dos33fsprogs/demos/trogdor/pt3_lib_core.s
2024-01-11 01:25:38 -05:00

2024 lines
45 KiB
ArmAsm

;===========================================
; Library to decode Vortex Tracker PT3 files
; in 6502 assembly for Apple ][ Mockingboard
;
; by Vince Weaver <vince@deater.net>
; Roughly based on the Formats.pas Pascal code from Ay_Emul
; Size Optimization -- Mem+Code (pt3_lib_end-note_a)
; + 3407 bytes -- original working implementation
; + 3302 bytes -- autogenerate the volume tables
; + 3297 bytes -- remove some un-needed bytes from struct
; + 3262 bytes -- combine some duplicated code in $1X/$BX env setting
; + 3253 bytes -- remove unnecessary variable
; + 3203 bytes -- combine common code in note decoder
; + 2937 bytes -- qkumba first pass
; + 2879 bytes -- qkumba second pass
; + 2839 bytes -- mask note command in common code
; + 2832 bytes -- combine $D0 and $E0 decode
; + 2816 bytes -- eliminate "decode_done" variable (2.75k)
; + 2817 bytes -- eliminate pt3_version. Slighly faster but also bigger
; + 2828 bytes -- fix some correctness issues
; + 2776 bytes -- init vars with loop (slower, but more correct and smaller)
; + 2739 bytes -- qkumba's crazy SMC everywhere patch
; + 2418+143 = 2561 bytes -- move NOTE structs to page0
; + 2423+143 = 2566 bytes -- fix vibrato code
; + 2554+143 = 2697 bytes -- generate all four tone tables
; + 2537+143 = 2680 bytes -- inline GetNoteFreq
; TODO
; move some of these flags to be bits rather than bytes?
; enabled could be bit 6 or 7 for fast checking
; NOTE_ENABLED,ENVELOPE_ENABLED,SIMPLE_GLISS,ENV_SLIDING,AMP_SLIDING?
; Header offsets
PT3_VERSION = $0D
PT3_HEADER_FREQUENCY = $63
PT3_SPEED = $64
PT3_LOOP = $66
PT3_PATTERN_LOC_L = $67
PT3_PATTERN_LOC_H = $68
PT3_SAMPLE_LOC_L = $69
PT3_SAMPLE_LOC_H = $6A
PT3_ORNAMENT_LOC_L = $A9
PT3_ORNAMENT_LOC_H = $AA
PT3_PATTERN_TABLE = $C9
; Use memset to set things to 0?
NOTE_VOLUME =0
NOTE_TONE_SLIDING_L =1
NOTE_TONE_SLIDING_H =2
NOTE_ENABLED =3
NOTE_ENVELOPE_ENABLED =4
NOTE_SAMPLE_POINTER_L =5
NOTE_SAMPLE_POINTER_H =6
NOTE_SAMPLE_LOOP =7
NOTE_SAMPLE_LENGTH =8
NOTE_TONE_L =9
NOTE_TONE_H =10
NOTE_AMPLITUDE =11
NOTE_NOTE =12
NOTE_LEN =13
NOTE_LEN_COUNT =14
NOTE_ADDR_L =15
NOTE_ADDR_H =16
NOTE_ORNAMENT_POINTER_L =17
NOTE_ORNAMENT_POINTER_H =18
NOTE_ORNAMENT_LOOP =19
NOTE_ORNAMENT_LENGTH =20
NOTE_ONOFF =21
NOTE_TONE_ACCUMULATOR_L =22
NOTE_TONE_ACCUMULATOR_H =23
NOTE_TONE_SLIDE_COUNT =24
NOTE_ORNAMENT_POSITION =25
NOTE_SAMPLE_POSITION =26
NOTE_ENVELOPE_SLIDING =27
NOTE_NOISE_SLIDING =28
NOTE_AMPLITUDE_SLIDING =29
NOTE_ONOFF_DELAY =30 ;ordering of DELAYs is hard-coded now
NOTE_OFFON_DELAY =31 ;ordering of DELAYs is hard-coded now
NOTE_TONE_SLIDE_STEP_L =32
NOTE_TONE_SLIDE_STEP_H =33
NOTE_TONE_SLIDE_DELAY =34
NOTE_SIMPLE_GLISS =35
NOTE_SLIDE_TO_NOTE =36
NOTE_TONE_DELTA_L =37
NOTE_TONE_DELTA_H =38
NOTE_TONE_SLIDE_TO_STEP =39
NOTE_STRUCT_SIZE=40
.ifdef PT3_USE_ZERO_PAGE
note_a = $80
note_b = $80+(NOTE_STRUCT_SIZE*1)
note_c = $80+(NOTE_STRUCT_SIZE*2)
begin_vars=$80
end_vars=$80+(NOTE_STRUCT_SIZE*3)
.else ; !PT3_USE_ZERO_PAGE
begin_vars:
note_a: ; reset?
.byte $0 ; NOTE_VOLUME ; 0 ; Y
.byte $0 ; NOTE_TONE_SLIDING_L ; 1 ; Y
.byte $0 ; NOTE_TONE_SLIDING_H ; 2 ; Y
.byte $0 ; NOTE_ENABLED ; 3 ; Y
.byte $0 ; NOTE_ENVELOPE_ENABLED ; 4 ; Y
.byte $0 ; NOTE_SAMPLE_POINTER_L ; 5 ; Y
.byte $0 ; NOTE_SAMPLE_POINTER_H ; 6 ; Y
.byte $0 ; NOTE_SAMPLE_LOOP ; 7 ; Y
.byte $0 ; NOTE_SAMPLE_LENGTH ; 8 ; Y
.byte $0 ; NOTE_TONE_L ; 9
.byte $0 ; NOTE_TONE_H ; 10
.byte $0 ; NOTE_AMPLITUDE ; 11
.byte $0 ; NOTE_NOTE ; 12
.byte $0 ; NOTE_LEN ; 13
.byte $0 ; NOTE_LEN_COUNT ; 14
.byte $0 ; NOTE_ADDR_L ; 15
.byte $0 ; NOTE_ADDR_H ; 16
.byte $0 ; NOTE_ORNAMENT_POINTER_L ; 17 ; Y
.byte $0 ; NOTE_ORNAMENT_POINTER_H ; 18 ; Y
.byte $0 ; NOTE_ORNAMENT_LOOP ; 19 ; Y
.byte $0 ; NOTE_ORNAMENT_LENGTH ; 20 ; Y
.byte $0 ; NOTE_ONOFF ; 21
.byte $0 ; NOTE_TONE_ACCUMULATOR_L ; 22
.byte $0 ; NOTE_TONE_ACCUMULATOR_H ; 23
.byte $0 ; NOTE_TONE_SLIDE_COUNT ; 24
.byte $0 ; NOTE_ORNAMENT_POSITION ; 25 ; Y
.byte $0 ; NOTE_SAMPLE_POSITION ; 26 ; Y
.byte $0 ; NOTE_ENVELOPE_SLIDING ; 27
.byte $0 ; NOTE_NOISE_SLIDING ; 28
.byte $0 ; NOTE_AMPLITUDE_SLIDING ; 29
.byte $0 ; NOTE_ONOFF_DELAY ; 30
.byte $0 ; NOTE_OFFON_DELAY ; 31
.byte $0 ; NOTE_TONE_SLIDE_STEP_L ; 32
.byte $0 ; NOTE_TONE_SLIDE_STEP_H ; 33
.byte $0 ; NOTE_TONE_SLIDE_DELAY ; 34
.byte $0 ; NOTE_SIMPLE_GLISS ; 35
.byte $0 ; NOTE_SLIDE_TO_NOTE ; 36
.byte $0 ; NOTE_TONE_DELTA_L ; 37
.byte $0 ; NOTE_TONE_DELTA_H ; 38
.byte $0 ; NOTE_TONE_SLIDE_TO_STEP ; 39
note_b:
.byte $0 ; NOTE_VOLUME
.byte $0 ; NOTE_TONE_SLIDING_L
.byte $0 ; NOTE_TONE_SLIDING_H
.byte $0 ; NOTE_ENABLED
.byte $0 ; NOTE_ENVELOPE_ENABLED
.byte $0 ; NOTE_SAMPLE_POINTER_L
.byte $0 ; NOTE_SAMPLE_POINTER_H
.byte $0 ; NOTE_SAMPLE_LOOP
.byte $0 ; NOTE_SAMPLE_LENGTH
.byte $0 ; NOTE_TONE_L
.byte $0 ; NOTE_TONE_H
.byte $0 ; NOTE_AMPLITUDE
.byte $0 ; NOTE_NOTE
.byte $0 ; NOTE_LEN
.byte $0 ; NOTE_LEN_COUNT
.byte $0 ; NOTE_ADDR_L
.byte $0 ; NOTE_ADDR_H
.byte $0 ; NOTE_ORNAMENT_POINTER_L
.byte $0 ; NOTE_ORNAMENT_POINTER_H
.byte $0 ; NOTE_ORNAMENT_LOOP
.byte $0 ; NOTE_ORNAMENT_LENGTH
.byte $0 ; NOTE_ONOFF
.byte $0 ; NOTE_TONE_ACCUMULATOR_L
.byte $0 ; NOTE_TONE_ACCUMULATOR_H
.byte $0 ; NOTE_TONE_SLIDE_COUNT
.byte $0 ; NOTE_ORNAMENT_POSITION
.byte $0 ; NOTE_SAMPLE_POSITION
.byte $0 ; NOTE_ENVELOPE_SLIDING
.byte $0 ; NOTE_NOISE_SLIDING
.byte $0 ; NOTE_AMPLITUDE_SLIDING
.byte $0 ; NOTE_ONOFF_DELAY
.byte $0 ; NOTE_OFFON_DELAY
.byte $0 ; NOTE_TONE_SLIDE_STEP_L
.byte $0 ; NOTE_TONE_SLIDE_STEP_H
.byte $0 ; NOTE_TONE_SLIDE_DELAY
.byte $0 ; NOTE_SIMPLE_GLISS
.byte $0 ; NOTE_SLIDE_TO_NOTE
.byte $0 ; NOTE_TONE_DELTA_L
.byte $0 ; NOTE_TONE_DELTA_H
.byte $0 ; NOTE_TONE_SLIDE_TO_STEP
note_c:
.byte $0 ; NOTE_VOLUME
.byte $0 ; NOTE_TONE_SLIDING_L
.byte $0 ; NOTE_TONE_SLIDING_H
.byte $0 ; NOTE_ENABLED
.byte $0 ; NOTE_ENVELOPE_ENABLED
.byte $0 ; NOTE_SAMPLE_POINTER_L
.byte $0 ; NOTE_SAMPLE_POINTER_H
.byte $0 ; NOTE_SAMPLE_LOOP
.byte $0 ; NOTE_SAMPLE_LENGTH
.byte $0 ; NOTE_TONE_L
.byte $0 ; NOTE_TONE_H
.byte $0 ; NOTE_AMPLITUDE
.byte $0 ; NOTE_NOTE
.byte $0 ; NOTE_LEN
.byte $0 ; NOTE_LEN_COUNT
.byte $0 ; NOTE_ADDR_L
.byte $0 ; NOTE_ADDR_H
.byte $0 ; NOTE_ORNAMENT_POINTER_L
.byte $0 ; NOTE_ORNAMENT_POINTER_H
.byte $0 ; NOTE_ORNAMENT_LOOP
.byte $0 ; NOTE_ORNAMENT_LENGTH
.byte $0 ; NOTE_ONOFF
.byte $0 ; NOTE_TONE_ACCUMULATOR_L
.byte $0 ; NOTE_TONE_ACCUMULATOR_H
.byte $0 ; NOTE_TONE_SLIDE_COUNT
.byte $0 ; NOTE_ORNAMENT_POSITION
.byte $0 ; NOTE_SAMPLE_POSITION
.byte $0 ; NOTE_ENVELOPE_SLIDING
.byte $0 ; NOTE_NOISE_SLIDING
.byte $0 ; NOTE_AMPLITUDE_SLIDING
.byte $0 ; NOTE_ONOFF_DELAY
.byte $0 ; NOTE_OFFON_DELAY
.byte $0 ; NOTE_TONE_SLIDE_STEP_L
.byte $0 ; NOTE_TONE_SLIDE_STEP_H
.byte $0 ; NOTE_TONE_SLIDE_DELAY
.byte $0 ; NOTE_SIMPLE_GLISS
.byte $0 ; NOTE_SLIDE_TO_NOTE
.byte $0 ; NOTE_TONE_DELTA_L
.byte $0 ; NOTE_TONE_DELTA_H
.byte $0 ; NOTE_TONE_SLIDE_TO_STEP
end_vars:
.endif
load_ornament0_sample1:
lda #0 ; 2
jsr load_ornament ; 6
; fall through
;===========================
; Load Sample
;===========================
; sample in A
; which note offset in X
; Sample table pointers are 16-bits little endian
; There are 32 of these pointers starting at $6a:$69
; Our sample starts at address (A*2)+that pointer
; We point SAMPLE_H:SAMPLE_L to this
; then we load the length/data values
; and then leave SAMPLE_H:SAMPLE_L pointing to begnning of
; the sample data
; Optimization:
; see comments on ornament setting
load_sample1:
lda #1 ; 2
load_sample:
sty PT3_TEMP ; 3
;pt3->ornament_patterns[i]=
; (pt3->data[0x6a+(i*2)]<<8)|pt3->data[0x69+(i*2)];
asl ; A*2 ; 2
tay ; 2
; Set the initial sample pointer
; a->sample_pointer=pt3->sample_patterns[a->sample];
lda PT3_LOC+PT3_SAMPLE_LOC_L,Y ; 4+
sta SAMPLE_L ; 3
lda PT3_LOC+PT3_SAMPLE_LOC_L+1,Y ; 4+
; assume pt3 file is at page boundary
adc #>PT3_LOC ; 2
sta SAMPLE_H ; 3
; Set the loop value
; a->sample_loop=pt3->data[a->sample_pointer];
ldy #0 ; 2
lda (SAMPLE_L),Y ; 5+
sta note_a+NOTE_SAMPLE_LOOP,X ; 5
; Set the length value
; a->sample_length=pt3->data[a->sample_pointer];
iny ; 2
lda (SAMPLE_L),Y ; 5+
sta note_a+NOTE_SAMPLE_LENGTH,X ; 5
; Set pointer to beginning of samples
lda SAMPLE_L ; 3
adc #$2 ; 2
sta note_a+NOTE_SAMPLE_POINTER_L,X ; 5
lda SAMPLE_H ; 3
adc #$0 ; 2
sta note_a+NOTE_SAMPLE_POINTER_H,X ; 5
ldy PT3_TEMP ; 3
rts ; 6
;============
; 76
;===========================
; Load Ornament
;===========================
; ornament value in A
; note offset in X
; Ornament table pointers are 16-bits little endian
; There are 16 of these pointers starting at $aa:$a9
; Our ornament starts at address (A*2)+that pointer
; We point ORNAMENT_H:ORNAMENT_L to this
; then we load the length/data values
; and then leave ORNAMENT_H:ORNAMENT_L pointing to begnning of
; the ornament data
; Optimization:
; Loop and length only used once, can be located negative
; from the pointer, but 6502 doesn't make addressing like that
; easy. Can't self modify as channels A/B/C have own copies
; of the var.
load_ornament:
sty PT3_TEMP ; save Y value ; 3
;pt3->ornament_patterns[i]=
; (pt3->data[0xaa+(i*2)]<<8)|pt3->data[0xa9+(i*2)];
asl ; A*2 ; 2
tay ; 2
; a->ornament_pointer=pt3->ornament_patterns[a->ornament];
lda PT3_LOC+PT3_ORNAMENT_LOC_L,Y ; 4+
sta ORNAMENT_L ; 3
lda PT3_LOC+PT3_ORNAMENT_LOC_L+1,Y ; 4+
; we're assuming PT3 is loaded to a page boundary
adc #>PT3_LOC ; 2
sta ORNAMENT_H ; 3
lda #0 ; 2
sta note_a+NOTE_ORNAMENT_POSITION,X ; 5
tay ; 2
; Set the loop value
; a->ornament_loop=pt3->data[a->ornament_pointer];
lda (ORNAMENT_L),Y ; 5+
sta note_a+NOTE_ORNAMENT_LOOP,X ; 5
; Set the length value
; a->ornament_length=pt3->data[a->ornament_pointer];
iny ; 2
lda (ORNAMENT_L),Y ; 5+
sta note_a+NOTE_ORNAMENT_LENGTH,X ; 5
; Set the pointer to the value past the length
lda ORNAMENT_L ; 3
adc #$2 ; 2
sta note_a+NOTE_ORNAMENT_POINTER_L,X ; 5
lda ORNAMENT_H ; 3
adc #$0 ; 2
sta note_a+NOTE_ORNAMENT_POINTER_H,X ; 5
ldy PT3_TEMP ; restore Y value ; 3
rts ; 6
;============
; 83
;=====================================
; Calculate Note
;=====================================
; note offset in X
calculate_note:
lda note_a+NOTE_ENABLED,X ; 4+
bne note_enabled ; 2/3
sta note_a+NOTE_AMPLITUDE,X ; 5
jmp done_note ; 3
note_enabled:
lda note_a+NOTE_SAMPLE_POINTER_H,X ; 4+
sta SAMPLE_H ; 3
lda note_a+NOTE_SAMPLE_POINTER_L,X ; 4+
sta SAMPLE_L ; 3
lda note_a+NOTE_ORNAMENT_POINTER_H,X ; 4+
sta ORNAMENT_H ; 3
lda note_a+NOTE_ORNAMENT_POINTER_L,X ; 4+
sta ORNAMENT_L ; 3
lda note_a+NOTE_SAMPLE_POSITION,X ; 4+
asl ; 2
asl ; 2
tay ; 2
; b0 = pt3->data[a->sample_pointer + a->sample_position * 4];
lda (SAMPLE_L),Y ; 5+
sta sample_b0_smc+1 ; 4
; b1 = pt3->data[a->sample_pointer + a->sample_position * 4 + 1];
iny ; 2
lda (SAMPLE_L),Y ; 5+
sta sample_b1_smc+1 ; 4
; a->tone = pt3->data[a->sample_pointer + a->sample_position*4+2];
; a->tone+=(pt3->data[a->sample_pointer + a->sample_position*4+3])<<8;
; a->tone += a->tone_accumulator;
iny ; 2
lda (SAMPLE_L),Y ; 5+
adc note_a+NOTE_TONE_ACCUMULATOR_L,X ; 4+
sta note_a+NOTE_TONE_L,X ; 4
iny ; 2
lda (SAMPLE_L),Y ; 5+
adc note_a+NOTE_TONE_ACCUMULATOR_H,X ; 4+
sta note_a+NOTE_TONE_H,X ; 4
;=============================
; Accumulate tone if set
; (if sample_b1 & $40)
bit sample_b1_smc+1
bvc no_accum ; (so, if b1&0x40 is zero, skip it)
sta note_a+NOTE_TONE_ACCUMULATOR_H,X
lda note_a+NOTE_TONE_L,X ; tone_accumulator=tone
sta note_a+NOTE_TONE_ACCUMULATOR_L,X
no_accum:
;============================
; Calculate tone
; j = a->note + (pt3->data[a->ornament_pointer + a->ornament_position]
clc ;;can be removed if ADC ACCUMULATOR_H cannot overflow
ldy note_a+NOTE_ORNAMENT_POSITION,X
lda (ORNAMENT_L),Y
adc note_a+NOTE_NOTE,X
; if (j < 0) j = 0;
bpl note_not_negative
lda #0
; if (j > 95) j = 95;
note_not_negative:
cmp #96
bcc note_not_too_high ; blt
lda #95
note_not_too_high:
; w = GetNoteFreq(j,pt3->frequency_table);
tay ; for GetNoteFreq later
; a->tone = (a->tone + a->tone_sliding + w) & 0xfff;
clc
lda note_a+NOTE_TONE_SLIDING_L,X
adc note_a+NOTE_TONE_L,X
sta temp_word_l1_smc+1
lda note_a+NOTE_TONE_H,X
adc note_a+NOTE_TONE_SLIDING_H,X
sta temp_word_h1_smc+1
clc ;;can be removed if ADC SLIDING_H cannot overflow
temp_word_l1_smc:
lda #$d1
adc NoteTable_low,Y ; GetNoteFreq
sta note_a+NOTE_TONE_L,X
temp_word_h1_smc:
lda #$d1
adc NoteTable_high,Y ; GetNoteFreq
and #$0f
sta note_a+NOTE_TONE_H,X
;=====================
; handle tone sliding
lda note_a+NOTE_TONE_SLIDE_COUNT,X
bmi no_tone_sliding ; if (a->tone_slide_count > 0) {
beq no_tone_sliding
dec note_a+NOTE_TONE_SLIDE_COUNT,X ; a->tone_slide_count--;
bne no_tone_sliding ; if (a->tone_slide_count==0) {
; a->tone_sliding+=a->tone_slide_step
clc ;;can be removed if ADC freq_h cannot overflow
lda note_a+NOTE_TONE_SLIDING_L,X
adc note_a+NOTE_TONE_SLIDE_STEP_L,X
sta note_a+NOTE_TONE_SLIDING_L,X
tay ; save NOTE_TONE_SLIDING_L in y
lda note_a+NOTE_TONE_SLIDING_H,X
adc note_a+NOTE_TONE_SLIDE_STEP_H,X
sta note_a+NOTE_TONE_SLIDING_H,X
; a->tone_slide_count = a->tone_slide_delay;
lda note_a+NOTE_TONE_SLIDE_DELAY,X
sta note_a+NOTE_TONE_SLIDE_COUNT,X
lda note_a+NOTE_SIMPLE_GLISS,X
bne no_tone_sliding ; if (!a->simplegliss) {
; FIXME: do these need to be signed compares?
check1:
lda note_a+NOTE_TONE_SLIDE_STEP_H,X
bpl check2 ; if ( ((a->tone_slide_step < 0) &&
; (a->tone_sliding <= a->tone_delta) ||
; 16 bit signed compare
tya ; y has NOTE_TONE_SLIDING_L
cmp note_a+NOTE_TONE_DELTA_L,X ; NUM1-NUM2
lda note_a+NOTE_TONE_SLIDING_H,X
sbc note_a+NOTE_TONE_DELTA_H,X
bvc sc_loser1 ; N eor V
eor #$80
sc_loser1:
bmi slide_to_note ; then A (signed) < NUM (signed) and BMI will branch
; equals case
tya ; y has NOTE_TONE_SLIDING_L
cmp note_a+NOTE_TONE_DELTA_L,X
bne check2
lda note_a+NOTE_TONE_SLIDING_H,X
cmp note_a+NOTE_TONE_DELTA_H,X
beq slide_to_note
check2:
lda note_a+NOTE_TONE_SLIDE_STEP_H,X
bmi no_tone_sliding ; ((a->tone_slide_step >= 0) &&
; (a->tone_sliding >= a->tone_delta)
; 16 bit signed compare
tya ; y has NOTE_TONE_SLIDING_L
cmp note_a+NOTE_TONE_DELTA_L,X ; num1-num2
lda note_a+NOTE_TONE_SLIDING_H,X
sbc note_a+NOTE_TONE_DELTA_H,X
bvc sc_loser2 ; N eor V
eor #$80
sc_loser2:
bmi no_tone_sliding ; then A (signed) < NUM (signed) and BMI will branch
slide_to_note:
; a->note = a->slide_to_note;
lda note_a+NOTE_SLIDE_TO_NOTE,X
sta note_a+NOTE_NOTE,X
lda #0
sta note_a+NOTE_TONE_SLIDE_COUNT,X
sta note_a+NOTE_TONE_SLIDING_L,X
sta note_a+NOTE_TONE_SLIDING_H,X
no_tone_sliding:
;=========================
; Calculate the amplitude
;=========================
calc_amplitude:
; get base value from the sample (bottom 4 bits of sample_b1)
sample_b1_smc:
lda #$d1 ; a->amplitude= (b1 & 0xf);
and #$f
;========================================
; if b0 top bit is set, it means sliding
; adjust amplitude sliding
bit sample_b0_smc+1 ; if ((b0 & 0x80)!=0) {
bpl done_amp_sliding ; so if top bit not set, skip
tay
;================================
; if top bits 0b11 then slide up
; if top bits 0b10 then slide down
; if ((b0 & 0x40)!=0) {
lda note_a+NOTE_AMPLITUDE_SLIDING,X
sec
bvc amp_slide_down
amp_slide_up:
; if (a->amplitude_sliding < 15) {
; a pain to do signed compares
sbc #15
bvc asu_signed
eor #$80
asu_signed:
bpl done_amp_sliding ; skip if A>=15
inc note_a+NOTE_AMPLITUDE_SLIDING,X ; a->amplitude_sliding++;
bne done_amp_sliding_y
amp_slide_down:
; if (a->amplitude_sliding > -15) {
; a pain to do signed compares
sbc #$f1 ; -15
bvc asd_signed
eor #$80
asd_signed:
bmi done_amp_sliding ; if A < -15, skip subtract
dec note_a+NOTE_AMPLITUDE_SLIDING,X ; a->amplitude_sliding--;
done_amp_sliding_y:
tya
done_amp_sliding:
; a->amplitude+=a->amplitude_sliding;
clc
adc note_a+NOTE_AMPLITUDE_SLIDING,X
; clamp amplitude to 0 - 15
check_amp_lo:
bmi write_clamp_amplitude
check_amp_hi:
cmp #16
bcc write_amplitude ; blt
lda #15
.byte $2C
write_clamp_amplitude:
lda #0
write_amplitude:
sta note_amp_smc+1
done_clamp_amplitude:
; We generate the proper table at runtime now
; so always in Volume Table
; a->amplitude = PT3VolumeTable_33_34[a->volume][a->amplitude];
; a->amplitude = PT3VolumeTable_35[a->volume][a->amplitude];
lda note_a+NOTE_VOLUME,X ; 4+
asl ; 2
asl ; 2
asl ; 2
asl ; 2
note_amp_smc:
ora #$d1 ; 4+
tay ; 2
lda VolumeTable,Y ; 4+
sta note_a+NOTE_AMPLITUDE,X ; 5
done_table:
check_envelope_enable:
; Bottom bit of b0 indicates our sample has envelope
; Also make sure envelopes are enabled
; if (((b0 & 0x1) == 0) && ( a->envelope_enabled)) {
sample_b0_smc:
lda #$d1
lsr
tay
bcs envelope_slide
lda note_a+NOTE_ENVELOPE_ENABLED,X
beq envelope_slide
; Bit 4 of the per-channel AY-3-8910 amplitude specifies
; envelope enabled
lda note_a+NOTE_AMPLITUDE,X ; a->amplitude |= 16;
ora #$10
sta note_a+NOTE_AMPLITUDE,X
envelope_slide:
; Envelope slide
; If b1 top bits are 10 or 11
lda sample_b0_smc+1
asl
asl
asl ; b0 bit 5 to carry flag
lda #$20
bit sample_b1_smc+1 ; b1 bit 7 to sign flag, bit 5 to zero flag
php
bpl else_noise_slide ; if ((b1 & 0x80) != 0) {
tya
ora #$f0
bcs envelope_slide_down ; if ((b0 & 0x20) == 0) {
envelope_slide_up:
; j = ((b0>>1)&0xF) + a->envelope_sliding;
and #$0f
clc
envelope_slide_down:
; j = ((b0>>1)|0xF0) + a->envelope_sliding
adc note_a+NOTE_ENVELOPE_SLIDING,X
sta e_slide_amount_smc+1 ; j
envelope_slide_done:
plp
beq last_envelope ; if (( b1 & 0x20) != 0) {
; a->envelope_sliding = j;
sta note_a+NOTE_ENVELOPE_SLIDING,X
last_envelope:
; pt3->envelope_add+=j;
clc
e_slide_amount_smc:
lda #$d1
adc pt3_envelope_add_smc+1
sta pt3_envelope_add_smc+1
jmp noise_slide_done ; skip else
else_noise_slide:
; Noise slide
; else {
; pt3->noise_add = (b0>>1) + a->noise_sliding;
tya
clc
adc note_a+NOTE_NOISE_SLIDING,X
sta pt3_noise_add_smc+1
plp
beq noise_slide_done ; if ((b1 & 0x20) != 0) {
; noise_sliding = pt3_noise_add
sta note_a+NOTE_NOISE_SLIDING,X
noise_slide_done:
;======================
; set mixer
lda sample_b1_smc+1 ; pt3->mixer_value = ((b1 >>1) & 0x48) | pt3->mixer_value;
lsr
and #$48
ora PT3_MIXER_VAL ; 3
sta PT3_MIXER_VAL ; 3
;========================
; increment sample position
inc note_a+NOTE_SAMPLE_POSITION,X ; a->sample_position++;
lda note_a+NOTE_SAMPLE_POSITION,X
cmp note_a+NOTE_SAMPLE_LENGTH,X
bcc sample_pos_ok ; blt
lda note_a+NOTE_SAMPLE_LOOP,X
sta note_a+NOTE_SAMPLE_POSITION,X
sample_pos_ok:
;========================
; increment ornament position
inc note_a+NOTE_ORNAMENT_POSITION,X ; a->ornament_position++;
lda note_a+NOTE_ORNAMENT_POSITION,X
cmp note_a+NOTE_ORNAMENT_LENGTH,X
bcc ornament_pos_ok ; blt
lda note_a+NOTE_ORNAMENT_LOOP,X
sta note_a+NOTE_ORNAMENT_POSITION,X
ornament_pos_ok:
done_note:
; set mixer value
; this is a bit complex (from original code)
; after 3 calls it is set up properly
lsr PT3_MIXER_VAL
handle_onoff:
ldy note_a+NOTE_ONOFF,X ;if (a->onoff>0) {
beq done_onoff
dey ; a->onoff--;
bne put_offon ; if (a->onoff==0) {
lda note_a+NOTE_ENABLED,X
eor #$1 ; toggle note_enabled
sta note_a+NOTE_ENABLED,X
beq do_offon
do_onoff:
ldy note_a+NOTE_ONOFF_DELAY,X ; if (a->enabled) a->onoff=a->onoff_delay;
jmp put_offon
do_offon:
ldy note_a+NOTE_OFFON_DELAY,X ; else a->onoff=a->offon_delay;
put_offon:
.ifdef PT3_USE_ZERO_PAGE
sty note_a+NOTE_ONOFF,X
.else
lda note_a+NOTE_ONOFF,X
tay
.endif
done_onoff:
rts ; 6
;=====================================
; Decode Note
;=====================================
; X points to the note offset
; Note! These timings are out of date (FIXME)
; Timings (from ===>)
; 00: 14+30
; 0X: 14+15
; 10: 14+5 +124
; 1X: 14+5 +193
; 2X/3X: 14+5 +17
; 4X: 14+5+5 + 111
; 5X-BX: 14+5+5+ 102
; CX:
; DX/EX:
; FX:
stop_decoding:
; we are still running, decrement and early return
dec note_a+NOTE_LEN_COUNT,X ; 7
rts ; 6
;=====================================
; Decode Line
;=====================================
pt3_decode_line:
; decode_note(&pt3->a,&(pt3->a_addr),pt3);
ldx #(NOTE_STRUCT_SIZE*0)
jsr decode_note
; decode_note(&pt3->b,&(pt3->b_addr),pt3);
ldx #(NOTE_STRUCT_SIZE*1)
jsr decode_note
; decode_note(&pt3->c,&(pt3->c_addr),pt3);
ldx #(NOTE_STRUCT_SIZE*2)
;;jsr decode_note ; fall through
; if (pt3->a.all_done && pt3->b.all_done && pt3->c.all_done) {
; return 1;
; }
decode_note:
; Init vars
ldy #0 ; 2
sty spec_command_smc+1 ; 4
; Skip decode if note still running
lda note_a+NOTE_LEN_COUNT,X ; 4+
cmp #2 ; 2
bcs stop_decoding ; blt, assume not negative ; 2/3
keep_decoding:
lda note_a+NOTE_NOTE,X ; store prev note ; 4+
sta prev_note_smc+1 ; 4
lda note_a+NOTE_TONE_SLIDING_H,X ; store prev sliding ; 4+
sta prev_sliding_h_smc+1 ; 4
lda note_a+NOTE_TONE_SLIDING_L,X ; 4+
sta prev_sliding_l_smc+1 ; 4
;============
; 24
note_decode_loop:
lda note_a+NOTE_LEN,X ; re-up length count ; 4+
sta note_a+NOTE_LEN_COUNT,X ; 5
lda note_a+NOTE_ADDR_L,X ; 4+
sta PATTERN_L ; 3
lda note_a+NOTE_ADDR_H,X ; 4+
sta PATTERN_H ; 3
;===>
; get next value
lda (PATTERN_L),Y ; 5+
sta note_command_smc+1 ; save termporarily ; 4
and #$0f ; 2
sta note_command_bottom_smc+1 ; 4
note_command_smc:
lda #$d1 ; 2
; FIXME: use a jump table??
; further reflection, that would require 32-bytes of addresses
; in addition to needing X or Y to index the jump table. hmmm
and #$f0 ; 2
; cmp #$00
bne decode_case_1X ; 2/3
;=============
; 14
decode_case_0X:
;==============================
; $0X set special effect
;==============================
; -1
note_command_bottom_smc:
lda #$d1 ; 2
; we can always store spec as 0 means no spec
; FIXME: what if multiple spec commands?
; Doesn't seem to happen in practice
; But AY_emul has code to handle it
sta spec_command_smc+1 ; 4
bne decode_case_0X_not_zero ; 2/3
;=============
; 8
; 00 case
; means end of pattern
; -1
sta note_a+NOTE_LEN_COUNT,X ; len_count=0; ; 5
dec pt3_pattern_done_smc+1 ; 6
jmp note_done_decoding ; 3
decode_case_1X:
;==============================
; $1X -- Set Envelope Type
;==============================
cmp #$10 ; 2
bne decode_case_2X ; 2/3
;============
; 5
; -1
lda note_command_bottom_smc+1 ; 4
bne decode_case_not_10 ; 3
decode_case_10:
; 10 case - disable ; -1
sta note_a+NOTE_ENVELOPE_ENABLED,X ; A is 0 ; 5
beq decode_case_1x_common ; branch always ; 3
decode_case_not_10:
; -1
jsr set_envelope ; 6+64
decode_case_1x_common:
iny ; 2
lda (PATTERN_L),Y ; 5+
lsr ; 2
jsr load_sample ; 6+86
lda #0 ; 2
sta note_a+NOTE_ORNAMENT_POSITION,X ; ornament_position=0 ; 5
decode_case_0X_not_zero:
jmp done_decode_loop ; 3
decode_case_2X:
decode_case_3X:
;==============================
; $2X/$3X set noise period
;==============================
cmp #$40 ; 2
bcs decode_case_4X ; branch greater/equal ; 3
; -1
lda note_command_smc+1 ; 4
adc #$e0 ; same as subtract $20 ; 2
sta pt3_noise_period_smc+1 ; 3
jmp done_decode_loop ; 3
;===========
; 16
decode_case_4X:
;==============================
; $4X -- set ornament
;==============================
; cmp #$40 ; already set ;
bne decode_case_5X ; 3
; -1
lda note_command_bottom_smc+1; set ornament to bottom nibble; 4
jsr load_ornament ; 6+93
jmp done_decode_loop ; 3
;============
; 110
decode_case_5X:
;==============================
; $5X-$AX set note
;==============================
cmp #$B0 ; 2
bcs decode_case_bX ; branch greater/equal ; 3
; -1
lda note_command_smc+1 ; 4
adc #$b0 ; 2
sta note_a+NOTE_NOTE,X ; note=(current_val-0x50); ; 5
jsr reset_note ; 6+69
lda #1 ; 2
sta note_a+NOTE_ENABLED,X ; enabled=1 ; 5
bne note_done_decoding ; 3
decode_case_bX:
;============================================
; $BX -- note length or envelope manipulation
;============================================
; cmp #$b0 ; already set from before
bne decode_case_cX ; 3
; -1
lda note_command_bottom_smc+1 ; 4
beq decode_case_b0 ; 3
; -1
sbc #1 ; envelope_type=(current_val&0xf)-1; ; 2
bne decode_case_bx_higher ; 3
decode_case_b1:
; Set Length
; get next byte
iny ; 2
lda (PATTERN_L),Y ; 5
sta note_a+NOTE_LEN,X ; 5
sta note_a+NOTE_LEN_COUNT,X ; 5
bcs done_decode_loop ; branch always ; 3
decode_case_b0:
; Disable envelope
sta note_a+NOTE_ENVELOPE_ENABLED,X ; 5
sta note_a+NOTE_ORNAMENT_POSITION,X ; 5
beq done_decode_loop ; 3
decode_case_bx_higher:
jsr set_envelope ; 6+64
bcs done_decode_loop ; branch always ; 3
decode_case_cX:
;==============================
; $CX -- set volume
;==============================
cmp #$c0 ; check top nibble $C ; 2
bne decode_case_dX ; 3
; -1
lda note_command_bottom_smc+1 ; 4
bne decode_case_cx_not_c0 ; 3
; -1
decode_case_c0:
; special case $C0 means shut down the note
sta note_a+NOTE_ENABLED,X ; enabled=0 ; 5
jsr reset_note ; 6+69
beq note_done_decoding ; branch always ; 3
decode_case_cx_not_c0:
sta note_a+NOTE_VOLUME,X ; volume=current_val&0xf; 5
bne done_decode_loop ; branch always ; 3
decode_case_dX:
;==============================
; $DX/$EX -- change sample
;==============================
; D0 = special case (end note)
; D1-EF = set sample to (value - $D0)
cmp #$f0 ; check top nibble $D/$E ; 2
beq decode_case_fX ; 3
; -1
lda note_command_smc+1 ; 4
sec ; 2
sbc #$d0 ; 2
beq note_done_decoding ; 3
decode_case_not_d0:
; -1
jsr load_sample ; load sample in bottom nybble ; 6+??
bcc done_decode_loop; branch always ; 3
;========================
; d0 case means end note
;decode_case_d0:
; jmp note_done_decoding
;==============================
; $FX - change ornament/sample
;==============================
decode_case_fX:
; disable envelope
lda #0 ; 2
sta note_a+NOTE_ENVELOPE_ENABLED,X ; 5
; Set ornament to low byte of command
lda note_command_bottom_smc+1 ; 4
jsr load_ornament ; ornament to load in A ; 6+?
; Get next byte
iny ; point to next byte ; 2
lda (PATTERN_L),Y ; 5
; Set sample to value/2
lsr ; divide by two ; 2
jsr load_sample ; sample to load in A ; 6+?
; fallthrough
done_decode_loop:
iny ; point to next byte ; 2
jmp note_decode_loop ; 3
note_done_decoding:
iny ; point to next byte ; 2
;=================================
; handle effects
;=================================
; Note, the AYemul code has code to make sure these are applied
; In the same order they appear. We don't bother?
handle_effects:
spec_command_smc:
lda #$d1 ; 2
;==============================
; Effect #1 -- Tone Down
;==============================
effect_1:
cmp #$1 ; 2
bne effect_2 ; 3
; -1
sta note_a+NOTE_SIMPLE_GLISS,X ; 5
lsr ; 2
sta note_a+NOTE_ONOFF,X ; 5
lda (PATTERN_L),Y ; load byte, set as slide delay ; 5
iny ; 2
sta note_a+NOTE_TONE_SLIDE_DELAY,X ; 5
sta note_a+NOTE_TONE_SLIDE_COUNT,X ; 5
lda (PATTERN_L),Y ; load byte, set as slide step low ; 5
iny ; 2
sta note_a+NOTE_TONE_SLIDE_STEP_L,X ; 5
lda (PATTERN_L),Y ; load byte, set as slide step high ; 5
iny ; 2
sta note_a+NOTE_TONE_SLIDE_STEP_H,X ; 5
jmp no_effect ; 3
;==============================
; Effect #2 -- Portamento
;==============================
effect_2:
cmp #$2 ; 2
beq effect_2_small ; 3
; -1
jmp effect_3 ; 3
effect_2_small: ; FIXME: make smaller
lda #0 ; 2
sta note_a+NOTE_SIMPLE_GLISS,X ; 5
sta note_a+NOTE_ONOFF,X ; 5
lda (PATTERN_L),Y ; load byte, set as delay ; 5
iny ; 2
sta note_a+NOTE_TONE_SLIDE_DELAY,X ; 5
sta note_a+NOTE_TONE_SLIDE_COUNT,X ; 5
iny ; 2
iny ; 2
iny ; 2
lda (PATTERN_L),Y ; load byte, set as slide_step high ; 5
php ; 3
; 16-bit absolute value
bpl slide_step_positive1 ; 3
;-1
eor #$ff ; 2
slide_step_positive1:
sta note_a+NOTE_TONE_SLIDE_STEP_H,X ; 5
dey ; 2
lda (PATTERN_L),Y ; load byte, set as slide_step low ; 5
plp ; 4
clc ; 2
bpl slide_step_positive2 ; 3
;-1
eor #$ff ; 2
sec ; 2
slide_step_positive2:
adc #$0 ; 2
sta note_a+NOTE_TONE_SLIDE_STEP_L,X ; 5
bcc skip_step_inc1 ; 3
inc note_a+NOTE_TONE_SLIDE_STEP_H,X ; 7
skip_step_inc1:
iny ; moved here as it messed with flags ; 2
iny ; 2
; a->tone_delta=GetNoteFreq(a->note,pt3)-
; GetNoteFreq(prev_note,pt3);
sty PT3_TEMP ; save Y
prev_note_smc:
ldy #$d1
lda NoteTable_low,Y ; GetNoteFreq
sta temp_word_l2_smc+1
lda NoteTable_high,Y ; GetNoteFreq
sta temp_word_h2_smc+1
ldy note_a+NOTE_NOTE,X
lda NoteTable_low,Y ; GetNoteFreq
sec
temp_word_l2_smc:
sbc #$d1
sta note_a+NOTE_TONE_DELTA_L,X
lda NoteTable_high,Y ; GetNoteFreq
temp_word_h2_smc:
sbc #$d1
sta note_a+NOTE_TONE_DELTA_H,X
; a->slide_to_note=a->note;
lda note_a+NOTE_NOTE,X
sta note_a+NOTE_SLIDE_TO_NOTE,X
ldy PT3_TEMP ; restore Y
; a->note=prev_note;
lda prev_note_smc+1
sta note_a+NOTE_NOTE,X
; implement file version 6 and above slide behavior
; this is done by SMC at song init time
version_smc:
jmp weird_version ; (JMP to BIT via smc) ; 3
prev_sliding_l_smc:
lda #$d1
sta note_a+NOTE_TONE_SLIDING_L,X
prev_sliding_h_smc:
lda #$d1
sta note_a+NOTE_TONE_SLIDING_H,X
weird_version:
; annoying 16-bit subtract, only care if negative
; if ((a->tone_delta - a->tone_sliding) < 0) {
sec
lda note_a+NOTE_TONE_DELTA_L,X
sbc note_a+NOTE_TONE_SLIDING_L,X
lda note_a+NOTE_TONE_DELTA_H,X
sbc note_a+NOTE_TONE_SLIDING_H,X
bpl no_effect
; a->tone_slide_step = -a->tone_slide_step;
lda note_a+NOTE_TONE_SLIDE_STEP_L,X
eor #$ff
clc
adc #$1
sta note_a+NOTE_TONE_SLIDE_STEP_L,X
lda note_a+NOTE_TONE_SLIDE_STEP_H,X
eor #$ff
adc #$0
sta note_a+NOTE_TONE_SLIDE_STEP_H,X
jmp no_effect
;==============================
; Effect #3 -- Sample Position
;==============================
effect_3:
cmp #$3
bne effect_4
lda (PATTERN_L),Y ; load byte, set as sample position
iny
sta note_a+NOTE_SAMPLE_POSITION,X
bne no_effect ; branch always
;==============================
; Effect #4 -- Ornament Position
;==============================
effect_4:
cmp #$4
bne effect_5
lda (PATTERN_L),Y ; load byte, set as ornament position
iny
sta note_a+NOTE_ORNAMENT_POSITION,X
bne no_effect ; branch always
;==============================
; Effect #5 -- Vibrato
;==============================
effect_5:
cmp #$5
bne effect_8
lda (PATTERN_L),Y ; load byte, set as onoff delay
iny
sta note_a+NOTE_ONOFF_DELAY,X
sta note_a+NOTE_ONOFF,X
lda (PATTERN_L),Y ; load byte, set as offon delay
iny
sta note_a+NOTE_OFFON_DELAY,X
lda #0
sta note_a+NOTE_TONE_SLIDE_COUNT,X
sta note_a+NOTE_TONE_SLIDING_L,X
sta note_a+NOTE_TONE_SLIDING_H,X
beq no_effect ; branch always
;==============================
; Effect #8 -- Envelope Down
;==============================
effect_8:
cmp #$8
bne effect_9
; delay
lda (PATTERN_L),Y ; load byte, set as speed
iny
sta pt3_envelope_delay_smc+1
sta pt3_envelope_delay_orig_smc+1
; low value
lda (PATTERN_L),Y ; load byte, set as low
iny
sta pt3_envelope_slide_add_l_smc+1
; high value
lda (PATTERN_L),Y ; load byte, set as high
iny
sta pt3_envelope_slide_add_h_smc+1
bne no_effect ; branch always
;==============================
; Effect #9 -- Set Speed
;==============================
effect_9:
cmp #$9
bne no_effect
lda (PATTERN_L),Y ; load byte, set as speed
iny
sta pt3_speed_smc+1
no_effect:
;================================
; add y into the address pointer
clc
tya
adc note_a+NOTE_ADDR_L,X
sta note_a+NOTE_ADDR_L,X
lda #0
adc note_a+NOTE_ADDR_H,X
sta note_a+NOTE_ADDR_H,X
sta PATTERN_H
rts
;=======================================
; Set Envelope
;=======================================
; pulls out common code from $1X and $BX
; commands
; A = new envelope type
set_envelope:
sta pt3_envelope_type_smc+1 ; 4
; give fake old to force update? maybe only needed if printing?
; pt3->envelope_type_old=0x78;
lda #$78 ; 2
sta pt3_envelope_type_old_smc+1 ; 4
; get next byte
iny ; 2
lda (PATTERN_L),Y ; 5+
sta pt3_envelope_period_h_smc+1 ; 4
iny ; 2
lda (PATTERN_L),Y ; 5+
sta pt3_envelope_period_l_smc+1 ; 4
lda #1 ; 2
sta note_a+NOTE_ENVELOPE_ENABLED,X ; envelope_enabled=1 ; 5
lsr ; 2
sta note_a+NOTE_ORNAMENT_POSITION,X ; ornament_position=0 ; 5
sta pt3_envelope_delay_smc+1 ; envelope_delay=0 ; 4
sta pt3_envelope_slide_l_smc+1 ; envelope_slide=0 ; 4
sta pt3_envelope_slide_h_smc+1 ; 4
rts ; 6
;===========
; 64
;========================
; reset note
;========================
; common code from the decode note code
reset_note:
lda #0 ; 2
sta note_a+NOTE_SAMPLE_POSITION,X ; sample_position=0 ; 5
sta note_a+NOTE_AMPLITUDE_SLIDING,X ; amplitude_sliding=0 ; 5
sta note_a+NOTE_NOISE_SLIDING,X ; noise_sliding=0 ; 5
sta note_a+NOTE_ENVELOPE_SLIDING,X ; envelope_sliding=0 ; 5
sta note_a+NOTE_ORNAMENT_POSITION,X ; ornament_position=0 ; 5
sta note_a+NOTE_TONE_SLIDE_COUNT,X ; tone_slide_count=0 ; 5
sta note_a+NOTE_TONE_SLIDING_L,X ; tone_sliding=0 ; 5
sta note_a+NOTE_TONE_SLIDING_H,X ; 5
sta note_a+NOTE_TONE_ACCUMULATOR_L,X ; tone_accumulator=0 ; 5
sta note_a+NOTE_TONE_ACCUMULATOR_H,X ; 5
sta note_a+NOTE_ONOFF,X ; onoff=0; ; 5
rts ; 6
;============
; 69
;=====================================
; Set Pattern
;=====================================
; FIXME: inline this? we do call it from outside
; in the player note length code
is_done:
; done with song, set it to non-zero
sta DONE_SONG ; 3
rts ; 6
pt3_set_pattern:
; Lookup current pattern in pattern table
current_pattern_smc:
ldy #$d1 ; 2
lda PT3_LOC+PT3_PATTERN_TABLE,Y ; 4+
; if value is $FF we are at the end of the song
cmp #$ff ; 2
beq is_done ; 2/3
;============
; 20 if end
not_done:
; set up the three pattern address pointers
; BUG BUG BUG
; pattern offset can be bigger than 128, and if we multiply
; by two to get word size it will overflow
; for example I have a .pt3 where pattern #48 ($30*3=$90) is used
; asl ; mul pattern offset by two, as word sized ; 2
; tay ; 2
; point PATTERN_H/PATTERN_L to the pattern address table
; clc ; 2
; lda PT3_LOC+PT3_PATTERN_LOC_L ; 4
; sta PATTERN_L ; 3
; lda PT3_LOC+PT3_PATTERN_LOC_H ; 4
; adc #>PT3_LOC ; assume page boundary ; 2
; sta PATTERN_H ; 3
clc
sta PATTERN_L
adc PT3_LOC+PT3_PATTERN_LOC_L
php ; save carry as we might generate two
clc
adc PATTERN_L
sta PATTERN_L
lda PT3_LOC+PT3_PATTERN_LOC_H ; 4
adc #>PT3_LOC ; assume page boundary ; 2
plp ; restore carry
adc #0
sta PATTERN_H ; 3
; clc
; tya
; adc PATTERN_L
; adc PATTERN_L
; sta PATTERN_L
; lda #0
; adc PATTERN_H
; sta PATTERN_H
ldy #0
; First 16-bits points to the Channel A address
lda (PATTERN_L),Y ; 5+
sta note_a+NOTE_ADDR_L ; 4
iny ; 2
lda (PATTERN_L),Y ; 5+
adc #>PT3_LOC ; assume page boundary ; 2
sta note_a+NOTE_ADDR_H ; 4
iny ; 2
; Next 16-bits points to the Channel B address
lda (PATTERN_L),Y ; 5+
sta note_b+NOTE_ADDR_L ; 4
iny ; 2
lda (PATTERN_L),Y ; 5+
adc #>PT3_LOC ; assume page boundary ; 2
sta note_b+NOTE_ADDR_H ; 4
iny ; 2
; Next 16-bits points to the Channel C address
lda (PATTERN_L),Y ; 5+
sta note_c+NOTE_ADDR_L ; 4
iny ; 2
lda (PATTERN_L),Y ; 5+
adc #>PT3_LOC ; assume page boundary ; 2
sta note_c+NOTE_ADDR_H ; 4
; clear out the noise channel
lda #0 ; 2
sta pt3_noise_period_smc+1 ; 4
; Set all three channels as active
; FIXME: num_channels, may need to be 6 if doing 6-channel pt3?
lda #3 ; 2
sta pt3_pattern_done_smc+1 ; 4
rts ; 6
;=====================================
; pt3 make frame
;=====================================
; update pattern or line if necessary
; then calculate the values for the next frame
;==========================
; pattern done early!
early_end:
inc current_pattern_smc+1 ; increment pattern ; 6
sta current_line_smc+1 ; 4
sta current_subframe_smc+1 ; 4
check_subframe:
lda current_subframe_smc+1 ; 4
bne pattern_good ; 2/3
; load a new pattern in
jsr pt3_set_pattern ;6+?
lda DONE_SONG ; 3
beq pattern_good ; 2/3
rts ; 6
pt3_make_frame:
; see if we need a new pattern
; we do if line==0 and subframe==0
; allow fallthrough where possible
current_line_smc:
lda #$d1 ; 2
beq check_subframe ; 2/3
pattern_good:
; see if we need a new line
current_subframe_smc:
lda #$d1 ; 2
bne line_good ; 2/3
; decode a new line
jsr pt3_decode_line ; 6+?
; check if pattern done early
pt3_pattern_done_smc:
lda #$d1 ; 2
beq early_end ; 2/3
line_good:
; Increment everything
inc current_subframe_smc+1 ; subframe++ ; 6
lda current_subframe_smc+1 ; 4
; if we hit pt3_speed, move to next
pt3_speed_smc:
eor #$d1 ; 2
bne do_frame ; 2/3
next_line:
sta current_subframe_smc+1 ; reset subframe to 0 ; 4
inc current_line_smc+1 ; and increment line ; 6
lda current_line_smc+1 ; 4
eor #64 ; always end at 64. ; 2
bne do_frame ; is this always needed? ; 2/3
next_pattern:
sta current_line_smc+1 ; reset line to 0 ; 4
inc current_pattern_smc+1 ; increment pattern ; 6
do_frame:
; AY-3-8910 register summary
;
; R0/R1 = A period low/high
; R2/R3 = B period low/high
; R4/R5 = C period low/high
; R6 = Noise period
; R7 = Enable XX Noise=!CBA Tone=!CBA
; R8/R9/R10 = Channel A/B/C amplitude M3210, M=envelope enable
; R11/R12 = Envelope Period low/high
; R13 = Envelope Shape, 0xff means don't write
; R14/R15 = I/O (ignored)
ldx #0 ; needed ; 2
stx PT3_MIXER_VAL ; 3
stx pt3_envelope_add_smc+1 ; 4
;;ldx #(NOTE_STRUCT_SIZE*0) ; Note A ; 2
jsr calculate_note ; 6+?
ldx #(NOTE_STRUCT_SIZE*1) ; Note B ; 2
jsr calculate_note ; 6+?
ldx #(NOTE_STRUCT_SIZE*2) ; Note C ; 2
jsr calculate_note ; 6+?
convert_177_smc1:
sec ; 2
; Load up the Frequency Registers
lda note_a+NOTE_TONE_L ; Note A Period L ; 4
sta AY_REGISTERS+0 ; into R0 ; 3
lda note_a+NOTE_TONE_H ; Note A Period H ; 4
sta AY_REGISTERS+1 ; into R1 ; 3
lda note_a+NOTE_TONE_L ; Note A Period L ; 4
bcc no_scale_a ; 2/3
; Convert from 1.77MHz to 1MHz by multiplying by 9/16
; conversion costs 100 cycles!
; first multiply by 8
asl ; 2
rol AY_REGISTERS+1 ; 5
asl ; 2
rol AY_REGISTERS+1 ; 5
asl ; 2
rol AY_REGISTERS+1 ; 5
; add in original to get 9
clc ; 2
adc note_a+NOTE_TONE_L ; 4
sta AY_REGISTERS+0 ; 3
lda note_a+NOTE_TONE_H ; 4
adc AY_REGISTERS+1 ; 3
; divide by 16 to get proper value
ror ; 2
ror AY_REGISTERS+0 ; 5
ror ; 2
ror AY_REGISTERS+0 ; 5
ror ; 2
ror AY_REGISTERS+0 ; 5
ror ; 2
ror AY_REGISTERS+0 ; 5
and #$0f ; 2
sta AY_REGISTERS+1 ; 3
no_scale_a:
convert_177_smc2:
sec ; 2
lda note_b+NOTE_TONE_L ; Note B Period L ; 4
sta AY_REGISTERS+2 ; into R2 ; 3
lda note_b+NOTE_TONE_H ; Note B Period H ; 4
sta AY_REGISTERS+3 ; into R3 ; 3
lda note_b+NOTE_TONE_L ; Note B Period L ; 4
bcc no_scale_b ; 2/3
; Convert from 1.77MHz to 1MHz by multiplying by 9/16
; first multiply by 8
asl ; 2
rol AY_REGISTERS+3 ; 5
asl ; 2
rol AY_REGISTERS+3 ; 5
asl ; 2
rol AY_REGISTERS+3 ; 5
; add in original to get 9
clc ; 2
adc note_b+NOTE_TONE_L ; 4
sta AY_REGISTERS+2 ; 3
lda note_b+NOTE_TONE_H ; 4
adc AY_REGISTERS+3 ; 3
; divide by 16 to get proper value
ror ; 2
ror AY_REGISTERS+2 ; 5
ror ; 2
ror AY_REGISTERS+2 ; 5
ror ; 2
ror AY_REGISTERS+2 ; 5
ror ; 2
ror AY_REGISTERS+2 ; 5
and #$0f ; 2
sta AY_REGISTERS+3 ; 3
no_scale_b:
convert_177_smc3:
sec ; 2
lda note_c+NOTE_TONE_L ; Note C Period L ; 4
sta AY_REGISTERS+4 ; into R4 ; 3
lda note_c+NOTE_TONE_H ; Note C Period H ; 4
sta AY_REGISTERS+5 ; into R5 ; 3
lda note_c+NOTE_TONE_L ; Note C Period L ; 4
bcc no_scale_c ; 2/3
; Convert from 1.77MHz to 1MHz by multiplying by 9/16
; first multiply by 8
asl ; 2
rol AY_REGISTERS+5 ; 5
asl ; 2
rol AY_REGISTERS+5 ; 5
asl ; 2
rol AY_REGISTERS+5 ; 5
; add in original to get 9
clc ; 2
adc note_c+NOTE_TONE_L ; 4
sta AY_REGISTERS+4 ; 3
lda note_c+NOTE_TONE_H ; 4
adc AY_REGISTERS+5 ; 3
; divide by 16 to get proper value
ror ; 2
ror AY_REGISTERS+4 ; 5
ror ; 2
ror AY_REGISTERS+4 ; 5
ror ; 2
ror AY_REGISTERS+4 ; 5
ror ; 2
ror AY_REGISTERS+4 ; 5
and #$0f ; 2
sta AY_REGISTERS+5 ; 3
no_scale_c:
; Noise
; frame[6]= (pt3->noise_period+pt3->noise_add)&0x1f;
clc ; 2
pt3_noise_period_smc:
lda #$d1 ; 2
pt3_noise_add_smc:
adc #$d1 ; 2
and #$1f ; 2
sta AY_REGISTERS+6 ; 3
convert_177_smc4:
sec ; 2
bcc no_scale_n ; 2/3
; Convert from 1.77MHz to 1MHz by multiplying by 9/16
; first multiply by 8
asl ; 2
asl ; 2
asl ; 2
; add in original to get 9
adc AY_REGISTERS+6 ; 3
; divide by 16 to get proper value
ror ; 2
ror ; 2
ror ; 2
ror ; 2
and #$1f ; 2
no_scale_n:
sta AY_REGISTERS+6 ; 3
;=======================
; Mixer
; PT3_MIXER_VAL is already in AY_REGISTERS+7
;=======================
; Amplitudes
lda note_a+NOTE_AMPLITUDE ; 3
sta AY_REGISTERS+8 ; 3
lda note_b+NOTE_AMPLITUDE ; 3
sta AY_REGISTERS+9 ; 3
lda note_c+NOTE_AMPLITUDE ; 3
sta AY_REGISTERS+10 ; 3
;======================================
; Envelope period
; result=period+add+slide (16-bits)
clc ; 2
pt3_envelope_period_l_smc:
lda #$d1 ; 2
pt3_envelope_add_smc:
adc #$d1 ; 2
tay ; 2
pt3_envelope_period_h_smc:
lda #$d1 ; 2
adc #0 ; 2
tax ; 2
clc ; 2
tya ; 2
pt3_envelope_slide_l_smc:
adc #$d1 ; 2
sta AY_REGISTERS+11 ; 3
txa ; 2
pt3_envelope_slide_h_smc:
adc #$d1 ; 2
sta AY_REGISTERS+12 ; 3
convert_177_smc5:
sec
bcc no_scale_e ; 2/3
; Convert from 1.77MHz to 1MHz by multiplying by 9/16
tay ; 2
; first multiply by 8
lda AY_REGISTERS+11 ; 3
asl ; 2
rol AY_REGISTERS+12 ; 5
asl ; 2
rol AY_REGISTERS+12 ; 5
asl ; 2
rol AY_REGISTERS+12 ; 5
; add in original to get 9
clc ; 2
adc AY_REGISTERS+11 ; 3
sta AY_REGISTERS+11 ; 3
tya ; 2
adc AY_REGISTERS+12 ; 3
; divide by 16 to get proper value
ror ; 2
ror AY_REGISTERS+11 ; 5
ror ; 2
ror AY_REGISTERS+11 ; 5
ror ; 2
ror AY_REGISTERS+11 ; 5
ror ; 2
ror AY_REGISTERS+11 ; 5
and #$0f ; 2
sta AY_REGISTERS+12 ; 3
no_scale_e:
;========================
; Envelope shape
pt3_envelope_type_smc:
lda #$d1 ; 2
pt3_envelope_type_old_smc:
cmp #$d1 ; 2
sta pt3_envelope_type_old_smc+1; copy old to new ; 4
bne envelope_diff ; 2/3
envelope_same:
lda #$ff ; if same, store $ff ; 2
envelope_diff:
sta AY_REGISTERS+13 ; 3
;==============================
; end-of-frame envelope update
;==============================
pt3_envelope_delay_smc:
lda #$d1 ; 2
beq done_do_frame ; assume can't be negative? ; 2/3
; do this if envelope_delay>0
dec pt3_envelope_delay_smc+1 ; 6
bne done_do_frame ; 2/3
; only do if we hit 0
pt3_envelope_delay_orig_smc:
lda #$d1 ; reset envelope delay ; 2
sta pt3_envelope_delay_smc+1 ; 4
clc ; 16-bit add ; 2
lda pt3_envelope_slide_l_smc+1 ; 4
pt3_envelope_slide_add_l_smc:
adc #$d1 ; 2
sta pt3_envelope_slide_l_smc+1 ; 4
lda pt3_envelope_slide_h_smc+1 ; 4
pt3_envelope_slide_add_h_smc:
adc #$d1 ; 2
sta pt3_envelope_slide_h_smc+1 ; 4
done_do_frame:
rts ; 6
; note, you might have slightly better performance if these are aligned
; so that loads don't have to cross page boundaries
NoteTable_high:
.res 96,0
NoteTable_low:
.res 96,0
VolumeTable:
.res 256,0
pt3_lib_end: