collapseos/apps/zasm/zasm.asm

#include "user.inc"
.org	USER_CODE
call	parseLine
ld	b, 0
ld	c, a	; written bytes
ret

; Sets Z is A is ';', CR, LF, or null.
isLineEnd:
	cp	';'
	ret	z
	cp	0
	ret	z
	cp	0x0d
	ret	z
	cp	0x0a
	ret

; Sets Z is A is ' ' or ','
isSep:
	cp	' '
	ret	z
	cp	','
	ret

; Sets Z is A is ' ', ',', ';', CR, LF, or null.
isSepOrLineEnd:
	call	isSep
	ret	z
	call	isLineEnd
	ret

; read word in (HL) and put it in (DE), null terminated. A is the read
; length. HL is advanced to the next separator char.
readWord:
	push	bc
	ld	b, 4
.loop:
	ld	a, (hl)
	call	isSepOrLineEnd
	jr	z, .success
	call	JUMP_UPCASE
	ld	(de), a
	inc	hl
	inc	de
	djnz	.loop
.success:
	xor	a
	ld	(de), a
	ld	a, 4
	sub	a, b
	jr	.end
.error:
	xor	a
	ld	(de), a
.end:
	pop	bc
	ret

; (HL) being a string, advance it to the next non-sep character.
; Set Z if we could do it before the line ended, reset Z if we couldn't.
toWord:
.loop:
	ld	a, (hl)
	call	isLineEnd
	jr	z, .error
	call	isSep
	jr	nz, .success
	inc	hl
	jr	.loop
.error:
	; we need the Z flag to be unset and it is set now. Let's CP with
	; something it can't be equal to, something not a line end.
	cp	'a'	; Z flag unset
	ret
.success:
	; We need the Z flag to be set and it is unset. Let's compare it with
	; itself to return a set Z
	cp	a
	ret


readLine:
	push	de
	xor	a
	ld	(curWord), a
	ld	(curArg1), a
	ld	(curArg2), a
	ld	de, curWord
	call	readWord
	call	toWord
	jr	nz, .end
	ld	de, curArg1
	call	readWord
	call	toWord
	jr	nz, .end
	ld	de, curArg2
	call	readWord
.end:
	pop	de
	ret

; match argument string at (HL) with argspec A.
; Set Z/NZ on match
matchArg:
	cp	0
	jr	z, .matchnone
	; Z is unset. TODO: implement rest
	jr	.end
.matchnone:
	ld	a, (hl)
	cp	0	; arg must be null to match
.end:
	ret

; Compare primary row at (DE) with string at curWord. Sets Z flag if there's a
; match, reset if not.
matchPrimaryRow:
	push	hl
	push	ix
	ld	hl, curWord
	ld	a, 4
	call	JUMP_STRNCMP
	jr	nz, .end
	; name matches, let's see the rest
	ld	ixh, d
	ld	ixl, e
	ld	hl, curArg1
	ld	a, (ix+4)
	call	matchArg
	jr	nz, .end
	ld	hl, curArg2
	ld	a, (ix+5)
	call	matchArg
.end:
	pop	ix
	pop	hl
	ret

; Parse line at (HL) and write resulting opcode(s) in (DE). Returns the number
; of bytes written in A.
parseLine:
	call	readLine
	push	de
	ld	de, instTBlPrimary
.loop:
	ld	a, (de)
	cp	0
	jr	z, .nomatch	; we reached last entry
	call	matchPrimaryRow
	jr	z, .match
	ld	a, 7
	call	JUMP_ADDDE
	jr	.loop

.nomatch:
	xor	a
	pop	de
	ret
.match:
	ld	a, 6	; upcode is on 7th byte
	call	JUMP_ADDDE
	ld	a, (de)
	pop	de
	ld	(de), a
	ld	a, 1
	ret

; In instruction metadata below, argument types arge indicated with a single
; char mnemonic that is called "argspec". This is the table of correspondance.
; Single letters are represented by themselves, so we don't need as much
; metadata.

argspecsSingle:
	.db	"ABCDEHL", 0

; Format: 1 byte argspec + 4 chars string
argspecTbl:
	.db	'h', "HL", 0, 0
	.db	'l', "(HL)"
	.db	'd', "DE", 0, 0
	.db	'e', "(DE)"
	.db	'b', "BC", 0, 0
	.db	'c', "(BC)"
	.db	'a', "AF", 0, 0
	.db	'f', "AF'", 0
	.db	'x', "(IX)"
	.db	'y', "(IY)"
	.db	's', "SP", 0, 0
	.db	'p', "(SP)"
	.db	0

; This is a list of primary instructions (single upcode) that lead to a
; constant (no group code to insert).
; That doesn't mean that they don't take any argument though. For example,
; "DEC IX" leads to a special upcode. These kind of constants are indicated
; as a single byte to save space. Meaning:
;
; All single char registers (A/B/C etc) -> themselves
; HL -> h
; (HL) -> l
; DE -> d
; (DE) -> e
; BC -> b
; (BC) -> c
; IX -> X
; (IX) -> x
; IY -> Y
; (IY) -> y
; AF -> a
; AF' -> f
; SP -> s
; (SP) -> p
; None -> 0
;
; This is a sorted list of "primary" (single byte) instructions along with
; metadata
; 4 bytes for the name (fill with zero)
; 1 byte for arg constant
; 1 byte for 2nd arg constant
; 1 byte for upcode
instTBlPrimary:
	.db "ADD", 0, 'A', 'h', 0x86		; ADD A, HL
	.db "CCF", 0, 0,   0,   0x3f		; CCF
	.db "CPL", 0, 0,   0,   0x2f		; CPL
	.db "DAA", 0, 0,   0,   0x27		; DAA
	.db "DI",0,0, 0,   0,   0xf3		; DI
	.db "EI",0,0, 0,   0,   0xfb		; EI
	.db "EX",0,0, 'p', 'h', 0xe3		; EX (SP), HL
	.db "EX",0,0, 'a', 'f', 0x08		; EX AF, AF'
	.db "EX",0,0, 'd', 'h', 0xeb		; EX DE, HL
	.db "EXX", 0, 0,   0,   0xd9		; EXX
	.db "HALT",   0,   0,   0x76		; HALT
	.db "INC", 0, 'l', 0,   0x34		; INC (HL)
	.db "JP",0,0, 'l', 0,   0xe9		; JP (HL)
	.db "LD",0,0, 'c', 'A', 0x02		; LD (BC), A
	.db "LD",0,0, 'e', 'A', 0x12		; LD (DE), A
	.db "LD",0,0, 'A', 'c', 0x0a		; LD A, (BC)
	.db "LD",0,0, 'A', 'e', 0x0a		; LD A, (DE)
	.db "LD",0,0, 's', 'h', 0x0a		; LD SP, HL
	.db "NOP", 0, 0,   0,   0x00		; NOP
	.db "RET", 0, 0,   0,   0xc9		; RET
	.db "RLA", 0, 0,   0,   0x17		; RLA
	.db "RLCA",   0,   0,   0x07		; RLCA
	.db "RRA", 0, 0,   0,   0x1f		; RRA
	.db "RRCA",   0,   0,   0x0f		; RRCA
	.db "SCF", 0, 0,   0,   0x37		; SCF
	.db 0

; *** Variables ***
; enough space for 4 chars and a null
curWord:
	.db	0, 0, 0, 0, 0
curArg1:
	.db	0, 0, 0, 0, 0
curArg2:
	.db	0, 0, 0, 0, 0
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`#include "user.inc"`
			`.org USER_CODE`
			`call parseLine`
			`ld b, 0`
			`ld c, a ; written bytes`
Add zasm app For now, only a dummy app, but it's emulated properly with libz80. Exciting times! 2019-04-17 03:36:57 +10:00			`ret`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`; Sets Z is A is ';', CR, LF, or null.`
			`isLineEnd:`
			`cp ';'`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`ret z`
			`cp 0`
			`ret z`
			`cp 0x0d`
			`ret z`
			`cp 0x0a`
			`ret`

zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`; Sets Z is A is ' ' or ','`
			`isSep:`
			`cp ' '`
			`ret z`
			`cp ','`
			`ret`

			`; Sets Z is A is ' ', ',', ';', CR, LF, or null.`
			`isSepOrLineEnd:`
			`call isSep`
			`ret z`
			`call isLineEnd`
			`ret`

			`; read word in (HL) and put it in (DE), null terminated. A is the read`
			`; length. HL is advanced to the next separator char.`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`readWord:`
			`push bc`
			`ld b, 4`
			`.loop:`
			`ld a, (hl)`
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`call isSepOrLineEnd`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`jr z, .success`
zasm: reuse code from core 2019-04-17 07:00:19 +10:00			`call JUMP_UPCASE`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`ld (de), a`
			`inc hl`
			`inc de`
			`djnz .loop`
			`.success:`
			`xor a`
			`ld (de), a`
			`ld a, 4`
			`sub a, b`
			`jr .end`
			`.error:`
			`xor a`
			`ld (de), a`
			`.end:`
			`pop bc`
			`ret`

zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`; (HL) being a string, advance it to the next non-sep character.`
			`; Set Z if we could do it before the line ended, reset Z if we couldn't.`
			`toWord:`
			`.loop:`
			`ld a, (hl)`
			`call isLineEnd`
			`jr z, .error`
			`call isSep`
			`jr nz, .success`
			`inc hl`
			`jr .loop`
			`.error:`
			`; we need the Z flag to be unset and it is set now. Let's CP with`
			`; something it can't be equal to, something not a line end.`
			`cp 'a' ; Z flag unset`
			`ret`
			`.success:`
			`; We need the Z flag to be set and it is unset. Let's compare it with`
			`; itself to return a set Z`
			`cp a`
			`ret`


			`readLine:`
			`push de`
			`xor a`
			`ld (curWord), a`
			`ld (curArg1), a`
			`ld (curArg2), a`
			`ld de, curWord`
			`call readWord`
			`call toWord`
			`jr nz, .end`
			`ld de, curArg1`
			`call readWord`
			`call toWord`
			`jr nz, .end`
			`ld de, curArg2`
			`call readWord`
			`.end:`
			`pop de`
			`ret`

			`; match argument string at (HL) with argspec A.`
			`; Set Z/NZ on match`
			`matchArg:`
			`cp 0`
			`jr z, .matchnone`
			`; Z is unset. TODO: implement rest`
			`jr .end`
			`.matchnone:`
			`ld a, (hl)`
			`cp 0 ; arg must be null to match`
			`.end:`
			`ret`

zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`; Compare primary row at (DE) with string at curWord. Sets Z flag if there's a`
			`; match, reset if not.`
			`matchPrimaryRow:`
			`push hl`
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`push ix`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`ld hl, curWord`
			`ld a, 4`
zasm: reuse code from core 2019-04-17 07:00:19 +10:00			`call JUMP_STRNCMP`
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`jr nz, .end`
			`; name matches, let's see the rest`
			`ld ixh, d`
			`ld ixl, e`
			`ld hl, curArg1`
			`ld a, (ix+4)`
			`call matchArg`
			`jr nz, .end`
			`ld hl, curArg2`
			`ld a, (ix+5)`
			`call matchArg`
			`.end:`
			`pop ix`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`pop hl`
			`ret`

			`; Parse line at (HL) and write resulting opcode(s) in (DE). Returns the number`
			`; of bytes written in A.`
			`parseLine:`
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`call readLine`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`push de`
			`ld de, instTBlPrimary`
			`.loop:`
			`ld a, (de)`
			`cp 0`
			`jr z, .nomatch ; we reached last entry`
			`call matchPrimaryRow`
			`jr z, .match`
			`ld a, 7`
zasm: reuse code from core 2019-04-17 07:00:19 +10:00			`call JUMP_ADDDE`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`jr .loop`

			`.nomatch:`
			`xor a`
			`pop de`
			`ret`
			`.match:`
			`ld a, 6 ; upcode is on 7th byte`
zasm: reuse code from core 2019-04-17 07:00:19 +10:00			`call JUMP_ADDDE`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`ld a, (de)`
			`pop de`
			`ld (de), a`
			`ld a, 1`
			`ret`

zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`; In instruction metadata below, argument types arge indicated with a single`
			`; char mnemonic that is called "argspec". This is the table of correspondance.`
			`; Single letters are represented by themselves, so we don't need as much`
			`; metadata.`

			`argspecsSingle:`
			`.db "ABCDEHL", 0`

			`; Format: 1 byte argspec + 4 chars string`
			`argspecTbl:`
			`.db 'h', "HL", 0, 0`
			`.db 'l', "(HL)"`
			`.db 'd', "DE", 0, 0`
			`.db 'e', "(DE)"`
			`.db 'b', "BC", 0, 0`
			`.db 'c', "(BC)"`
			`.db 'a', "AF", 0, 0`
			`.db 'f', "AF'", 0`
			`.db 'x', "(IX)"`
			`.db 'y', "(IY)"`
			`.db 's', "SP", 0, 0`
			`.db 'p', "(SP)"`
			`.db 0`

zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00			`; This is a list of primary instructions (single upcode) that lead to a`
			`; constant (no group code to insert).`
			`; That doesn't mean that they don't take any argument though. For example,`
			`; "DEC IX" leads to a special upcode. These kind of constants are indicated`
			`; as a single byte to save space. Meaning:`
			`;`
			`; All single char registers (A/B/C etc) -> themselves`
			`; HL -> h`
			`; (HL) -> l`
			`; DE -> d`
			`; (DE) -> e`
			`; BC -> b`
			`; (BC) -> c`
			`; IX -> X`
			`; (IX) -> x`
			`; IY -> Y`
			`; (IY) -> y`
			`; AF -> a`
			`; AF' -> f`
			`; SP -> s`
			`; (SP) -> p`
			`; None -> 0`
			`;`
			`; This is a sorted list of "primary" (single byte) instructions along with`
			`; metadata`
			`; 4 bytes for the name (fill with zero)`
			`; 1 byte for arg constant`
			`; 1 byte for 2nd arg constant`
			`; 1 byte for upcode`
			`instTBlPrimary:`
			`.db "ADD", 0, 'A', 'h', 0x86 ; ADD A, HL`
			`.db "CCF", 0, 0, 0, 0x3f ; CCF`
			`.db "CPL", 0, 0, 0, 0x2f ; CPL`
			`.db "DAA", 0, 0, 0, 0x27 ; DAA`
			`.db "DI",0,0, 0, 0, 0xf3 ; DI`
			`.db "EI",0,0, 0, 0, 0xfb ; EI`
			`.db "EX",0,0, 'p', 'h', 0xe3 ; EX (SP), HL`
			`.db "EX",0,0, 'a', 'f', 0x08 ; EX AF, AF'`
			`.db "EX",0,0, 'd', 'h', 0xeb ; EX DE, HL`
			`.db "EXX", 0, 0, 0, 0xd9 ; EXX`
			`.db "HALT", 0, 0, 0x76 ; HALT`
			`.db "INC", 0, 'l', 0, 0x34 ; INC (HL)`
			`.db "JP",0,0, 'l', 0, 0xe9 ; JP (HL)`
			`.db "LD",0,0, 'c', 'A', 0x02 ; LD (BC), A`
			`.db "LD",0,0, 'e', 'A', 0x12 ; LD (DE), A`
			`.db "LD",0,0, 'A', 'c', 0x0a ; LD A, (BC)`
			`.db "LD",0,0, 'A', 'e', 0x0a ; LD A, (DE)`
			`.db "LD",0,0, 's', 'h', 0x0a ; LD SP, HL`
			`.db "NOP", 0, 0, 0, 0x00 ; NOP`
			`.db "RET", 0, 0, 0, 0xc9 ; RET`
			`.db "RLA", 0, 0, 0, 0x17 ; RLA`
			`.db "RLCA", 0, 0, 0x07 ; RLCA`
			`.db "RRA", 0, 0, 0, 0x1f ; RRA`
			`.db "RRCA", 0, 0, 0x0f ; RRCA`
			`.db "SCF", 0, 0, 0, 0x37 ; SCF`
			`.db 0`

			`; * Variables *`
			`; enough space for 4 chars and a null`
			`curWord:`
			`.db 0, 0, 0, 0, 0`
zasm: start matching args We now properly match arg-less operations. 2019-04-17 09:40:37 +10:00			`curArg1:`
			`.db 0, 0, 0, 0, 0`
			`curArg2:`
			`.db 0, 0, 0, 0, 0`
zasm: begin parsing with easy pickings Single opcodes that yield constants. "echo ret \| zasm" yields 0xc9. 2019-04-17 06:49:47 +10:00