mirror of https://github.com/pret/pokecrystal.git
Recomment lz deecompression.
This commit is contained in:
parent
20444d2f63
commit
21708a2271
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@ -1,19 +1,14 @@
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FarDecompress:: ; b40
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; Decompress graphics data at a:hl to de
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; Decompress graphics data from a:hl to de.
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; put a away for a sec
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ld [$c2c4], a
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; save bank
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ld a, [hROMBank]
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push af
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; bankswitch
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ld a, [$c2c4]
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rst Bankswitch
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; what we came here for
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call Decompress
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; restore bank
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pop af
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rst Bankswitch
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ret
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@ -22,170 +17,158 @@ FarDecompress:: ; b40
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Decompress:: ; b50
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; Pokemon Crystal uses an lz variant for compression.
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; This is mainly (but not necessarily) used for graphics.
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; This is mainly used for graphics, but the intro's
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; tilemaps also use this compression.
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; This function decompresses lz-compressed data at hl to de.
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; This function decompresses lz-compressed data from hl to de.
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; Basic rundown:
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; A typical control command consists of:
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; -the command (bits 5-7)
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; -the count (bits 0-4)
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; -and any additional params
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; $ff is used as a terminator.
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LZ_END EQU $ff ; Compressed data is terminated with $ff.
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; Commands:
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; A typical control command consists of:
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; 0: literal
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; literal data for some number of bytes
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; 1: iterate
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; one byte repeated for some number of bytes
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; 2: alternate
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; two bytes alternated for some number of bytes
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; 3: zero (whitespace)
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; 0x00 repeated for some number of bytes
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LZ_CMD EQU %11100000 ; command id (bits 5-7)
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LZ_LEN EQU %00011111 ; length n (bits 0-4)
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; Repeater control commands have a signed parameter used to determine the start point.
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; Wraparound is simulated:
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; Positive values are added to the start address of the decompressed data
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; and negative values are subtracted from the current position.
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; Additional parameters are read during command execution.
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; 4: repeat
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; repeat some number of bytes from decompressed data
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; 5: flipped
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; repeat some number of flipped bytes from decompressed data
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; ex: $ad = %10101101 -> %10110101 = $b5
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; 6: reverse
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; repeat some number of bytes in reverse from decompressed data
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; If the value in the count needs to be larger than 5 bits,
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; control code 7 can be used to expand the count to 10 bits.
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; Commands:
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; A new control command is read in bits 2-4.
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; The new 10-bit count is split:
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; bits 0-1 contain the top 2 bits
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; another byte is added containing the latter 8
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LZ_LITERAL EQU 0 << 5 ; Read literal data for n bytes.
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LZ_ITERATE EQU 1 << 5 ; Write the same byte for n bytes.
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LZ_ALTERNATE EQU 2 << 5 ; Alternate two bytes for n bytes.
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LZ_ZERO EQU 3 << 5 ; Write 0 for n bytes.
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; So, the structure of the control command becomes:
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; 111xxxyy yyyyyyyy
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; | | | |
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; | | our new count
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; | the control command for this count
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; 7 (this command)
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; For more information, refer to the code below and in extras/gfx.py .
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; Another class of commands reuses data from the decompressed output.
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LZ_RW EQU 2 + 5 ; bit
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; save starting output address
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; These commands take a signed offset to start copying from.
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; Wraparound is simulated.
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; Positive offsets (15-bit) are added to the start address.
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; Negative offsets (7-bit) are subtracted from the current position.
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LZ_REPEAT EQU 4 << 5 ; Repeat n bytes from the offset.
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LZ_FLIP EQU 5 << 5 ; Repeat n bitflipped bytes.
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LZ_REVERSE EQU 6 << 5 ; Repeat n bytes in reverse.
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; If the value in the count needs to be larger than 5 bits,
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; LZ_LONG can be used to expand the count to 10 bits.
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LZ_LONG EQU 7 << 5
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; A new control command is read in bits 2-4.
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; The top two bits of the length are bits 0-1.
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; Another byte is read containing the bottom 8 bits.
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LZ_LONG_HI EQU %00000011
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; In other words, the structure of the command becomes
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; 111xxxyy yyyyyyyy
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; x: the new control command
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; y: the length
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; For more information, refer to the code below and in extras/gfx.py.
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; Save the output address
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; for rewrite commands.
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ld a, e
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ld [$c2c2], a
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ld a, d
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ld [$c2c3], a
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ld [$c2c2 + 1], a
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.loop
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; get next byte
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.Main
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ld a, [hl]
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; done?
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cp $ff ; end
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cp LZ_END
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ret z
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; get control code
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and %11100000
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and LZ_CMD
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; 10-bit param?
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cp $e0 ; LZ_HI
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jr nz, .normal
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cp LZ_LONG
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jr nz, .short
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.long
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; The count is now 10 bits.
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; 10-bit param:
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; get next 3 bits (%00011100)
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; Read the next 3 bits.
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; %00011100 -> %11100000
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ld a, [hl]
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add a
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add a ; << 3
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add a
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; this is our new control code
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and %11100000
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; This is our new control code.
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and LZ_CMD
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push af
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; get param hi
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ld a, [hli]
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and %00000011
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and LZ_LONG_HI
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ld b, a
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; get param lo
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ld a, [hli]
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ld c, a
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; read at least 1 byte
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; read at least 1 byte
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inc bc
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jr .readers
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jr .command
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.normal
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; push control code
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.short
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push af
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; get param
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ld a, [hli]
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and %00011111
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and LZ_LEN
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ld c, a
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ld b, $0
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; read at least 1 byte
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ld b, 0
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; read at least 1 byte
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inc c
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.readers
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; let's get started
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; inc loop counts since we bail as soon as they hit 0
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.command
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; Increment loop counts.
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; We bail the moment they hit 0.
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inc b
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inc c
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; get control code
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pop af
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; command type
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bit 7, a ; 80, a0, c0
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jr nz, .repeatertype
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; literals
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cp $20 ; LZ_ITER
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jr z, .iter
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cp $40 ; LZ_ALT
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jr z, .alt
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cp $60 ; LZ_ZERO
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jr z, .zero
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; else $00
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bit LZ_RW, a
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jr nz, .rewrite
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; 00 ; LZ_LIT
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; literal data for bc bytes
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.loop1
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; done?
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cp LZ_ITERATE
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jr z, .Iter
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cp LZ_ALTERNATE
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jr z, .Alt
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cp LZ_ZERO
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jr z, .Zero
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.Literal
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; Read literal data for bc bytes.
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.lloop
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dec c
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jr nz, .next1
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jr nz, .lnext
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dec b
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jp z, .loop
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jp z, .Main
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.next1
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.lnext
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ld a, [hli]
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ld [de], a
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inc de
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jr .loop1
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jr .lloop
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; 20 ; LZ_ITER
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; write byte for bc bytes
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.iter
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.Iter
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; Write the same byte for bc bytes.
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ld a, [hli]
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.iterloop
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dec c
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jr nz, .iternext
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dec b
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jp z, .loop
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jp z, .Main
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.iternext
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ld [de], a
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@ -193,88 +176,79 @@ Decompress:: ; b50
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jr .iterloop
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; 40 ; LZ_ALT
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; alternate two bytes for bc bytes
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; next pair
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.alt
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; done?
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.Alt
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; Alternate two bytes for bc bytes.
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dec c
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jr nz, .alt0
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jr nz, .anext1
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dec b
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jp z, .altclose0
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; alternate for bc
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.alt0
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jp z, .adone1
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.anext1
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ld a, [hli]
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ld [de], a
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inc de
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dec c
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jr nz, .alt1
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; done?
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jr nz, .anext2
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dec b
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jp z, .altclose1
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.alt1
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jp z, .adone2
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.anext2
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ld a, [hld]
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ld [de], a
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inc de
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jr .alt
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; skip past the bytes we were alternating
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.altclose0
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jr .Alt
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; Skip past the bytes we were alternating.
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.adone1
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inc hl
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.altclose1
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.adone2
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inc hl
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jr .loop
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jr .Main
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; 60 ; LZ_ZERO
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; write 00 for bc bytes
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.zero
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.Zero
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; Write 0 for bc bytes.
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xor a
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.zeroloop
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.zloop
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dec c
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jr nz, .zeronext
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jr nz, .znext
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dec b
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jp z, .loop
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jp z, .Main
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.zeronext
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.znext
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ld [de], a
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inc de
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jr .zeroloop
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jr .zloop
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; repeats
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; 80, a0, c0
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; repeat decompressed data from output
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.repeatertype
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.rewrite
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; Repeat decompressed data from output.
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push hl
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push af
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; get next byte
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ld a, [hli]
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; absolute?
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bit 7, a
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jr z, .absolute
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; relative
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; a = -a
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and %01111111 ; forget the bit we just looked at
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ld a, [hli]
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bit 7, a ; sign
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jr z, .positive
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.negative
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; hl = de - a
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; Since we can't subtract a from de,
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; Make it negative and add de.
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and %01111111
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cpl
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; add de (current output address)
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add e
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ld l, a
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ld a, $ff ; -1
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ld a, -1
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adc d
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ld h, a
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jr .repeaters
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jr .ok
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.absolute
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; get next byte (lo)
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.positive
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; Positive offsets are two bytes.
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ld l, [hl]
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; last byte (hi)
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ld h, a
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; add starting output address
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; add to starting output address
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ld a, [$c2c2]
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add l
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ld l, a
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@ -282,86 +256,86 @@ Decompress:: ; b50
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adc h
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ld h, a
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.repeaters
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.ok
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pop af
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cp $80 ; LZ_REPEAT
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jr z, .repeat
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cp $a0 ; LZ_FLIP
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jr z, .flip
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cp $c0 ; LZ_REVERSE
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jr z, .reverse
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; e0 -> 80
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cp LZ_REPEAT
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jr z, .Repeat
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cp LZ_FLIP
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jr z, .Flip
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cp LZ_REVERSE
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jr z, .Reverse
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; 80 ; LZ_REPEAT
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; repeat some decompressed data
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.repeat
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; done?
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; Since LZ_LONG is command 7,
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; only commands 0-6 are passed in.
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; This leaves room for an extra command 7.
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; However, lengths longer than 768
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; would be interpreted as LZ_END.
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; For now, it defaults to LZ_REPEAT.
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.Repeat
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; Copy decompressed data for bc bytes.
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dec c
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jr nz, .repeatnext
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jr nz, .rnext
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dec b
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jr z, .cleanup
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jr z, .donerw
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.repeatnext
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.rnext
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ld a, [hli]
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ld [de], a
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inc de
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jr .repeat
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jr .Repeat
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; a0 ; LZ_FLIP
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; repeat some decompressed data w/ flipped bit order
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.flip
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.Flip
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; Copy bitflipped decompressed data for bc bytes.
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dec c
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jr nz, .flipnext
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jr nz, .fnext
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dec b
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jp z, .cleanup
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jp z, .donerw
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.flipnext
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.fnext
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ld a, [hli]
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push bc
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ld bc, $0008
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lb bc, 0, 8
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.fliploop
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.floop
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rra
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rl b
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dec c
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jr nz, .fliploop
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jr nz, .floop
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ld a, b
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pop bc
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ld [de], a
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inc de
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jr .flip
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jr .Flip
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; c0 ; LZ_REVERSE
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; repeat some decompressed data in reverse
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.reverse
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.Reverse
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; Copy reversed decompressed data for bc bytes.
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dec c
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jr nz, .reversenext
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jr nz, .rvnext
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dec b
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jp z, .cleanup
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jp z, .donerw
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.reversenext
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.rvnext
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ld a, [hld]
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ld [de], a
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inc de
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jr .reverse
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jr .Reverse
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.cleanup
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; get type of repeat we just used
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.donerw
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pop hl
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; was it relative or absolute?
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bit 7, [hl]
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jr nz, .next
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; skip two bytes for absolute
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inc hl
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; skip one byte for relative
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inc hl ; positive offset is two bytes
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.next
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inc hl
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jp .loop
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jp .Main
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; c2f
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