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;;; Optimized xor of N source vectors using AVX
;;; int xor_gen_avx(int vects, int len, void **array)
;;; Generates xor parity vector from N (vects-1) sources in array of pointers
;;; (**array). Last pointer is the dest.
;;; Vectors must be aligned to 32 bytes. Length can be any value.
%include "reg_sizes.asm"
%ifidn __OUTPUT_FORMAT__, elf64
%define arg0 rdi
%define arg1 rsi
%define arg2 rdx
%define arg3 rcx
%define arg4 r8
%define arg5 r9
%define tmp r11
%define tmp3 arg4
%define func(x) x: endbranch
%define return rax
%define FUNC_SAVE
%define FUNC_RESTORE
%elifidn __OUTPUT_FORMAT__, win64
%define arg0 rcx
%define arg1 rdx
%define arg2 r8
%define arg3 r9
%define tmp r11
%define tmp3 r10
%define func(x) proc_frame x
%define return rax
%define stack_size 2*32 + 8 ;must be an odd multiple of 8
%macro FUNC_SAVE 0
alloc_stack stack_size
vmovdqu [rsp + 0*32], ymm6
vmovdqu [rsp + 1*32], ymm7
end_prolog
%endmacro
%macro FUNC_RESTORE 0
vmovdqu ymm6, [rsp + 0*32]
vmovdqu ymm7, [rsp + 1*32]
add rsp, stack_size
%endmacro
%endif ;output formats
%define vec arg0
%define len arg1
%define ptr arg3
%define tmp2 rax
%define tmp2.b al
%define pos tmp3
%define PS 8
;;; Use Non-temporal load/stor
%ifdef NO_NT_LDST
%define XLDR vmovdqa
%define XSTR vmovdqa
%else
%define XLDR vmovdqa
%define XSTR vmovntdq
%endif
default rel
[bits 64]
section .text
align 16
mk_global xor_gen_avx, function
func(xor_gen_avx)
FUNC_SAVE
sub vec, 2 ;Keep as offset to last source
jng return_fail ;Must have at least 2 sources
cmp len, 0
je return_pass
test len, (128-1) ;Check alignment of length
jnz len_not_aligned
len_aligned_128bytes:
sub len, 128
mov pos, 0
loop128:
mov tmp, vec ;Back to last vector
mov tmp2, [arg2+vec*PS] ;Fetch last pointer in array
sub tmp, 1 ;Next vect
XLDR ymm0, [tmp2+pos] ;Start with end of array in last vector
XLDR ymm1, [tmp2+pos+32] ;Keep xor parity in xmm0-7
XLDR ymm2, [tmp2+pos+(2*32)]
XLDR ymm3, [tmp2+pos+(3*32)]
next_vect:
mov ptr, [arg2+tmp*PS]
sub tmp, 1
XLDR ymm4, [ptr+pos] ;Get next vector (source)
XLDR ymm5, [ptr+pos+32]
XLDR ymm6, [ptr+pos+(2*32)]
XLDR ymm7, [ptr+pos+(3*32)]
vxorpd ymm0, ymm0, ymm4 ;Add to xor parity
vxorpd ymm1, ymm1, ymm5
vxorpd ymm2, ymm2, ymm6
vxorpd ymm3, ymm3, ymm7
jge next_vect ;Loop for each source
mov ptr, [arg2+PS+vec*PS] ;Address of parity vector
XSTR [ptr+pos], ymm0 ;Write parity xor vector
XSTR [ptr+pos+(1*32)], ymm1
XSTR [ptr+pos+(2*32)], ymm2
XSTR [ptr+pos+(3*32)], ymm3
add pos, 128
cmp pos, len
jle loop128
return_pass:
FUNC_RESTORE
mov return, 0
ret
;;; Do one byte at a time for no alignment case
loop_1byte:
mov tmp, vec ;Back to last vector
mov ptr, [arg2+vec*PS] ;Fetch last pointer in array
mov tmp2.b, [ptr+len-1] ;Get array n
sub tmp, 1
nextvect_1byte:
mov ptr, [arg2+tmp*PS]
xor tmp2.b, [ptr+len-1]
sub tmp, 1
jge nextvect_1byte
mov tmp, vec
add tmp, 1 ;Add back to point to last vec
mov ptr, [arg2+tmp*PS]
mov [ptr+len-1], tmp2.b ;Write parity
sub len, 1
test len, (PS-1)
jnz loop_1byte
cmp len, 0
je return_pass
test len, (128-1) ;If not 0 and 128bit aligned
jz len_aligned_128bytes ; then do aligned case. len = y * 128
;; else we are 8-byte aligned so fall through to recheck
;; Unaligned length cases
len_not_aligned:
test len, (PS-1)
jne loop_1byte
mov tmp3, len
and tmp3, (128-1) ;Do the unaligned bytes 8 at a time
;; Run backwards 8 bytes at a time for (tmp3) bytes
loop8_bytes:
mov tmp, vec ;Back to last vector
mov ptr, [arg2+vec*PS] ;Fetch last pointer in array
mov tmp2, [ptr+len-PS] ;Get array n
sub tmp, 1
nextvect_8bytes:
mov ptr, [arg2+tmp*PS] ;Get pointer to next vector
xor tmp2, [ptr+len-PS]
sub tmp, 1
jge nextvect_8bytes ;Loop for each source
mov tmp, vec
add tmp, 1 ;Add back to point to last vec
mov ptr, [arg2+tmp*PS]
mov [ptr+len-PS], tmp2 ;Write parity
sub len, PS
sub tmp3, PS
jg loop8_bytes
cmp len, 128 ;Now len is aligned to 128B
jge len_aligned_128bytes ;We can do the rest aligned
cmp len, 0
je return_pass
return_fail:
FUNC_RESTORE
mov return, 1
ret
endproc_frame
section .data
;;; func core, ver, snum
slversion xor_gen_avx, 02, 05, 0037