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https://github.com/emmanuel-marty/lzsa.git
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668204d953
Manually merge PR #44
582 lines
22 KiB
NASM
582 lines
22 KiB
NASM
; lzsa2fta.asm time-efficient decompressor implementation for 808x CPUs.
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; Turbo Assembler IDEAL mode dialect.
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; (Is supposed to also assemble with NASM's IDEAL mode support, but YMMV.)
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;
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; This code assembles to about 3K of lookup tables and unrolled code,
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; but the tradeoff for that size is the absolute fastest decompressor
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; of LZSA1 block data for 808x CPUs.
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; If you need moderately fast code with less size, see LZSA1FTA.ASM.
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; If you need the smallest decompression code, see decompress_small_v1.S.
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;
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; Usual DOS assembler SMALL model assumptions apply. This code:
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; - Assumes it was invoked via NEAR call (change RET to RETF for FAR calls)
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; - Is interrupt-safe
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; - Is not re-entrant (do not decompress while already running decompression)
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; - Trashes all data and segment registers
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;
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; Copyright (C) 2019 Jim Leonard, Emmanuel Marty
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; Additional speed optimizations by Pavel Zagrebin
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;
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; This software is provided 'as-is', without any express or implied
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; warranty. In no event will the authors be held liable for any damages
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; arising from the use of this software.
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;
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; Permission is granted to anyone to use this software for any purpose,
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; including commercial applications, and to alter it and redistribute it
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; freely, subject to the following restrictions:
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;
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; 1. The origin of this software must not be misrepresented; you must not
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; claim that you wrote the original software. If you use this software
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; in a product, an acknowledgment in the product documentation would be
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; appreciated but is not required.
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; 2. Altered source versions must be plainly marked as such, and must not be
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; misrepresented as being the original software.
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; 3. This notice may not be removed or altered from any source distribution.
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;
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; ===========================================================================
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;
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; The key area to concentrate on when optimizing LZSA1 decompression speed is
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; reducing time spent handling the shortest matches. This is for two reasons:
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; 1. shorter matches are more common
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; 2. short matches are least efficient in terms of decomp speed per byte
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; You can confirm #1 using the --stats mode of the compressor.
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;
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; Branches are costly on 8086. To ensure we branch as little as possible, a
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; jumptable will be used to branch directly to as many direct decode paths as
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; possible. This will burn up 512 bytes of RAM for a jumptable, and a few
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; hundred bytes of duplicated program code (rather than JMP/CALL common code
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; blocks, we inline them to avoid the branch overhead).
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;
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; ===========================================================================
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;
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; === LZSA1 block reference:
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;
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; Blocks encoded as LZSA1 are composed from consecutive commands.
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; Each command follows this format:
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;
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; token: <O|LLL|MMMM>
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; optional extra literal length
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; literal values
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; match offset low
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; optional match offset high
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; optional extra encoded match length
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;
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;
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; === LZSA1 Token Reference:
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;
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; 7 6 5 4 3 2 1 0
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; O L L L M M M M
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;
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; L: 3-bit literals length (0-6, or 7 if extended). If the number of literals for
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; this command is 0 to 6, the length is encoded in the token and no extra bytes
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; are required. Otherwise, a value of 7 is encoded and extra bytes follow as
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; 'optional extra literal length'
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;
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; M: 4-bit encoded match length (0-14, or 15 if extended). Likewise, if the
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; encoded match length for this command is 0 to 14, it is directly stored,
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; otherwise 15 is stored and extra bytes follow as 'optional extra encoded match
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; length'. Except for the last command in a block, a command always contains a
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; match, so the encoded match length is the actual match length, offset by the
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; minimum which is 3 bytes. For instance, an actual match length of 10 bytes to
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; be copied, is encoded as 7.
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;
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; O: set for a 2-bytes match offset, clear for a 1-byte match offset
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;
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;
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; === Decoding extended literal length:
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;
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; If the literals length is 7 or more, then an extra byte follows here, with
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; three possible values:
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;
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; 0-248: the value is added to the 7 stored in the token.
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; 250: a second byte follows. The final literals value is 256 + the second byte.
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; 249: a little-endian 16-bit value follows, forming the final literals value.
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;
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;
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; === Decoding match offsets:
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;
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; match offset low: The low 8 bits of the match offset follows.
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;
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; optional match offset high: If the 'O' bit (bit 7) is set in the token, the
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; high 8 bits of the match offset follow, otherwise they are understood to be all
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; set to 1. For instance, a short offset of 0x70 is interpreted as 0xff70
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;
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;
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; === Decoding extra encoded match length:
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;
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; optional extra encoded match length: If the encoded match length is 15 or more,
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; the 'M' bits in the token form the value 15, and an extra byte follows here,
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; with three possible types of value.
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;
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; 0-237: the value is added to the 15 stored in the token.
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; The final value is 3 + 15 + this byte.
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; 239: a second byte follows. The final match length is 256 + the second byte.
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; 238: a second and third byte follow, forming a little-endian 16-bit value.
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; The final encoded match length is that 16-bit value.
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;
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; ===========================================================================
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IDEAL ; Use Turbo Assembler IDEAL syntax checking
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P8086 ; Restrict code generation to the 808x and later
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JUMPS ; Perform fixups for out-of-bound conditional jumps
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; This is required for the (L=07 & M=0Fh) decode paths as they
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; have the most code, but these are uncommon paths so the
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; tiny speed loss in just these paths is not a concern.
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;Setting OPTIMIZE_LONG_RLE to 1 speeds up decompressing long runs of the
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;same 16-bit word value, but hurts decompression speed of other data
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;types slightly. Turn this on if you know your data has very long 16-bit
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;word-based runs (reported as RLE2 sequences in the LZSA compressor output
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;with an average length of at least 32 bytes), otherwise leave it off.
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OPTIMIZE_LONG_RLE EQU 0
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SEGMENT CODE para public
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ASSUME cs:CODE, ds:CODE
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PUBLIC lzsa1_decompress_speed_jumptable
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; EQU helper statements (so we can construct a jump table without going crazy)
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minmatch EQU 3
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litrunlen EQU 7
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leml1 EQU OFFSET lit_ext_mat_len_1b
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leme1 EQU OFFSET lit_ext_mat_ext_1b
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leml2 EQU OFFSET lit_ext_mat_len_2b
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leme2 EQU OFFSET lit_ext_mat_ext_2b
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;short-circuit special cases for 0 through 6 literal copies:
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l6ml1 EQU OFFSET lit_len_mat_len_1b_6
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l6me1 EQU OFFSET lit_len_mat_ext_1b
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l6ml2 EQU OFFSET lit_len_mat_len_2b_6
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l6me2 EQU OFFSET lit_len_mat_ext_2b
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l5ml1 EQU OFFSET lit_len_mat_len_1b_45
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l5me1 EQU OFFSET lit_len_mat_ext_1b + 1
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l5ml2 EQU OFFSET lit_len_mat_len_2b_45
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l5me2 EQU OFFSET lit_len_mat_ext_2b + 1
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l4ml1 EQU OFFSET lit_len_mat_len_1b_45 + 1
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l4me1 EQU OFFSET lit_len_mat_ext_1b + 2
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l4ml2 EQU OFFSET lit_len_mat_len_2b_45 + 1
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l4me2 EQU OFFSET lit_len_mat_ext_2b + 2
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l3ml1 EQU OFFSET lit_len_mat_len_1b_23
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l3me1 EQU OFFSET lit_len_mat_ext_1b + 3
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l3ml2 EQU OFFSET lit_len_mat_len_2b_23
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l3me2 EQU OFFSET lit_len_mat_ext_2b + 3
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l2ml1 EQU OFFSET lit_len_mat_len_1b_23 + 1
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l2me1 EQU OFFSET lit_len_mat_ext_1b + 4
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l2ml2 EQU OFFSET lit_len_mat_len_2b_23 + 1
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l2me2 EQU OFFSET lit_len_mat_ext_2b + 4
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l1ml1 EQU OFFSET lit_len_mat_len_1b_01
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l1me1 EQU OFFSET lit_len_mat_ext_1b + 5
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l1ml2 EQU OFFSET lit_len_mat_len_2b_01
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l1me2 EQU OFFSET lit_len_mat_ext_2b + 5
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l0ml1 EQU OFFSET lit_len_mat_len_1b_01 + 1 ; MMMM handling comes after LLL code
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l0me1 EQU OFFSET lit_len_mat_ext_1b + 6 ; MMMM handling comes after LLL code
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l0ml2 EQU OFFSET lit_len_mat_len_2b_01 + 1 ; MMMM handling comes after LLL code
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l0me2 EQU OFFSET lit_len_mat_ext_2b + 6 ; MMMM handling comes after LLL code
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; 0 1 2 3 4 5 6 7 8 9 a b c d e f
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jtbl DW l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0ml1,l0me1 ;0
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DW l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1ml1,l1me1 ;1
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DW l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2ml1,l2me1 ;2
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DW l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3ml1,l3me1 ;3
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DW l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4ml1,l4me1 ;4
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DW l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5ml1,l5me1 ;5
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DW l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6ml1,l6me1 ;6
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DW leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leml1,leme1 ;7
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DW l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0ml2,l0me2 ;8
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DW l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1ml2,l1me2 ;9
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DW l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2ml2,l2me2 ;a
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DW l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3ml2,l3me2 ;b
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DW l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4ml2,l4me2 ;c
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DW l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5ml2,l5me2 ;d
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DW l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6ml2,l6me2 ;e
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DW leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leml2,leme2 ;f
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PROC lzsa1_decompress_speed_jumptable NEAR
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; ---------------------------------------------------------------------------
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; Decompress raw LZSA1 block
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; inputs:
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; * ds:si: raw LZSA1 block
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; * es:di: output buffer
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; output:
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; * ax: decompressed size
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; ---------------------------------------------------------------------------
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MACRO get_byte_match_offset
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mov ah,0ffh ;O=0, so set up offset's high byte
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lodsb ;load low byte; ax=match offset
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xchg bp,ax ;bp=match offset ax=00 + original token
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ENDM
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MACRO get_word_match_offset
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lodsw ;ax=match offset
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xchg bp,ax ;bp=match offset ax=00 + original token
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ENDM
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MACRO do_match_copy_long
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LOCAL even0,even1,even2,do_run,do_run_w
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; Copies a long match as optimally as possible.
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; requirements: cx=length, bp=negative offset, ds:si=compdata, es:di=output
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; trashes: ax, bx
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; must leave cx=0 at exit
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mov bx,ds ;save ds
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mov ax,es
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mov ds,ax ;ds=es
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xchg ax,si ;save si
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lea si,[bp+di] ;si = output buffer + negative match offset
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cmp bp,-2 ;do we have a byte/word run to optimize?
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IF OPTIMIZE_LONG_RLE
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jae do_run ;catch offset = -2 or -1
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ELSE
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ja do_run ;catch offset = -1
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ENDIF
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;If we're here, we have a long copy and it isn't byte-overlapping (if it
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;overlapped, we'd be in @@do_run) So, let's copy faster with REP MOVSW.
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;This affects 8088 only slightly, but is a bigger win on 8086 and higher.
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shr cx,1
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jnc even0
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movsb
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even0:
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rep movsw
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xchg si,ax ;restore si
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mov ds,bx ;restore ds
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jmp decode_token
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do_run:
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IF OPTIMIZE_LONG_RLE
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je do_run_w ;if applicable, handle word-sized value faster
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ENDIF
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xchg dx,ax ;save si into dx, as ax is getting trashed
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lodsb ;load first byte of run into al
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mov ah,al
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shr cx,1
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jnc even1
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stosb
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even1:
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rep stosw ;perform word run
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mov si,dx ;restore si
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mov ds,bx ;restore ds
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jmp decode_token
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IF OPTIMIZE_LONG_RLE
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do_run_w:
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xchg dx,ax ;save si into dx, as ax is getting trashed
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lodsw ;load first word of run
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shr cx,1
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rep stosw ;perform word run
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jnc even2
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stosb ;should be after rep stosw!
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even2:
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mov si,dx ;restore si
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mov ds,bx ;restore ds
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jmp decode_token
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ENDIF
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ENDM
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MACRO do_match_copy
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; Copies a shorter match with as little overhead as possible.
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; requirements: cx=length, bp=negative offset, ds:si=compdata, es:di=output
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; trashes: ax, bx
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; must leave cx=0 at exit
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mov bx,ds ;save ds
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mov ax,es
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mov ds,ax ;ds=es
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xchg ax,si ;save si
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lea si,[bp+di] ;si = output buffer + negative match offset
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movsb
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movsb
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movsb ;Handle MINMATCH (instead of add cx,MINMATCH)
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rep movsb
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xchg si,ax ;restore si
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mov ds,bx ;restore ds
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jmp decode_token
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ENDM
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MACRO do_literal_copy
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LOCAL even
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; Copies a literal sequence using words.
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; Meant for longer lengths; for 128 bytes or less, use REP MOVSB.
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; requirements: cx=length, ds:si=compdata, es:di=output
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; must leave cx=0 at exit
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shr cx,1
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jnc even
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movsb
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even:
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rep movsw
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ENDM
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MACRO copy_small_match_len
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and al,0FH ;isolate length in token (MMMM)
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xchg cx,ax ;cx=match length
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do_match_copy ;copy match with cx=length, bp=offset
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ENDM
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MACRO copy_large_match_len
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LOCAL val239,val238,EOD
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; Handle MMMM=Fh
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; Assumptions: ah=0 from get_????_match_offset's xchg
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lodsb ;grab extra match length byte
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add al,0Fh+minmatch ;add MATCH_RUN_LEN + MIN_MATCH_SIZE
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; jz val238 ;if zf & cf, 238: get 16-bit match length
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jc val239 ;if cf, 239: get extra match length byte
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xchg cx,ax ;otherwise, we have our match length
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do_match_copy_long ;copy match with cx=length, bp=offset
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val239:
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jz val238
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lodsb ;ah=0; grab single extra length byte
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inc ah ;ax=256+length byte
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xchg cx,ax
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do_match_copy_long ;copy match with cx=length, bp=offset
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val238:
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lodsw ;grab 16-bit length
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xchg cx,ax
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jcxz EOD ;is it the EOD marker? Exit if so
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do_match_copy_long ;copy match with cx=length, bp=offset
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EOD:
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jmp done_decompressing
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ENDM
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lzsa1_start:
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push di ;remember decompression offset
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cld ;ensure string ops move forward
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xor cx,cx
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decode_token:
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xchg cx,ax ;clear ah (cx = 0 from match copy's REP)
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lodsb ;read token byte: O|LLL|MMMM
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mov bp,ax ;preserve 0+token in bp for later MMMM handling
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mov bx,ax ;prep for table lookup
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shl bx,1 ;adjust for offset word size
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jmp [cs:jtbl+bx] ;jump directly to relevant decode path
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; There are eight basic decode paths for an LZSA1 token. Each of these
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; paths perform only the necessary actions to decode the token and then
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; fetch the next token. This results in a lot of code duplication, but
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; it is the only way to get down to two branches per token (jump to unique
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; decode path, then jump back to next token) for the most common cases.
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; Path #1: LLL=0-6, MMMM=0-Eh, O=0 (1-byte match offset)
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; Handle LLL=0-6 by jumping directly into # of bytes to copy (6 down to 1)
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lit_len_mat_len_1b_01:
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movsb
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get_byte_match_offset
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copy_small_match_len
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lit_len_mat_len_1b_23:
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movsb
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movsw
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get_byte_match_offset
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copy_small_match_len
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lit_len_mat_len_1b_45:
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movsb
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movsw
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movsw
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get_byte_match_offset
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copy_small_match_len
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lit_len_mat_len_1b_6:
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movsw
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movsw
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movsw
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get_byte_match_offset
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copy_small_match_len
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; Path #2: LLL=0-6, MMMM=Fh, O=0 (1-byte match offset)
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lit_len_mat_ext_1b:
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movsb
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movsb
|
|
movsb
|
|
movsb
|
|
movsb
|
|
movsb
|
|
get_byte_match_offset
|
|
copy_large_match_len
|
|
|
|
|
|
; Path #3: LLL=7, MMMM=0-Eh, O=0 (1-byte match offset)
|
|
lit_ext_mat_len_1b:
|
|
; on entry: ax=0 + token, bp=ax
|
|
lodsb ;grab extra literal length byte
|
|
add al,litrunlen ;add 7h literal run length
|
|
; jz @@val249_3 ;if zf & cf, 249: get 16-bit literal length
|
|
jc @@val250_3 ;if cf, 250: get extra literal length byte
|
|
xchg cx,ax ;otherwise, we have our literal length
|
|
do_literal_copy ;this might be better as rep movsw !!! benchmark
|
|
get_byte_match_offset
|
|
copy_small_match_len
|
|
@@val250_3:
|
|
jz @@val249_3
|
|
lodsb ;ah=0; grab single extra length byte
|
|
inc ah ;ax=256+length byte
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_byte_match_offset
|
|
copy_small_match_len
|
|
@@val249_3:
|
|
lodsw ;grab 16-bit length
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_byte_match_offset
|
|
copy_small_match_len
|
|
|
|
|
|
; Path #4: LLL=7, MMMM=Fh, O=0 (1-byte match offset)
|
|
lit_ext_mat_ext_1b:
|
|
; on entry: ax=0 + token, bp=ax
|
|
lodsb ;grab extra literal length byte
|
|
add al,litrunlen ;add 7h literal run length
|
|
; jz @@val249_4 ;if zf & cf, 249: get 16-bit literal length
|
|
jc @@val250_4 ;if cf, 250: get extra literal length byte
|
|
xchg cx,ax ;otherwise, we have our literal length
|
|
do_literal_copy ;this might be better as rep movsw !!! benchmark
|
|
get_byte_match_offset
|
|
copy_large_match_len
|
|
@@val250_4:
|
|
jz @@val249_4
|
|
lodsb ;ah=0; grab single extra length byte
|
|
inc ah ;ax=256+length byte
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_byte_match_offset
|
|
copy_large_match_len
|
|
@@val249_4:
|
|
lodsw ;grab 16-bit length
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_byte_match_offset
|
|
copy_large_match_len
|
|
|
|
|
|
; Path #5: LLL=0-6, MMMM=0-Eh, O=1 (2-byte match offset)
|
|
; Handle LLL=0-6 by jumping directly into # of bytes to copy (6 down to 1)
|
|
lit_len_mat_len_2b_01:
|
|
movsb
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
lit_len_mat_len_2b_23:
|
|
movsb
|
|
movsw
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
lit_len_mat_len_2b_45:
|
|
movsb
|
|
movsw
|
|
movsw
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
lit_len_mat_len_2b_6:
|
|
movsw
|
|
movsw
|
|
movsw
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
|
|
|
|
; Path #6: LLL=0-6, MMMM=Fh, O=1 (2-byte match offset)
|
|
; Path #6: LLL=0-6, MMMM=Fh, O=1 (2-byte match offset)
|
|
lit_len_mat_ext_2b:
|
|
movsb
|
|
movsb
|
|
movsb
|
|
movsb
|
|
movsb
|
|
movsb
|
|
get_word_match_offset
|
|
copy_large_match_len
|
|
|
|
; Path #7: LLL=7, MMMM=0-Eh, O=1 (2-byte match offset)
|
|
lit_ext_mat_len_2b:
|
|
; on entry: ax=0 + token, bp=ax
|
|
lodsb ;grab extra literal length byte
|
|
add al,litrunlen ;add 7h literal run length
|
|
; jz @@val249_7 ;if zf & cf, 249: get 16-bit literal length
|
|
jc @@val250_7 ;if cf, 250: get extra literal length byte
|
|
xchg cx,ax ;otherwise, we have our literal length
|
|
do_literal_copy ;this might be better as rep movsw !!! benchmark
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
@@val250_7:
|
|
jz @@val249_7
|
|
lodsb ;ah=0; grab single extra length byte
|
|
inc ah ;ax=256+length byte
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
@@val249_7:
|
|
lodsw ;grab 16-bit length
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_word_match_offset
|
|
copy_small_match_len
|
|
|
|
|
|
; Path #8: LLL=7, MMMM=Fh, O=1 (2-byte match offset)
|
|
lit_ext_mat_ext_2b:
|
|
; on entry: ax=0 + token, bp=ax
|
|
lodsb ;grab extra literal length byte
|
|
add al,litrunlen ;add 7h literal run length
|
|
; jz @@val249_8 ;if zf & cf, 249: get 16-bit literal length
|
|
jc @@val250_8 ;if cf, 250: get extra literal length byte
|
|
xchg cx,ax ;otherwise, we have our literal length
|
|
do_literal_copy ;this might be better as rep movsw !!! benchmark
|
|
get_word_match_offset
|
|
copy_large_match_len
|
|
@@val250_8:
|
|
jz @@val249_8
|
|
lodsb ;ah=0; grab single extra length byte
|
|
inc ah ;ax=256+length byte
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_word_match_offset
|
|
copy_large_match_len
|
|
@@val249_8:
|
|
lodsw ;grab 16-bit length
|
|
xchg cx,ax
|
|
do_literal_copy
|
|
get_word_match_offset
|
|
copy_large_match_len
|
|
|
|
|
|
done_decompressing:
|
|
;return # of decompressed bytes in ax
|
|
pop ax ;retrieve the original decompression offset
|
|
sub di,ax ;adjust for original offset
|
|
xchg di,ax ;return adjusted value in ax
|
|
ret ;done decompressing, exit to caller
|
|
|
|
ENDP lzsa1_decompress_speed_jumptable
|
|
|
|
ENDS CODE
|
|
|
|
END
|
|
|
|
|
|
|
|
;Speed optimization history (decompression times in microseconds @ 4.77 MHz):
|
|
; defer add MIN_MATCH_SIZE shuttle 97207 alice 57200 robotron 362884 ++*
|
|
; jumptable rewrite, no RLE shuttle 97744 alice 46905 robotron 309032 -++
|
|
; adc cx,0 -> adc cl,0 shuttle 97744 alice 46893 robotron 309032 .+.!
|
|
; jumptable rewrite w/RLE shuttle 88776 alice 50433 robotron 319222 +--
|
|
; short match copies movsb shuttle 97298 alice 49769 robotron 326282 ---rb
|
|
; long match copy #1 16-bit shuttle 92490 alice 46905 robotron 308722 +*+
|
|
; long match copy #2 extraB shuttle 92464 alice 46905 robotron 308371 +.+
|
|
; long match copy #3 0f->ed shuttle 86765 alice 46864 robotron 303895 +++!
|
|
; baseline new test harness shuttle 83925 alice 37948 robotron 269002 ***
|
|
; Pavel optimizations shuttle 82225 alice 36798 robotron 261226 +++
|
|
; OPTIMIZE_LONG_RLE 1 shuttle 82242 alice 36787 robotron 261392 **-
|
|
;
|
|
;------
|
|
;
|
|
;Pavel's optimization history:
|
|
; shuttle alice robotron time in 1.193 MHz timer clocks
|
|
;baseline 19109 D9A6 570F6
|
|
;adc cl,0->adc cl,cl 19035 D9A6 56FAB
|
|
;rep movsb->shr cx,1;jnc 18FD4 D998 56F14
|
|
;cmp bp,-2->inc bp;inc bp 18F07 D999 56EA3
|
|
;jz;jc->jc 18D81 D973 56B2F
|
|
;add al,3->movsb x3 18B1E D777 56197
|
|
;more lit_len_mat tables 18A83 D341 54ACC
|