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6502bench/SourceGen/SGTestData/Expected/10001-allops-value-65C02_cc65.S
Andy McFadden 39b7b20144 ORG rework, part 1
This is the first step toward changing the address region map from a
linear list to a hierarchy.  See issue #107 for the plan.

The AddressMap class has been rewritten to support the new approach.
The rest of the project has been updated to conform to the new API,
but feature-wise is unchanged.  While the map class supports
nested regions with explicit lengths, the rest of the application
still assumes a series of non-overlapping regions with "floating"
lengths.

The Set Address dialog is currently non-functional.

All of the output for cc65 changed because generation of segment
comments has been removed.  Some of the output for ACME changed as
well, because we no longer follow "* = addr" with a redundant
pseudopc statement.  ACME and 65tass have similar approaches to
placing things in memory, and so now have similar implementations.
2021-09-16 17:02:19 -07:00

276 lines
5.6 KiB
ArmAsm

.setcpu "65C02"
.org $1000
jsr L1014
jsr L108A
jsr L10C4
jsr L10D8
jsr L10F6
nop
nop
nop
brk
.byte $ff
L1014: ora ($ff,x)
.byte $02,$ff
.byte $03
tsb $ff
ora $ff
asl $ff
.byte $07
php
ora #$ff
asl A
.byte $0b
tsb $feff
ora $feff
asl $feff
.byte $0f
bpl @L1031
@L1031: ora ($ff),y
ora ($ff)
.byte $13
trb $ff
ora $ff,x
asl $ff,x
.byte $17
clc
ora $feff,y
inc A
.byte $1b
trb $feff
ora $feff,x
asl $feff,x
.byte $1f
jsr $feff
and ($ff,x)
.byte $22,$ff
.byte $23
bit $ff
and $ff
rol $ff
.byte $27
plp
and #$ff
rol A
.byte $2b
bit $feff
and $feff
rol $feff
.byte $2f
bmi @L106D
@L106D: and ($ff),y
and ($ff)
.byte $33
bit $ff,x
and $ff,x
rol $ff,x
.byte $37
sec
and $feff,y
dec A
.byte $3b
bit $feff,x
and $feff,x
rol $feff,x
.byte $3f
rti
L108A: eor ($ff,x)
.byte $42,$ff
.byte $43
.byte $44,$ff
eor $ff
lsr $ff
.byte $47
pha
eor #$ff
lsr A
.byte $4b
jmp @L109E
@L109E: eor $feff
lsr $feff
.byte $4f
bvc @L10A7
@L10A7: eor ($ff),y
eor ($ff)
.byte $53
.byte $54,$ff
eor $ff,x
lsr $ff,x
.byte $57
cli
eor $feff,y
phy
.byte $5b
.byte $5c,$ff,$fe
eor $feff,x
lsr $feff,x
.byte $5f
rts
L10C4: adc ($ff,x)
.byte $62,$ff
.byte $63
stz $ff
adc $ff
ror $ff
.byte $67
pla
adc #$ff
ror A
.byte $6b
jmp ($feff)
L10D8: adc $feff
ror $feff
.byte $6f
bvs @L10E1
@L10E1: adc ($ff),y
adc ($ff)
.byte $73
stz $ff,x
adc $ff,x
ror $ff,x
.byte $77
sei
adc $feff,y
ply
.byte $7b
jmp ($feff,x)
L10F6: adc $feff,x
ror $feff,x
.byte $7f
bra @L10FF
@L10FF: sta ($ff,x)
.byte $82,$ff
.byte $83
sty $ff
sta $ff
stx $ff
.byte $87
dey
bit #$ff
txa
.byte $8b
sty $feff
sta $feff
stx $feff
.byte $8f
bcc @L111C
@L111C: sta ($ff),y
sta ($ff)
.byte $93
sty $ff,x
sta $ff,x
stx $ff,y
.byte $97
tya
sta $feff,y
txs
.byte $9b
stz $feff
sta $feff,x
stz $feff,x
.byte $9f
ldy #$ff
lda ($ff,x)
ldx #$ff
.byte $a3
ldy $ff
lda $ff
ldx $ff
.byte $a7
tay
lda #$ff
tax
.byte $ab
ldy $feff
lda $feff
ldx $feff
.byte $af
bcs @L1157
@L1157: lda ($ff),y
lda ($ff)
.byte $b3
ldy $ff,x
lda $ff,x
ldx $ff,y
.byte $b7
clv
lda $feff,y
tsx
.byte $bb
ldy $feff,x
lda $feff,x
ldx $feff,y
.byte $bf
cpy #$ff
cmp ($ff,x)
.byte $c2,$ff
.byte $c3
cpy $ff
cmp $ff
dec $ff
.byte $c7
iny
cmp #$ff
dex
.byte $cb
cpy $feff
cmp $feff
dec $feff
.byte $cf
bne @L1192
@L1192: cmp ($ff),y
cmp ($ff)
.byte $d3
.byte $d4,$ff
cmp $ff,x
dec $ff,x
.byte $d7
cld
cmp $feff,y
phx
.byte $db
.byte $dc,$ff,$fe
cmp $feff,x
dec $feff,x
.byte $df
cpx #$ff
sbc ($ff,x)
.byte $e2,$ff
.byte $e3
cpx $ff
sbc $ff
inc $ff
.byte $e7
inx
sbc #$ff
nop
.byte $eb
cpx $feff
sbc $feff
inc $feff
.byte $ef
beq @L11CD
@L11CD: sbc ($ff),y
sbc ($ff)
.byte $f3
.byte $f4,$ff
sbc $ff,x
inc $ff,x
.byte $f7
sed
sbc $feff,y
plx
.byte $fb
.byte $fc,$ff,$fe
sbc $feff,x
inc $feff,x
.byte $ff