dnl x86-64 mpn_rsh1add_n/mpn_rsh1sub_n optimized for Pentium 4.
dnl Contributed to the GNU project by Torbjorn Granlund.
dnl Copyright 2007, 2008, 2010-2012 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
C AMD K8,K9 4.13
C AMD K10 4.13
C Intel P4 5.70
C Intel core2 4.75
C Intel corei 5
C Intel atom 8.75
C VIA nano 5.25
C TODO
C * Try to make this smaller, 746 bytes seem excessive for this 2nd class
C function. Less sw pipelining would help, and since we now probably
C pipeline somewhat too deeply, it might not affect performance too much.
C * A separate small-n loop might speed things as well as make things smaller.
C That loop should be selected before pushing registers.
C INPUT PARAMETERS
define(`rp', `%rdi')
define(`up', `%rsi')
define(`vp', `%rdx')
define(`n', `%rcx')
define(`cy', `%r8')
ifdef(`OPERATION_rsh1add_n', `
define(ADDSUB, add)
define(func, mpn_rsh1add_n)
define(func_nc, mpn_rsh1add_nc)')
ifdef(`OPERATION_rsh1sub_n', `
define(ADDSUB, sub)
define(func, mpn_rsh1sub_n)
define(func_nc, mpn_rsh1sub_nc)')
ABI_SUPPORT(DOS64)
ABI_SUPPORT(STD64)
MULFUNC_PROLOGUE(mpn_rsh1add_n mpn_rsh1add_nc mpn_rsh1sub_n mpn_rsh1sub_nc)
ASM_START()
TEXT
PROLOGUE(func)
FUNC_ENTRY(4)
xor %r8, %r8
IFDOS(` jmp L(ent) ')
EPILOGUE()
PROLOGUE(func_nc)
FUNC_ENTRY(4)
IFDOS(` mov 56(%rsp), %r8 ')
L(ent): push %rbx
push %r12
push %r13
push %r14
push %r15
mov (vp), %r9
mov (up), %r15
mov R32(n), R32(%rax)
and $3, R32(%rax)
jne L(n00)
mov R32(%r8), R32(%rbx) C n = 0, 4, 8, ...
mov 8(up), %r10
ADDSUB %r9, %r15
mov 8(vp), %r9
setc R8(%rax)
ADDSUB %rbx, %r15 C return bit
jnc 1f
mov $1, R8(%rax)
1: mov 16(up), %r12
ADDSUB %r9, %r10
mov 16(vp), %r9
setc R8(%rbx)
mov %r15, %r13
ADDSUB %rax, %r10
jnc 1f
mov $1, R8(%rbx)
1: mov 24(up), %r11
ADDSUB %r9, %r12
lea 32(up), up
mov 24(vp), %r9
lea 32(vp), vp
setc R8(%rax)
mov %r10, %r14
shl $63, %r10
shr %r13
jmp L(L00)
L(n00): cmp $2, R32(%rax)
jnc L(n01)
xor R32(%rbx), R32(%rbx) C n = 1, 5, 9, ...
lea -24(rp), rp
mov R32(%r8), R32(%rax)
dec n
jnz L(gt1)
ADDSUB %r9, %r15
setc R8(%rbx)
ADDSUB %rax, %r15
jnc 1f
mov $1, R8(%rbx)
1: mov %r15, %r14
shl $63, %rbx
shr %r14
jmp L(cj1)
L(gt1): mov 8(up), %r8
ADDSUB %r9, %r15
mov 8(vp), %r9
setc R8(%rbx)
ADDSUB %rax, %r15
jnc 1f
mov $1, R8(%rbx)
1: mov 16(up), %r10
ADDSUB %r9, %r8
mov 16(vp), %r9
setc R8(%rax)
mov %r15, %r14
ADDSUB %rbx, %r8
jnc 1f
mov $1, R8(%rax)
1: mov 24(up), %r12
ADDSUB %r9, %r10
mov 24(vp), %r9
setc R8(%rbx)
mov %r8, %r13
shl $63, %r8
shr %r14
lea 8(up), up
lea 8(vp), vp
jmp L(L01)
L(n01): jne L(n10)
lea -16(rp), rp C n = 2, 6, 10, ...
mov R32(%r8), R32(%rbx)
mov 8(up), %r11
ADDSUB %r9, %r15
mov 8(vp), %r9
setc R8(%rax)
ADDSUB %rbx, %r15
jnc 1f
mov $1, R8(%rax)
1: sub $2, n
jnz L(gt2)
ADDSUB %r9, %r11
setc R8(%rbx)
mov %r15, %r13
ADDSUB %rax, %r11
jnc 1f
mov $1, R8(%rbx)
1: mov %r11, %r14
shl $63, %r11
shr %r13
jmp L(cj2)
L(gt2): mov 16(up), %r8
ADDSUB %r9, %r11
mov 16(vp), %r9
setc R8(%rbx)
mov %r15, %r13
ADDSUB %rax, %r11
jnc 1f
mov $1, R8(%rbx)
1: mov 24(up), %r10
ADDSUB %r9, %r8
mov 24(vp), %r9
setc R8(%rax)
mov %r11, %r14
shl $63, %r11
shr %r13
lea 16(up), up
lea 16(vp), vp
jmp L(L10)
L(n10): xor R32(%rbx), R32(%rbx) C n = 3, 7, 11, ...
lea -8(rp), rp
mov R32(%r8), R32(%rax)
mov 8(up), %r12
ADDSUB %r9, %r15
mov 8(vp), %r9
setc R8(%rbx)
ADDSUB %rax, %r15
jnc 1f
mov $1, R8(%rbx)
1: mov 16(up), %r11
ADDSUB %r9, %r12
mov 16(vp), %r9
setc R8(%rax)
mov %r15, %r14
ADDSUB %rbx, %r12
jnc 1f
mov $1, R8(%rax)
1: sub $3, n
jnz L(gt3)
ADDSUB %r9, %r11
setc R8(%rbx)
mov %r12, %r13
shl $63, %r12
shr %r14
jmp L(cj3)
L(gt3): mov 24(up), %r8
ADDSUB %r9, %r11
mov 24(vp), %r9
setc R8(%rbx)
mov %r12, %r13
shl $63, %r12
shr %r14
lea 24(up), up
lea 24(vp), vp
jmp L(L11)
L(c0): mov $1, R8(%rbx)
jmp L(rc0)
L(c1): mov $1, R8(%rax)
jmp L(rc1)
L(c2): mov $1, R8(%rbx)
jmp L(rc2)
ALIGN(16)
L(top): mov (up), %r8 C not on critical path
or %r13, %r10
ADDSUB %r9, %r11 C not on critical path
mov (vp), %r9 C not on critical path
setc R8(%rbx) C save carry out
mov %r12, %r13 C new for later
shl $63, %r12 C shift new right
shr %r14 C shift old left
mov %r10, (rp)
L(L11): ADDSUB %rax, %r11 C apply previous carry out
jc L(c0) C jump if ripple
L(rc0): mov 8(up), %r10
or %r14, %r12
ADDSUB %r9, %r8
mov 8(vp), %r9
setc R8(%rax)
mov %r11, %r14
shl $63, %r11
shr %r13
mov %r12, 8(rp)
L(L10): ADDSUB %rbx, %r8
jc L(c1)
L(rc1): mov 16(up), %r12
or %r13, %r11
ADDSUB %r9, %r10
mov 16(vp), %r9
setc R8(%rbx)
mov %r8, %r13
shl $63, %r8
shr %r14
mov %r11, 16(rp)
L(L01): ADDSUB %rax, %r10
jc L(c2)
L(rc2): mov 24(up), %r11
or %r14, %r8
ADDSUB %r9, %r12
lea 32(up), up
mov 24(vp), %r9
lea 32(vp), vp
setc R8(%rax)
mov %r10, %r14
shl $63, %r10
shr %r13
mov %r8, 24(rp)
lea 32(rp), rp
L(L00): ADDSUB %rbx, %r12
jc L(c3)
L(rc3): sub $4, n
ja L(top)
L(end): or %r13, %r10
ADDSUB %r9, %r11
setc R8(%rbx)
mov %r12, %r13
shl $63, %r12
shr %r14
mov %r10, (rp)
L(cj3): ADDSUB %rax, %r11
jnc 1f
mov $1, R8(%rbx)
1: or %r14, %r12
mov %r11, %r14
shl $63, %r11
shr %r13
mov %r12, 8(rp)
L(cj2): or %r13, %r11
shl $63, %rbx
shr %r14
mov %r11, 16(rp)
L(cj1): or %r14, %rbx
mov %rbx, 24(rp)
mov R32(%r15), R32(%rax)
and $1, R32(%rax)
pop %r15
pop %r14
pop %r13
pop %r12
pop %rbx
FUNC_EXIT()
ret
L(c3): mov $1, R8(%rax)
jmp L(rc3)
EPILOGUE()