw SWAP
.dw STORE
.dw EXIT
; ( n -- )
; HERE +!
.db "ALLOT"
.fill 3
.dw STOREINC
ALLOT:
.dw compiledWord
.dw HERE_
.dw STOREINC
.dw EXIT
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; CREATE 2 ALLOT
.db "VARIABL"
.db 0
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.dw ALLOT
VARIABLE:
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.dw compiledWord
.dw CREATE
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.dw NUMBER
.dw 2
.dw ALLOT
.dw EXIT
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; ( n -- )
; CREATE HERE @ ! DOES> @
.db "CONSTAN"
.db 0
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.dw VARIABLE
CONSTANT:
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.dw compiledWord
.dw CREATE
.dw HERE_
.dw FETCH
.dw STORE
.dw DOES
.dw FETCH
.dw EXIT
; ( f -- f )
; IF 0 ELSE 1 THEN
.db "NOT"
.fill 5
.dw CONSTANT
NOT:
.dw compiledWord
.dw IF
.dw NUMBER
.dw 0
.dw ELSE
.dw NUMBER
.dw 1
.dw THEN
.dw EXIT
; ( n1 n2 -- f )
; CMP NOT
.db "="
.fill 7
.dw NOT
EQ:
.dw compiledWord
.dw CMP
.dw NOT
.dw EXIT
; ( n1 n2 -- f )
; CMP -1 =
.db "<"
.fill 7
.dw EQ
LT:
.dw compiledWord
.dw CMP
.dw NUMBER
.dw -1
.dw EQ
.dw EXIT
; ( n1 n2 -- f )
; CMP 1 =
.db ">"
.fill 7
.dw LT
GT:
LATEST:
.dw compiledWord
.dw CMP
.dw NUMBER
.dw 1
.dw EQ
.dw EXIT
;