itty-bitty-vtty/vt100.csi.S

861 lines
9.8 KiB
ArmAsm

lst off
cas se
rel
xc
xc
use vt.equ
use debug
mx %11
ext reset_tab,reset_all_tabs
ext recalc_cursor,recalc_cursor_x,recalc_cursor_y
ext erase_line_0,erase_line_1,erase_line_2
ext erase_screen_0,erase_screen_1,erase_screen_2
ext write_modem
vt100_csi ent
debug vt100_csi
* 0123456789;ycnlhgrqJKmABCDHf
* based on testing -
* everything except '0' - '?' and control chars
* will finish.
* '?' only matters for h/l
* a misplaced ? (or anything in '0' - '?', except 0-9;)
* will cancel the sequence AFTER it's finished.
* < = > ? are allowed as an initial modifier but only '?' is private
* a mis-placed < = > ? will prevent 0x20-0x2f from terminating the sequence.
ldx #st_vt100
stx state
stz pcount
stz parms
stz parms+1 ; some assume 2 parms.
stz pmod
* tay ; save for modifier
cmp #:MIN
blt :rts
cmp #:MAX+1
bge :rts
sec
sbc #:MIN
asl
tax
jmp (:table,x)
*
:rts rts
:MIN equ 48
:MAX equ 121
:table
dw :digit ; 0
dw :digit ; 1
dw :digit ; 2
dw :digit ; 3
dw :digit ; 4
dw :digit ; 5
dw :digit ; 6
dw :digit ; 7
dw :digit ; 8
dw :digit ; 9
dw digit ; :
dw semi
dw :xmod ; <
dw :xmod ; =
dw :xmod ; >
dw :modifier ; ?
dw :rts ; @
dw csi_A ; A
dw csi_B ; B
dw csi_C ; C
dw csi_D ; D
dw :rts ; E
dw :rts ; F
dw :rts ; G
dw csi_H ; H
dw :rts ; I
dw csi_J ; J
dw csi_K ; K
dw :rts ; L
dw :rts ; M
dw :rts ; N
dw :rts ; O
dw :rts ; P
dw :rts ; Q
dw :rts ; R
dw :rts ; S
dw :rts ; T
dw :rts ; U
dw :rts ; V
dw :rts ; W
dw :rts ; X
dw :rts ; Y
dw :rts ; Z
dw :rts ; [
dw :rts ; \
dw :rts ; ]
dw :rts ; ^
dw :rts ; _
dw :rts ; `
dw :rts ; a
dw :rts ; b
dw csi_c ; c
dw :rts ; d
dw :rts ; e
dw csi_f ; f
dw csi_g ; g
dw csi_h ; h
dw :rts ; i
dw :rts ; j
dw :rts ; k
dw csi_l ; l
dw csi_m ; m
dw csi_n ; n
dw :rts ; o
dw :rts ; p
dw csi_q ; q
dw csi_r ; r
dw :rts ; s
dw :rts ; t
dw :rts ; u
dw :rts ; v
dw :rts ; w
dw :rts ; x
dw csi_y ; y
:digit
ldx #st_vt100_csi_2
stx state
lsr ; undo asl
sta parms
rts
:modifier
ldx #st_vt100_csi_2
stx state
lda #$80
sta pmod
rts
:xmod
* ignored.
ldx #st_vt100_csi_2
stx state
rts
vt100_csi_bad ent
cmp #'@'
blt :rts
ldx #st_vt100
stx state
:rts rts
vt100_csi_2 ent
debug vt100_csi_2
ldx #st_vt100
stx state
cmp #:MIN
blt :rts
cmp #:MAX+1
bge :rts
sec
sbc #:MIN
asl
tax
jmp (:table,x)
:rts rts
:MIN equ 48
:MAX equ 121
:table
dw digit ; 0
dw digit ; 1
dw digit ; 2
dw digit ; 3
dw digit ; 4
dw digit ; 5
dw digit ; 6
dw digit ; 7
dw digit ; 8
dw digit ; 9
dw digit ; :
dw semi
dw :modifier ; <
dw :modifier ; =
dw :modifier ; >
dw :modifier ; ?
dw :rts ; @
dw csi_A ; A
dw csi_B ; B
dw csi_C ; C
dw csi_D ; D
dw :rts ; E
dw :rts ; F
dw :rts ; G
dw csi_H ; H
dw :rts ; I
dw csi_J ; J
dw csi_K ; K
dw :rts ; L
dw :rts ; M
dw :rts ; N
dw :rts ; O
dw :rts ; P
dw :rts ; Q
dw :rts ; R
dw :rts ; S
dw :rts ; T
dw :rts ; U
dw :rts ; V
dw :rts ; W
dw :rts ; X
dw :rts ; Y
dw :rts ; Z
dw :rts ; [
dw :rts ; \
dw :rts ; ]
dw :rts ; ^
dw :rts ; _
dw :rts ; `
dw :rts ; a
dw :rts ; b
dw csi_c ; c
dw :rts ; d
dw :rts ; e
dw csi_f ; f
dw csi_g ; g
dw csi_h ; h
dw :rts ; i
dw :rts ; j
dw :rts ; k
dw csi_l ; l
dw csi_m ; m
dw csi_n ; n
dw :rts ; o
dw :rts ; p
dw csi_q ; q
dw csi_r ; r
dw :rts ; s
dw :rts ; t
dw :rts ; u
dw :rts ; v
dw :rts ; w
dw :rts ; x
dw csi_y ; y
:modifier
ldx #st_vt100_csi_bad
stx state
rts
semi
ldx #st_vt100_csi_2
stx state
ldx pcount
cpx #MAX_PCOUNT
bge :big
inx
stx pcount
:big stz parms,x
:rts rts
* parameter digit. clamped to 255 (250+ rounds up to 255)
* in 132 is the largest valid parameter so this is ok.
digit
ldx #st_vt100_csi_2
stx state
lsr ; undo asl
sta r0
ldx pcount
lda parms,x
* cmp #255
* beq :rts
cmp #25
bge :v
tay
lda :mult,y
* clc ; cleared via cmp
adc r0
sta parms,x
:rts
rts
:v
lda #$255
sta parms,x
rts
:mult db 0,10,20,30,40,50,60,70,80,90
db 100,110,120,130,140,150,160,170,180,190
db 200,210,220,230,240,250
csi_h
; esc [ ... h (vt100)
; esc [ ? ... h (private)
ldy #$80
bra mode_common
csi_l
; esc [ ... l (vt100)
; esc [ ? ... l (private)
ldy #0
mode_common
inc pcount
ldx #0
:loop lda parms,x
cmp #:MIN
blt :next
cmp #:MAX+1
bge :next
phx
asl
tax
jsr (:table,x)
plx
:next inx
cpx pcount
blt :loop
:rts rts
:MIN equ 0
:MAX equ 20
:table
dw :rts ; error
dw mode_DECCKM
dw mode_DECANM
dw :rts ; DECCOLM
dw :rts ; DECSCLM
dw mode_DECSCNM
dw mode_DECOM
dw mode_DECAWM
dw mode_DECARM
dw :rts ; DECINLM
dw :rts ; 10
dw :rts ; 11
dw :rts ; 12
dw :rts ; 13
dw :rts ; 14
dw :rts ; 15
dw :rts ; 16
dw :rts ; 17
dw :rts ; 18
dw :rts ; 19
dw mode_LNM
*:mask dw 0,$40,$40,$40,$40,$40,$40,$40,$40,$40
* dw 0,0,0,0,0,0,0,0,0,0,0
mode_DECCKM
bit pmod
bpl :rts
sty DECCKM
:rts rts
mode_DECANM
bit pmod
bpl :rts
sty DECANM
cpy #0
bne :rts
* switch to vt52 mode
ldx #st_vt52
stx state
:rts rts
*mode_DECCOLM
* sty DECCOLM
* rts
mode_DECSCNM
bit pmod
bpl :rts
* todo - invert on-screen characters?
sty DECSCNM
:rts rts
mode_DECOM
bit pmod
bpl :rts
sty DECOM
; move to the new home position
stz x
stz y
cpy #0
beq :rts
lda DECTM
sta y
phy
jsr recalc_cursor
ply
:rts rts
mode_DECAWM
bit pmod
bpl :rts
sty DECAWM
:rts rts
mode_DECARM
bit pmod
bpl :rts
sty DECARM
:rts rts
mode_LNM
bit pmod
bmi :rts
sty LNM
:rts rts
csi_m
* esc [ ... m
* 0 - attributes off
* 1 - bold
* 4 - underscore
* 5 - blink
* 7 - inverted
inc pcount
ldx #0
:loop lda parms,x
cmp #8
bge :next
tay
lda SGR
and :and,y
ora :or,y
sta SGR
:next inx
cpx pcount
blt :loop
* now update - bit 7 indicates inverse.
stz draw_inverse
lda SGR
beq :rts
lda #$80
* and #$80
sta draw_inverse
:rts rts
:and db $00,$ff,$ff,$ff,$ff,$ff,$ff,$ff
:or db %0000_0000,%0000_0010,%0000_0000,%0000_0000
db %0001_0000,%0010_0000,%0000_0000,%1000_0000
csi_g
* ESC [ g, ESC [ 0 g - clear tab at column
* ESC [ 3 g - clear all tabs
lda parms
beq :0
cmp #3
beq :3
rts
:0 ldx x
jmp reset_tab
:3 jmp reset_all_tabs
p1 mac
lda parms
bne ok
lda #1
ok sta parms
<<<
* cursor movement.
* if private mode, no effect.
csi_A
* up
* if cursor is outside the scrolling region, it is not locked to the scrolling region.
bit pmod
bmi :rts
p1
lda y
cmp DECTM
beq :rts
bcc :simple
sec
sbc parms
bcc :top
cmp DECTM
* bcc :top
* bra :sta
bcs :sta
:top lda DECTM
bra :sta
:rts rts
:simple
* lda y
sec
sbc parms
* bcc :0 ; clear indicate underflow.
bcc :sta
:0 lda #0
:sta sta y
jmp recalc_cursor_y
csi_B
* down
bit pmod
bmi :rts
p1
lda y
cmp DECBM
beq :rts
bge :simple
clc
adc parms
bcs :bottom ; overflow
cmp DECBM
bcc :sta
:bottom lda DECBM
bra :sta
:rts rts
:simple
clc
adc parms
bcs :23 ; overflow
cmp #24
bcc :sta
:23 lda #23
:sta sta y
jmp recalc_cursor_y
csi_C
* right
* in column 80, no effect.
bit pmod
bmi :rts
lda x
cmp #79
bcs :rts
p1
lda x
* and #$7f
clc
adc parms
bcs :79 ; overflow
cmp #80
bcc :sta
:79 lda #79
:sta sta x
jmp recalc_cursor_x
:rts rts
csi_D
* left
bit pmod
bmi :rts
p1
lda x
and #$7f
sec
sbc parms
* bcc :0 ; underflow
bcs :sta
:0 lda #0
:sta sta x
jmp recalc_cursor_x
:rts rts
csi_f
csi_H ; direct cursor addressing
debug csi_H
* honors origin
* large numbers are clamped
* 0 or 1 treated as 1 (1-based counting)
* based on testing, esc [ 253-255 H will position outside the scrolling
* region when DECOM is active (to first 3 lines, respectively)
* this is not emulated.
* y
lda parms
beq :yy
dec
:yy bit DECOM
bmi :org
cmp #23
blt :yyy
lda #23
:yyy sta y
bra :x
:org
clc
adc DECTM
cmp DECBM
blt :org1
lda DECBM
:org1 sta y
* x
:x
ldx parms+1
beq :xx
dex
:xx
cpx #79
blt :xxx
ldx #79
:xxx stx x
jmp recalc_cursor
csi_r ; scrolling region
debug csi_r
* based on testing
* esc [ n r (no second parmeter) is equivalent to esc [ n ; 24 r
* esc [ r sets scrolling region to 1 ; 24 ( in accordance with above )
* 24 is assumed value for second parameter
* invalid parameters exit without updating
* based on testing, row parameters are not affected by DECOM.
lda parms
beq :p1
dec parms
:p1
lda parms+1
beq :p2
dec parms+1
bra :check
:p2 lda #23
sta parms+1
:check
* 23 max
ldx parms+0
cpx #23+1
bge :rts
ldx parms+1
cpx #23+1
bge :rts
* must be at least 1 line
lda parms+1
sec
sbc parms
beq :rts
bmi :rts
* move cursor to origin.
lda parms
sta DECTM
sta y
lda parms+1
sta DECBM
stz x
bit DECOM
bmi :j
stz y
:j jmp recalc_cursor
:rts rts
csi_J ; erase screen
lda parms
cmp #2+1
bcs :rts
asl
tax
jmp (:table,x)
:rts rts
:table
dw erase_screen_0
dw erase_screen_1
dw erase_screen_2
csi_K ; erase line
lda parms
cmp #2+1
bcs :rts
asl
tax
jmp (:table,x)
:rts rts
:table
dw erase_line_0
dw erase_line_1
dw erase_line_2
csi_q ; LEDs
rts
csi_n ; status report
bit LOCAL
bmi :rts
lda parms
cmp #5
beq :dsr
cmp #6
beq :cpr
:rts rts
:dsr ; report status
lda #ESC
jsr write_modem
lda #'['
jsr write_modem
lda #'0'
jsr write_modem
lda #'n'
jmp write_modem
:cpr ; cursor report
* returned y is in terms of DECOM.
lda #ESC
jsr write_modem
lda #'['
jsr write_modem
lda y
bit DECOM
bpl :y
sec
sbc DECTM
:y inc
jsr write_digit
lda #';'
jsr write_modem
lda x
inc
jsr write_digit
lda #'R'
jmp write_modem
write_digit
* digit must be in the range 1-80
cmp #10
bcs :multi
:0 ora #'0'
jmp write_modem
:multi
ldx #8
]loop cmp :table,x
bcs :ok
dex
bra ]loop
:ok sec
sbc :table,x
pha ; save
txa
ora #'0'
jsr write_modem
pla
bra :0
:table db 0,10,20,30,40,50,60,70,80
csi_c ; what are you?
lda #ESC
jsr write_modem
lda #'['
jsr write_modem
lda #'?'
jsr write_modem
lda #'1'
jsr write_modem
lda #'?'
jsr write_modem
lda #'0'
jsr write_modem
lda #'c'
jmp write_modem
csi_y ; invoke confidence test
* ???
rts
sav vt100.csi.L