Snoopy Concert/ROM map

The following article is a ROM map for Snoopy Concert.

Bank $00

$C0/0000 Boot Sequence

$C0/0000 E2 20       SEP #$20       ; A = 8 bit
$C0/0002 C2 10       REP #$10       ; X/Y = 16 bit
$C0/0004 A9 01       LDA #$01       ; Activate FastROM
$C0/0006 8D 0D 42    STA $420D
$C0/0009 A9 80       LDA #$80       ; FBLANK
$C0/000B 8D 00 21    STA $2100
$C0/000E 9C 00 42    STZ $4200      ; Deactivate NMI/HIRQ/VIRQ/Auto Joypad Read
$C0/0011 9C 0C 42    STZ $420C      ; Deactivate HDMAs
$C0/0014 9C 0B 42    STZ $420B      ; Deactivate DMAs
$C0/0017 9C 40 21    STZ $2140      ; Clear APU Communication Registers
$C0/001A 9C 41 21    STZ $2141
$C0/001D 9C 42 21    STZ $2142
$C0/0020 9C 43 21    STZ $2143
$C0/0023 A2 FF 1F    LDX #$1FFF     ; Stack starts at $1FFF
$C0/0026 9A          TXS
$C0/0027 C2 20       REP #$20       ; Set Direct Page to $0000
$C0/0029 A9 00 00    LDA #$0000
$C0/002C 48          PHA
$C0/002D 2B          PLD
$C0/002E E2 20       SEP #$20
$C0/0030 A9 82       LDA #$82       ; Set Direct Bank to $82
$C0/0032 48          PHA
$C0/0033 AB          PLB
$C0/0034 E2 20       SEP #$20       ; Probably unnecessary line
$C0/0036 A2 00 E0    LDX #$E000              A:0082 X:1FFF Y:0000 P:eNvMxdIzC
$C0/0039 A0 00 00    LDY #$0000              A:0082 X:E000 Y:0000 P:eNvMxdIzC
$C0/003C A9 C0       LDA #$C0                A:0082 X:E000 Y:0000 P:envMxdIZC
$C0/003E 85 11       STA $11    [$00:0011]   A:00C0 X:E000 Y:0000 P:eNvMxdIzC
$C0/0040 C2 20       REP #$20                A:00C0 X:E000 Y:0000 P:eNvMxdIzC
$C0/0042 A9 73 00    LDA #$0073              A:00C0 X:E000 Y:0000 P:eNvmxdIzC
$C0/0045 85 0F       STA $0F    [$00:000F]   A:0073 X:E000 Y:0000 P:envmxdIzC
$C0/0047 64 12       STZ $12    [$00:0012]   A:0073 X:E000 Y:0000 P:envmxdIzC
$C0/0049 B7 0F       LDA [$0F],y[$C0:0073]   A:0073 X:E000 Y:0000 P:envmxdIzC
$C0/004B DF 00 00 7E CMP $7E0000,x[$7E:E000] A:6948 X:E000 Y:0000 P:envmxdIzC
$C0/004F 9F 00 00 7E STA $7E0000,x[$7E:E000] A:6948 X:E000 Y:0000 P:envmxdIzC
$C0/0053 F0 05       BEQ $05    [$005A]      A:6948 X:E000 Y:0000 P:envmxdIzC
$C0/0055 A9 01 00    LDA #$0001              A:6948 X:E000 Y:0000 P:envmxdIzC
$C0/0058 85 12       STA $12    [$00:0012]   A:0001 X:E000 Y:0000 P:envmxdIzC
$C0/005A C8          INY                     A:0001 X:E000 Y:0000 P:envmxdIzC
$C0/005B C8          INY                     A:0001 X:E000 Y:0001 P:envmxdIzC
$C0/005C 98          TYA                     A:0001 X:E000 Y:0002 P:envmxdIzC
$C0/005D 29 0F 00    AND #$000F              A:0002 X:E000 Y:0002 P:envmxdIzC
$C0/0060 A8          TAY                     A:0002 X:E000 Y:0002 P:envmxdIzC
$C0/0061 E8          INX                     A:0002 X:E000 Y:0002 P:envmxdIzC
$C0/0062 E8          INX                     A:0002 X:E001 Y:0002 P:eNvmxdIzC
$C0/0063 D0 E4       BNE $E4    [$0049]      A:0002 X:E002 Y:0002 P:eNvmxdIzC
$C0/0065 A9 34 12    LDA #$1234              A:0000 X:0000 Y:0000 P:envmxdIZc
$C0/0068 CD 04 01    CMP $0104  [$82:0104]   A:1234 X:0000 Y:0000 P:envmxdIzc
$C0/006B D0 16       BNE $16    [$0083]      A:1234 X:0000 Y:0000 P:eNvmxdIzc

$C0/0083 C2 20       REP #$20                A:1234 X:0000 Y:0000 P:eNvmxdIzc
$C0/0085 A9 00 00    LDA #$0000     ; Clear Loop for $7E/0000 to $7E/DFFF
$C0/0088 AA          TAX
$C0/0089 9F 00 00 7E STA $7E0000,x
$C0/008D E8          INX
$C0/008E E8          INX
$C0/008F E0 00 E0    CPX #$E000
$C0/0092 D0 F5       BNE $F5        ; [$0089]
$C0/0094 AA          TAX            ; Clear Loop for whole Bank $7F
$C0/0095 9F 00 00 7F STA $7F0000,x
$C0/0099 E8          INX
$C0/009A E8          INX
$C0/009B D0 F8       BNE $F8        ; [$0095]
$C0/009D 20 DE 01    JSR $01DE  [$C0:01DE]   A:0000 X:0000 Y:0000 P:envmxdIZC
$C0/00A0 E2 20       SEP #$20                A:05E5 X:0000 Y:0003 P:envMXdIZC
$C0/00A2 9C 06 01    STZ $0106  [$82:0106]   A:05E5 X:0000 Y:0003 P:envMXdIZC
$C0/00A5 9C 07 01    STZ $0107  [$82:0107]   A:05E5 X:0000 Y:0003 P:envMXdIZC
$C0/00A8 C2 20       REP #$20                A:05E5 X:0000 Y:0003 P:envMXdIZC
$C0/00AA AD 04 01    LDA $0104  [$82:0104]   A:05E5 X:0000 Y:0003 P:envmXdIZC
$C0/00AD C9 34 12    CMP #$1234              A:0000 X:0000 Y:0003 P:envmXdIZC
$C0/00B0 D0 07       BNE $07    [$00B9]      A:0000 X:0000 Y:0003 P:eNvmXdIzc
$C0/00B9 C2 20       REP #$20                A:0000 X:0000 Y:0003 P:eNvmXdIzc
$C0/00BB A9 34 12    LDA #$1234              A:0000 X:0000 Y:0003 P:eNvmXdIzc
$C0/00BE 8D 04 01    STA $0104  [$82:0104]   A:1234 X:0000 Y:0003 P:envmXdIzc
$C0/00C1 20 E9 00    JSR $00E9      ; Graphic Settings
$C0/00C4 E2 20       SEP #$20                A:1234 X:0000 Y:0003 P:envmXdIzc
$C0/00C6 A9 58       LDA #$58                A:1234 X:0000 Y:0003 P:envMXdIzc
$C0/00C8 8D 0B 01    STA $010B  [$82:010B]   A:1258 X:0000 Y:0003 P:envMXdIzc
$C0/00CB A9 02       LDA #$02                A:1258 X:0000 Y:0003 P:envMXdIzc
$C0/00CD 8D 0C 01    STA $010C  [$82:010C]   A:1202 X:0000 Y:0003 P:envMXdIzc
$C0/00D0 A9 C0       LDA #$C0                A:1202 X:0000 Y:0003 P:envMXdIzc
$C0/00D2 8D 0D 01    STA $010D  [$82:010D]   A:12C0 X:0000 Y:0003 P:eNvMXdIzc
$C0/00D5 20 22 09    JSR $0922  [$C0:0922]   A:12C0 X:0000 Y:0003 P:eNvMXdIzc
$C0/00D8 AD 08 01    LDA $0108      ; Deactivate NMI
$C0/00DB 29 CF       AND #$CF
$C0/00DD 8D 00 42    STA $4200
$C0/00E0 8D 08 01    STA $0108
$C0/00E3 58          CLI            ; Enable interrupts
$C0/00E4 20 0D 0D    JSR $0D0D  [$C0:0D0D]   A:1201 X:0000 Y:0003 P:envMXdizc

$C0/00E9 Graphic Settings

This subroutine sets a lot of screen settings. For more detail, see comments at $C0/00F4

$C0/00E9 22 C5 07 C0 JSL $C007C5    ; Set values of a number of registers

   Arguments:
   $C0/00ED C0 F4 00 00 4E 00       ; Transfer #$4E data sets from $C0/00F4

$C0/00F3 60          RTS

$C0/00F4 Data for $C0/00E9

A whole lot of graphic settings, see $C0/00E9

   $C0/00F4 00 42 01                ; Data Set #$01: Activate Auto Joypad Read, Deactivate NMI/HIRQ/VIRQ
   $C0/00F7 08 01 01                ; Data Set #$02: Update $4200 buffer, too
   $C0/00FA 16 40 00                ; Data Set #$03: Clear Joypad Input Register
   $C0/00FD 17 40 00                ; Data Set #$04: Clear Joypad Input Register
   $C0/0100 01 42 FF                ; Data Set #$05: VBLANK Flag register... read only!? Unnecessary line?
   $C0/0103 02 42 00                ; Data Set #$06: Unused CPU Port? Unnecessary line?
   $C0/0106 03 42 00                ; Data Set #$07: Unused CPU Port? Unnecessary line?
   $C0/0109 04 42 00                ; Data Set #$08: Unused CPU Port? Unnecessary line?
   $C0/010C 05 42 00                ; Data Set #$09: Unused CPU Port? Unnecessary line?
   $C0/010F 06 42 00                ; Data Set #$0A: Unused CPU Port? Unnecessary line?
   $C0/0112 07 42 00                ; Data Set #$0B: Unused CPU Port? Unnecessary line?
   $C0/0115 08 42 00                ; Data Set #$0C: Unused CPU Port? Unnecessary line?
   $C0/0118 09 42 00                ; Data Set #$0D: Unused CPU Port? Unnecessary line?
   $C0/011B 0A 42 00                ; Data Set #$0E: Unused CPU Port? Unnecessary line?
   $C0/011E 0B 42 00                ; Data Set #$0F: Unused CPU Port? Unnecessary line?
   $C0/0121 0C 42 00                ; Data Set #$10: Unused CPU Port? Unnecessary line?
   $C0/0124 00 21 80                ; Data Set #$11: FBLANK
   $C0/0127 09 01 80                ; Data Set #$12: Update $2100 buffer, too
   $C0/012A 02 21 00                ; Data Set #$13: OAM Address $8000
   $C0/012D 03 21 80                ; Data Set #$14: OAM Address $8000
   $C0/0130 04 21 00                ; Data Set #$15: Write #$0000 to OAM
   $C0/0133 04 21 00                ; Data Set #$16: Write #$0000 to OAM
   $C0/0136 0D 21 00                ; Data Set #$17: BG1 H-Scroll = #$0000
   $C0/0139 0D 21 00                ; Data Set #$18: BG1 H-Scroll = #$0000
   $C0/013C 0E 21 00                ; Data Set #$19: BG1 V-Scroll = #$0000
   $C0/013F 0E 21 00                ; Data Set #$1A: BG1 V-Scroll = #$0000
   $C0/0142 0F 21 00                ; Data Set #$1B: BG2 H-Scroll = #$0000
   $C0/0145 0F 21 00                ; Data Set #$1C: BG2 H-Scroll = #$0000
   $C0/0148 10 21 00                ; Data Set #$1D: BG2 V-Scroll = #$0000
   $C0/014B 10 21 00                ; Data Set #$1E: BG2 V-Scroll = #$0000
   $C0/014E 11 21 00                ; Data Set #$1F: BG3 H-Scroll = #$0000
   $C0/0151 11 21 00                ; Data Set #$20: BG3 H-Scroll = #$0000
   $C0/0154 12 21 00                ; Data Set #$21: BG3 V-Scroll = #$0000
   $C0/0157 12 21 00                ; Data Set #$22: BG3 V-Scroll = #$0000
   $C0/015A 13 21 00                ; Data Set #$23: BG4 H-Scroll = #$0000
   $C0/015D 13 21 00                ; Data Set #$24: BG4 H-Scroll = #$0000
   $C0/0160 14 21 00                ; Data Set #$25: BG4 V-Scroll = #$0000
   $C0/0163 14 21 00                ; Data Set #$26: BG4 V-Scroll = #$0000
   $C0/0166 15 21 00                ; Data Set #$27: VRAM Settings
   $C0/0169 16 21 00                ; Data Set #$28: VRAM Address Low Byte
   $C0/016C 17 21 00                ; Data Set #$29: VRAM Address High Byte
   $C0/016F 18 21 00                ; Data Set #$2A: Write $0000 to VRAM
   $C0/0172 19 21 00                ; Data Set #$2B: Write $0000 to VRAM
   $C0/0175 1A 21 00                ; Data Set #$2C: Mode 7 - Clear Rotation Scaling Settings
   $C0/0178 1B 21 00                ; Data Set #$2D: Mode 7 - Rotation/Scaling Parameter A
   $C0/017B 1B 21 01                ; Data Set #$2E: Mode 7 - Rotation/Scaling Parameter A
   $C0/017E 1C 21 00                ; Data Set #$2F: Mode 7 - Rotation/Scaling Parameter B
   $C0/0181 1C 21 00                ; Data Set #$30: Mode 7 - Rotation/Scaling Parameter B
   $C0/0184 1D 21 00                ; Data Set #$31: Mode 7 - Rotation/Scaling Parameter C
   $C0/0187 1D 21 00                ; Data Set #$32: Mode 7 - Rotation/Scaling Parameter C
   $C0/018A 1E 21 00                ; Data Set #$33: Mode 7 - Rotation/Scaling Parameter D
   $C0/018D 1E 21 01                ; Data Set #$34: Mode 7 - Rotation/Scaling Parameter D
   $C0/0190 1F 21 00                ; Data Set #$35: Mode 7 - Rotation/Scaling Center Coordinate X
   $C0/0193 1F 21 00                ; Data Set #$36: Mode 7 - Rotation/Scaling Center Coordinate X
   $C0/0196 20 21 00                ; Data Set #$37: Mode 7 - Rotation/Scaling Center Coordinate Y
   $C0/0199 20 21 00                ; Data Set #$38: Mode 7 - Rotation/Scaling Center Coordinate Y
   $C0/019C 21 21 00                ; Data Set #$39: CGRAM Address: #$00
   $C0/019F 22 21 00                ; Data Set #$3A: Write #$0000 to CGRAM (Pitchblack)
   $C0/01A2 22 21 00                ; Data Set #$3B: Write #$0000 to CGRAM (Pitchblack)
   $C0/01A5 23 21 00                ; Data Set #$3C: Window BG1/BG2 Mask Settings
   $C0/01A8 24 21 00                ; Data Set #$3D: Window BG3/BG4 Mask Settings
   $C0/01AB 25 21 00                ; Data Set #$3E: Window OBJ/MATH Mask Settings
   $C0/01AE 26 21 00                ; Data Set #$3F: Window 1 Left Position (X1)
   $C0/01B1 27 21 FF                ; Data Set #$40: Window 1 Right Position (X2)
   $C0/01B4 28 21 00                ; Data Set #$41: Window 2 Left Position (X1)
   $C0/01B7 29 21 FF                ; Data Set #$42: Window 2 Right Position (X2)
   $C0/01BA 2A 21 00                ; Data Set #$43: Window 1/2 Mask Logic (BG1-BG4)
   $C0/01BD 2B 21 00                ; Data Set #$44: Window 1/2 Mask Logic (OBJ/MATH)
   $C0/01C0 2C 21 00                ; Data Set #$45: Main Screen Designation
   $C0/01C3 2D 21 00                ; Data Set #$46: Main Screen Designation
   $C0/01C6 2E 21 00                ; Data Set #$47: Window Area Main Screen Disable
   $C0/01C9 2F 21 00                ; Data Set #$48: Window Area Sub Screen Disable
   $C0/01CC 30 21 00                ; Data Set #$49: Color Math Control Register A
   $C0/01CF 31 21 00                ; Data Set #$4A: Color Math Control Register B
   $C0/01D2 32 21 00                ; Data Set #$4B: Color Math Sub Screen Backdrop Color
   $C0/01D5 33 21 00                ; Data Set #$4C: Display Control 2
   $C0/01D8 06 21 00                ; Data Set #$4D: Mosaic
   $C0/01DB 0A 01 00                ; Data Set #$4E: ? (Mosaic Buffer?)

$C0/01DE ? (Sound related)

This subroutine calls two other subroutines which are both (sound related

$C0/01DE E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/01E0 20 E5 0A    JSR $0AE5  [$C0:0AE5]   A:0000 X:0000 Y:0000 P:envMXdIZC
$C0/01E3 20 36 0B    JSR $0B36  [$C0:0B36]   A:00FF X:0087 Y:0000 P:envMXdIZC
$C0/01E6 60          RTS

$C0/01E7 NMI Handler

$C0/01E7 C2 30       REP #$30       ; Buffer Direct Bank, Direct Page and A/X/Y on stack
$C0/01E9 8B          PHB
$C0/01EA 0B          PHD
$C0/01EB 48          PHA
$C0/01EC DA          PHX
$C0/01ED 5A          PHY
$C0/01EE E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/01F0 A9 82       LDA #$82       ; Set Direct Bank to $82
$C0/01F2 48          PHA
$C0/01F3 AB          PLB
$C0/01F4 AD 10 42    LDA $4210      ; Remove NMI flag
$C0/01F7 A5 A9       LDA $A9        ; Check General Update flag (are there updates to do?)
$C0/01F9 F0 03       BEQ $03        ; [$01FE] Branch if there are updates to do
$C0/01FB 4C 58 02    JMP $0258      ; Jump to the exit if not

$C0/01FE A5 AA       LDA $AA        ; Shall the VRAM Pipeline be worked off?
$C0/0200 F0 03       BEQ $03        ; [$0205] Branch if not
$C0/0202 20 62 02    JSR $0262      ; VRAM DMA Pipeline during NMI Handler

$C0/0205 A5 AB       LDA $AB        ; Has $2100 to be updated?
$C0/0207 F0 0A       BEQ $0A        ; [$0213] Branch if not
$C0/0209 A5 57       LDA $57        ; Load value for $2100
$C0/020B 8D 00 21    STA $2100      ; Set $2100 to it
$C0/020E 8D 09 01    STA $0109      ; Store in buffer of current $2100 value
$C0/0211 64 AB       STZ $AB        ; Remove $2100 update flag

$C0/0213 A5 AC       LDA $AC    [$00:00AC]   A:0480 X:0087 Y:0003 P:eNvMXdIzC
$C0/0215 F0 0A       BEQ $0A    [$0221]      A:0400 X:0087 Y:0003 P:envMXdIZC

code is missing here

$C0/0221 A5 AD       LDA $AD        ; Do the scroll registers have to be updated?
$C0/0223 F0 03       BEQ $03        ; [$0228] Branch if not
$C0/0225 20 D8 02    JSR $02D8      ; Update Scroll Registers

$C0/0228 A5 AE       LDA $AE        ; Do the Mode 7 registers have to be updated?
$C0/022A F0 03       BEQ $03        ; [$022F] Branch if not
$C0/022C 20 2B 03    JSR $032B      ; Update Mode 7 registers

$C0/022F A5 AF       LDA $AF    [$00:00AF]   A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/0231 F0 03       BEQ $03    [$0236]      A:0400 X:0087 Y:0003 P:envMXdIZC

code is missing here

$C0/0236 E2 20       SEP #$20                A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/0238 A5 B0       LDA $B0        ; Set HDMA flags
$C0/023A 8D 0C 42    STA $420C

sound related

$C0/023D A5 B1       LDA $B1    [$00:00B1]   A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/023F F0 03       BEQ $03    [$0244]      A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/0241 20 85 03    JSR $0385  [$C0:0385]   A:8001 X:00FF Y:0003 P:envMXdIzC

$C0/0244 A5 B2       LDA $B2        ; Flag set to update Joypad Input registers?
$C0/0246 F0 06       BEQ $06        ; [$024E] Branch if not
$C0/0248 20 FD 03    JSR $03FD      ; Buffer Joypad Inputs
$C0/024B 20 9D 09    JSR $099D  [$C0:099D]   A:0000 X:0004 Y:0000 P:envMXdIZC

code is missing here

$C0/024E A5 B3       LDA $B3    [$00:00B3]   A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/0250 F0 03       BEQ $03    [$0255]      A:0400 X:0087 Y:0003 P:envMXdIZC

code is missing here

$C0/0255 20 18 04    JSR $0418  [$C0:0418]   A:0400 X:0087 Y:0003 P:envMXdIZC

$C0/0258 E6 B4       INC $B4        ; Increment Frame Counter(?)
$C0/025A C2 30       REP #$30       ; Restore Direct Bank, Direct Page and A/X/Y
$C0/025C 7A          PLY
$C0/025D FA          PLX
$C0/025E 68          PLA
$C0/025F 2B          PLD
$C0/0260 AB          PLB
$C0/0261 40          RTI

$C0/0262 VRAM DMA Pipeline during NMI Handler

$C0/0262 A9 80       LDA #$80                A:2401 X:0062 Y:0000 P:envMXdIzC
$C0/0264 8D 03 21    STA $2103  [$82:2103]   A:2480 X:0062 Y:0000 P:eNvMXdIzC
$C0/0267 9C 02 21    STZ $2102  [$82:2102]   A:2480 X:0062 Y:0000 P:eNvMXdIzC
$C0/026A A2 00       LDX #$00                A:2480 X:0062 Y:0000 P:eNvMXdIzC
$C0/026C BD 0E 01    LDA $010E,x    ; Has this slot a flag set that it is used?
$C0/026F F0 54       BEQ $54        ; [$02C5] If not, branch (and exit)
$C0/0271 9E 0E 01    STZ $010E,x    ; Before working off, remove that flag of this slot
$C0/0274 BD 0F 01    LDA $010F,x    ; Build a 24-bit address in [$3F] out of the other three bytes of this slot
$C0/0277 85 3F       STA $3F
$C0/0279 BD 10 01    LDA $0110,x
$C0/027C 85 40       STA $40
$C0/027E BD 11 01    LDA $0111,x
$C0/0281 85 41       STA $41
$C0/0283 A0 00       LDY #$00                A:2482 X:0000 Y:0000 P:eNvMXdIzC
$C0/0285 B7 3F       LDA [$3F],y[$82:8010]   A:2482 X:0000 Y:0000 P:envMXdIZC
$C0/0287 8D 00 43    STA $4300  [$82:4300]   A:2402 X:0000 Y:0000 P:envMXdIzC
$C0/028A C8          INY                     A:2402 X:0000 Y:0000 P:envMXdIzC
$C0/028B B7 3F       LDA [$3F],y[$82:8011]   A:2402 X:0000 Y:0001 P:envMXdIzC
$C0/028D 8D 01 43    STA $4301  [$82:4301]   A:2404 X:0000 Y:0001 P:envMXdIzC
$C0/0290 C8          INY                     A:2404 X:0000 Y:0001 P:envMXdIzC
$C0/0291 B7 3F       LDA [$3F],y[$82:8012]   A:2404 X:0000 Y:0002 P:envMXdIzC
$C0/0293 8D 02 43    STA $4302  [$82:4302]   A:2407 X:0000 Y:0002 P:envMXdIzC
$C0/0296 C8          INY                     A:2407 X:0000 Y:0002 P:envMXdIzC
$C0/0297 B7 3F       LDA [$3F],y[$82:8013]   A:2407 X:0000 Y:0003 P:envMXdIzC
$C0/0299 8D 03 43    STA $4303  [$82:4303]   A:2422 X:0000 Y:0003 P:envMXdIzC
$C0/029C C8          INY                     A:2422 X:0000 Y:0003 P:envMXdIzC
$C0/029D B7 3F       LDA [$3F],y[$82:8014]   A:2422 X:0000 Y:0004 P:envMXdIzC
$C0/029F 8D 04 43    STA $4304  [$82:4304]   A:247E X:0000 Y:0004 P:envMXdIzC
$C0/02A2 C8          INY                     A:247E X:0000 Y:0004 P:envMXdIzC
$C0/02A3 B7 3F       LDA [$3F],y[$82:8015]   A:247E X:0000 Y:0005 P:envMXdIzC
$C0/02A5 8D 05 43    STA $4305  [$82:4305]   A:2420 X:0000 Y:0005 P:envMXdIzC
$C0/02A8 C8          INY                     A:2420 X:0000 Y:0005 P:envMXdIzC
$C0/02A9 B7 3F       LDA [$3F],y[$82:8016]   A:2420 X:0000 Y:0006 P:envMXdIzC
$C0/02AB 8D 06 43    STA $4306  [$82:4306]   A:2402 X:0000 Y:0006 P:envMXdIzC
$C0/02AE C8          INY                     A:2402 X:0000 Y:0006 P:envMXdIzC
$C0/02AF B7 3F       LDA [$3F],y[$82:8017]   A:2402 X:0000 Y:0007 P:envMXdIzC
$C0/02B1 8D 16 21    STA $2116  [$82:2116]   A:2453 X:0000 Y:0007 P:envMXdIzC
$C0/02B4 C8          INY                     A:2453 X:0000 Y:0007 P:envMXdIzC
$C0/02B5 B7 3F       LDA [$3F],y[$82:8018]   A:2453 X:0000 Y:0008 P:envMXdIzC
$C0/02B7 8D 17 21    STA $2117  [$82:2117]   A:2480 X:0000 Y:0008 P:eNvMXdIzC
$C0/02BA C8          INY                     A:2480 X:0000 Y:0008 P:eNvMXdIzC
$C0/02BB B7 3F       LDA [$3F],y[$82:8019]   A:2480 X:0000 Y:0009 P:envMXdIzC
$C0/02BD 8D 15 21    STA $2115  [$82:2115]   A:244F X:0000 Y:0009 P:envMXdIzC
$C0/02C0 A9 01       LDA #$01                A:244F X:0000 Y:0009 P:envMXdIzC
$C0/02C2 8D 0B 42    STA $420B  [$82:420B]   A:2401 X:0000 Y:0009 P:envMXdIzC
$C0/02C5 E8          INX            ; Increment Load Index four times to point to the next Pipeline slot
$C0/02C6 E8          INX
$C0/02C7 E8          INX
$C0/02C8 E8          INX
$C0/02C9 E0 40       CPX #$40       ; Was the maximum of Pipeline slots reached?
$C0/02CB D0 9F       BNE $9F        ; [$026C] If not, loop
$C0/02CD A9 80       LDA #$80                A:2400 X:0040 Y:0009 P:envMXdIZC
$C0/02CF 8D 03 21    STA $2103  [$82:2103]   A:2480 X:0040 Y:0009 P:eNvMXdIzC
$C0/02D2 9C 02 21    STZ $2102  [$82:2102]   A:2480 X:0040 Y:0009 P:eNvMXdIzC
$C0/02D5 64 AA       STZ $AA        ; Clear Flag for this work off
$C0/02D7 60          RTS

$C0/02D8 Update Scroll Registers

$C0/02D8 A5 61       LDA $61        ; Update BG1 H-Scroll Register
$C0/02DA 8D 0D 21    STA $210D
$C0/02DD A5 62       LDA $62
$C0/02DF 8D 0D 21    STA $210D
$C0/02E2 A5 63       LDA $63        ; Update BG1 V-Scroll Register
$C0/02E4 8D 0E 21    STA $210E
$C0/02E7 A5 64       LDA $64
$C0/02E9 8D 0E 21    STA $210E
$C0/02EC A5 65       LDA $65        ; Update BG2 H-Scroll Register
$C0/02EE 8D 0F 21    STA $210F
$C0/02F1 A5 66       LDA $66
$C0/02F3 8D 0F 21    STA $210F
$C0/02F6 A5 67       LDA $67        ; Update BG2 V-Scroll Register
$C0/02F8 8D 10 21    STA $2110
$C0/02FB A5 68       LDA $68
$C0/02FD 8D 10 21    STA $2110
$C0/0300 A5 69       LDA $69        ; Update BG3 H-Scroll Register
$C0/0302 8D 11 21    STA $2111
$C0/0305 A5 6A       LDA $6A
$C0/0307 8D 11 21    STA $2111
$C0/030A A5 6B       LDA $6B        ; Update BG3 V-Scroll Register
$C0/030C 8D 12 21    STA $2112
$C0/030F A5 6C       LDA $6C
$C0/0311 8D 12 21    STA $2112
$C0/0314 A5 6D       LDA $6D        ; Update BG4 H-Scroll Register
$C0/0316 8D 13 21    STA $2113
$C0/0319 A5 6E       LDA $6E
$C0/031B 8D 13 21    STA $2113
$C0/031E A5 6F       LDA $6F        ; Update BG4 V-Scroll Register
$C0/0320 8D 14 21    STA $2114
$C0/0323 A5 70       LDA $70
$C0/0325 8D 14 21    STA $2114
$C0/0328 64 AD       STZ $AD        ; Remove Flag for Scroll Register Update
$C0/032A 60          RTS

$C0/032B Update Mode 7 registers

$C0/032B A5 71       LDA $71    [$00:0071]   A:8585 X:0001 Y:0000 P:eNvMXdIzC
$C0/032D 8D 1A 21    STA $211A  [$82:211A]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0330 A5 72       LDA $72    [$00:0072]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0332 8D 1B 21    STA $211B  [$82:211B]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0335 A5 73       LDA $73    [$00:0073]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0337 8D 1B 21    STA $211B  [$82:211B]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/033A A5 74       LDA $74    [$00:0074]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/033C 8D 1C 21    STA $211C  [$82:211C]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/033F A5 75       LDA $75    [$00:0075]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0341 8D 1C 21    STA $211C  [$82:211C]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0344 A5 76       LDA $76    [$00:0076]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0346 8D 1D 21    STA $211D  [$82:211D]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0349 A5 77       LDA $77    [$00:0077]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/034B 8D 1D 21    STA $211D  [$82:211D]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/034E A5 78       LDA $78    [$00:0078]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0350 8D 1E 21    STA $211E  [$82:211E]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0353 A5 79       LDA $79    [$00:0079]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0355 8D 1E 21    STA $211E  [$82:211E]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0358 A5 7A       LDA $7A    [$00:007A]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/035A 8D 1F 21    STA $211F  [$82:211F]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/035D A5 7B       LDA $7B    [$00:007B]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/035F 8D 1F 21    STA $211F  [$82:211F]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0362 A5 7C       LDA $7C    [$00:007C]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0364 8D 20 21    STA $2120  [$82:2120]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0367 A5 7D       LDA $7D    [$00:007D]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/0369 8D 20 21    STA $2120  [$82:2120]   A:8500 X:0001 Y:0000 P:envMXdIZC
$C0/036C 64 AE       STZ $AE        ; Remove flag for Mode 7 Register update
$C0/036E 60          RTS

$C0/0385 ? (Sound related)

$C0/0385 AE D0 01    LDX $01D0  [$82:01D0]   A:8001 X:00FF Y:0003 P:envMXdIzC
$C0/0388 EC CF 01    CPX $01CF  [$82:01CF]   A:8001 X:0000 Y:0003 P:envMXdIZC
$C0/038B F0 16       BEQ $16    [$03A3]      A:8001 X:0000 Y:0003 P:eNvMXdIzc
$C0/038D BD 4E 01    LDA $014E,x[$82:014E]   A:8001 X:0000 Y:0003 P:eNvMXdIzc
$C0/0390 8D 40 21    STA $2140  [$82:2140]   A:8002 X:0000 Y:0003 P:envMXdIzc
$C0/0393 85 59       STA $59    [$00:0059]   A:8002 X:0000 Y:0003 P:envMXdIzc
$C0/0395 E8          INX                     A:8002 X:0000 Y:0003 P:envMXdIzc
$C0/0396 8A          TXA                     A:8002 X:0001 Y:0003 P:envMXdIzc
$C0/0397 29 1F       AND #$1F                A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0399 8D D0 01    STA $01D0  [$82:01D0]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/039C A9 05       LDA #$05                A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/039E 8D CE 01    STA $01CE  [$82:01CE]   A:8005 X:0001 Y:0003 P:envMXdIzc
$C0/03A1 80 45       BRA $45        ; [$03E8] Update APU register buffers

code is missing here

$C0/03E8 AD 40 21    LDA $2140      ; Update APU register buffers
$C0/03EB 85 5D       STA $5D
$C0/03ED AD 41 21    LDA $2141
$C0/03F0 85 5E       STA $5E
$C0/03F2 AD 42 21    LDA $2142
$C0/03F5 85 5F       STA $5F
$C0/03F7 AD 43 21    LDA $2143
$C0/03FA 85 60       STA $60
$C0/03FC 60          RTS

$C0/03FD Buffer Joypad Inputs

$C0/03FD E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/03FF AD 12 42    LDA $4212      ; Wait until Auto Joypad Read is done
$C0/0402 29 01       AND #$01
$C0/0404 D0 F9       BNE $F9        ; [$03FF]
$C0/0406 C2 20       REP #$20       ; A = 16 bit
$C0/0408 A2 00       LDX #$00       ; Transfer Joypad Input into buffer registers at $7E-$81
$C0/040A BD 18 42    LDA $4218,x
$C0/040D 95 7E       STA $7E,x
$C0/040F E8          INX
$C0/0410 E8          INX
$C0/0411 E0 04       CPX #$04
$C0/0413 D0 F5       BNE $F5        ; [$040A]
$C0/0415 E2 20       SEP #$20
$C0/0417 60          RTS

$C0/0418 ?

$C0/0418 A5 BA       LDA $BA    [$00:00BA]   A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/041A F0 1C       BEQ $1C    [$0438]      A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/041C E6 BB       INC $BB    [$00:00BB]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/041E A5 BB       LDA $BB    [$00:00BB]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0420 C9 01       CMP #$01                A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0422 D0 14       BNE $14    [$0438]      A:8001 X:0001 Y:0003 P:envMXdIZC
$C0/0424 64 BB       STZ $BB    [$00:00BB]   A:8001 X:0001 Y:0003 P:envMXdIZC
$C0/0426 AD 09 01    LDA $0109  [$82:0109]   A:8001 X:0001 Y:0003 P:envMXdIZC
$C0/0429 18          CLC                     A:8000 X:0001 Y:0003 P:envMXdIZC
$C0/042A 65 BD       ADC $BD    [$00:00BD]   A:8000 X:0001 Y:0003 P:envMXdIZc
$C0/042C 29 8F       AND #$8F                A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/042E 85 57       STA $57    [$00:0057]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0430 E6 AB       INC $AB    [$00:00AB]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0432 C6 BC       DEC $BC    [$00:00BC]   A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0434 D0 02       BNE $02    [$0438]      A:8001 X:0001 Y:0003 P:envMXdIzc
$C0/0436 64 BA       STZ $BA    [$00:00BA]   A:800F X:0000 Y:0003 P:envMXdIZc
$C0/0438 A5 B6       LDA $B6    [$00:00B6]   A:0400 X:0087 Y:0003 P:envMXdIZC
$C0/043A F0 1A       BEQ $1A    [$0456]      A:0400 X:0087 Y:0003 P:envMXdIZC

code is missing here

$C0/0456 60          RTS

$C0/0545 Execute General Updates while VBLANK

This activates NMI while VBLANK, sets the General Update flag and waits for the next VBLANK, so all the updates that were prepared are done. Afterwards, this subroutine clears the General Update flag (but does NOT deactivate NMI!).

$C0/0545 08          PHP            ; Buffer Flag register and A on stack
$C0/0546 C2 20       REP #$20
$C0/0548 48          PHA
$C0/0549 E2 20       SEP #$20
$C0/054B A9 01       LDA #$01       ; Set General Update flag
$C0/054D 85 A9       STA $A9
$C0/054F AD 08 01    LDA $0108      ; Activate NMI
$C0/0552 09 80       ORA #$80
$C0/0554 8D 00 42    STA $4200
$C0/0557 8D 08 01    STA $0108
$C0/055A 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/055D 64 A9       STZ $A9        ; Remove General Update flag
$C0/055F C2 20       REP #$20       ; Restore Flag register and A
$C0/0561 68          PLA
$C0/0562 28          PLP
$C0/0563 60          RTS

$C0/0564 Deactivate NMI

$C0/0564 08          PHP            ; Buffer Flag register and A on stack
$C0/0565 C2 20       REP #$20
$C0/0567 48          PHA
$C0/0568 E2 20       SEP #$20
$C0/056A AD 08 01    LDA $0108      ; Clear NMI flag from $4200 and its value buffer $0108
$C0/056D 29 7F       AND #$7F
$C0/056F 8D 00 42    STA $4200
$C0/0572 8D 08 01    STA $0108
$C0/0575 C2 20       REP #$20       ; Restore Flag register and A
$C0/0577 68          PLA
$C0/0578 28          PLP
$C0/0579 60          RTS

$C0/057A Activate FBLANK

Note that this subroutine does not set the flag for an $2100 update.

$C0/057A 08          PHP            ; Buffer Flag register and A on stack
$C0/057B C2 20       REP #$20
$C0/057D 48          PHA
$C0/057E E2 20       SEP #$20       ; This takes the value that currently is in $2100 ($0109) ...
$C0/0580 AD 09 01    LDA $0109      ; ... sets the MSB and stores it in $57, which is the buffer for...
$C0/0583 09 80       ORA #$80       ; ... the value to be transfered to $2100. This deactivates the FBLANK
$C0/0585 85 57       STA $57
$C0/0587 C2 20       REP #$20       ; Restore Flag register and A
$C0/0589 68          PLA
$C0/058A 28          PLP
$C0/058B 60          RTS

$C0/058C Deactivate FBLANK

Note that this subroutine does not set the flag for an $2100 update.

$C0/058C 08          PHP            ; Buffer Flag register and A on stack
$C0/058D C2 20       REP #$20
$C0/058F 48          PHA
$C0/0590 E2 20       SEP #$20       ; This takes the value that currently is in $2100 ($0109) ...
$C0/0592 AD 09 01    LDA $0109      ; ... removes the MSB and stores it in $57, which is the buffer for...
$C0/0595 29 7F       AND #$7F       ; ... the value to be transfered to $2100. This deactivates the FBLANK
$C0/0597 85 57       STA $57
$C0/0599 C2 20       REP #$20       ; Restore Flag register and A
$C0/059B 68          PLA
$C0/059C 28          PLP
$C0/059D 60          RTS

$C0/059E Wait for VBLANK

This subroutine waits until the Frame Counter gets incremented (which happens in the NMI handler)

$C0/059E 08          PHP            ; Buffer Flag register/A on stack
$C0/059F C2 20       REP #$20
$C0/05A1 48          PHA
$C0/05A2 E2 20       SEP #$20
$C0/05A4 A5 B4       LDA $B4
$C0/05A6 C5 B4       CMP $B4
$C0/05A8 F0 FC       BEQ $FC        ; [$05A6] Loop until the Frame Counter has incremented
$C0/05AA C2 20       REP #$20       ; Restore Flag register/A
$C0/05AC 68          PLA
$C0/05AD 28          PLP
$C0/05AE 60          RTS

$C0/05EA Which buttons were pushed this frame?

This subroutine determines which buttons were pushed in this frame

$C0/05EA 08          PHP            ; Buffer Flag register/A/X on stack
$C0/05EB C2 30       REP #$30
$C0/05ED 48          PHA
$C0/05EE DA          PHX
$C0/05EF E2 10       SEP #$10       ; X/Y = 8 bit
$C0/05F1 A2 00       LDX #$00       ; Setup Loop Counter / Index
$C0/05F3 B5 7E       LDA $7E,x      ; Load buffered raw Joypad Input of this frame
$C0/05F5 55 82       EOR $82,x      ;  ($82,x contains the raw Joypad Input of last frame)
$C0/05F7 35 7E       AND $7E,x
$C0/05F9 95 86       STA $86,x      ; $86,x contains now every button that was pushed in this frame (not held!)
$C0/05FB B5 7E       LDA $7E,x      ; Transfer this frames input in buffer for last frame's input
$C0/05FD 95 82       STA $82,x
$C0/05FF 74 7E       STZ $7E,x      ; After this, clear this frame's buffer
$C0/0601 E8          INX            ; Increment loop counter
$C0/0602 E8          INX
$C0/0603 E0 04       CPX #$04
$C0/0605 D0 EC       BNE $EC        ; [$05F3] Repeat this for the second controller, too
$C0/0607 C2 30       REP #$30
$C0/0609 FA          PLX            ; Restore Flag register/A/X
$C0/060A 68          PLA
$C0/060B 28          PLP
$C0/060C 60          RTS

$C0/07AE ?

$C0/07AE 08          PHP            ; Buffer Flag register/A on stack
$C0/07AF C2 20       REP #$20
$C0/07B1 48          PHA
$C0/07B2 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/07B5 E2 20       SEP #$20       ; A = 8 bit
$C0/07B7 A5 B6       LDA $B6        ; Loop until both $B6 and $BA = #$00
$C0/07B9 05 BA       ORA $BA
$C0/07BB D0 F5       BNE $F5        ; [$07B2]
$C0/07BD 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/07C0 C2 20       REP #$20       ; Restore Flag register/A
$C0/07C2 68          PLA
$C0/07C3 28          PLP
$C0/07C4 60          RTS

$C0/07C5 Tool: Set values of a number of registers

This subroutine is useful if you have a number of single byte values that you want to store in registers that are scattered on the same bank. It works off a number of "data sets". These sets consist of three bytes: two bytes address on that particular bank and the value for it. Can be used for WRAM addresses or Registers.

The bytes after the Jump Command to this subroutine are the data for this subroutine:

1st byte: Bank for 24-bit Load address (address of the data sets)
2nd byte: Address Low Byte for 24-bit Load address
3rd byte: Address High Byte for 24-bit Load address
4th byte: Bank for 24-bit Store address (Bank on which the store addresses are)
5th byte: Number of data sets to do, Low Byte
6th byte: Number of data sets to do, High Byte

Please take care that the 24-bit address is not in order: Bank, Low Byte, High Byte.

$C0/07C5 08          PHP            ; Buffer Flag register/A/X/Y on stack
$C0/07C6 C2 30       REP #$30
$C0/07C8 48          PHA
$C0/07C9 DA          PHX
$C0/07CA 5A          PHY
$C0/07CB E2 20       SEP #$20       ; A = 8 bit (X/Y = 16 bit)
$C0/07CD BA          TSX            ; Load Return Address from Stack
$C0/07CE B5 08       LDA $08,x
$C0/07D0 85 00       STA $00        ; Store original Return Address in $00 as 24-bit Load Address
$C0/07D2 18          CLC            ; Add #$06 to Return Address and store it back on stack
$C0/07D3 69 06       ADC #$06       ;  (This way, the bytes following the Jump Command are left out)
$C0/07D5 95 08       STA $08,x      ;  (These bytes are data for this subroutine)
$C0/07D7 B5 09       LDA $09,x      ; Load upper byte of the Return Address from Stack
$C0/07D9 85 01       STA $01        ; Store it in $01 as 24-bit Load Address
$C0/07DB 69 00       ADC #$00       ; Add Carry (if set)
$C0/07DD 95 09       STA $09,x      ; Store back for new Return Address
$C0/07DF B5 0A       LDA $0A,x      ; Load Return Address Bank in $02 as 24-bit Load Address
$C0/07E1 85 02       STA $02
$C0/07E3 E2 10       SEP #$10       ; Build an 24-bit load address in $03 out of the first three data bytes
$C0/07E5 A0 01       LDY #$01
$C0/07E7 B7 00       LDA [$00],y
$C0/07E9 85 05       STA $05
$C0/07EB C8          INY
$C0/07EC C2 20       REP #$20
$C0/07EE B7 00       LDA [$00],y
$C0/07F0 85 03       STA $03
$C0/07F2 C8          INY
$C0/07F3 C8          INY
$C0/07F4 E2 20       SEP #$20       ; 4th data byte is used as Bank of the 24-bit Store Address in $06-$08
$C0/07F6 B7 00       LDA [$00],y
$C0/07F8 85 08       STA $08
$C0/07FA C8          INY
$C0/07FB C2 20       REP #$20       ; Next double-byte is loaded and multiplied by 3
$C0/07FD B7 00       LDA [$00],y    ;  (It's the number of data sets to do. Each data set is 3 bytes in size)
$C0/07FF 0A          ASL A          ;  (This way, the number of bytes is stored in $09/$0A)
$C0/0800 18          CLC            ;  (It is used as a Compare Value for the Store Index later)
$C0/0801 77 00       ADC [$00],y
$C0/0803 85 09       STA $09
$C0/0805 C2 10       REP #$10       ; X/Y = 16 bit (A already is 16 bit)
$C0/0807 A0 00 00    LDY #$0000     ; Setup Load Index
$C0/080A C2 20       REP #$20       ; A = 16 bit (this is part of a loop, so it's not unnecessary)
$C0/080C B7 03       LDA [$03],y    ; Load first double-byte of data set
$C0/080E 85 06       STA $06        ; Store as part of the 24-bit Store Address
$C0/0810 C8          INY            ; Increment Load Index twice
$C0/0811 C8          INY
$C0/0812 E2 20       SEP #$20       ; Transfer data set value to its destination
$C0/0814 B7 03       LDA [$03],y
$C0/0816 87 06       STA [$06]
$C0/0818 C8          INY            ; Increment Load Index
$C0/0819 C4 09       CPY $09        ; Does the Load Index have reached its limit?
$C0/081B D0 ED       BNE $ED        ; [$080A] Loop if not
$C0/081D C2 20       REP #$20       ; Restore Flag register/A/X/Y
$C0/081F 7A          PLY
$C0/0820 FA          PLX
$C0/0821 68          PLA
$C0/0822 28          PLP
$C0/0823 6B          RTL

$C0/0824 Setup DMA

This subroutine sets up an DMA. The bytes after the Jump Command to this subroutine are the data for this subroutine:

1st byte: No. of the DMA channel to use (0-7)
2nd byte: $43x0 - DMA Settings
3rd byte: $43x1 - I/O-Bus address ($21xx)
4th byte: $43x4 - Bank
5th byte: $43x2 - Address - Low Byte
6th byte: $43x3 - Address - High Byte
7th byte: $43x5 - Number of Bytes to transfer - Low Byte
8th byte: $43x6 - Number of Bytes to transfer - High Byte

This subroutine does not change A/X/Y

$C0/0824 08          PHP            ; Buffer Flag register/A/X/Y on stack
$C0/0825 C2 30       REP #$30
$C0/0827 48          PHA
$C0/0828 DA          PHX
$C0/0829 5A          PHY
$C0/082A E2 20       SEP #$20       ; A = 8 bit (X/Y = 16 bit)
$C0/082C BA          TSX            ; Load Return Address from Stack
$C0/082D B5 08       LDA $08,x
$C0/082F 85 00       STA $00        ; Store original Return Address in $00 as 24-bit Load Address
$C0/0831 18          CLC            ; Add #$08 to Return Address and store it back on stack
$C0/0832 69 08       ADC #$08       ;  (This way, the bytes following the Jump Command are left out)
$C0/0834 95 08       STA $08,x      ;  (These bytes are data for this subroutine)
$C0/0836 B5 09       LDA $09,x      ; Load upper byte of the Return Address from Stack
$C0/0838 85 01       STA $01        ; Store it in $01 as 24-bit Load Address
$C0/083A 69 00       ADC #$00       ; Add Carry (if set)
$C0/083C 95 09       STA $09,x      ; Store back for new Return Address
$C0/083E B5 0A       LDA $0A,x      ; Load Return Address Bank in $02 as 24-bit Load Address
$C0/0840 85 02       STA $02
$C0/0842 E2 10       SEP #$10       ; X/Y = 8 bit
$C0/0844 A0 01       LDY #$01       ; Use Y as Load Counter
$C0/0846 B7 00       LDA [$00],y    ; Load 1st byte (No. of the DMA Channel to use)
$C0/0848 0A          ASL A          ; No. * #$10 = Store Index
$C0/0849 0A          ASL A
$C0/084A 0A          ASL A
$C0/084B 0A          ASL A
$C0/084C AA          TAX            ; Transfer Store Index in X
$C0/084D C8          INY            ; Increment Load Index
$C0/084E B7 00       LDA [$00],y    ; Load 2nd byte
$C0/0850 9D 00 43    STA $4300,x    ; Set as DMA Settings
$C0/0853 C8          INY            ; Increment Load Index
$C0/0854 B7 00       LDA [$00],y    ; Load 3rd byte
$C0/0856 9D 01 43    STA $4301,x    ; Set as $21xx address
$C0/0859 C8          INY            ; Increment Load Index
$C0/085A B7 00       LDA [$00],y    ; Load 4th byte
$C0/085C 9D 04 43    STA $4304,x    ; Set as Bank
$C0/085F C8          INY            ; Increment Load Index
$C0/0860 B7 00       LDA [$00],y    ; Load 5th byte
$C0/0862 9D 02 43    STA $4302,x    ; Set as address Low Byte
$C0/0865 C8          INY            ; Increment Load Index
$C0/0866 B7 00       LDA [$00],y    ; Load 6th byte
$C0/0868 9D 03 43    STA $4303,x    ; Set as address High Byte
$C0/086B C8          INY            ; Increment Load Index
$C0/086C B7 00       LDA [$00],y    ; Load 7th byte
$C0/086E 9D 05 43    STA $4305,x    ; Set as DMA Size Low Byte
$C0/0871 C8          INY            ; Increment Load Index
$C0/0872 B7 00       LDA [$00],y    ; Load 8th byte
$C0/0874 9D 06 43    STA $4306,x    ; Set as DMA Size High Byte
$C0/0877 C2 30       REP #$30       ; Restore Flag register/A/X/Y
$C0/0879 7A          PLY
$C0/087A FA          PLX
$C0/087B 68          PLA
$C0/087C 28          PLP
$C0/087D 6B          RTL

$C0/0922 ?

$C0/0922 08          PHP                     A:12C0 X:0000 Y:0003 P:eNvMXdIzc
$C0/0923 C2 20       REP #$20                A:12C0 X:0000 Y:0003 P:eNvMXdIzc
$C0/0925 48          PHA                     A:12C0 X:0000 Y:0003 P:eNvmXdIzc
$C0/0926 A9 45 23    LDA #$2345              A:12C0 X:0000 Y:0003 P:eNvmXdIzc
$C0/0929 8D 00 01    STA $0100  [$82:0100]   A:2345 X:0000 Y:0003 P:envmXdIzc
$C0/092C 68          PLA                     A:2345 X:0000 Y:0003 P:envmXdIzc
$C0/092D 28          PLP                     A:12C0 X:0000 Y:0003 P:envmXdIzc
$C0/092E 60          RTS                     A:12C0 X:0000 Y:0003 P:eNvMXdIzc

$C0/0AE5 ? (Sound related?)

Probably this subroutine is for clearing sound related registers?

$C0/0AE5 08          PHP            ; Buffer Flag Register value on stack
$C0/0AE6 E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/0AE8 64 B1       STZ $B1    [$00:00B1]   A:0000 X:0000 Y:0000 P:envMXdIZC
$C0/0AEA A2 88       LDX #$88                A:0000 X:0000 Y:0000 P:envMXdIZC
$C0/0AEC 9E 4E 01    STZ $014E,x[$82:01D6]   A:0000 X:0088 Y:0000 P:eNvMXdIzC
$C0/0AEF CA          DEX                     A:0000 X:0088 Y:0000 P:eNvMXdIzC
$C0/0AF0 10 FA       BPL $FA    [$0AEC]      A:0000 X:0087 Y:0000 P:eNvMXdIzC
$C0/0AF2 A9 FF       LDA #$FF                A:0000 X:0087 Y:0000 P:eNvMXdIzC
$C0/0AF4 8D D7 01    STA $01D7  [$82:01D7]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0AF7 8D D8 01    STA $01D8  [$82:01D8]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0AFA 8D D9 01    STA $01D9  [$82:01D9]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0AFD 9C 40 21    STZ $2140      ; Clear APU Registers
$C0/0B00 9C 41 21    STZ $2141
$C0/0B03 9C 42 21    STZ $2142
$C0/0B06 9C 43 21    STZ $2143
$C0/0B09 64 59       STZ $59    [$00:0059]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B0B 64 5D       STZ $5D        ; Clear $2140 current value buffer (APU buffer)
$C0/0B0D 64 5A       STZ $5A    [$00:005A]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B0F 64 5E       STZ $5E        ; Clear $2141 current value buffer (APU buffer)
$C0/0B11 64 5B       STZ $5B    [$00:005B]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B13 64 5F       STZ $5F        ; Clear $2142 current value buffer (APU buffer)
$C0/0B15 64 5C       STZ $5C    [$00:005C]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B17 64 60       STZ $60        ; Clear $2143 current value buffer (APU buffer)
$C0/0B19 9C D0 01    STZ $01D0  [$82:01D0]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B1C 9C CF 01    STZ $01CF  [$82:01CF]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B1F 9C D2 01    STZ $01D2  [$82:01D2]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B22 9C D1 01    STZ $01D1  [$82:01D1]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B25 9C D4 01    STZ $01D4  [$82:01D4]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B28 9C D3 01    STZ $01D3  [$82:01D3]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B2B 9C D6 01    STZ $01D6  [$82:01D6]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B2E 9C D5 01    STZ $01D5  [$82:01D5]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B31 9C DA 01    STZ $01DA  [$82:01DA]   A:00FF X:0087 Y:0000 P:eNvMXdIzC
$C0/0B34 28          PLP            ; Restore Flag Register value
$C0/0B35 60          RTS

$C0/0B36 ? (Sound related)

$C0/0B36 08          PHP            ; Buffer Flag Register value on stack
$C0/0B37 E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/0B39 64 B1       STZ $B1    [$00:00B1]   A:00FF X:0087 Y:0000 P:envMXdIZC
$C0/0B3B A9 00       LDA #$00                A:00FF X:0087 Y:0000 P:envMXdIZC
$C0/0B3D 85 4B       STA $4B    [$00:004B]   A:0000 X:0087 Y:0000 P:envMXdIZC
$C0/0B3F A9 CC       LDA #$CC                A:0000 X:0087 Y:0000 P:envMXdIZC
$C0/0B41 85 53       STA $53    [$00:0053]   A:00CC X:0087 Y:0000 P:eNvMXdIzC
$C0/0B43 A9 FE       LDA #$FE                A:00CC X:0087 Y:0000 P:eNvMXdIzC
$C0/0B45 8D 40 21    STA $2140  [$82:2140]   A:00FE X:0087 Y:0000 P:eNvMXdIzC
$C0/0B48 C2 20       REP #$20       ; Wait for signal that APU has booted
$C0/0B4A A9 AA BB    LDA #$BBAA
$C0/0B4D CD 40 21    CMP $2140
$C0/0B50 D0 FB       BNE $FB        ; [$0B4D]
$C0/0B52 20 DF 0B    JSR $0BDF  [$C0:0BDF]   A:BBAA X:0087 Y:0000 P:envmXdIZC
$C0/0B55 C2 20       REP #$20                A:00FF X:0000 Y:0003 P:envmxdIZC
$C0/0B57 AF 11 00 C5 LDA $C50011[$C5:0011]   A:00FF X:0000 Y:0003 P:envmxdIZC
$C0/0B5B 85 4B       STA $4B    [$00:004B]   A:011D X:0000 Y:0003 P:envmxdIzC
$C0/0B5D E2 20       SEP #$20                A:011D X:0000 Y:0003 P:envmxdIzC
$C0/0B5F AF 13 00 C5 LDA $C50013[$C5:0013]   A:011D X:0000 Y:0003 P:envMxdIzC
$C0/0B63 85 4D       STA $4D    [$00:004D]   A:01C5 X:0000 Y:0003 P:eNvMxdIzC
$C0/0B65 9C 41 21    STZ $2141  [$82:2141]   A:01C5 X:0000 Y:0003 P:eNvMxdIzC
$C0/0B68 C2 20       REP #$20                A:01C5 X:0000 Y:0003 P:eNvMxdIzC
$C0/0B6A A9 00 05    LDA #$0500              A:01C5 X:0000 Y:0003 P:eNvmxdIzC
$C0/0B6D 8D 42 21    STA $2142  [$82:2142]   A:0500 X:0000 Y:0003 P:envmxdIzC
$C0/0B70 E2 20       SEP #$20                A:0500 X:0000 Y:0003 P:envmxdIzC
$C0/0B72 A5 53       LDA $53    [$00:0053]   A:0500 X:0000 Y:0003 P:envMxdIzC
$C0/0B74 8D 40 21    STA $2140  [$82:2140]   A:05E5 X:0000 Y:0003 P:eNvMxdIzC
$C0/0B77 CD 40 21    CMP $2140  [$82:2140]   A:05E5 X:0000 Y:0003 P:eNvMxdIzC
$C0/0B7A D0 FB       BNE $FB    [$0B77]      A:05E5 X:0000 Y:0003 P:envMxdIzC
$C0/0B7C E2 20       SEP #$20       ; UNNECESSARY LINE?
$C0/0B7E 28          PLP            ; Restore Flag Register value
$C0/0B7F 60          RTS

$C0/0C95 ? (Sound related)

$C0/0C95 08          PHP            ; Buffer Flag register value on stack
$C0/0C96 E2 30       SEP #$30       ; A/X/Y = 8 bit
$C0/0C98 64 B1       STZ $B1    [$00:00B1]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0C9A 9C 40 21    STZ $2140  [$82:2140]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0C9D 9C 41 21    STZ $2141  [$82:2141]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0CA0 9C 42 21    STZ $2142  [$82:2142]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0CA3 9C 43 21    STZ $2143  [$82:2143]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0CA6 A9 FF       LDA #$FF                A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0CA8 8D 40 21    STA $2140  [$82:2140]   A:12FF X:0087 Y:0003 P:eNvMXdizc
$C0/0CAB A9 AA       LDA #$AA       ; Wait for signals that APU is ready
$C0/0CAD CD 40 21    CMP $2140
$C0/0CB0 D0 F4       BNE $F4        ; [$0CA6]
$C0/0CB2 A9 BB       LDA #$BB
$C0/0CB4 CD 41 21    CMP $2141
$C0/0CB7 D0 ED       BNE $ED        ; [$0CA6]
$C0/0CB9 C2 20       REP #$20                A:12BB X:0087 Y:0003 P:envMXdiZC
$C0/0CBB A9 30 04    LDA #$0430              A:12BB X:0087 Y:0003 P:envmXdiZC
$C0/0CBE 8D 42 21    STA $2142  [$82:2142]   A:0430 X:0087 Y:0003 P:envmXdizC
$C0/0CC1 E2 20       SEP #$20                A:0430 X:0087 Y:0003 P:envmXdizC
$C0/0CC3 A9 FF       LDA #$FF                A:0430 X:0087 Y:0003 P:envMXdizC
$C0/0CC5 8D 41 21    STA $2141  [$82:2141]   A:04FF X:0087 Y:0003 P:eNvMXdizC
$C0/0CC8 A9 CC       LDA #$CC       ; Activate Data transfer between CPU and APU
$C0/0CCA 8D 40 21    STA $2140
$C0/0CCD CD 40 21    CMP $2140      ; Loop until Command has reached APU
$C0/0CD0 D0 FB       BNE $FB        ; [$0CCD]
$C0/0CD2 AD DB 01    LDA $01DB  [$82:01DB]   A:04CC X:0087 Y:0003 P:envMXdiZC
$C0/0CD5 8D 41 21    STA $2141  [$82:2141]   A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CD8 A9 00       LDA #$00                A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CDA 8D 40 21    STA $2140  [$82:2140]   A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CDD CD 40 21    CMP $2140  [$82:2140]   A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CE0 D0 FB       BNE $FB    [$0CDD]      A:0400 X:0087 Y:0003 P:envMXdizc
$C0/0CE2 9C 41 21    STZ $2141  [$82:2141]   A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CE5 A9 02       LDA #$02                A:0400 X:0087 Y:0003 P:envMXdiZC
$C0/0CE7 8D 40 21    STA $2140  [$82:2140]   A:0402 X:0087 Y:0003 P:envMXdizC
$C0/0CEA CD 40 21    CMP $2140  [$82:2140]   A:0402 X:0087 Y:0003 P:envMXdizC
$C0/0CED D0 F8       BNE $F8    [$0CE7]      A:0402 X:0087 Y:0003 P:envMXdizC
$C0/0CEF 28          PLP            ; Restore Flag register value
$C0/0CF0 60          RTS

$C0/0D0D ?

$C0/0D0D E2 20       SEP #$20                A:1201 X:0000 Y:0003 P:envMXdizc
$C0/0D0F AD 07 01    LDA $0107  [$82:0107]   A:1201 X:0000 Y:0003 P:envMXdizc
$C0/0D12 9C 07 01    STZ $0107  [$82:0107]   A:1200 X:0000 Y:0003 P:envMXdiZc
$C0/0D15 F0 0E       BEQ $0E    [$0D25]      A:1200 X:0000 Y:0003 P:envMXdiZc

code is missing here

$C0/0D25 E2 20       SEP #$20       ; A = 8 bit
$C0/0D27 C2 10       REP #$10       ; X/Y = 16 bit
$C0/0D29 A5 5D       LDA $5D    [$00:005D]   A:1200 X:0000 Y:0003 P:envMxdiZc
$C0/0D2B 29 7F       AND #$7F                A:1200 X:0000 Y:0003 P:envMxdiZc
$C0/0D2D C9 02       CMP #$02                A:1200 X:0000 Y:0003 P:envMxdiZc
$C0/0D2F F0 06       BEQ $06    [$0D37]      A:1200 X:0000 Y:0003 P:eNvMxdizc
$C0/0D31 20 E5 0A    JSR $0AE5  [$C0:0AE5]   A:1200 X:0000 Y:0003 P:eNvMxdizc
$C0/0D34 20 95 0C    JSR $0C95  [$C0:0C95]   A:12FF X:0087 Y:0003 P:eNvMxdizc
$C0/0D37 9C E4 01    STZ $01E4  [$82:01E4]   A:0402 X:0087 Y:0003 P:eNvMxdizc
$C0/0D3A 9C E5 01    STZ $01E5  [$82:01E5]   A:0402 X:0087 Y:0003 P:eNvMxdizc
$C0/0D3D 64 AA       STZ $AA        ; Clear VRAM DMA Pipeline Workoff Flag
$C0/0D3F 64 AB       STZ $AB        ; Clear $2100 Update Flag
$C0/0D41 64 AC       STZ $AC        ; Clear Flag
$C0/0D43 64 AD       STZ $AD        ; Clear Scroll Register Update Flag
$C0/0D45 64 AE       STZ $AE        ; Clear Mode 7 Register Update Flag
$C0/0D47 64 AF       STZ $AF        ; Clear Flag
$C0/0D49 64 B0       STZ $B0        ; Clear $420C buffer (HDMA flags)
$C0/0D4B 64 B1       STZ $B1        ; Clear Flag
$C0/0D4D 64 B2       STZ $B2        ; Clear Joypad Input Flag
$C0/0D4F 64 B3       STZ $B3        ; Clear Flag
$C0/0D51 9C 0E 01    STZ $010E      ; Clear flags of ALL the VRAM DMA Pipeline slots
$C0/0D54 9C 12 01    STZ $0112
$C0/0D57 9C 16 01    STZ $0116
$C0/0D5A 9C 1A 01    STZ $011A
$C0/0D5D 9C 1E 01    STZ $011E
$C0/0D60 9C 22 01    STZ $0122
$C0/0D63 9C 26 01    STZ $0126
$C0/0D66 9C 2A 01    STZ $012A
$C0/0D69 9C 2E 01    STZ $012E
$C0/0D6C 9C 32 01    STZ $0132
$C0/0D6F 9C 36 01    STZ $0136
$C0/0D72 9C 3A 01    STZ $013A
$C0/0D75 9C 3E 01    STZ $013E
$C0/0D78 9C 42 01    STZ $0142
$C0/0D7B 9C 46 01    STZ $0146
$C0/0D7E 9C 4A 01    STZ $014A
$C0/0D81 20 45 05    JSR $0545      ; Execute General Updates while VBLANK
$C0/0D84 20 7A 05    JSR $057A      ; Activate FBLANK
$C0/0D87 A5 57       LDA $57        ; FBLANK after next VBLANK
$C0/0D89 29 80       AND #$80
$C0/0D8B 85 57       STA $57
$C0/0D8D E6 AB       INC $AB        ; Set $2100 Update flag (for FBLANK)
$C0/0D8F 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/0D92 20 64 05    JSR $0564      ; Deactivate NMI
$C0/0D95 AD 08 01    LDA $0108      ; Deactivate NMI
$C0/0D98 29 CF       AND #$CF
$C0/0D9A 8D 00 42    STA $4200
$C0/0D9D 8D 08 01    STA $0108
$C0/0DA0 22 C5 07 C0 JSL $C007C5    ; Standard Graphic Settings / Set values of a number of registers

   Arguments:
   $C0/0DA4 C0 91 32 00 17 00       ; Transfer #$17 data sets from $C0/3291

$C0/0DAA 20 01 4B    JSR $4B01  [$C0:4B01]   A:0401 X:0087 Y:0003 P:envMxdizc
$C0/0DAD 20 13 83    JSR $8313  [$C0:8313]   A:0401 X:0087 Y:0003 P:envMxdizc
$C0/0DB0 A9 30       LDA #$30       ; Data to Decompress at: $DF/E230 (Palettes)
$C0/0DB2 8D DC 01    STA $01DC
$C0/0DB5 A9 E2       LDA #$E2
$C0/0DB7 8D DD 01    STA $01DD
$C0/0DBA A9 DF       LDA #$DF
$C0/0DBC 8D DE 01    STA $01DE
$C0/0DBF 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/0DC2 A9 00       LDA #$00       ; CGRAM write address
$C0/0DC4 8D 21 21    STA $2121
$C0/0DC7 22 24 08 C0 JSL $C00824    ; Setup DMA - Transfer Palette

   Arguments:
   $C0/0DCB 00 02 22 7F 00 00 00 02 ; DMA channel 0, to CGRAM, from $7F/0000, 200 Byte

$C0/0DD3 A9 01       LDA #$01       ; Activate DMA
$C0/0DD5 8D 0B 42    STA $420B
$C0/0DD8 A9 80       LDA #$80       ; VRAM Transfer Settings: 16-bit Transfer
$C0/0DDA 8D 15 21    STA $2115
$C0/0DDD A9 00       LDA #$00       ; VRAM Destination: $2000
$C0/0DDF 8D 16 21    STA $2116
$C0/0DE2 A9 20       LDA #$20
$C0/0DE4 8D 17 21    STA $2117
$C0/0DE7 A9 00       LDA #$00       ; Data to Decompress at: $D0/0000
$C0/0DE9 8D DC 01    STA $01DC
$C0/0DEC A9 00       LDA #$00
$C0/0DEE 8D DD 01    STA $01DD
$C0/0DF1 A9 D0       LDA #$D0
$C0/0DF3 8D DE 01    STA $01DE
$C0/0DF6 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/0DF9 22 24 08 C0 JSL $C00824    ; Setup DMA - Clear whole VRAM

   Arguments:
   $C0/0DFD 00 01 18 7F 00 00 00 80 ; Single Byte DMA, channel 0, to VRAM, from $7F/0000, #$8000 Bytes

$C0/0E05 A9 01       LDA #$01       ; Activate DMA
$C0/0E07 8D 0B 42    STA $420B
$C0/0E0A A9 4F       LDA #$4F       ; Data to Decompress at: $DA/F44F
$C0/0E0C 8D DC 01    STA $01DC
$C0/0E0F A9 F4       LDA #$F4
$C0/0E11 8D DD 01    STA $01DD
$C0/0E14 A9 DA       LDA #$DA
$C0/0E16 8D DE 01    STA $01DE
$C0/0E19 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/0E1C A9 00       LDA #$00       ; Set VRAM Address to $6000
$C0/0E1E 8D 16 21    STA $2116
$C0/0E21 A9 60       LDA #$60
$C0/0E23 8D 17 21    STA $2117
$C0/0E26 22 24 08 C0 JSL $C00824    ; Setup DMA

   Arguments:
   $C0/0DFD 00 01 18 7F 00 00 00 08 ; Single Byte DMA, channel 0, to VRAM, from $7F/0000, #$0800 Bytes

$C0/0E32 A9 01       LDA #$01       ; Activate DMA
$C0/0E34 8D 0B 42    STA $420B
$C0/0E37 E2 20       SEP #$20                A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E39 A5 5D       LDA $5D    [$00:005D]   A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E3B 29 7F       AND #$7F                A:8000 X:FFFF Y:0003 P:envMxdiZc
$C0/0E3D C9 02       CMP #$02                A:8000 X:FFFF Y:0003 P:envMxdiZc
$C0/0E3F F0 09       BEQ $09    [$0E4A]      A:8000 X:FFFF Y:0003 P:eNvMxdizc
$C0/0E41 A9 02       LDA #$02                A:8000 X:FFFF Y:0003 P:eNvMxdizc
$C0/0E43 85 4C       STA $4C    [$00:004C]   A:8002 X:FFFF Y:0003 P:envMxdizc
$C0/0E45 64 4B       STZ $4B    [$00:004B]   A:8002 X:FFFF Y:0003 P:envMxdizc
$C0/0E47 20 7C 0A    JSR $0A7C  [$C0:0A7C]   A:8002 X:FFFF Y:0003 P:envMxdizc
$C0/0E4A A9 01       LDA #$01                A:8002 X:FFFF Y:0003 P:envMxdizc
$C0/0E4C 8D 2C 21    STA $212C  [$82:212C]   A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E4F 20 46 07    JSR $0746  [$C0:0746]   A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E52 20 8C 05    JSR $058C      ; Deactivate the FBLANK
$C0/0E55 20 45 05    JSR $0545      ; Execute General Updates while VBLANK
$C0/0E58 20 AE 07    JSR $07AE  [$C0:07AE]   A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E5B 9C D5 02    STZ $02D5  [$82:02D5]   A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E5E A9 0E       LDA #$0E                A:8001 X:FFFF Y:0003 P:envMxdizc
$C0/0E60 8D D6 02    STA $02D6  [$82:02D6]   A:800E X:FFFF Y:0003 P:envMxdizc
$C0/0E63 A0 40 00    LDY #$0040     ; Wait for 40 frames
$C0/0E66 20 9E 05    JSR $059E      ;    Wait for VBLANK
$C0/0E69 C0 00 00    CPY #$0000
$C0/0E6C F0 03       BEQ $03        ;    [$0E71] Branch if Frame Counter has run out
$C0/0E6E 88          DEY            ;    If not, decrement Frame Counter and Loop
$C0/0E6F 80 F5       BRA $F5        ;    [$0E66]
$C0/0E71 C2 20       REP #$20                A:800E X:FFFF Y:0000 P:envMxdiZC
$C0/0E73 CE D5 02    DEC $02D5  [$82:02D5]   A:800E X:FFFF Y:0000 P:envmxdiZC
$C0/0E76 D0 1D       BNE $1D    [$0E95]      A:800E X:FFFF Y:0000 P:envmxdizC
$C0/0E78 20 54 07    JSR $0754  [$C0:0754]   A:8000 X:FFFF Y:0000 P:envmxdiZC
$C0/0E7B 20 AE 07    JSR $07AE  [$C0:07AE]   A:8000 X:FFFF Y:0000 P:envmxdiZC
$C0/0E7E 20 2F 09    JSR $092F  [$C0:092F]   A:8000 X:FFFF Y:0000 P:envmxdiZC
$C0/0E81 29 07 00    AND #$0007              A:80B5 X:FFFF Y:0000 P:envmxdiZC
$C0/0E84 0A          ASL A                   A:0005 X:FFFF Y:0000 P:envmxdizC
$C0/0E85 AA          TAX                     A:000A X:FFFF Y:0000 P:envmxdizc
$C0/0E86 BF C8 0E C0 LDA $C00EC8,x[$C0:0ED2] A:000A X:000A Y:0000 P:envmxdizc
$C0/0E8A 85 C6       STA $C6    [$00:00C6]   A:2C7D X:000A Y:0000 P:envmxdizc
$C0/0E8C E2 20       SEP #$20                A:2C7D X:000A Y:0000 P:envmxdizc
$C0/0E8E A9 C2       LDA #$C2                A:2C7D X:000A Y:0000 P:envMxdizc
$C0/0E90 85 C8       STA $C8    [$00:00C8]   A:2CC2 X:000A Y:0000 P:eNvMxdizc
$C0/0E92 4C 72 87    JMP $8772  [$C0:8772]   A:2CC2 X:000A Y:0000 P:eNvMxdizc
$C0/0E95 E2 20       SEP #$20                A:800E X:FFFF Y:0000 P:envmxdizC
$C0/0E97 A9 01       LDA #$01       ; Set flag to Update the Joypad Input buffers
$C0/0E99 85 B2       STA $B2
$C0/0E9B 20 EA 05    JSR $05EA      ; Which buttons were pushed this frame?
$C0/0E9E 20 0D 06    JSR $060D  [$C0:060D]   A:8001 X:FFFF Y:0000 P:envMxdizC
$C0/0EA1 20 2F 09    JSR $092F  [$C0:092F]   A:8001 X:FFFF Y:0000 P:envMxdizC
$C0/0EA4 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/0EA7 A5 A2       LDA $A2    [$00:00A2]   A:80BF X:FFFF Y:0000 P:envMxdizC
$C0/0EA9 05 A3       ORA $A3    [$00:00A3]   A:8000 X:FFFF Y:0000 P:envMxdiZC
$C0/0EAB F0 C4       BEQ $C4    [$0E71]      A:8000 X:FFFF Y:0000 P:envMxdiZC

$C0/3291 Standard Graphic Settings (Data)

Graphic settings, executed in $C0/0D0D

   $C0/3291 0B 42 00                ; Data Set #$01: Deactivate DMAs
   $C0/3294 0C 42 00                ; Data Set #$02: Deactivate HDMAs
   $C0/3297 01 21 00                ; Data Set #$03: Sprites at $0000, 8x8/16x16
   $C0/329A 02 21 00                ; Data Set #$04: OAM Address: $00
   $C0/329D 03 21 80                ; Data Set #$05: OAM Address: Low Table
   $C0/32A0 05 21 01                ; Data Set #$06: BG Mode 1
   $C0/32A3 07 21 60                ; Data Set #$07: BG1 Tilemap at $6000, no mirroring
   $C0/32A6 08 21 70                ; Data Set #$08: BG2 Tilemap at $7000, no mirroring
   $C0/32A9 0B 21 42                ; Data Set #$09: BG1 Tiles at $2000, BG2 Tiles at $4000
   $C0/32AC 0C 21 88                ; Data Set #$0A: BG3/4 Tiles at $8000
   $C0/32AF 0D 21 00                ; Data Set #$0B: BG1 HScroll #$0000
   $C0/32B2 0D 21 00                ; Data Set #$0C: BG1 HScroll #$0000
   $C0/32B5 0E 21 00                ; Data Set #$0D: BG1 VScroll #$0000
   $C0/32B8 0E 21 00                ; Data Set #$0E: BG1 VScroll #$0000
   $C0/32BB 0F 21 00                ; Data Set #$0F: BG2 HScroll #$0000
   $C0/32BE 0F 21 00                ; Data Set #$10: BG2 HScroll #$0000
   $C0/32C1 10 21 00                ; Data Set #$11: BG2 VScroll #$0000
   $C0/32C4 10 21 00                ; Data Set #$12: BG2 VScroll #$0000
   $C0/32C7 11 21 00                ; Data Set #$13: BG3 HScroll #$0000
   $C0/32CA 11 21 00                ; Data Set #$14: BG3 HScroll #$0000
   $C0/32CD 12 21 00                ; Data Set #$15: BG3 VScroll #$0000
   $C0/32D0 12 21 00                ; Data Set #$16: BG3 VScroll #$0000
   $C0/32D3 2C 21 03                ; Data Set #$17: Show BG1 and 2 on Main Screen

$C0/32D6 ? (Data)

   $C0/32D6 0B 42 00
   $C0/32D9 0C 42 00
   $C0/32DC 01 21 00
   $C0/32DF 02 21 00
   $C0/32E2 03 21 80
   $C0/32E5 05 21 09
   $C0/32E8 06 21 00
   $C0/32EB 07 21 6C
   $C0/32EE 08 21 70
   $C0/32F1 09 21 74
   $C0/32F4 0B 21 33
   $C0/32F7 0C 21 82
   $C0/32FA 0D 21 00

$C0/4B01 ? (Clear WRAM from $7E/0237 onwards)

$C0/4B01 08          PHP            ; Buffer Flag register
$C0/4B02 E2 20       SEP #$20       ; A = 8 bit
$C0/4B04 C2 10       REP #$10       ; X/Y = 16 bit
$C0/4B06 A9 37       LDA #$37       ; Set WRAM write address to $7E/0237
$C0/4B08 8D 81 21    STA $2181
$C0/4B0B A9 02       LDA #$02
$C0/4B0D 8D 82 21    STA $2182
$C0/4B10 A9 7E       LDA #$7E
$C0/4B12 8D 83 21    STA $2183
$C0/4B15 22 24 08 C0 JSL $C00824    ; Setup DMA

   Arguments:
   $C0/0DFD 00 08 80 C0 28 4B CD 12 ; Fixed DMA, channel 0, to WRAM, from $C0/4B28, #$12CD Bytes

$C0/4B21 A9 01       LDA #$01       ; Activate DMA
$C0/4B23 8D 0B 42    STA $420B
$C0/4B26 28          PLP            ; Restore Flag register
$C0/4B27 60          RTS

   $C0/4B28 00 00                   ; Clear Bytes for DMA

$C0/73F1 ?

$C0/73F1 E2 20       SEP #$20       ; A = 8 bit
$C0/73F3 C2 10       REP #$10       ; X/Y = 16 bit
$C0/73F5 A0 01 00    LDY #$0001              A:0000 X:0000 Y:0000 P:envMxdiZc
$C0/73F8 B7 C6       LDA [$C6],y[$C2:2A01]   A:0000 X:0000 Y:0001 P:envMxdizc
$C0/73FA 8D CF 04    STA $04CF  [$82:04CF]   A:0003 X:0000 Y:0001 P:envMxdizc
$C0/73FD C9 02       CMP #$02                A:0003 X:0000 Y:0001 P:envMxdizc
$C0/73FF D0 03       BNE $03    [$7404]      A:0003 X:0000 Y:0001 P:envMxdizC

code is missing here

$C0/7404 64 AA       STZ $AA        ; Clear VRAM DMA Pipeline Workoff Flag
$C0/7406 64 AB       STZ $AB        ; Clear $2100 Update Flag
$C0/7408 64 AC       STZ $AC    [$00:00AC]   A:0003 X:0000 Y:0001 P:envMxdizC
$C0/740A 64 AD       STZ $AD        ; Clear Scroll Register Update Flag
$C0/740C 64 AE       STZ $AE        ; Clear Mode 7 Register Update Flag
$C0/740E 64 AF       STZ $AF    [$00:00AF]   A:0003 X:0000 Y:0001 P:envMxdizC
$C0/7410 64 B0       STZ $B0        ; Clear HDMA flag buffer
$C0/7412 64 B3       STZ $B3    [$00:00B3]   A:0003 X:0000 Y:0001 P:envMxdizC
$C0/7414 9C 0E 01    STZ $010E      ; Clear flags of ALL the VRAM DMA Pipeline slots
$C0/7417 9C 12 01    STZ $0112
$C0/741A 9C 16 01    STZ $0116
$C0/741D 9C 1A 01    STZ $011A
$C0/7420 9C 1E 01    STZ $011E
$C0/7423 9C 22 01    STZ $0122
$C0/7426 9C 26 01    STZ $0126
$C0/7429 9C 2A 01    STZ $012A
$C0/742C 9C 2E 01    STZ $012E
$C0/742F 9C 32 01    STZ $0132
$C0/7432 9C 36 01    STZ $0136
$C0/7435 9C 3A 01    STZ $013A
$C0/7438 9C 3E 01    STZ $013E
$C0/743B 9C 42 01    STZ $0142
$C0/743E 9C 46 01    STZ $0146
$C0/7441 9C 4A 01    STZ $014A
$C0/7444 E2 20       SEP #$20                A:0003 X:0000 Y:0001 P:envMxdizC
$C0/7446 A9 80       LDA #$80                A:0003 X:0000 Y:0001 P:envMxdizC
$C0/7448 85 57       STA $57    [$00:0057]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/744A 64 61       STZ $61    [$00:0061]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/744C 64 63       STZ $63    [$00:0063]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/744E 64 65       STZ $65    [$00:0065]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7450 64 67       STZ $67    [$00:0067]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7452 64 69       STZ $69    [$00:0069]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7454 64 6B       STZ $6B    [$00:006B]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7456 9C A8 02    STZ $02A8  [$82:02A8]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7459 9C A9 02    STZ $02A9  [$82:02A9]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/745C 9C AA 02    STZ $02AA  [$82:02AA]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/745F 9C AB 02    STZ $02AB  [$82:02AB]   A:0080 X:0000 Y:0001 P:eNvMxdizC
$C0/7462 A9 01       LDA #$01
$C0/7464 85 AD       STA $AD        ; Set flag to update $2100
$C0/7466 85 AB       STA $AB        ; Set flag to update Scroll Registers
$C0/7468 20 9E 05    JSR $059E      ; Wait for VBLANK
$C0/746B 20 64 05    JSR $0564      ; Deactivate NMI
$C0/746E AD 08 01    LDA $0108      ; Disable V/H-IRQ
$C0/7471 29 CF       AND #$CF
$C0/7473 8D 00 42    STA $4200
$C0/7476 8D 08 01    STA $0108
$C0/7479 22 C5 07 C0 JSL $C007C5    ; Set values of a number of registers

   Arguments:
   $C0/0DA4 C0 89 7D 00 2D 00       ; Transfer #$2D data sets from $C0/7D89

$C0/7483 20 13 83    JSR $8313  [$C0:8313]   A:0001 X:0000 Y:0001 P:envMxdizC
$C0/7486 A9 0F       LDA #$0F      ; Clear flags of ALL the VRAM DMA Pipeline slots (via loop)
$C0/7488 85 0F       STA $0F
$C0/748A A2 00 00    LDX #$0000
$C0/748D 9E 0E 01    STZ $010E,x
$C0/7490 E8          INX
$C0/7491 E8          INX
$C0/7492 E8          INX
$C0/7493 E8          INX
$C0/7494 C6 0F       DEC $0F
$C0/7496 D0 F5       BNE $F5        ; [$748D]
$C0/7498 A9 01       LDA #$01                A:800F X:003C Y:0001 P:envMxdiZC
$C0/749A 85 B2       STA $B2    [$00:00B2]   A:8001 X:003C Y:0001 P:envMxdizC
$C0/749C A9 B0       LDA #$B0       ; H-IRQ at $00B0
$C0/749E 8D 07 42    STA $4207
$C0/74A1 A9 00       LDA #$00
$C0/74A3 8D 08 42    STA $4208
$C0/74A6 A9 6F       LDA #$6F       ; V-IRQ at $006F
$C0/74A8 8D 09 42    STA $4209
$C0/74AB A9 00       LDA #$00
$C0/74AD 8D 0A 42    STA $420A
$C0/74B0 A9 01       LDA #$01                A:8000 X:003C Y:0001 P:envMxdiZC
$C0/74B2 8D 47 02    STA $0247  [$82:0247]   A:8001 X:003C Y:0001 P:envMxdizC
$C0/74B5 A9 18       LDA #$18                A:8001 X:003C Y:0001 P:envMxdizC
$C0/74B7 8D 48 02    STA $0248  [$82:0248]   A:8018 X:003C Y:0001 P:envMxdizC
$C0/74BA A9 7E       LDA #$7E                A:8018 X:003C Y:0001 P:envMxdizC
$C0/74BC 8D 4B 02    STA $024B  [$82:024B]   A:807E X:003C Y:0001 P:envMxdizC
$C0/74BF A9 80       LDA #$80                A:807E X:003C Y:0001 P:envMxdizC
$C0/74C1 8D 50 02    STA $0250  [$82:0250]   A:8080 X:003C Y:0001 P:eNvMxdizC
$C0/74C4 A9 00       LDA #$00                A:8080 X:003C Y:0001 P:eNvMxdizC
$C0/74C6 8D 19 01    STA $0119  [$82:0119]   A:8000 X:003C Y:0001 P:envMxdiZC
$C0/74C9 A9 09       LDA #$09                A:8000 X:003C Y:0001 P:envMxdiZC
$C0/74CB 8D 51 02    STA $0251  [$82:0251]   A:8009 X:003C Y:0001 P:envMxdizC
$C0/74CE A9 18       LDA #$18                A:8009 X:003C Y:0001 P:envMxdizC
$C0/74D0 8D 52 02    STA $0252  [$82:0252]   A:8018 X:003C Y:0001 P:envMxdizC
$C0/74D3 A9 C0       LDA #$C0                A:8018 X:003C Y:0001 P:envMxdizC
$C0/74D5 8D 55 02    STA $0255  [$82:0255]   A:80C0 X:003C Y:0001 P:eNvMxdizC
$C0/74D8 A9 80       LDA #$80                A:80C0 X:003C Y:0001 P:eNvMxdizC
$C0/74DA 8D 5A 02    STA $025A  [$82:025A]   A:8080 X:003C Y:0001 P:eNvMxdizC
$C0/74DD A9 00       LDA #$00                A:8080 X:003C Y:0001 P:eNvMxdizC
$C0/74DF 8D 1D 01    STA $011D  [$82:011D]   A:8000 X:003C Y:0001 P:envMxdiZC
$C0/74E2 C2 20       REP #$20                A:8000 X:003C Y:0001 P:envMxdiZC
$C0/74E4 A9 00 20    LDA #$2000              A:8000 X:003C Y:0001 P:envmxdiZC
$C0/74E7 8D 49 02    STA $0249  [$82:0249]   A:2000 X:003C Y:0001 P:envmxdizC
$C0/74EA A9 40 00    LDA #$0040              A:2000 X:003C Y:0001 P:envmxdizC
$C0/74ED 8D 4C 02    STA $024C  [$82:024C]   A:0040 X:003C Y:0001 P:envmxdizC
$C0/74F0 A9 47 02    LDA #$0247              A:0040 X:003C Y:0001 P:envmxdizC
$C0/74F3 8D 17 01    STA $0117  [$82:0117]   A:0247 X:003C Y:0001 P:envmxdizC
$C0/74F6 A9 78 79    LDA #$7978              A:0247 X:003C Y:0001 P:envmxdizC
$C0/74F9 8D 53 02    STA $0253  [$82:0253]   A:7978 X:003C Y:0001 P:envmxdizC
$C0/74FC A9 00 0E    LDA #$0E00              A:7978 X:003C Y:0001 P:envmxdizC
$C0/74FF 8D 56 02    STA $0256  [$82:0256]   A:0E00 X:003C Y:0001 P:envmxdizC
$C0/7502 A9 51 02    LDA #$0251              A:0E00 X:003C Y:0001 P:envmxdizC
$C0/7505 8D 1B 01    STA $011B  [$82:011B]   A:0251 X:003C Y:0001 P:envmxdizC
$C0/7508 9C 3C 02    STZ $023C  [$82:023C]   A:0251 X:003C Y:0001 P:envmxdizC
$C0/750B 22 24 08 C0 JSL $C00824    ; Setup DMA

   Arguments:
   $C0/750F 00 09 18 C0 78 79 00 1C ; DMA channel 0, to VRAM, DECREMENT ADDRESS, from $C0/7879, 1C00 Byte

$C0/7517 C2 20       REP #$20                A:0251 X:003C Y:0001 P:envmxdizC
$C0/7519 A9 00 22    LDA #$2200              A:0251 X:003C Y:0001 P:envmxdizC
$C0/751C 8D 16 21    STA $2116  [$82:2116]   A:2200 X:003C Y:0001 P:envmxdizC
$C0/751F E2 20       SEP #$20                A:2200 X:003C Y:0001 P:envmxdizC
$C0/7521 A9 80       LDA #$80                A:2200 X:003C Y:0001 P:envMxdizC
$C0/7523 8D 15 21    STA $2115  [$82:2115]   A:2280 X:003C Y:0001 P:eNvMxdizC
$C0/7526 A9 01       LDA #$01       ; Activate DMA
$C0/7528 8D 0B 42    STA $420B
$C0/752B 22 24 08 C0 JSL $C00824    ; Setup DMA

   Arguments:
   $C0/750F 00 09 18 C0 78 79 00 08 ; DMA channel 0, to VRAM, DECREMENT ADDRESS, from $C0/7879, 0800 Byte

$C0/7537 C2 20       REP #$20                A:2201 X:003C Y:0001 P:envMxdizC
$C0/7539 A9 00 78    LDA #$7800              A:2201 X:003C Y:0001 P:envmxdizC
$C0/753C 8D 16 21    STA $2116  [$82:2116]   A:7800 X:003C Y:0001 P:envmxdizC
$C0/753F E2 20       SEP #$20                A:7800 X:003C Y:0001 P:envmxdizC
$C0/7541 A9 80       LDA #$80                A:7800 X:003C Y:0001 P:envMxdizC
$C0/7543 8D 15 21    STA $2115  [$82:2115]   A:7880 X:003C Y:0001 P:eNvMxdizC
$C0/7546 A9 01       LDA #$01       ; Activate DMA
$C0/7548 8D 0B 42    STA $420B
$C0/754B 22 24 08 C0 JSL $C00824    ; Setup DMA

   Arguments:
   $C0/750F 00 09 18 C0 78 79 00 10 ; DMA channel 0, to VRAM, DECREMENT ADDRESS, from $C0/7879, 1000 Byte

$C0/7557 C2 20       REP #$20                A:7801 X:003C Y:0001 P:envMxdizC
$C0/7559 A9 00 6C    LDA #$6C00              A:7801 X:003C Y:0001 P:envmxdizC
$C0/755C 8D 16 21    STA $2116  [$82:2116]   A:6C00 X:003C Y:0001 P:envmxdizC
$C0/755F E2 20       SEP #$20                A:6C00 X:003C Y:0001 P:envmxdizC
$C0/7561 A9 80       LDA #$80                A:6C00 X:003C Y:0001 P:envMxdizC
$C0/7563 8D 15 21    STA $2115  [$82:2115]   A:6C80 X:003C Y:0001 P:eNvMxdizC
$C0/7566 A9 01       LDA #$01       ; Activate DMA
$C0/7568 8D 0B 42    STA $420B
$C0/756B C2 20       REP #$20                A:6C01 X:003C Y:0001 P:envMxdizC
$C0/756D AD E6 01    LDA $01E6  [$82:01E6]   A:6C01 X:003C Y:0001 P:envmxdizC
$C0/7570 29 FF 00    AND #$00FF              A:0004 X:003C Y:0001 P:envmxdizC
$C0/7573 0A          ASL A                   A:0004 X:003C Y:0001 P:envmxdizC
$C0/7574 AA          TAX                     A:0008 X:003C Y:0001 P:envmxdizc
$C0/7575 BF 06 0C C5 LDA $C50C06,x[$C5:0C0E] A:0008 X:0008 Y:0001 P:envmxdizc
$C0/7579 AA          TAX                     A:0CF5 X:0008 Y:0001 P:envmxdizc
$C0/757A E2 20       SEP #$20                A:0CF5 X:0CF5 Y:0001 P:envmxdizc
$C0/757C BF 00 00 C5 LDA $C50000,x[$C5:0CF5] A:0CF5 X:0CF5 Y:0001 P:envMxdizc
$C0/7580 8D DC 01    STA $01DC  [$82:01DC]   A:0C47 X:0CF5 Y:0001 P:envMxdizc
$C0/7583 BF 01 00 C5 LDA $C50001,x[$C5:0CF6] A:0C47 X:0CF5 Y:0001 P:envMxdizc
$C0/7587 8D DD 01    STA $01DD  [$82:01DD]   A:0C57 X:0CF5 Y:0001 P:envMxdizc
$C0/758A BF 02 00 C5 LDA $C50002,x[$C5:0CF7] A:0C57 X:0CF5 Y:0001 P:envMxdizc
$C0/758E 8D DE 01    STA $01DE  [$82:01DE]   A:0CDF X:0CF5 Y:0001 P:eNvMxdizc
$C0/7591 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/7594 E2 20       SEP #$20       ; A = 8 bit
$C0/7596 A9 00       LDA #$00       ; Prepare DMA: channel 0 from $7F/0000 to CGRAM, $200 byte
$C0/7598 8D 02 43    STA $4302
$C0/759B A9 00       LDA #$00
$C0/759D 8D 03 43    STA $4303
$C0/75A0 A9 7F       LDA #$7F
$C0/75A2 8D 04 43    STA $4304
$C0/75A5 A9 00       LDA #$00
$C0/75A7 8D 05 43    STA $4305
$C0/75AA A9 02       LDA #$02
$C0/75AC 8D 06 43    STA $4306
$C0/75AF A9 00       LDA #$00
$C0/75B1 8D 00 43    STA $4300
$C0/75B4 A9 22       LDA #$22
$C0/75B6 8D 01 43    STA $4301
$C0/75B9 9C 21 21    STZ $2121      ; CGRAM Write address: $00
$C0/75BC A9 01       LDA #$01       ; Activate DMA
$C0/75BE 8D 0B 42    STA $420B
$C0/75C1 BF 03 00 C5 LDA $C50003,x[$C5:0CF8] A:0C01 X:0CF5 Y:0001 P:envMxdizc
$C0/75C5 F0 03       BEQ $03    [$75CA]      A:0C00 X:0CF5 Y:0001 P:envMxdiZc

code is missing here

$C0/75CA BF 04 00 C5 LDA $C50004,x[$C5:0CF9] A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/75CE D0 03       BNE $03    [$75D3]      A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/75D0 4C 63 76    JMP $7663  [$C0:7663]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc

code is missing here

$C0/7663 E2 20       SEP #$20                A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7665 BF 05 00 C5 LDA $C50005,x[$C5:0CFA] A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7669 8D 38 02    STA $0238  [$82:0238]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/766C BF 06 00 C5 LDA $C50006,x[$C5:0CFB] A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7670 8D 37 02    STA $0237  [$82:0237]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7673 BF 07 00 C5 LDA $C50007,x[$C5:0CFC] A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7677 8D 3A 02    STA $023A  [$82:023A]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/767A BF 08 00 C5 LDA $C50008,x[$C5:0CFD] A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/767E 8D 39 02    STA $0239  [$82:0239]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7681 AD CF 04    LDA $04CF  [$82:04CF]   A:0C00 X:0CF5 Y:0001 P:envMxdiZc
$C0/7684 C9 03       CMP #$03                A:0C03 X:0CF5 Y:0001 P:envMxdizc
$C0/7686 D0 01       BNE $01    [$7689]      A:0C03 X:0CF5 Y:0001 P:envMxdiZC
$C0/7688 60          RTS                     A:0C03 X:0CF5 Y:0001 P:envMxdiZC

$C0/7D89 Graphic Settings/Data for $C0/73F1

   $C0/7D89 0B 42 00                ; Data Set #$01: Deactivate DMAs
   $C0/7D8C 0C 42 00                ; Data Set #$02: Deactivate HDMAs
   $C0/7D8F 01 21 00                ; Data Set #$03: Sprites at $0000, 8x8/16x16
   $C0/7D92 02 21 00                ; Data Set #$04: OAM Address: $00
   $C0/7D95 03 21 00                ; Data Set #$05: OAM Address: Low Table
   $C0/7D98 05 21 09                ; Data Set #$06: BG Mode 1, BG3 Priority bit
   $C0/7D9B 06 21 00                ; Data Set #$07: No Mosaic
   $C0/7D9E 07 21 6C                ; Data Set #$08: BG1 Tilemap at $6C00, no mirroring
   $C0/7DA1 08 21 70                ; Data Set #$09: BG2 Tilemap at $7000, no mirroring
   $C0/7DA4 09 21 74                ; Data Set #$0A: BG3 Tilemap at $7400, no mirroring
   $C0/7DA7 0B 21 33                ; Data Set #$0B: BG1/2 Tiles at $3000
   $C0/7DAA 0C 21 82                ; Data Set #$0C: BG3 Tiles at $2000, BG4 Tiles at $8000
   $C0/7DAD 0D 21 00                ; Data Set #$0D: BG1 HScroll #$0000
   $C0/7DB0 0D 21 00                ; Data Set #$0E: BG1 HScroll #$0000
   $C0/7DB3 0E 21 00                ; Data Set #$0F: BG1 VScroll #$0000
   $C0/7DB6 0E 21 00                ; Data Set #$10: BG1 VScroll #$0000
   $C0/7DB9 0F 21 00                ; Data Set #$11: BG2 HScroll #$0000
   $C0/7DBC 0F 21 00                ; Data Set #$12: BG2 HScroll #$0000
   $C0/7DBF 10 21 00                ; Data Set #$13: BG2 VScroll #$0000
   $C0/7DC2 10 21 00                ; Data Set #$14: BG2 VScroll #$0000
   $C0/7DC5 11 21 00                ; Data Set #$15: BG3 HScroll #$0000
   $C0/7DC8 11 21 00                ; Data Set #$16: BG3 HScroll #$0000
   $C0/7DCB 12 21 00                ; Data Set #$17: BG3 VScroll #$0000
   $C0/7DCE 12 21 00                ; Data Set #$18: BG3 VScroll #$0000
   $C0/7DD1 21 21 00                ; Data Set #$19: CGRAM Address $00
   $C0/7DD4 23 21 00                ; Data Set #$1A: Window BG1/BG2 Mask Settings
   $C0/7DD7 24 21 02                ; Data Set #$1B: Window BG3/BG4 Mask Settings: BG3 Window 1 Outside
   $C0/7DDA 25 21 00                ; Data Set #$1C: Window OBJ/MATH Mask Settings
   $C0/7DDD 26 21 FF                ; Data Set #$1D: Window 1 Left Position
   $C0/7DE0 27 21 00                ; Data Set #$1E: Window 1 Right Position
   $C0/7DE3 28 21 00                ; Data Set #$1F: Window 2 Left Position
   $C0/7DE6 29 21 FF                ; Data Set #$20: Window 2 Right Position
   $C0/7DE9 2A 21 00                ; Data Set #$21: Window Mask Logic for BGs
   $C0/7DEC 2B 21 00                ; Data Set #$22: Window Mask Logic for Sprites
   $C0/7DEF 2C 21 17                ; Data Set #$23: Main Screen Designation: BG1-3 and Sprites
   $C0/7DF2 2D 21 00                ; Data Set #$24: Subscreen Designation: Nothing
   $C0/7DF5 2E 21 04                ; Data Set #$25: Disable Main Screen BG3 inside the Window
   $C0/7DF8 2F 21 00                ; Data Set #$26: Nothing for Subscreen Disabling
   $C0/7DFB 30 21 00                ; Data Set #$27: Clear Color Math Register A
   $C0/7DFE 31 21 00                ; Data Set #$28: Clear Color Math Register B 
   $C0/7E01 32 21 00                ; Data Set #$29: Clear Color Math Subscreen Backdrop
   $C0/7E04 33 21 00                ; Data Set #$2A: Clear Display Control Special function gizmo trickery
   $C0/7E07 81 21 00                ; Data Set #$2B: Clear WRAM Address
   $C0/7E0A 82 21 00                ; Data Set #$2C: Clear WRAM Address
   $C0/7E0D 83 21 00                ; Data Set #$2D: Clear WRAM Address

$C0/8772 ? (Use Jump Table at $C0/87A3)

This subroutine uses the Jump Table $87A3, according to the value in the address in $C6-8.

$C0/8772 E2 20       SEP #$20       ; A = 8 bit
$C0/8774 C2 10       REP #$10       ; X/Y = 16 bit
$C0/8776 A0 00 00    LDY #$0000
$C0/8779 B7 C6       LDA [$C6],y    ; Load byte from $C6-8 (Index for the Jump Table)
$C0/877B 85 0F       STA $0F        ; Buffer Jump Table Index for 16-bit Loading
$C0/877D 64 10       STZ $10        ; Clear High Byte for 16-bit Loading
$C0/877F C2 20       REP #$20       ; A = 16 bit
$C0/8781 A5 0F       LDA $0F        ; The afforementioned 16-bit loading
$C0/8783 0A          ASL A          ; multiply by 2 (Each Jump Table entry is of course 2 bytes in size)
$C0/8784 AA          TAX            ; Transfer in X as Index for Jump Table
$C0/8785 7C A3 87    JMP ($87A3,x)

$C0/8794 Increment Address of the next Jump Table Pointer for $C0/8772

Increments the Address in $C6 and returns to $8772. This way, it changes the next Index for the Jump Table at $87A3.

This subroutine can be entered at different points, depending on how often $C6/$C7 shall be incremented.

$C0/8794 C2 20       REP #$20
$C0/8796 E6 C6       INC $C6
$C0/8798 C2 20       REP #$20
$C0/879A E6 C6       INC $C6
$C0/879C C2 20       REP #$20
$C0/879E E6 C6       INC $C6
$C0/87A0 4C 72 87    JMP $8772

$C0/87A3 Jump Table for $C0/8772

19 88
28 88
37 88
46 88
5F 88
78 88
A5 88
E8 88
09 89
15 89
31 89
C8 89
16 8A
58 8A
7F 8A
A6 8A
CD 8A
F4 8A
1B 8B
42 8B
60 8B

$C0/8819 ?

$C0/8819 E2 20       SEP #$20                A:0000 X:0000 Y:0000 P:envmxdiZc
$C0/881B C2 10       REP #$10                A:0000 X:0000 Y:0000 P:envMxdiZc
$C0/881D A0 01 00    LDY #$0001              A:0000 X:0000 Y:0000 P:envMxdiZc
$C0/8820 B7 C6       LDA [$C6],y[$C2:2C7E]   A:0000 X:0000 Y:0001 P:envMxdizc
$C0/8822 8D E4 01    STA $01E4  [$82:01E4]   A:0000 X:0000 Y:0001 P:envMxdiZc
$C0/8825 4C 98 87    JMP $8798      ; Increment $C6 twice and use Jump Table

$C0/8828 ?

$C0/8828 E2 20       SEP #$20                A:0002 X:0002 Y:0000 P:envmxdizc
$C0/882A C2 10       REP #$10                A:0002 X:0002 Y:0000 P:envMxdizc
$C0/882C A0 01 00    LDY #$0001              A:0002 X:0002 Y:0000 P:envMxdizc
$C0/882F B7 C6       LDA [$C6],y[$C2:2C80]   A:0002 X:0002 Y:0001 P:envMxdizc
$C0/8831 8D E5 01    STA $01E5  [$82:01E5]   A:0005 X:0002 Y:0001 P:envMxdizc
$C0/8834 4C 98 87    JMP $8798      ; Increment $C6 twice and use Jump Table

$C0/8837 ?

$C0/8837 E2 20       SEP #$20                A:0004 X:0004 Y:0000 P:envmxdizc
$C0/8839 C2 10       REP #$10                A:0004 X:0004 Y:0000 P:envMxdizc
$C0/883B A0 01 00    LDY #$0001              A:0004 X:0004 Y:0000 P:envMxdizc
$C0/883E B7 C6       LDA [$C6],y[$C2:29FF]   A:0004 X:0004 Y:0001 P:envMxdizc
$C0/8840 8D E6 01    STA $01E6  [$82:01E6]   A:0004 X:0004 Y:0001 P:envMxdizc
$C0/8843 4C 98 87    JMP $8798      ; Increment $C6 twice and use Jump Table

$C0/8846 ?

$C0/8846 E2 30       SEP #$30                A:0006 X:0006 Y:0000 P:envmxdizc
$C0/8848 AD E4 01    LDA $01E4  [$82:01E4]   A:0006 X:0006 Y:0000 P:envMXdizc
$C0/884B 0A          ASL A                   A:0000 X:0006 Y:0000 P:envMXdiZc
$C0/884C AA          TAX                     A:0000 X:0006 Y:0000 P:envMXdiZc
$C0/884D FC 53 88    JSR ($8853,x)[$C0:73F1] A:0000 X:0000 Y:0000 P:envMXdiZc
$C0/8850 4C 98 87    JMP $8798      ; Increment $C6 twice and use Jump Table

$C0/8853 Jump Table for $C0/8846

$C0/8853 F1 73
$C0/8855 F1 73
$C0/8857 60 87
$C0/8859 83 B6
$C0/885B F1 73
$C0/885D 

$C0/8B83 ?

$C0/8B83 E2 30       SEP #$30                A:002C X:002C Y:0000 P:envmxdizc
$C0/8B85 A0 01       LDY #$01                A:002C X:002C Y:0000 P:envMXdizc
$C0/8B87 B7 C6       LDA [$C6],y[$C2:2C82]   A:002C X:002C Y:0001 P:envMXdizc
$C0/8B89 AA          TAX                     A:0008 X:002C Y:0001 P:envMXdizc
$C0/8B8A C8          INY                     A:0008 X:0008 Y:0001 P:envMXdizc
$C0/8B8B B7 C6       LDA [$C6],y[$C2:2C83]   A:0008 X:0008 Y:0002 P:envMXdizc
$C0/8B8D 9D CF 04    STA $04CF,x[$82:04D7]   A:00FF X:0008 Y:0002 P:eNvMXdizc
$C0/8B90 4C 94 87    JMP $8794      ; Increment $C6 thrice and use Jump Table

$C0/AB3F ?

$C0/AB3F E2 20       SEP #$20       ; UNNECESSARY LINE
$C0/AB41 C2 10       REP #$10       ; X/Y = 16 bit
$C0/AB43 E2 20       SEP #$20       ; A = 8 bit
$C0/AB45 A9 00       LDA #$00                A:8B7F X:0028 Y:0001 P:eNvMxdizc
$C0/AB47 8D E4 01    STA $01E4  [$82:01E4]   A:8B00 X:0028 Y:0001 P:envMxdiZc
$C0/AB4A A9 05       LDA #$05                A:8B00 X:0028 Y:0001 P:envMxdiZc
$C0/AB4C 8D E5 01    STA $01E5  [$82:01E5]   A:8B05 X:0028 Y:0001 P:envMxdizc
$C0/AB4F AD D7 04    LDA $04D7  [$82:04D7]   A:8B05 X:0028 Y:0001 P:envMxdizc
$C0/AB52 48          PHA                     A:8BFF X:0028 Y:0001 P:eNvMxdizc
$C0/AB53 9C D7 04    STZ $04D7  [$82:04D7]   A:8BFF X:0028 Y:0001 P:eNvMxdizc
$C0/AB56 20 13 83    JSR $8313  [$C0:8313]   A:8BFF X:0028 Y:0001 P:eNvMxdizc
$C0/AB59 A9 00       LDA #$00                A:8082 X:FFFF Y:0001 P:eNvMxdizc
$C0/AB5B 8F 00 00 7F STA $7F0000[$7F:0000]   A:8000 X:FFFF Y:0001 P:envMxdiZc
$C0/AB5F 8D 02 21    STA $2102  [$82:2102]   A:8000 X:FFFF Y:0001 P:envMxdiZc
$C0/AB62 8D 03 21    STA $2103  [$82:2103]   A:8000 X:FFFF Y:0001 P:envMxdiZc
$C0/AB65 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/AB71 A9 01       LDA #$01       ; Activate DMA
$C0/AB73 8D 0B 42    STA $420B
$C0/AB76 A9 EB       LDA #$EB       ; Data to Decompress at: $D1/E8EB
$C0/AB78 8D DC 01    STA $01DC
$C0/AB7B A9 E8       LDA #$E8
$C0/AB7D 8D DD 01    STA $01DD
$C0/AB80 A9 D1       LDA #$D1
$C0/AB82 8D DE 01    STA $01DE
$C0/AB85 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/AB88 A9 00       LDA #$00       ; Set VRAM Write Address to $0000
$C0/AB8A 8D 16 21    STA $2116
$C0/AB8D A9 00       LDA #$00
$C0/AB8F 8D 17 21    STA $2117
$C0/AB92 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/AB94 8D 15 21    STA $2115
$C0/AB97 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/ABA3 A9 01       LDA #$01       ; Activate DMA
$C0/ABA5 8D 0B 42    STA $420B
$C0/ABA8 A9 00       LDA #$00       ; Set VRAM Write Address to $6000
$C0/ABAA 8D 16 21    STA $2116
$C0/ABAD A9 60       LDA #$60
$C0/ABAF 8D 17 21    STA $2117
$C0/ABB2 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/ABB4 8D 15 21    STA $2115
$C0/ABB7 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/ABC3 A9 01       LDA #$01       ; Activate DMA
$C0/ABC5 8D 0B 42    STA $420B
$C0/ABC8 A9 25       LDA #$25       ; Data to Decompress at: $C7/F725
$C0/ABCA 8D DC 01    STA $01DC
$C0/ABCD A9 F7       LDA #$F7
$C0/ABCF 8D DD 01    STA $01DD
$C0/ABD2 A9 C7       LDA #$C7
$C0/ABD4 8D DE 01    STA $01DE
$C0/ABD7 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/ABDA A9 00       LDA #$00       ; Set VRAM Write Address to $1000
$C0/ABDC 8D 16 21    STA $2116
$C0/ABDF A9 10       LDA #$10
$C0/ABE1 8D 17 21    STA $2117
$C0/ABE4 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/ABE6 8D 15 21    STA $2115
$C0/ABE9 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/ABF5 A9 01       LDA #$01       ; Activate DMA
$C0/ABF7 8D 0B 42    STA $420B
$C0/ABFA A9 99       LDA #$99       ; Data to Decompress at: $DF/F099
$C0/ABFC 8D DC 01    STA $01DC
$C0/ABFF A9 F0       LDA #$F0
$C0/AC01 8D DD 01    STA $01DD
$C0/AC04 A9 DF       LDA #$DF
$C0/AC06 8D DE 01    STA $01DE
$C0/AC09 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/AC0C A9 00       LDA #$00       ; Set VRAM Write Address to $2000
$C0/AC0E 8D 16 21    STA $2116
$C0/AC11 A9 20       LDA #$20
$C0/AC13 8D 17 21    STA $2117
$C0/AC16 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/AC18 8D 15 21    STA $2115
$C0/AC1B 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/AC27 A9 01       LDA #$01       ; Activate DMA
$C0/AC29 8D 0B 42    STA $420B
$C0/AC2C A9 CF       LDA #$CF       ; Data to Decompress at: $C5/FFCF
$C0/AC2E 8D DC 01    STA $01DC
$C0/AC31 A9 FF       LDA #$FF
$C0/AC33 8D DD 01    STA $01DD
$C0/AC36 A9 C5       LDA #$C5
$C0/AC38 8D DE 01    STA $01DE
$C0/AC3B 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/AC3E A9 00       LDA #$00       ; Set VRAM Write Address to $5000
$C0/AC40 8D 16 21    STA $2116
$C0/AC43 A9 50       LDA #$50
$C0/AC45 8D 17 21    STA $2117
$C0/AC48 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/AC4A 8D 15 21    STA $2115
$C0/AC4D 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/AC59 A9 01       LDA #$01       ; Activate DMA
$C0/AC5B 8D 0B 42    STA $420B
$C0/AC5E A9 00       LDA #$00       ; Set VRAM Write Address to $5C00
$C0/AC60 8D 16 21    STA $2116
$C0/AC63 A9 5C       LDA #$5C
$C0/AC65 8D 17 21    STA $2117
$C0/AC68 A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/AC6A 8D 15 21    STA $2115
$C0/AC6D 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/AC79 A9 01       LDA #$01       ; Activate DMA
$C0/AC7B 8D 0B 42    STA $420B
$C0/AC7E A9 5E       LDA #$5E       ; Data to Decompress at: $DF/DF5E
$C0/AC80 8D DC 01    STA $01DC
$C0/AC83 A9 DF       LDA #$DF
$C0/AC85 8D DD 01    STA $01DD
$C0/AC88 A9 DF       LDA #$DF
$C0/AC8A 8D DE 01    STA $01DE
$C0/AC8D 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/AC90 A9 00       LDA #$00       ; Set VRAM Write Address to $4F00
$C0/AC92 8D 16 21    STA $2116
$C0/AC95 A9 4F       LDA #$4F
$C0/AC97 8D 17 21    STA $2117
$C0/AC9A A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/AC9C 8D 15 21    STA $2115
$C0/AC9F 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/ACAB A9 01       LDA #$01       ; Activate DMA
$C0/ACAD 8D 0B 42    STA $420B
$C0/ACB0 A9 E0       LDA #$E0       ; Data to Decompress at: $CF/E3E0
$C0/ACB2 8D DC 01    STA $01DC
$C0/ACB5 A9 E3       LDA #$E3
$C0/ACB7 8D DD 01    STA $01DD
$C0/ACBA A9 CF       LDA #$CF
$C0/ACBC 8D DE 01    STA $01DE
$C0/ACBF 20 37 EB    JSR $EB37      ; Graphics Decompression to $7F/0000 (Setup A)
$C0/ACC2 A9 80       LDA #$80       ; Set VRAM Write Address to $2080
$C0/ACC4 8D 16 21    STA $2116
$C0/ACC7 A9 20       LDA #$20
$C0/ACC9 8D 17 21    STA $2117
$C0/ACCC A9 80       LDA #$80       ; 16-bit transfer: Increment VRAM Write address after accessing $2119
$C0/ACCE 8D 15 21    STA $2115
$C0/ACD1 22 24 08 C0 JSL $C00824    ; Setup DMA

arguments are missing here

$C0/ACDD A9 01       LDA #$01       ; Activate DMA
$C0/ACDF 8D 0B 42    STA $420B
$C0/ACE2 C2 20       REP #$20                A:8001 X:FFFF Y:0001 P:envMxdizc
$C0/ACE4 A9 00 00    LDA #$0000              A:8001 X:FFFF Y:0001 P:envmxdizc
$C0/ACE7 8D ED 02    STA $02ED  [$82:02ED]   A:0000 X:FFFF Y:0001 P:envmxdiZc
$C0/ACEA A9 00 06    LDA #$0600              A:0000 X:FFFF Y:0001 P:envmxdiZc
$C0/ACED 8D EF 02    STA $02EF  [$82:02EF]   A:0600 X:FFFF Y:0001 P:envmxdizc
$C0/ACF0 A9 D0 07    LDA #$07D0              A:0600 X:FFFF Y:0001 P:envmxdizc
$C0/ACF3 8D F1 02    STA $02F1  [$82:02F1]   A:07D0 X:FFFF Y:0001 P:envmxdizc
$C0/ACF6 A9 90 08    LDA #$0890              A:07D0 X:FFFF Y:0001 P:envmxdizc
$C0/ACF9 8D F3 02    STA $02F3  [$82:02F3]   A:0890 X:FFFF Y:0001 P:envmxdizc
$C0/ACFC A9 50 09    LDA #$0950              A:0890 X:FFFF Y:0001 P:envmxdizc
$C0/ACFF 8D F5 02    STA $02F5  [$82:02F5]   A:0950 X:FFFF Y:0001 P:envmxdizc
$C0/AD02 A9 80 0E    LDA #$0E80              A:0950 X:FFFF Y:0001 P:envmxdizc
$C0/AD05 8D F7 02    STA $02F7  [$82:02F7]   A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD08 C2 20       REP #$20                A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD0A 64 61       STZ $61    [$00:0061]   A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD0C 64 63       STZ $63    [$00:0063]   A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD0E 64 65       STZ $65    [$00:0065]   A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD10 64 67       STZ $67    [$00:0067]   A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD12 E2 20       SEP #$20                A:0E80 X:FFFF Y:0001 P:envmxdizc
$C0/AD14 A9 09       LDA #$09       ; BG Mode 1, BG3 priority bit
$C0/AD16 8D 05 21    STA $2105
$C0/AD19 A9 61       LDA #$61       ; BG1 Tilemap at $6000, V-mirroring
$C0/AD1B 8D 07 21    STA $2107
$C0/AD1E A9 69       LDA #$69       ; BG2 Tilemap at $6800, V-mirroring
$C0/AD20 8D 08 21    STA $2108
$C0/AD23 A9 5C       LDA #$5C       ; BG3 Tilemap at $5C00
$C0/AD25 8D 09 21    STA $2109
$C0/AD28 A9 11       LDA #$11       ; BG1/2 Tiles at $1000
$C0/AD2A 8D 0B 21    STA $210B
$C0/AD2D A9 05       LDA #$05       ; BG3 Tiles at $5000, BG4 Tiles at $0000
$C0/AD2F 8D 0C 21    STA $210C
$C0/AD32 A9 17       LDA #$17       ; BG1-3 + Sprites on Main Screen
$C0/AD34 8D 2C 21    STA $212C
$C0/AD37 A9 01       LDA #$01       ; Set VRAM DMA Pipeline Workoff Flag
$C0/AD39 85 AA       STA $AA
$C0/AD3B 64 AF       STZ $AF    [$00:00AF]   A:0E01 X:FFFF Y:0001 P:envMxdizc
$C0/AD3D 20 8C 05    JSR $058C      ; Deactivate FBLANK
$C0/AD40 20 46 07    JSR $0746  [$C0:0746]   A:0E01 X:FFFF Y:0001 P:envMxdizc
$C0/AD43 20 45 05    JSR $0545  [$C0:0545]   A:0E01 X:FFFF Y:0001 P:envMxdizc
$C0/AD46 20 0E 32    JSR $320E  [$C0:320E]   A:0E01 X:FFFF Y:0001 P:envMxdizc
$C0/AD49 20 AE 07    JSR $07AE  [$C0:07AE]   A:2400 X:0C62 Y:0000 P:envMxdizc
$C0/AD4C 68          PLA                     A:2400 X:0C62 Y:0000 P:envMxdizc
$C0/AD4D 8D D7 04    STA $04D7  [$82:04D7]   A:24FF X:0C62 Y:0000 P:eNvMxdizc
$C0/AD50 6B          RTL                     A:24FF X:0C62 Y:0000 P:eNvMxdizc

$C0/EB37 Graphics Decompression Setup A

This subroutine decompresses (graphic) data to $7F/0000. There are flags that show if the compressed data can be transfered to $7F/0000 without editing (flag set) or if something of the already decompressed data can be repeated (flag cleared).

If something has to be repeated, the commands are:

1st byte: Address of the first byte to repeat, low byte
2nd byte: Address of the first byte to repeat, high byte
3rd byte: Number of bytes to repeat (minus three, e. g. "#$00" repeats three bytes, "#$04" repeats seven bytes and so on)

It uses several registers:

$0F - "Primary Data Load" Address Low Byte - points to general data at first, later to the compressed data
$10 - "Primary Data Load" Address High Byte - points to general data at first, later to the compressed data
$11 - "Primary Data Load" Address Bank - points to general data at first, later to the compressed data
$12 - Size of the decompressed data (number of bytes to do), Low Byte
$13 - Size of the decompressed data (number of bytes to do), High Byte

$15 - "Secondary Data Load" Address Low Byte - points to the decompression flags
$16 - "Secondary Data Load" Address High Byte - points to the decompression flags
$17 - "Secondary Data Load" Address Bank - points to the decompression flags
$18 - Counter of how many decompression flags already have been worked off (valid values: 0-7)
$19 - Buffer of the decompression flags, MSB gets worked off first, LSB last

$1E - Buffer for the Repition Load Address, Low Byte
$1F - Buffer for the Repition Load Address, High Byte
$20 - Buffer for the Repition Load Bank
$21 - Buffer for the number of bytes to repeat

$01E2 - Size of decompressed data (gets carried out of the subroutine)

Before this subroutine is executed, there has to be a 24-bit address set in $01DC-$01DE that points to the data for this subroutine. This data is structured as follows:

1st byte: Size of the decompressed data (number of bytes to do), Low Byte
2nd byte: Size of the decompressed data (number of bytes to do), High Byte
3rd byte: Offset between decompression flags and compressed data - Low Byte
4th byte: Offset between decompression flags and compressed data - High Byte
5th byte on: Decompression Flags (that is: repition flags)
5th byte + offset: Uncompressed Data / Commands for repition

$C0/EB37 08          PHP            ; Buffer Flag register, A/X/Y and Direct Bank on stack
$C0/EB38 C2 30       REP #$30
$C0/EB3A 48          PHA
$C0/EB3B DA          PHX
$C0/EB3C 5A          PHY
$C0/EB3D 8B          PHB
$C0/EB3E E2 20       SEP #$20       ; Rebuild the brought-in address from $01DC-E in $0F-$11
$C0/EB40 AD DE 01    LDA $01DE      ;   ($0F-$10 will always be #$0000, the address on the bank is in Y ...
$C0/EB43 85 11       STA $11        ;   (... and both will be combined in Indexed Loading, see below)
$C0/EB45 85 17       STA $17        ; Bank is stored in $17 (for the secondary 24-bit address)
$C0/EB47 C2 20       REP #$20       ; A = 16 bit
$C0/EB49 AC DC 01    LDY $01DC      ; Finish setting up the Address in $0F-$11 + Y
$C0/EB4C 64 0F       STZ $0F
$C0/EB4E 9C DF 01    STZ $01DF      ; Clear unused register ($01DF is only important in the other Setup)
$C0/EB51 B7 0F       LDA [$0F],y    ; Load first data double-byte (Decomp. data size = number of bytes to do)
$C0/EB53 85 12       STA $12        ; Store it in $12
$C0/EB55 8D E2 01    STA $01E2      ; Store it in $01E2 for a latter use
$C0/EB58 C8          INY            ; Increment Load Index twice
$C0/EB59 C8          INY
$C0/EB5A B7 0F       LDA [$0F],y    ; Load next data double-byte
$C0/EB5C 85 0F       STA $0F        ; Store in $0F as new offset of the Data Load Address
$C0/EB5E C8          INY            ; Increment Load Index twice
$C0/EB5F C8          INY
$C0/EB60 84 15       STY $15        ; Store Index (i. e. the Address without offset) in $15/6 for 24-bit Address
$C0/EB62 9C 81 21    STZ $2181      ; WRAM I/O Address: $0000 (on bank $7F, see below)
$C0/EB65 64 1E       STZ $1E        ; Clear Repition Address storage
$C0/EB67 64 21       STZ $21        ; Clear Repition Byte number storage
$C0/EB69 64 18       STZ $18        ; Clear counter for worked off decompression flags
$C0/EB6B E2 20       SEP #$20       ; Set #$7F as Direct Bank and as WRAM I/O Address bank ($2183)
$C0/EB6D A9 7F       LDA #$7F
$C0/EB6F 48          PHA
$C0/EB70 8D 83 21    STA $2183
$C0/EB73 AB          PLB
$C0/EB74 4C B5 EB    JMP $EBB5      ; Go to the actual Graphics Decompression

$C0/EB77 Graphics Decompression Setup B

This subroutine works basically the same as the one above, a minor difference:

Instead of storing the decompressed data to a fixed address ($7F/0000), you can decompress to a specified address. That address has to be carried into this subroutine in $01DF-$01E1.

$C0/EB77 08          PHP            ; Buffer Flag register, A/X/Y and Direct Bank on stack
$C0/EB78 C2 30       REP #$30
$C0/EB7A 48          PHA
$C0/EB7B DA          PHX
$C0/EB7C 5A          PHY
$C0/EB7D 8B          PHB
$C0/EB7E E2 20       SEP #$20       ; Rebuild the brought-in address from $01DC-E in $0F-$11
$C0/EB80 AD DE 01    LDA $01DE      ;   ($0F-$10 will always be #$0000, the address on the bank is in Y ...
$C0/EB83 85 11       STA $11        ;   (... and both will be combined in Indexed Loading, see below)
$C0/EB85 85 17       STA $17        ; Bank is stored in $17 (for the secondary 24-bit address)
$C0/EB87 C2 20       REP #$20       ; A = 16 bit
$C0/EB89 AC DC 01    LDY $01DC      ; Finish setting up the Address in $0F-$11 + Y
$C0/EB8C 64 0F       STZ $0F
$C0/EB8E B7 0F       LDA [$0F],y    ; Load first data double-byte (Decomp. data size = number of bytes to do)
$C0/EB90 85 12       STA $12        ; Store it in $12
$C0/EB92 8D E2 01    STA $01E2      ; Store it in $01E2 for a latter use
$C0/EB95 C8          INY            ; Increment Load Index twice
$C0/EB96 C8          INY
$C0/EB97 B7 0F       LDA [$0F],y    ; Load next data double-byte
$C0/EB99 85 0F       STA $0F        ; Store in $0F as new offset of the Data Load Address
$C0/EB9B C8          INY            ; Increment Load Index twice
$C0/EB9C C8          INY
$C0/EB9D 84 15       STY $15        ; Store Index (i. e. the Address without offset) in $15/6 for 24-bit Address
$C0/EB9F AD DF 01    LDA $01DF      ; Set destination of the decompressed data in WRAM Address registers
$C0/EBA2 8D 81 21    STA $2181
$C0/EBA5 64 1E       STZ $1E        ; Clear Repition Address storage
$C0/EBA7 64 21       STZ $21        ; Clear Repition Byte number storage
$C0/EBA9 64 18       STZ $18        ; Clear counter for worked off decompression flags
$C0/EBAB E2 20       SEP #$20       ; Set $7F as Direct Bank and as WRAM I/O Address bank ($2183)
$C0/EBAD AD E1 01    LDA $01E1      ; Set the missing bank of the decompressed data in WRAM Address registers...
$C0/EBB0 48          PHA            ; ... and set it as Direct Bank
$C0/EBB1 8D 83 21    STA $2183
$C0/EBB4 AB          PLB

$C0/EBB5 Graphics Decompression

These are the "guts" of the graphics decompression. This is executed through one of the two preparation subroutines right above.

See the description at $C0/EB37 or $C0/EB77 for more detail

$C0/EBB5 A2 00 00    LDX #$0000     ; Clear X for convenience (after this X isn't used here)
$C0/EBB8 80 0C       BRA $0C        ; [$EBC6] Go to Decompression Main Handler

$C0/EBBA E2 20       SEP #$20       ; Remove worked off flag from decompression flag buffer
$C0/EBBC 06 19       ASL $19
$C0/EBBE E6 18       INC $18        ; Increment counter of worked off flags
$C0/EBC0 A9 07       LDA #$07       ; Have 8 flags been worked off?
$C0/EBC2 25 18       AND $18
$C0/EBC4 D0 0A       BNE $0A        ; [$EBD0] Branch if not, else: load next flag value into buffer

$C0/EBC6 A7 15       LDA [$15]      ; Load next decompression flag byte from data and store it in $19
$C0/EBC8 85 19       STA $19
$C0/EBCA C2 20       REP #$20       ; 16-bit INC secondary Load Address after loading
$C0/EBCC E6 15       INC $15
$C0/EBCE E2 20       SEP #$20
$C0/EBD0 A5 19       LDA $19        ; Check next decompression flag
$C0/EBD2 10 10       BPL $10        ; [$EBE4] Branch if it is not set
$C0/EBD4 B7 0F       LDA [$0F],y    ; If decompression flag is SET, one byte gets transfered to WRAM as it is
$C0/EBD6 8F 80 21 00 STA $002180
$C0/EBDA C8          INY            ; Increment Load Index
$C0/EBDB C2 20       REP #$20       ; Decrement the number of bytes to do
$C0/EBDD C6 12       DEC $12
$C0/EBDF D0 D9       BNE $D9        ; [$EBBA] Loop if there is still something left to do
$C0/EBE1 4C 1B EC    JMP $EC1B      ; Exit

$C0/EBE4 C2 20       REP #$20       ; This is executed if something has to be repeated
$C0/EBE6 B7 0F       LDA [$0F],y    ; Load first Double Byte (address of the data to repeat)
$C0/EBE8 18          CLC
$C0/EBE9 6F DF 01 00 ADC $0001DF    ; Add offset of the Destination of the Decompressed Data (if Setup B was used)
$C0/EBED 85 1E       STA $1E        ; Store as Load address (for this repition)
$C0/EBEF C8          INY            ; Increment Load Index (of the data) twice
$C0/EBF0 C8          INY
$C0/EBF1 B7 0F       LDA [$0F],y    ; Load third byte (number of bytes to transfer)
$C0/EBF3 29 FF 00    AND #$00FF
$C0/EBF6 18          CLC
$C0/EBF7 69 03 00    ADC #$0003     ; Do 3 more bytes than the byte originally said
$C0/EBFA 85 21       STA $21        ; Store this counter value in temp store
$C0/EBFC C8          INY            ; Increment Load Index (of the data)
$C0/EBFD 5A          PHY            ; Buffer Load Index
$C0/EBFE A0 00 00    LDY #$0000     ; Clear Y as new Index for the Repition's Data Loading
$C0/EC01 E2 20       SEP #$20       ; A = 8 bit
$C0/EC03 B1 1E       LDA ($1E),y    ; Load data byte
$C0/EC05 8F 80 21 00 STA $002180    ; Store it to the decompressed data
$C0/EC09 C8          INY            ; Increment Load Index (for the repition)
$C0/EC0A C2 20       REP #$20       ; A = 16 bit
$C0/EC0C C6 21       DEC $21        ; 16-bit DEC number of bytes to repeat
$C0/EC0E C6 12       DEC $12        ; 16-bit DEC number of bytes to do (overall)
$C0/EC10 F0 08       BEQ $08        ; [$EC1A] Exit if all bytes are done
$C0/EC12 A5 21       LDA $21        ; Check if bytes to repeat has run out by now
$C0/EC14 10 EB       BPL $EB        ; [$EC01] Loop if not
$C0/EC16 7A          PLY            ; If it has, restore the Data Load Index...
$C0/EC17 4C BA EB    JMP $EBBA      ; [$C0:EBBA] ... end loop
$C0/EC1A 7A          PLY            ; Pull Data Load index from stack (executed when the decomp ended on a repition)
$C0/EC1B AB          PLB            ; Restore Flag register, A/X/Y and Direct Bank
$C0/EC1C C2 30       REP #$30
$C0/EC1E 7A          PLY
$C0/EC1F FA          PLX
$C0/EC20 68          PLA
$C0/EC21 28          PLP
$C0/EC22 60          RTS

$00/FF90 PROGRAM START

$00/FF90 78          SEI            ; Disable Interrupts
$00/FF91 18          CLC            ; Native Mode
$00/FF92 FB          XCE
$00/FF93 D8          CLD            ; Deactivate Decimal Mode
$00/FF94 5C 00 00 C0 JMP $C00000    ; Go to whole Boot Sequence / FastROM/HiROM

$00/FF98 NMI HANDLER

$00/FF98 5C E7 01 C0 JMP $C001E7    ; Jump to actual NMI Handler / FastROM/HiROM

Internal Data for Snoopy Concert
ROM Map • RAM Map • Text Table • Notes • Tutorials