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|
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Copyright(c) 2011-2018 Intel Corporation All rights reserved.
;
; Redistribution and use in source and binary forms, with or without
; modification, are permitted provided that the following conditions
; are met:
; * Redistributions of source code must retain the above copyright
; notice, this list of conditions and the following disclaimer.
; * Redistributions in binary form must reproduce the above copyright
; notice, this list of conditions and the following disclaimer in
; the documentation and/or other materials provided with the
; distribution.
; * Neither the name of Intel Corporation nor the names of its
; contributors may be used to endorse or promote products derived
; from this software without specific prior written permission.
;
; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
; "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
; LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
; A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
; OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
; SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
; LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
; DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
; THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
; (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
; OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
default rel
%include "reg_sizes.asm"
%define DECOMP_OK 0
%define END_INPUT 1
%define OUT_OVERFLOW 2
%define INVALID_BLOCK -1
%define INVALID_SYMBOL -2
%define INVALID_LOOKBACK -3
%define ISAL_DECODE_LONG_BITS 12
%define ISAL_DECODE_SHORT_BITS 10
%define COPY_SIZE 16
%define COPY_LEN_MAX 258
%define IN_BUFFER_SLOP 8
%define OUT_BUFFER_SLOP COPY_SIZE + COPY_LEN_MAX
%include "inflate_data_structs.asm"
%include "stdmac.asm"
extern rfc1951_lookup_table
%define LARGE_SHORT_SYM_LEN 25
%define LARGE_SHORT_SYM_MASK ((1 << LARGE_SHORT_SYM_LEN) - 1)
%define LARGE_LONG_SYM_LEN 10
%define LARGE_LONG_SYM_MASK ((1 << LARGE_LONG_SYM_LEN) - 1)
%define LARGE_SHORT_CODE_LEN_OFFSET 28
%define LARGE_LONG_CODE_LEN_OFFSET 10
%define LARGE_FLAG_BIT_OFFSET 25
%define LARGE_FLAG_BIT (1 << LARGE_FLAG_BIT_OFFSET)
%define LARGE_SYM_COUNT_OFFSET 26
%define LARGE_SYM_COUNT_LEN 2
%define LARGE_SYM_COUNT_MASK ((1 << LARGE_SYM_COUNT_LEN) - 1)
%define LARGE_SHORT_MAX_LEN_OFFSET 26
%define SMALL_SHORT_SYM_LEN 9
%define SMALL_SHORT_SYM_MASK ((1 << SMALL_SHORT_SYM_LEN) - 1)
%define SMALL_LONG_SYM_LEN 9
%define SMALL_LONG_SYM_MASK ((1 << SMALL_LONG_SYM_LEN) - 1)
%define SMALL_SHORT_CODE_LEN_OFFSET 11
%define SMALL_LONG_CODE_LEN_OFFSET 10
%define SMALL_FLAG_BIT_OFFSET 10
%define SMALL_FLAG_BIT (1 << SMALL_FLAG_BIT_OFFSET)
%define DIST_SYM_OFFSET 0
%define DIST_SYM_LEN 5
%define DIST_SYM_MASK ((1 << DIST_SYM_LEN) - 1)
%define DIST_SYM_EXTRA_OFFSET 5
%define DIST_SYM_EXTRA_LEN 4
%define DIST_SYM_EXTRA_MASK ((1 << DIST_SYM_EXTRA_LEN) - 1)
;; rax
%define tmp3 rax
%define read_in_2 rax
%define look_back_dist rax
;; rcx
;; rdx arg3
%define next_sym2 rdx
%define copy_start rdx
%define tmp4 rdx
;; rdi arg1
%define tmp1 rdi
%define look_back_dist2 rdi
%define next_bits2 rdi
%define next_sym3 rdi
;; rsi arg2
%define tmp2 rsi
%define next_sym_num rsi
%define next_bits rsi
;; rbx ; Saved
%define next_in rbx
;; rbp ; Saved
%define end_in rbp
;; r8
%define repeat_length r8
;; r9
%define read_in r9
;; r10
%define read_in_length r10
;; r11
%define state r11
;; r12 ; Saved
%define next_out r12
;; r13 ; Saved
%define end_out r13
;; r14 ; Saved
%define next_sym r14
;; r15 ; Saved
%define rfc_lookup r15
start_out_mem_offset equ 0
read_in_mem_offset equ 8
read_in_length_mem_offset equ 16
next_out_mem_offset equ 24
gpr_save_mem_offset equ 32
stack_size equ 4 * 8 + 8 * 8
%define _dist_extra_bit_count 264
%define _dist_start _dist_extra_bit_count + 1*32
%define _len_extra_bit_count _dist_start + 4*32
%define _len_start _len_extra_bit_count + 1*32
%ifidn __OUTPUT_FORMAT__, elf64
%define arg0 rdi
%define arg1 rsi
%macro FUNC_SAVE 0
%ifdef ALIGN_STACK
push rbp
mov rbp, rsp
sub rsp, stack_size
and rsp, ~15
%else
sub rsp, stack_size
%endif
mov [rsp + gpr_save_mem_offset + 0*8], rbx
mov [rsp + gpr_save_mem_offset + 1*8], rbp
mov [rsp + gpr_save_mem_offset + 2*8], r12
mov [rsp + gpr_save_mem_offset + 3*8], r13
mov [rsp + gpr_save_mem_offset + 4*8], r14
mov [rsp + gpr_save_mem_offset + 5*8], r15
%endm
%macro FUNC_RESTORE 0
mov rbx, [rsp + gpr_save_mem_offset + 0*8]
mov rbp, [rsp + gpr_save_mem_offset + 1*8]
mov r12, [rsp + gpr_save_mem_offset + 2*8]
mov r13, [rsp + gpr_save_mem_offset + 3*8]
mov r14, [rsp + gpr_save_mem_offset + 4*8]
mov r15, [rsp + gpr_save_mem_offset + 5*8]
%ifndef ALIGN_STACK
add rsp, stack_size
%else
mov rsp, rbp
pop rbp
%endif
%endm
%endif
%ifidn __OUTPUT_FORMAT__, win64
%define arg0 rcx
%define arg1 rdx
%macro FUNC_SAVE 0
%ifdef ALIGN_STACK
push rbp
mov rbp, rsp
sub rsp, stack_size
and rsp, ~15
%else
sub rsp, stack_size
%endif
mov [rsp + gpr_save_mem_offset + 0*8], rbx
mov [rsp + gpr_save_mem_offset + 1*8], rsi
mov [rsp + gpr_save_mem_offset + 2*8], rdi
mov [rsp + gpr_save_mem_offset + 3*8], rbp
mov [rsp + gpr_save_mem_offset + 4*8], r12
mov [rsp + gpr_save_mem_offset + 5*8], r13
mov [rsp + gpr_save_mem_offset + 6*8], r14
mov [rsp + gpr_save_mem_offset + 7*8], r15
%endm
%macro FUNC_RESTORE 0
mov rbx, [rsp + gpr_save_mem_offset + 0*8]
mov rsi, [rsp + gpr_save_mem_offset + 1*8]
mov rdi, [rsp + gpr_save_mem_offset + 2*8]
mov rbp, [rsp + gpr_save_mem_offset + 3*8]
mov r12, [rsp + gpr_save_mem_offset + 4*8]
mov r13, [rsp + gpr_save_mem_offset + 5*8]
mov r14, [rsp + gpr_save_mem_offset + 6*8]
mov r15, [rsp + gpr_save_mem_offset + 7*8]
%ifndef ALIGN_STACK
add rsp, stack_size
%else
mov rsp, rbp
pop rbp
%endif
%endm
%endif
;; Load read_in and updated in_buffer accordingly
;; when there are at least 8 bytes in the in buffer
;; Clobbers rcx, unless rcx is %%read_in_length
%macro inflate_in_load 6
%define %%next_in %1
%define %%end_in %2
%define %%read_in %3
%define %%read_in_length %4
%define %%tmp1 %5 ; Tmp registers
%define %%tmp2 %6
SHLX %%tmp1, [%%next_in], %%read_in_length
or %%read_in, %%tmp1
mov %%tmp1, 64
sub %%tmp1, %%read_in_length
shr %%tmp1, 3
add %%next_in, %%tmp1
lea %%read_in_length, [%%read_in_length + 8 * %%tmp1]
%%end:
%endm
;; Load read_in and updated in_buffer accordingly
;; Clobbers rcx, unless rcx is %%read_in_length
%macro inflate_in_small_load 6
%define %%next_in %1
%define %%end_in %2
%define %%read_in %3
%define %%read_in_length %4
%define %%avail_in %5 ; Tmp registers
%define %%tmp1 %5
%define %%loop_count %6
mov %%avail_in, %%end_in
sub %%avail_in, %%next_in
%ifnidn %%read_in_length, rcx
mov rcx, %%read_in_length
%endif
mov %%loop_count, 64
sub %%loop_count, %%read_in_length
shr %%loop_count, 3
cmp %%loop_count, %%avail_in
cmovg %%loop_count, %%avail_in
cmp %%loop_count, 0
je %%end
%%load_byte:
xor %%tmp1, %%tmp1
mov %%tmp1 %+ b, byte [%%next_in]
SHLX %%tmp1, %%tmp1, rcx
or %%read_in, %%tmp1
add rcx, 8
add %%next_in, 1
sub %%loop_count, 1
jg %%load_byte
%ifnidn %%read_in_length, rcx
mov %%read_in_length, rcx
%endif
%%end:
%endm
;; Clears all bits at index %%bit_count and above in %%next_bits
;; May clobber rcx and %%bit_count
%macro CLEAR_HIGH_BITS 3
%define %%next_bits %1
%define %%bit_count %2
%define %%lookup_size %3
sub %%bit_count, 0x40 + %%lookup_size
;; Extract the 15-DECODE_LOOKUP_SIZE bits beyond the first DECODE_LOOKUP_SIZE bits.
%ifdef USE_HSWNI
and %%bit_count, 0x1F
bzhi %%next_bits, %%next_bits, %%bit_count
%else
%ifnidn %%bit_count, rcx
mov rcx, %%bit_count
%endif
neg rcx
shl %%next_bits, cl
shr %%next_bits, cl
%endif
%endm
;; Decode next symbol
;; Clobber rcx
%macro decode_next_lit_len 8
%define %%state %1 ; State structure associated with compressed stream
%define %%lookup_size %2 ; Number of bits used for small lookup
%define %%state_offset %3 ; Type of huff code, should be either LIT or DIST
%define %%read_in %4 ; Bits read in from compressed stream
%define %%read_in_length %5 ; Number of valid bits in read_in
%define %%next_sym %6 ; Returned symbols
%define %%next_sym_num %7 ; Returned symbols count
%define %%next_bits %8
mov %%next_sym_num, %%next_sym
mov rcx, %%next_sym
shr rcx, LARGE_SHORT_CODE_LEN_OFFSET
jz invalid_symbol
and %%next_sym_num, LARGE_SYM_COUNT_MASK << LARGE_SYM_COUNT_OFFSET
shr %%next_sym_num, LARGE_SYM_COUNT_OFFSET
;; Check if symbol or hint was looked up
and %%next_sym, LARGE_FLAG_BIT | LARGE_SHORT_SYM_MASK
test %%next_sym, LARGE_FLAG_BIT
jz %%end
shl rcx, LARGE_SYM_COUNT_LEN
or rcx, %%next_sym_num
;; Save length associated with symbol
mov %%next_bits, %%read_in
shr %%next_bits, %%lookup_size
;; Extract the bits beyond the first %%lookup_size bits.
CLEAR_HIGH_BITS %%next_bits, rcx, %%lookup_size
and %%next_sym, LARGE_SHORT_SYM_MASK
add %%next_sym, %%next_bits
;; Lookup actual next symbol
movzx %%next_sym, word [%%state + LARGE_LONG_CODE_SIZE * %%next_sym + %%state_offset + LARGE_SHORT_CODE_SIZE * (1 << %%lookup_size)]
mov %%next_sym_num, 1
;; Save length associated with symbol
mov rcx, %%next_sym
shr rcx, LARGE_LONG_CODE_LEN_OFFSET
jz invalid_symbol
and %%next_sym, LARGE_LONG_SYM_MASK
%%end:
;; Updated read_in to reflect the bits which were decoded
SHRX %%read_in, %%read_in, rcx
sub %%read_in_length, rcx
%endm
;; Decode next symbol
;; Clobber rcx
%macro decode_next_lit_len_with_load 8
%define %%state %1 ; State structure associated with compressed stream
%define %%lookup_size %2 ; Number of bits used for small lookup
%define %%state_offset %3
%define %%read_in %4 ; Bits read in from compressed stream
%define %%read_in_length %5 ; Number of valid bits in read_in
%define %%next_sym %6 ; Returned symbols
%define %%next_sym_num %7 ; Returned symbols count
%define %%next_bits %8
;; Lookup possible next symbol
mov %%next_bits, %%read_in
and %%next_bits, (1 << %%lookup_size) - 1
mov %%next_sym %+ d, dword [%%state + %%state_offset + LARGE_SHORT_CODE_SIZE * %%next_bits]
decode_next_lit_len %%state, %%lookup_size, %%state_offset, %%read_in, %%read_in_length, %%next_sym, %%next_sym_num, %%next_bits
%endm
;; Decode next symbol
;; Clobber rcx
%macro decode_next_dist 8
%define %%state %1 ; State structure associated with compressed stream
%define %%lookup_size %2 ; Number of bits used for small lookup
%define %%state_offset %3 ; Type of huff code, should be either LIT or DIST
%define %%read_in %4 ; Bits read in from compressed stream
%define %%read_in_length %5 ; Number of valid bits in read_in
%define %%next_sym %6 ; Returned symobl
%define %%next_extra_bits %7
%define %%next_bits %8
mov rcx, %%next_sym
shr rcx, SMALL_SHORT_CODE_LEN_OFFSET
jz invalid_dist_symbol_ %+ %%next_sym
;; Check if symbol or hint was looked up
and %%next_sym, SMALL_FLAG_BIT | SMALL_SHORT_SYM_MASK
test %%next_sym, SMALL_FLAG_BIT
jz %%end
;; Save length associated with symbol
mov %%next_bits, %%read_in
shr %%next_bits, %%lookup_size
;; Extract the 15-DECODE_LOOKUP_SIZE bits beyond the first %%lookup_size bits.
lea %%next_sym, [%%state + SMALL_LONG_CODE_SIZE * %%next_sym]
CLEAR_HIGH_BITS %%next_bits, rcx, %%lookup_size
;; Lookup actual next symbol
movzx %%next_sym, word [%%next_sym + %%state_offset + SMALL_LONG_CODE_SIZE * %%next_bits + SMALL_SHORT_CODE_SIZE * (1 << %%lookup_size) - SMALL_LONG_CODE_SIZE * SMALL_FLAG_BIT]
;; Save length associated with symbol
mov rcx, %%next_sym
shr rcx, SMALL_LONG_CODE_LEN_OFFSET
jz invalid_dist_symbol_ %+ %%next_sym
and %%next_sym, SMALL_SHORT_SYM_MASK
%%end:
;; Updated read_in to reflect the bits which were decoded
SHRX %%read_in, %%read_in, rcx
sub %%read_in_length, rcx
mov rcx, %%next_sym
shr rcx, DIST_SYM_EXTRA_OFFSET
and %%next_sym, DIST_SYM_MASK
%endm
;; Decode next symbol
;; Clobber rcx
%macro decode_next_dist_with_load 8
%define %%state %1 ; State structure associated with compressed stream
%define %%lookup_size %2 ; Number of bits used for small lookup
%define %%state_offset %3
%define %%read_in %4 ; Bits read in from compressed stream
%define %%read_in_length %5 ; Number of valid bits in read_in
%define %%next_sym %6 ; Returned symobl
%define %%next_extra_bits %7
%define %%next_bits %8
;; Lookup possible next symbol
mov %%next_bits, %%read_in
and %%next_bits, (1 << %%lookup_size) - 1
movzx %%next_sym, word [%%state + %%state_offset + SMALL_SHORT_CODE_SIZE * %%next_bits]
decode_next_dist %%state, %%lookup_size, %%state_offset, %%read_in, %%read_in_length, %%next_sym, %%next_extra_bits, %%next_bits
%endm
global decode_huffman_code_block_stateless_ %+ ARCH
decode_huffman_code_block_stateless_ %+ ARCH %+ :
FUNC_SAVE
mov state, arg0
mov [rsp + start_out_mem_offset], arg1
lea rfc_lookup, [rfc1951_lookup_table]
mov read_in,[state + _read_in]
mov read_in_length %+ d, dword [state + _read_in_length]
mov next_out, [state + _next_out]
mov end_out %+ d, dword [state + _avail_out]
add end_out, next_out
mov next_in, [state + _next_in]
mov end_in %+ d, dword [state + _avail_in]
add end_in, next_in
mov dword [state + _copy_overflow_len], 0
mov dword [state + _copy_overflow_dist], 0
sub end_out, OUT_BUFFER_SLOP
sub end_in, IN_BUFFER_SLOP
cmp next_in, end_in
jg end_loop_block_pre
cmp read_in_length, 64
je skip_load
inflate_in_load next_in, end_in, read_in, read_in_length, tmp1, tmp2
skip_load:
mov tmp3, read_in
and tmp3, (1 << ISAL_DECODE_LONG_BITS) - 1
mov next_sym %+ d, dword [state + _lit_huff_code + LARGE_SHORT_CODE_SIZE * tmp3]
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Main Loop
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
loop_block:
;; Check if near end of in buffer or out buffer
cmp next_in, end_in
jg end_loop_block_pre
cmp next_out, end_out
jg end_loop_block_pre
;; Decode next symbol and reload the read_in buffer
decode_next_lit_len state, ISAL_DECODE_LONG_BITS, _lit_huff_code, read_in, read_in_length, next_sym, next_sym_num, tmp1
;; Specutively write next_sym if it is a literal
mov [next_out], next_sym
add next_out, next_sym_num
lea next_sym2, [8 * next_sym_num - 8]
SHRX next_sym2, next_sym, next_sym2
;; Find index to specutively preload next_sym from
mov tmp3, (1 << ISAL_DECODE_LONG_BITS) - 1
and tmp3, read_in
;; Start reloading read_in
mov tmp1, [next_in]
SHLX tmp1, tmp1, read_in_length
or read_in, tmp1
;; Specutively load data associated with length symbol
lea repeat_length, [next_sym2 - 254]
;; Test for end of block symbol
cmp next_sym2, 256
je end_symbol_pre
;; Specutively load next_sym for next loop if a literal was decoded
mov next_sym %+ d, dword [state + _lit_huff_code + LARGE_SHORT_CODE_SIZE * tmp3]
;; Finish updating read_in_length for read_in
mov tmp1, 64
sub tmp1, read_in_length
shr tmp1, 3
add next_in, tmp1
lea read_in_length, [read_in_length + 8 * tmp1]
;; Specultively load next dist code
mov next_bits2, (1 << ISAL_DECODE_SHORT_BITS) - 1
and next_bits2, read_in
movzx next_sym3, word [state + _dist_huff_code + SMALL_SHORT_CODE_SIZE * next_bits2]
;; Check if next_sym2 is a literal, length, or end of block symbol
cmp next_sym2, 256
jl loop_block
decode_len_dist:
;; Determine next_out after the copy is finished
lea next_out, [next_out + repeat_length - 1]
;; Decode distance code
decode_next_dist state, ISAL_DECODE_SHORT_BITS, _dist_huff_code, read_in, read_in_length, next_sym3, rcx, tmp2
mov look_back_dist2 %+ d, [rfc_lookup + _dist_start + 4 * next_sym3]
; ;; Load distance code extra bits
mov next_bits, read_in
;; Calculate the look back distance
BZHI next_bits, next_bits, rcx, tmp4
SHRX read_in, read_in, rcx
;; Setup next_sym, read_in, and read_in_length for next loop
mov read_in_2, (1 << ISAL_DECODE_LONG_BITS) - 1
and read_in_2, read_in
mov next_sym %+ d, dword [state + _lit_huff_code + LARGE_SHORT_CODE_SIZE * read_in_2]
sub read_in_length, rcx
;; Copy distance in len/dist pair
add look_back_dist2, next_bits
;; Find beginning of copy
mov copy_start, next_out
sub copy_start, repeat_length
sub copy_start, look_back_dist2
;; Check if a valid look back distances was decoded
cmp copy_start, [rsp + start_out_mem_offset]
jl invalid_look_back_distance
MOVDQU xmm1, [copy_start]
;; Set tmp2 to be the minimum of COPY_SIZE and repeat_length
;; This is to decrease use of small_byte_copy branch
mov tmp2, COPY_SIZE
cmp tmp2, repeat_length
cmovg tmp2, repeat_length
;; Check for overlapping memory in the copy
cmp look_back_dist2, tmp2
jl small_byte_copy_pre
large_byte_copy:
;; Copy length distance pair when memory overlap is not an issue
MOVDQU [copy_start + look_back_dist2], xmm1
sub repeat_length, COPY_SIZE
jle loop_block
add copy_start, COPY_SIZE
MOVDQU xmm1, [copy_start]
jmp large_byte_copy
small_byte_copy_pre:
;; Copy length distance pair when source and destination overlap
add repeat_length, look_back_dist2
small_byte_copy:
MOVDQU [copy_start + look_back_dist2], xmm1
shl look_back_dist2, 1
MOVDQU xmm1, [copy_start]
cmp look_back_dist2, COPY_SIZE
jl small_byte_copy
sub repeat_length, look_back_dist2
jge large_byte_copy
jmp loop_block
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
; Finish Main Loop
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
end_loop_block_pre:
;; Fix up in buffer and out buffer to reflect the actual buffer end
add end_out, OUT_BUFFER_SLOP
add end_in, IN_BUFFER_SLOP
end_loop_block:
;; Load read in buffer and decode next lit/len symbol
inflate_in_small_load next_in, end_in, read_in, read_in_length, tmp1, tmp2
mov [rsp + read_in_mem_offset], read_in
mov [rsp + read_in_length_mem_offset], read_in_length
mov [rsp + next_out_mem_offset], next_out
decode_next_lit_len_with_load state, ISAL_DECODE_LONG_BITS, _lit_huff_code, read_in, read_in_length, next_sym, next_sym_num, tmp1
;; Check that enough input was available to decode symbol
cmp read_in_length, 0
jl end_of_input
multi_symbol_start:
cmp next_sym_num, 1
jg decode_literal
cmp next_sym, 256
jl decode_literal
je end_symbol
decode_len_dist_2:
lea repeat_length, [next_sym - 254]
;; Decode distance code
decode_next_dist_with_load state, ISAL_DECODE_SHORT_BITS, _dist_huff_code, read_in, read_in_length, next_sym, rcx, tmp1
;; Load distance code extra bits
mov next_bits, read_in
mov look_back_dist %+ d, [rfc_lookup + _dist_start + 4 * next_sym]
;; Calculate the look back distance and check for enough input
BZHI next_bits, next_bits, rcx, tmp1
SHRX read_in, read_in, rcx
add look_back_dist, next_bits
sub read_in_length, rcx
jl end_of_input
;; Setup code for byte copy using rep movsb
mov rsi, next_out
mov rdi, rsi
mov rcx, repeat_length
sub rsi, look_back_dist
;; Check if a valid look back distance was decoded
cmp rsi, [rsp + start_out_mem_offset]
jl invalid_look_back_distance
;; Check for out buffer overflow
add repeat_length, next_out
cmp repeat_length, end_out
jg out_buffer_overflow_repeat
mov next_out, repeat_length
rep movsb
jmp end_loop_block
decode_literal:
;; Store literal decoded from the input stream
cmp next_out, end_out
jge out_buffer_overflow_lit
add next_out, 1
mov byte [next_out - 1], next_sym %+ b
sub next_sym_num, 1
jz end_loop_block
shr next_sym, 8
jmp multi_symbol_start
;; Set exit codes
end_of_input:
mov read_in, [rsp + read_in_mem_offset]
mov read_in_length, [rsp + read_in_length_mem_offset]
mov next_out, [rsp + next_out_mem_offset]
xor tmp1, tmp1
mov dword [state + _write_overflow_lits], tmp1 %+ d
mov dword [state + _write_overflow_len], tmp1 %+ d
mov rax, END_INPUT
jmp end
out_buffer_overflow_repeat:
mov rcx, end_out
sub rcx, next_out
sub repeat_length, rcx
sub repeat_length, next_out
rep movsb
mov [state + _copy_overflow_len], repeat_length %+ d
mov [state + _copy_overflow_dist], look_back_dist %+ d
mov next_out, end_out
mov rax, OUT_OVERFLOW
jmp end
out_buffer_overflow_lit:
mov dword [state + _write_overflow_lits], next_sym %+ d
mov dword [state + _write_overflow_len], next_sym_num %+ d
sub next_sym_num, 1
shl next_sym_num, 3
SHRX next_sym, next_sym, next_sym_num
mov rax, OUT_OVERFLOW
shr next_sym_num, 3
cmp next_sym, 256
jl end
mov dword [state + _write_overflow_len], next_sym_num %+ d
jg decode_len_dist_2
jmp end_state
invalid_look_back_distance:
mov rax, INVALID_LOOKBACK
jmp end
invalid_dist_symbol_ %+ next_sym:
cmp read_in_length, next_sym
jl end_of_input
jmp invalid_symbol
invalid_dist_symbol_ %+ next_sym3:
cmp read_in_length, next_sym3
jl end_of_input
invalid_symbol:
mov rax, INVALID_SYMBOL
jmp end
end_symbol_pre:
;; Fix up in buffer and out buffer to reflect the actual buffer
sub next_out, 1
add end_out, OUT_BUFFER_SLOP
add end_in, IN_BUFFER_SLOP
end_symbol:
xor rax, rax
end_state:
;; Set flag identifying a new block is required
mov byte [state + _block_state], ISAL_BLOCK_NEW_HDR
cmp dword [state + _bfinal], 0
je end
mov byte [state + _block_state], ISAL_BLOCK_INPUT_DONE
end:
;; Save current buffer states
mov [state + _read_in], read_in
mov [state + _read_in_length], read_in_length %+ d
;; Set avail_out
sub end_out, next_out
mov dword [state + _avail_out], end_out %+ d
;; Set total_out
mov tmp1, next_out
sub tmp1, [state + _next_out]
add [state + _total_out], tmp1 %+ d
;; Set next_out
mov [state + _next_out], next_out
;; Set next_in
mov [state + _next_in], next_in
;; Set avail_in
sub end_in, next_in
mov [state + _avail_in], end_in %+ d
FUNC_RESTORE
ret
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