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6502bench/SourceGen/SGTestData/Expected/10001-allops-value-65C02_cc65.S
Andy McFadden 3ff0fbae34 Regression test rework, part 1
The regression tests were written with the assumption that all cross
assemblers would support 6502, 65C02, and 65816 code.  There are a
few that support 65816 partially (e.g. ACME) or not at all.  To best
support these, we need to split some of the tests into pieces, so
that important 6502 tests aren't skipped simply because parts of the
test also exercise 65816 code.

The first step is to change the regression test naming scheme.  The
old system used 1xxx for tests without project files, and 2xxx for
tests with project files.  The new system uses 1xxxN / 2xxxN, where
N indicates the CPU type: 0 for 6502, 1 for 65C02, and 2 for 65816.
For the 1xxxN tests the new value determines which CPU is used,
which allows us to move the "allops" 6502/65C02 tests into the
no-project category.  For 2xxxN it just allows the 6502 and 65816
versions to have the same base name and number.

This change updates the first batch of tests.  It involves minor
changes to the test harness and a whole bunch of renaming.
2020-06-06 14:47:19 -07:00

277 lines
5.6 KiB
ArmAsm

.setcpu "65C02"
; .segment "SEG000"
.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