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cc65/libsrc/zlib/inflatemem.s

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;
; Piotr Fusik, 21.09.2003
;
; unsigned __fastcall__ inflatemem (char* dest, const char* source);
;
.export _inflatemem
.import incsp2
.importzp sp, sreg, ptr1, ptr2, ptr3, ptr4, tmp1
; --------------------------------------------------------------------------
;
; Constants
;
; Maximum length of a Huffman code.
MAX_BITS = 15
; All Huffman trees are stored in the bitsCount, bitsPointer_l
; and bitsPointer_h arrays. There may be two trees: the literal/length tree
; and the distance tree, or just one - the temporary tree.
; Index in the mentioned arrays for the beginning of the literal/length tree
; or the temporary tree.
PRIMARY_TREE = 0
; Index in the mentioned arrays for the beginning of the distance tree.
DISTANCE_TREE = MAX_BITS
; Size of each array.
TREES_SIZE = 2*MAX_BITS
; --------------------------------------------------------------------------
;
; Page zero
;
; Pointer to the compressed data.
inputPointer = ptr1 ; 2 bytes
; Pointer to the uncompressed data.
outputPointer = ptr2 ; 2 bytes
; Local variables.
; As far as there is no conflict, same memory locations are used
; for different variables.
inflateDynamicBlock_cnt = ptr3 ; 1 byte
inflateCodes_src = ptr3 ; 2 bytes
buildHuffmanTree_src = ptr3 ; 2 bytes
getNextLength_last = ptr3 ; 1 byte
getNextLength_index = ptr3+1 ; 1 byte
buildHuffmanTree_ptr = ptr4 ; 2 bytes
fetchCode_ptr = ptr4 ; 2 bytes
getBits_tmp = ptr4 ; 1 byte
moveBlock_len = sreg ; 2 bytes
inflateDynamicBlock_np = sreg ; 1 byte
inflateDynamicBlock_nd = sreg+1 ; 1 byte
getBit_hold = tmp1 ; 1 byte
; --------------------------------------------------------------------------
;
; Code
;
_inflatemem:
; inputPointer = source
sta inputPointer
stx inputPointer+1
; outputPointer = dest
.ifpc02
lda (sp)
ldy #1
.else
ldy #0
lda (sp),y
iny
.endif
sta outputPointer
lda (sp),y
sta outputPointer+1
; ldy #1
sty getBit_hold
inflatemem_1:
; Get a bit of EOF and two bits of block type
ldx #3
lda #0
jsr getBits
lsr a
; A and Z contain block type, C contains EOF flag
; Save EOF flag
php
; Go to the routine decompressing this block
jsr callExtr
plp
bcc inflatemem_1
; C flag is set!
; return outputPointer - dest;
lda outputPointer
.ifpc02
sbc (sp) ; C flag is set
ldy #1
.else
ldy #0
sbc (sp),y ; C flag is set
iny
.endif
pha
lda outputPointer+1
sbc (sp),y
tax
pla
; pop dest
jmp incsp2
; --------------------------------------------------------------------------
; Go to proper block decoding routine.
callExtr:
bne inflateCompressedBlock
; --------------------------------------------------------------------------
; Decompress a 'stored' data block.
inflateCopyBlock:
; Ignore bits until byte boundary
ldy #1
sty getBit_hold
; Get 16-bit length
ldx #inputPointer
lda (0,x)
sta moveBlock_len
lda (inputPointer),y
sta moveBlock_len+1
; Skip the length and one's complement of it
lda #4
clc
adc inputPointer
sta inputPointer
bcc moveBlock
inc inputPointer+1
; jmp moveBlock
; --------------------------------------------------------------------------
; Copy block of length moveBlock_len from (0,x) to the output.
moveBlock:
ldy moveBlock_len
beq moveBlock_1
.ifpc02
.else
ldy #0
.endif
inc moveBlock_len+1
moveBlock_1:
lda (0,x)
.ifpc02
sta (outputPointer)
.else
sta (outputPointer),y
.endif
inc 0,x
bne moveBlock_2
inc 1,x
moveBlock_2:
inc outputPointer
bne moveBlock_3
inc outputPointer+1
moveBlock_3:
.ifpc02
dey
.else
dec moveBlock_len
.endif
bne moveBlock_1
dec moveBlock_len+1
bne moveBlock_1
rts
; --------------------------------------------------------------------------
; Decompress a Huffman-coded data block
; (A = 1: fixed, A = 2: dynamic).
inflateCompressedBlock:
lsr a
bne inflateDynamicBlock
; Note: inflateDynamicBlock may assume that A = 1
; --------------------------------------------------------------------------
; Decompress a Huffman-coded data block with default Huffman trees
; (defined by the DEFLATE format):
; literalCodeLength: 144 times 8, 112 times 9
; endCodeLength: 7
; lengthCodeLength: 23 times 7, 6 times 8
; distanceCodeLength: 30 times 5+DISTANCE_TREE, 2 times 8
; (two 8-bit codes from the primary tree are not used).
inflateFixedBlock:
ldx #159
stx distanceCodeLength+32
lda #8
inflateFixedBlock_1:
sta literalCodeLength-1,x
sta literalCodeLength+159-1,x
dex
bne inflateFixedBlock_1
ldx #112
; lda #9
inflateFixedBlock_2:
inc literalCodeLength+144-1,x ; sta
dex
bne inflateFixedBlock_2
ldx #24
; lda #7
inflateFixedBlock_3:
dec endCodeLength-1,x ; sta
dex
bne inflateFixedBlock_3
ldx #30
lda #5+DISTANCE_TREE
inflateFixedBlock_4:
sta distanceCodeLength-1,x
dex
bne inflateFixedBlock_4
beq inflateCodes ; branch always
; --------------------------------------------------------------------------
; Decompress a Huffman-coded data block, reading Huffman trees first.
inflateDynamicBlock:
; numberOfPrimaryCodes = 257 + getBits(5)
ldx #5
; lda #1
jsr getBits
sta inflateDynamicBlock_np
; numberOfDistanceCodes = 1 + getBits(5)
ldx #5
lda #1+29+1
jsr getBits
sta inflateDynamicBlock_nd
; numberOfTemporaryCodes = 4 + getBits(4)
lda #4
tax
jsr getBits
sta inflateDynamicBlock_cnt
; Get lengths of temporary codes in the order stored in tempCodeLengthOrder
txa ; lda #0
tay
inflateDynamicBlock_1:
ldx #3 ; A = 0
jsr getBits ; does not change Y
inflateDynamicBlock_2:
ldx tempCodeLengthOrder,y
sta literalCodeLength,x
lda #0
iny
cpy inflateDynamicBlock_cnt
bcc inflateDynamicBlock_1
cpy #19
bcc inflateDynamicBlock_2
ror literalCodeLength+19 ; C flag is set, so this will set b7
; Build the tree for temporary codes
jsr buildHuffmanTree
; Use temporary codes to get lengths of literal/length and distance codes
ldx #0
ldy #1
stx getNextLength_last
inflateDynamicBlock_3:
jsr getNextLength
sta literalCodeLength,x
inx
bne inflateDynamicBlock_3
inflateDynamicBlock_4:
jsr getNextLength
inflateDynamicBlock_5:
sta endCodeLength,x
inx
cpx inflateDynamicBlock_np
bcc inflateDynamicBlock_4
lda #0
cpx #1+29
bcc inflateDynamicBlock_5
inflateDynamicBlock_6:
jsr getNextLength
cmp #0
beq inflateDynamicBlock_7
adc #DISTANCE_TREE-1 ; C flag is set
inflateDynamicBlock_7:
sta endCodeLength,x
inx
cpx inflateDynamicBlock_nd
bcc inflateDynamicBlock_6
ror endCodeLength,x ; C flag is set, so this will set b7
; jmp inflateCodes
; --------------------------------------------------------------------------
; Decompress a data block basing on given Huffman trees.
inflateCodes:
jsr buildHuffmanTree
inflateCodes_1:
jsr fetchPrimaryCode
bcs inflateCodes_2
; Literal code
.ifpc02
sta (outputPointer)
.else
ldy #0
sta (outputPointer),y
.endif
inc outputPointer
bne inflateCodes_1
inc outputPointer+1
bcc inflateCodes_1 ; branch always
; End of block
inflateCodes_ret:
rts
inflateCodes_2:
beq inflateCodes_ret
; Restore a block from the look-behind buffer
jsr getValue
sta moveBlock_len
tya
jsr getBits
sta moveBlock_len+1
ldx #DISTANCE_TREE
jsr fetchCode
jsr getValue
sec
eor #$ff
adc outputPointer
sta inflateCodes_src
php
tya
jsr getBits
plp
eor #$ff
adc outputPointer+1
sta inflateCodes_src+1
ldx #inflateCodes_src
jsr moveBlock
beq inflateCodes_1 ; branch always
; --------------------------------------------------------------------------
; Build Huffman trees basing on code lengths (in bits).
; stored in the *CodeLength arrays.
; A byte with its highest bit set marks the end.
buildHuffmanTree:
lda #<literalCodeLength
sta buildHuffmanTree_src
lda #>literalCodeLength
sta buildHuffmanTree_src+1
; Clear bitsCount and bitsPointer_l
ldy #2*TREES_SIZE+1
lda #0
buildHuffmanTree_1:
sta bitsCount-1,y
dey
bne buildHuffmanTree_1
beq buildHuffmanTree_3 ; branch always
; Count number of codes of each length
buildHuffmanTree_2:
tax
inc bitsPointer_l,x
iny
bne buildHuffmanTree_3
inc buildHuffmanTree_src+1
buildHuffmanTree_3:
lda (buildHuffmanTree_src),y
bpl buildHuffmanTree_2
; Calculate a pointer for each length
ldx #0
lda #<sortedCodes
ldy #>sortedCodes
clc
buildHuffmanTree_4:
sta bitsPointer_l,x
tya
sta bitsPointer_h,x
lda bitsPointer_l+1,x
adc bitsPointer_l,x ; C flag is zero
bcc buildHuffmanTree_5
iny
buildHuffmanTree_5:
inx
cpx #TREES_SIZE
bcc buildHuffmanTree_4
lda #>literalCodeLength
sta buildHuffmanTree_src+1
ldy #0
bcs buildHuffmanTree_9 ; branch always
; Put codes into their place in sorted table
buildHuffmanTree_6:
beq buildHuffmanTree_7
tax
lda bitsPointer_l-1,x
sta buildHuffmanTree_ptr
lda bitsPointer_h-1,x
sta buildHuffmanTree_ptr+1
tya
ldy bitsCount-1,x
inc bitsCount-1,x
sta (buildHuffmanTree_ptr),y
tay
buildHuffmanTree_7:
iny
bne buildHuffmanTree_9
inc buildHuffmanTree_src+1
ldx #MAX_BITS-1
buildHuffmanTree_8:
lda bitsCount,x
sta literalCount,x
dex
bpl buildHuffmanTree_8
buildHuffmanTree_9:
lda (buildHuffmanTree_src),y
bpl buildHuffmanTree_6
rts
; --------------------------------------------------------------------------
; Decode next code length using temporary codes.
getNextLength:
stx getNextLength_index
dey
bne getNextLength_1
; Fetch a temporary code
jsr fetchPrimaryCode
; Temporary code 0..15: put this length
ldy #1
cmp #16
bcc getNextLength_2
; Temporary code 16: repeat last length 3 + getBits(2) times
; Temporary code 17: put zero length 3 + getBits(3) times
; Temporary code 18: put zero length 11 + getBits(7) times
tay
ldx tempExtraBits-16,y
lda tempBaseValue-16,y
jsr getBits
cpy #17
tay
txa ; lda #0
bcs getNextLength_2
getNextLength_1:
lda getNextLength_last
getNextLength_2:
sta getNextLength_last
ldx getNextLength_index
rts
; --------------------------------------------------------------------------
; Read a code basing on the primary tree.
fetchPrimaryCode:
ldx #PRIMARY_TREE
; jmp fetchCode
; --------------------------------------------------------------------------
; Read a code from input basing on the tree specified in X.
; Return low byte of this code in A.
; For the literal/length tree, the C flag is set if the code is non-literal.
fetchCode:
lda #0
fetchCode_1:
jsr getBit
rol a
inx
sec
sbc bitsCount-1,x
bcs fetchCode_1
adc bitsCount-1,x ; C flag is zero
cmp literalCount-1,x
sta fetchCode_ptr
ldy bitsPointer_l-1,x
lda bitsPointer_h-1,x
sta fetchCode_ptr+1
lda (fetchCode_ptr),y
rts
; --------------------------------------------------------------------------
; Decode low byte of a value (length or distance), basing on the code in A.
; The result is the base value for this code plus some bits read from input.
getValue:
tay
ldx lengthExtraBits-1,y
lda lengthBaseValue_l-1,y
pha
lda lengthBaseValue_h-1,y
tay
pla
; jmp getBits
; --------------------------------------------------------------------------
; Read X-bit number from the input and add it to A.
; Increment Y if overflow.
; If X > 8, read only 8 bits.
; On return X holds number of unread bits: X = (X > 8 ? X - 8 : 0);
getBits:
cpx #0
beq getBits_ret
.ifpc02
stz getBits_tmp
dec getBits_tmp
.else
pha
lda #$ff
sta getBits_tmp
pla
.endif
getBits_1:
jsr getBit
bcc getBits_2
sbc getBits_tmp ; C flag is set
bcc getBits_2
iny
getBits_2:
dex
beq getBits_ret
asl getBits_tmp
bmi getBits_1
getBits_ret:
rts
; --------------------------------------------------------------------------
; Read a single bit from input, return it in the C flag.
getBit:
lsr getBit_hold
bne getBit_ret
pha
.ifpc02
lda (inputPointer)
.else
sty getBit_hold
ldy #0
lda (inputPointer),y
ldy getBit_hold
.endif
inc inputPointer
bne getBit_1
inc inputPointer+1
getBit_1:
ror a ; C flag is set
sta getBit_hold
pla
getBit_ret:
rts
; --------------------------------------------------------------------------
;
; Constant data
;
.rodata
; --------------------------------------------------------------------------
; Arrays for the temporary codes.
; Order, in which lengths of the temporary codes are stored.
tempCodeLengthOrder:
.byte 16,17,18,0,8,7,9,6,10,5,11,4,12,3,13,2,14,1,15
; Base values.
tempBaseValue:
.byte 3,3,11
; Number of extra bits to read.
tempExtraBits:
.byte 2,3,7
; --------------------------------------------------------------------------
; Arrays for the length and distance codes.
; Base values.
lengthBaseValue_l:
.byte <3,<4,<5,<6,<7,<8,<9,<10
.byte <11,<13,<15,<17,<19,<23,<27,<31
.byte <35,<43,<51,<59,<67,<83,<99,<115
.byte <131,<163,<195,<227,<258
distanceBaseValue_l:
.byte <1,<2,<3,<4,<5,<7,<9,<13
.byte <17,<25,<33,<49,<65,<97,<129,<193
.byte <257,<385,<513,<769,<1025,<1537,<2049,<3073
.byte <4097,<6145,<8193,<12289,<16385,<24577
lengthBaseValue_h:
.byte >3,>4,>5,>6,>7,>8,>9,>10
.byte >11,>13,>15,>17,>19,>23,>27,>31
.byte >35,>43,>51,>59,>67,>83,>99,>115
.byte >131,>163,>195,>227,>258
distanceBaseValue_h:
.byte >1,>2,>3,>4,>5,>7,>9,>13
.byte >17,>25,>33,>49,>65,>97,>129,>193
.byte >257,>385,>513,>769,>1025,>1537,>2049,>3073
.byte >4097,>6145,>8193,>12289,>16385,>24577
; Number of extra bits to read.
lengthExtraBits:
.byte 0,0,0,0,0,0,0,0
.byte 1,1,1,1,2,2,2,2
.byte 3,3,3,3,4,4,4,4
.byte 5,5,5,5,0
distanceExtraBits:
.byte 0,0,0,0,1,1,2,2
.byte 3,3,4,4,5,5,6,6
.byte 7,7,8,8,9,9,10,10
.byte 11,11,12,12,13,13
; --------------------------------------------------------------------------
;
; Uninitialised data
;
.bss
; Number of literal codes of each length in the primary tree
; (MAX_BITS bytes, overlap with literalCodeLength).
literalCount:
; --------------------------------------------------------------------------
; Data for building the primary tree.
; Lengths of literal codes.
literalCodeLength:
.res 256
; Length of the end code.
endCodeLength:
.res 1
; Lengths of length codes.
lengthCodeLength:
.res 29
; --------------------------------------------------------------------------
; Data for building the distance tree.
; Lengths of distance codes.
distanceCodeLength:
.res 30
; For two unused codes in the fixed trees and an 'end' mark.
.res 3
; --------------------------------------------------------------------------
; The Huffman trees.
; Number of codes of each length.
bitsCount:
.res TREES_SIZE
; Pointers to sorted codes of each length.
bitsPointer_l:
.res TREES_SIZE+1
bitsPointer_h:
.res TREES_SIZE
; Sorted codes.
sortedCodes:
.res 256+1+29+30+2