dnl X86-64 mpn_sqr_basecase optimised
for Intel Nehalem/Westmere.
dnl It also seems good
for Conroe/Wolfdale.
dnl Contributed to the GNU project by Torbjörn Granlund.
dnl Copyright 2008, 2011-2013 Free Software Foundation,
Inc .
dnl
This file is part of the GNU MP Library.
dnl
dnl The GNU MP Library is free software
; you can redistribute it and/or modify
dnl it under the terms of either:
dnl
dnl * the GNU Lesser General
Public License as published by the Free
dnl Software Foundation
; either version 3 of the License, or (at your
dnl
option ) any later
version .
dnl
dnl
or
dnl
dnl * the GNU General
Public License as published by the Free Software
dnl Foundation
; either version 2 of the License, or (at your option) any
dnl later
version .
dnl
dnl
or both in parallel, as here.
dnl
dnl The GNU MP Library is distributed in the hope that it will be useful, but
dnl WITHOUT ANY WARRANTY
; without even the implied warranty of MERCHANTABILITY
dnl
or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU General
Public License
dnl
for more details.
dnl
dnl You should have received copies of the GNU General
Public License
and the
dnl GNU Lesser General
Public License along with the GNU MP Library.
If not,
dnl see
https://www.gnu. org /licenses/.
include (`../config.m4
')
C cycles/limb mul_2 addmul_2 sqr_diag_addlsh1
C AMD K8,K9
C AMD K10
C AMD bull
C AMD pile
C AMD steam
C AMD bobcat
C AMD jaguar
C Intel P4
C Intel core 4.9 4.18-4.25 3.87
C Intel NHM 3.8 4.06-4.2 3.5
C Intel SBR
C Intel IBR
C Intel HWL
C Intel BWL
C Intel atom
C VIA nano
C The inner loops of
this code are the result of running a
code generation
and
C optimisation tool suite written by David Harvey
and Torbjörn Granlund.
C
Code structure:
C
C
C m_2(0m4) m_2(2m4) m_2(1m4) m_2(3m4)
C | | | |
C | | | |
C | | | |
C \|/ \|/ \|/ \|/
C ____________ ____________
C / \ / \
C \|/ \ \|/ \
C am_2(3m4) am_2(1m4) am_2(0m4) am_2(2m4)
C \ /|\ \ /|\
C \____________/ \____________/
C \ /
C \ /
C \ /
C tail(0m2) tail(1m2)
C \ /
C \ /
C sqr_diag_addlsh1
C TODO
C * Tune. None done so far.
C * Currently 2761 bytes, making it smaller would be nice.
C * Consider using a jumptab-based entry sequence. One might
even use a mask-
C less sequence,
if the table is large enough to support tuneup
's needs.
C The
code would be, using non-PIC
code ,
C
lea tab(%rip),%rax
; jmp *(n,%rax)
C
or ,
C
lea tab(%rip),%rax
; lea (%rip),%rbx; add (n,%rax),%rbx; jmp *%rbx
C using PIC
code . The table entries would be Ln1,Ln2,Ln3,Lm0,Lm1,Lm2,Lm3,..
C with the last four entries repeated a safe number of times.
C * Consider expanding feed-in
code in order to avoid zeroing registers.
C *
Zero consistently with
xor .
C * Check
if using
"lea (reg),reg" should be done in more places
; we have some
C explicit
"mov %rax,reg" now.
C * Try zeroing with
xor in m2 loops.
C * Try re-rolling the m2 loops to avoid the current 9 insn
code duplication
C between loop header
and wind-down
code .
C * Consider
adc reg,reg instead of
adc $0,reg in m2 loops.
This save a
byte .
C When playing with pointers, set
this to $2 to fall back to conservative
C indexing in wind-down
code .
define(`I
',`$1' )
C Define
this to $1 to use late loop index variable as
zero , $2 to use an
C explicit $0.
define(`Z
',`$1' )
define(`rp
', `%rdi' )
define(`up
', `%rsi' )
define(`n_param
', `%rdx' )
define(`n
', `%r8' )
define(`v0
', `%r10' )
define(`v1
', `%r11' )
define(`w0
', `%rbx' )
define(`w1
', `%rcx' )
define(`w2
', `%rbp' )
define(`w3
', `%r9' )
define(`i
', `%r13' )
define(`X0
', `%r12' )
define(`X1
', `%r14' )
C rax rbx rcx rdx rdi rsi rbp r8 r9 r10 r11 r12 r13 r14 r15
ABI_SUPPORT(DOS64)
ABI_SUPPORT(STD64)
define(`ALIGNx
', `ALIGN(16)' )
define(`N
', 85)
ifdef (`N
',,`define(`N' ,0)
')
define(`
MOV ', `ifelse(eval(N & $3),0,`mov $1, $2' ,`
lea ($1), $2
')' )
ASM_START()
TEXT
ALIGN (32)
PROLOGUE(mpn_sqr_basecase)
FUNC_ENTRY(3)
cmp $4, n_param
jl L(small)
push %rbx
push %rbp
push %r12
push %r13
push %r14
mov (up), v0
mov 8(up), %rax
mov %rax, v1
mov $1, R32(n)
sub n_param, n C n = -n_param+1
push n
lea (up,n_param,8), up
lea (rp,n_param,8), rp
mul v0
test $1, R8(n)
jnz L(bx1)
L(bx0): test $2, R8(n)
mov %rax, (rp,n,8)
jnz L(b10)
L(b00):
lea (n), i C n = 5, 9, ...
mov %rdx, w1 C FIXME: Use
lea ?
xor R32(w2), R32(w2)
jmp L(m2e0)
L(b10):
lea 2(n), i C n = 7, 11, ...
mov 8(up,n,8), %rax
mov %rdx, w3 C FIXME: Use
lea ?
xor R32(w0), R32(w0)
xor R32(w1), R32(w1)
jmp L(m2e2)
L(bx1): test $2, R8(n)
mov %rax, (rp,n,8)
jz L(b11)
L(b01):
lea 1(n), i C n = 6, 10, ...
mov %rdx, w0 C FIXME: Use
lea ?
xor R32(w1), R32(w1)
jmp L(m2e1)
L(b11):
lea -1(n), i C n = 4, 8, 12, ...
mov %rdx, w2 C FIXME: Use
lea ?
xor R32(w3), R32(w3)
jmp L(m2e3)
ALIGNx
L(m2top1):
mul v0
add %rax, w3
mov -8(up,i,8), %rax
mov w3, -8(rp,i,8)
adc %rdx, w0
adc $0, R32(w1)
mul v1
add %rax, w0
adc %rdx, w1
L(m2e1):
mov $0, R32(w2)
mov (up,i,8), %rax
mul v0
add %rax, w0
mov w0, (rp,i,8)
adc %rdx, w1
mov (up,i,8), %rax
adc $0, R32(w2)
mul v1
add %rax, w1
adc %rdx, w2
mov 8(up,i,8), %rax
mul v0
mov $0, R32(w3)
add %rax, w1
adc %rdx, w2
adc $0, R32(w3)
mov 8(up,i,8), %rax
mul v1
add %rax, w2
mov w1, 8(rp,i,8)
adc %rdx, w3
mov $0, R32(w0)
mov 16(up,i,8), %rax
mul v0
add %rax, w2
mov 16(up,i,8), %rax
adc %rdx, w3
adc $0, R32(w0)
mul v1
mov $0, R32(w1)
add %rax, w3
mov 24(up,i,8), %rax
mov w2, 16(rp,i,8)
adc %rdx, w0
add $4, i
js L(m2top1)
mul v0
add %rax, w3
mov I(-8(up),-8(up,i,8)), %rax
mov w3, I(-8(rp),-8(rp,i,8))
adc %rdx, w0
adc R32(w1), R32(w1)
mul v1
add w0, %rax
adc w1, %rdx
mov %rax, I((rp),(rp,i,8))
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n C decrease |n|
jmp L(am2o3)
ALIGNx
L(m2top3):
mul v0
add %rax, w3
mov -8(up,i,8), %rax
mov w3, -8(rp,i,8)
adc %rdx, w0
adc $0, R32(w1)
mul v1
add %rax, w0
adc %rdx, w1
mov $0, R32(w2)
mov (up,i,8), %rax
mul v0
add %rax, w0
mov w0, (rp,i,8)
adc %rdx, w1
mov (up,i,8), %rax
adc $0, R32(w2)
mul v1
add %rax, w1
adc %rdx, w2
mov 8(up,i,8), %rax
mul v0
mov $0, R32(w3)
add %rax, w1
adc %rdx, w2
adc $0, R32(w3)
mov 8(up,i,8), %rax
mul v1
add %rax, w2
mov w1, 8(rp,i,8)
adc %rdx, w3
L(m2e3):
mov $0, R32(w0)
mov 16(up,i,8), %rax
mul v0
add %rax, w2
mov 16(up,i,8), %rax
adc %rdx, w3
adc $0, R32(w0)
mul v1
mov $0, R32(w1)
add %rax, w3
mov 24(up,i,8), %rax
mov w2, 16(rp,i,8)
adc %rdx, w0
add $4, i
js L(m2top3)
mul v0
add %rax, w3
mov I(-8(up),-8(up,i,8)), %rax
mov w3, I(-8(rp),-8(rp,i,8))
adc %rdx, w0
adc R32(w1), R32(w1)
mul v1
add w0, %rax
adc w1, %rdx
mov %rax, I((rp),(rp,i,8))
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n C decrease |n|
cmp $-1, n
jz L(cor1) C jumps iff entry n = 4
L(am2o1):
mov -8(up,n,8), v0
mov (up,n,8), %rax
mov %rax, v1
lea 1(n), i
mul v0
mov %rax, X1
MOV ( %rdx, X0, 128)
mov (rp,n,8), w1
xor R32(w2), R32(w2)
mov 8(up,n,8), %rax
xor R32(w3), R32(w3)
jmp L(lo1)
ALIGNx
L(am2top1):
mul v1
add w0, w1
adc %rax, w2
mov (up,i,8), %rax
MOV ( %rdx, w3, 1)
adc $0, w3
L(lo1):
mul v0
add w1, X1
mov X1, -8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 2)
adc $0, X1
mov (up,i,8), %rax
mul v1
MOV ( %rdx, w0, 4)
mov (rp,i,8), w1
add w1, w2
adc %rax, w3
adc $0, w0
mov 8(up,i,8), %rax
mul v0
add w2, X0
adc %rax, X1
mov X0, (rp,i,8)
MOV ( %rdx, X0, 8)
adc $0, X0
mov 8(up,i,8), %rax
mov 8(rp,i,8), w2
mul v1
add w2, w3
adc %rax, w0
MOV ( %rdx, w1, 16)
adc $0, w1
mov 16(up,i,8), %rax
mul v0
add w3, X1
mov X1, 8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 32)
mov 16(rp,i,8), w3
adc $0, X1
mov 16(up,i,8), %rax
mul v1
add w3, w0
MOV ( %rdx, w2, 64)
adc %rax, w1
mov 24(up,i,8), %rax
adc $0, w2
mul v0
add w0, X0
mov X0, 16(rp,i,8)
MOV ( %rdx, X0, 128)
adc %rax, X1
mov 24(up,i,8), %rax
mov 24(rp,i,8), w0
adc $0, X0
add $4, i
jnc L(am2top1)
mul v1
add w0, w1
adc w2, %rax
adc Z(i,$0), %rdx
add w1, X1
adc Z(i,$0), X0
mov X1, I(-8(rp),-8(rp,i,8))
add X0, %rax
mov %rax, I((rp),(rp,i,8))
adc Z(i,$0), %rdx
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n
L(am2o3):
mov -8(up,n,8), v0
mov (up,n,8), %rax
mov %rax, v1
lea -1(n), i
mul v0
mov %rax, X1
MOV ( %rdx, X0, 8)
mov (rp,n,8), w3
xor R32(w0), R32(w0)
xor R32(w1), R32(w1)
mov 8(up,n,8), %rax
jmp L(lo3)
ALIGNx
L(am2top3):
mul v1
add w0, w1
adc %rax, w2
mov (up,i,8), %rax
MOV ( %rdx, w3, 1)
adc $0, w3
mul v0
add w1, X1
mov X1, -8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 2)
adc $0, X1
mov (up,i,8), %rax
mul v1
MOV ( %rdx, w0, 4)
mov (rp,i,8), w1
add w1, w2
adc %rax, w3
adc $0, w0
mov 8(up,i,8), %rax
mul v0
add w2, X0
adc %rax, X1
mov X0, (rp,i,8)
MOV ( %rdx, X0, 8)
adc $0, X0
mov 8(up,i,8), %rax
mov 8(rp,i,8), w2
mul v1
add w2, w3
adc %rax, w0
MOV ( %rdx, w1, 16)
adc $0, w1
mov 16(up,i,8), %rax
L(lo3):
mul v0
add w3, X1
mov X1, 8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 32)
mov 16(rp,i,8), w3
adc $0, X1
mov 16(up,i,8), %rax
mul v1
add w3, w0
MOV ( %rdx, w2, 64)
adc %rax, w1
mov 24(up,i,8), %rax
adc $0, w2
mul v0
add w0, X0
mov X0, 16(rp,i,8)
MOV ( %rdx, X0, 128)
adc %rax, X1
mov 24(up,i,8), %rax
mov 24(rp,i,8), w0
adc $0, X0
add $4, i
jnc L(am2top3)
mul v1
add w0, w1
adc w2, %rax
adc Z(i,$0), %rdx
add w1, X1
adc Z(i,$0), X0
mov X1, I(-8(rp),-8(rp,i,8))
add X0, %rax
mov %rax, I((rp),(rp,i,8))
adc Z(i,$0), %rdx
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n
cmp $-1, n
jnz L(am2o1)
L(cor1):
pop n
mov %rdx, w3
mov -16(up), v0
mov -8(up), %rax
mul v0
add w3, %rax
adc $0, %rdx
mov %rax, -8(rp)
mov %rdx, (rp)
jmp L(sqr_diag_addlsh1)
ALIGNx
L(m2top2):
L(m2e2):
mul v0
add %rax, w3
mov -8(up,i,8), %rax
mov w3, -8(rp,i,8)
adc %rdx, w0
adc $0, R32(w1)
mul v1
add %rax, w0
adc %rdx, w1
mov $0, R32(w2)
mov (up,i,8), %rax
mul v0
add %rax, w0
mov w0, (rp,i,8)
adc %rdx, w1
mov (up,i,8), %rax
adc $0, R32(w2)
mul v1
add %rax, w1
adc %rdx, w2
mov 8(up,i,8), %rax
mul v0
mov $0, R32(w3)
add %rax, w1
adc %rdx, w2
adc $0, R32(w3)
mov 8(up,i,8), %rax
mul v1
add %rax, w2
mov w1, 8(rp,i,8)
adc %rdx, w3
mov $0, R32(w0)
mov 16(up,i,8), %rax
mul v0
add %rax, w2
mov 16(up,i,8), %rax
adc %rdx, w3
adc $0, R32(w0)
mul v1
mov $0, R32(w1)
add %rax, w3
mov 24(up,i,8), %rax
mov w2, 16(rp,i,8)
adc %rdx, w0
add $4, i
js L(m2top2)
mul v0
add %rax, w3
mov I(-8(up),-8(up,i,8)), %rax
mov w3, I(-8(rp),-8(rp,i,8))
adc %rdx, w0
adc R32(w1), R32(w1)
mul v1
add w0, %rax
adc w1, %rdx
mov %rax, I((rp),(rp,i,8))
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n C decrease |n|
jmp L(am2o0)
ALIGNx
L(m2top0):
mul v0
add %rax, w3
mov -8(up,i,8), %rax
mov w3, -8(rp,i,8)
adc %rdx, w0
adc $0, R32(w1)
mul v1
add %rax, w0
adc %rdx, w1
mov $0, R32(w2)
mov (up,i,8), %rax
mul v0
add %rax, w0
mov w0, (rp,i,8)
adc %rdx, w1
mov (up,i,8), %rax
adc $0, R32(w2)
mul v1
add %rax, w1
adc %rdx, w2
L(m2e0):
mov 8(up,i,8), %rax
mul v0
mov $0, R32(w3)
add %rax, w1
adc %rdx, w2
adc $0, R32(w3)
mov 8(up,i,8), %rax
mul v1
add %rax, w2
mov w1, 8(rp,i,8)
adc %rdx, w3
mov $0, R32(w0)
mov 16(up,i,8), %rax
mul v0
add %rax, w2
mov 16(up,i,8), %rax
adc %rdx, w3
adc $0, R32(w0)
mul v1
mov $0, R32(w1)
add %rax, w3
mov 24(up,i,8), %rax
mov w2, 16(rp,i,8)
adc %rdx, w0
add $4, i
js L(m2top0)
mul v0
add %rax, w3
mov I(-8(up),-8(up,i,8)), %rax
mov w3, I(-8(rp),-8(rp,i,8))
adc %rdx, w0
adc R32(w1), R32(w1)
mul v1
add w0, %rax
adc w1, %rdx
mov %rax, I((rp),(rp,i,8))
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n C decrease |n|
cmp $-2, n
jz L(cor2) C jumps iff entry n = 5
L(am2o2):
mov -8(up,n,8), v0
mov (up,n,8), %rax
mov %rax, v1
lea -2(n), i
mul v0
mov %rax, X0
MOV ( %rdx, X1, 32)
mov (rp,n,8), w0
xor R32(w1), R32(w1)
xor R32(w2), R32(w2)
mov 8(up,n,8), %rax
jmp L(lo2)
ALIGNx
L(am2top2):
mul v1
add w0, w1
adc %rax, w2
mov (up,i,8), %rax
MOV ( %rdx, w3, 1)
adc $0, w3
mul v0
add w1, X1
mov X1, -8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 2)
adc $0, X1
mov (up,i,8), %rax
mul v1
MOV ( %rdx, w0, 4)
mov (rp,i,8), w1
add w1, w2
adc %rax, w3
adc $0, w0
mov 8(up,i,8), %rax
mul v0
add w2, X0
adc %rax, X1
mov X0, (rp,i,8)
MOV ( %rdx, X0, 8)
adc $0, X0
mov 8(up,i,8), %rax
mov 8(rp,i,8), w2
mul v1
add w2, w3
adc %rax, w0
MOV ( %rdx, w1, 16)
adc $0, w1
mov 16(up,i,8), %rax
mul v0
add w3, X1
mov X1, 8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 32)
mov 16(rp,i,8), w3
adc $0, X1
mov 16(up,i,8), %rax
mul v1
add w3, w0
MOV ( %rdx, w2, 64)
adc %rax, w1
mov 24(up,i,8), %rax
adc $0, w2
L(lo2):
mul v0
add w0, X0
mov X0, 16(rp,i,8)
MOV ( %rdx, X0, 128)
adc %rax, X1
mov 24(up,i,8), %rax
mov 24(rp,i,8), w0
adc $0, X0
add $4, i
jnc L(am2top2)
mul v1
add w0, w1
adc w2, %rax
adc Z(i,$0), %rdx
add w1, X1
adc Z(i,$0), X0
mov X1, I(-8(rp),-8(rp,i,8))
add X0, %rax
mov %rax, I((rp),(rp,i,8))
adc Z(i,$0), %rdx
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n
L(am2o0):
mov -8(up,n,8), v0
mov (up,n,8), %rax
mov %rax, v1
lea 0(n), i
mul v0
mov %rax, X0
MOV ( %rdx, X1, 2)
xor R32(w0), R32(w0)
mov (rp,n,8), w2
xor R32(w3), R32(w3)
jmp L(lo0)
ALIGNx
L(am2top0):
mul v1
add w0, w1
adc %rax, w2
mov (up,i,8), %rax
MOV ( %rdx, w3, 1)
adc $0, w3
mul v0
add w1, X1
mov X1, -8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 2)
adc $0, X1
mov (up,i,8), %rax
mul v1
MOV ( %rdx, w0, 4)
mov (rp,i,8), w1
add w1, w2
adc %rax, w3
adc $0, w0
L(lo0):
mov 8(up,i,8), %rax
mul v0
add w2, X0
adc %rax, X1
mov X0, (rp,i,8)
MOV ( %rdx, X0, 8)
adc $0, X0
mov 8(up,i,8), %rax
mov 8(rp,i,8), w2
mul v1
add w2, w3
adc %rax, w0
MOV ( %rdx, w1, 16)
adc $0, w1
mov 16(up,i,8), %rax
mul v0
add w3, X1
mov X1, 8(rp,i,8)
adc %rax, X0
MOV ( %rdx, X1, 32)
mov 16(rp,i,8), w3
adc $0, X1
mov 16(up,i,8), %rax
mul v1
add w3, w0
MOV ( %rdx, w2, 64)
adc %rax, w1
mov 24(up,i,8), %rax
adc $0, w2
mul v0
add w0, X0
mov X0, 16(rp,i,8)
MOV ( %rdx, X0, 128)
adc %rax, X1
mov 24(up,i,8), %rax
mov 24(rp,i,8), w0
adc $0, X0
add $4, i
jnc L(am2top0)
mul v1
add w0, w1
adc w2, %rax
adc Z(i,$0), %rdx
add w1, X1
adc Z(i,$0), X0
mov X1, I(-8(rp),-8(rp,i,8))
add X0, %rax
mov %rax, I((rp),(rp,i,8))
adc Z(i,$0), %rdx
mov %rdx, I(8(rp),8(rp,i,8))
lea 16(rp), rp
add $2, n
cmp $-2, n
jnz L(am2o2)
L(cor2):
pop n
mov -24(up), v0
mov %rax, w2
mov %rdx, w0
mov -16(up), %rax
mov %rax, v1
mul v0
mov %rax, X0
MOV ( %rdx, X1, 32)
mov -8(up), %rax
mul v0
add w2, X0
mov X0, -16(rp)
MOV ( %rdx, X0, 128)
adc %rax, X1
mov -8(up), %rax
adc $0, X0
mul v1
add w0, X1
adc $0, X0
mov X1, -8(rp)
add X0, %rax
mov %rax, (rp)
adc $0, %rdx
mov %rdx, 8(rp)
lea 8(rp), rp
L(sqr_diag_addlsh1):
mov -8(up,n,8), %rax
shl n
xor R32(%rbx), R32(%rbx)
mul %rax
mov 8(rp,n,8), %r11
lea (%rdx), %r10
mov 16(rp,n,8), %r9
add %r11, %r11
jmp L(dm)
ALIGNx
L(dtop):
mul %rax
add %r11, %r10
mov 8(rp,n,8), %r11
mov %r10, -8(rp,n,8)
adc %r9, %rax
lea (%rdx,%rbx), %r10
mov 16(rp,n,8), %r9
adc %r11, %r11
L(dm):
mov %rax, (rp,n,8)
mov (up,n,4), %rax
adc %r9, %r9
setc R8(%rbx)
add $2, n
js L(dtop)
mul %rax
add %r11, %r10
mov %r10, -8(rp)
adc %r9, %rax
lea (%rdx,%rbx), %r10
mov %rax, (rp)
adc $0, %r10
mov %r10, 8(rp)
pop %r14
pop %r13
pop %r12
pop %rbp
pop %rbx
FUNC_EXIT()
ret
ALIGN (16)
L(small):
mov (up), %rax
cmp $2, n_param
jae L(gt1)
L(n1):
mul %rax
mov %rax, (rp)
mov %rdx, 8(rp)
FUNC_EXIT()
ret
L(gt1):
jne L(gt2)
L(n2):
mov %rax, %r8
mul %rax
mov 8(up), %r11
mov %rax, (rp)
mov %r11, %rax
mov %rdx, %r9
mul %rax
mov %rax, %r10
mov %r11, %rax
mov %rdx, %r11
mul %r8
xor %r8, %r8
add %rax, %r9
adc %rdx, %r10
adc %r8, %r11
add %rax, %r9
mov %r9, 8(rp)
adc %rdx, %r10
mov %r10, 16(rp)
adc %r8, %r11
mov %r11, 24(rp)
FUNC_EXIT()
ret
L(gt2):
L(n3):
mov %rax, %r10
mul %rax
mov 8(up), %r11
mov %rax, (rp)
mov %r11, %rax
mov %rdx, 8(rp)
mul %rax
mov 16(up), %rcx
mov %rax, 16(rp)
mov %rcx, %rax
mov %rdx, 24(rp)
mul %rax
mov %rax, 32(rp)
mov %rdx, 40(rp)
mov %r11, %rax
mul %r10
mov %rax, %r8
mov %rcx, %rax
mov %rdx, %r9
mul %r10
xor %r10, %r10
add %rax, %r9
mov %r11, %rax
mov %r10, %r11
adc %rdx, %r10
mul %rcx
add %rax, %r10
adc %r11, %rdx
add %r8, %r8
adc %r9, %r9
adc %r10, %r10
adc %rdx, %rdx
adc %r11, %r11
add %r8, 8(rp)
adc %r9, 16(rp)
adc %r10, 24(rp)
adc %rdx, 32(rp)
adc %r11, 40(rp)
FUNC_EXIT()
ret
EPILOGUE()
Messung V0.5 in Prozent C=100 H=95 G=97
¤ Dauer der Verarbeitung: 0.17 Sekunden
(vorverarbeitet am 2026-04-29)
¤ *© Formatika GbR, Deutschland
