virtualx-engine/drivers/builtin_openssl/crypto/bn/asm/ia64-mont.pl
Juan Linietsky 87f37bc5a3 -Added OpenSSL and HTTPS support
-Built-in version of the library for Windows, Android and iOS (other OSs use system one)
-Small fixes all around
2014-04-28 21:56:43 -03:00

851 lines
25 KiB
Raku
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

#!/usr/bin/env perl
#
# ====================================================================
# Written by Andy Polyakov <appro@fy.chalmers.se> for the OpenSSL
# project. The module is, however, dual licensed under OpenSSL and
# CRYPTOGAMS licenses depending on where you obtain it. For further
# details see http://www.openssl.org/~appro/cryptogams/.
# ====================================================================
# January 2010
#
# "Teaser" Montgomery multiplication module for IA-64. There are
# several possibilities for improvement:
#
# - modulo-scheduling outer loop would eliminate quite a number of
# stalls after ldf8, xma and getf.sig outside inner loop and
# improve shorter key performance;
# - shorter vector support [with input vectors being fetched only
# once] should be added;
# - 2x unroll with help of n0[1] would make the code scalable on
# "wider" IA-64, "wider" than Itanium 2 that is, which is not of
# acute interest, because upcoming Tukwila's individual cores are
# reportedly based on Itanium 2 design;
# - dedicated squaring procedure(?);
#
# January 2010
#
# Shorter vector support is implemented by zero-padding ap and np
# vectors up to 8 elements, or 512 bits. This means that 256-bit
# inputs will be processed only 2 times faster than 512-bit inputs,
# not 4 [as one would expect, because algorithm complexity is n^2].
# The reason for padding is that inputs shorter than 512 bits won't
# be processed faster anyway, because minimal critical path of the
# core loop happens to match 512-bit timing. Either way, it resulted
# in >100% improvement of 512-bit RSA sign benchmark and 50% - of
# 1024-bit one [in comparison to original version of *this* module].
#
# So far 'openssl speed rsa dsa' output on 900MHz Itanium 2 *with*
# this module is:
# sign verify sign/s verify/s
# rsa 512 bits 0.000290s 0.000024s 3452.8 42031.4
# rsa 1024 bits 0.000793s 0.000058s 1261.7 17172.0
# rsa 2048 bits 0.005908s 0.000148s 169.3 6754.0
# rsa 4096 bits 0.033456s 0.000469s 29.9 2133.6
# dsa 512 bits 0.000253s 0.000198s 3949.9 5057.0
# dsa 1024 bits 0.000585s 0.000607s 1708.4 1647.4
# dsa 2048 bits 0.001453s 0.001703s 688.1 587.4
#
# ... and *without* (but still with ia64.S):
#
# rsa 512 bits 0.000670s 0.000041s 1491.8 24145.5
# rsa 1024 bits 0.001988s 0.000080s 502.9 12499.3
# rsa 2048 bits 0.008702s 0.000189s 114.9 5293.9
# rsa 4096 bits 0.043860s 0.000533s 22.8 1875.9
# dsa 512 bits 0.000441s 0.000427s 2265.3 2340.6
# dsa 1024 bits 0.000823s 0.000867s 1215.6 1153.2
# dsa 2048 bits 0.001894s 0.002179s 528.1 458.9
#
# As it can be seen, RSA sign performance improves by 130-30%,
# hereafter less for longer keys, while verify - by 74-13%.
# DSA performance improves by 115-30%.
if ($^O eq "hpux") {
$ADDP="addp4";
for (@ARGV) { $ADDP="add" if (/[\+DD|\-mlp]64/); }
} else { $ADDP="add"; }
$code=<<___;
.explicit
.text
// int bn_mul_mont (BN_ULONG *rp,const BN_ULONG *ap,
// const BN_ULONG *bp,const BN_ULONG *np,
// const BN_ULONG *n0p,int num);
.align 64
.global bn_mul_mont#
.proc bn_mul_mont#
bn_mul_mont:
.prologue
.body
{ .mmi; cmp4.le p6,p7=2,r37;;
(p6) cmp4.lt.unc p8,p9=8,r37
mov ret0=r0 };;
{ .bbb;
(p9) br.cond.dptk.many bn_mul_mont_8
(p8) br.cond.dpnt.many bn_mul_mont_general
(p7) br.ret.spnt.many b0 };;
.endp bn_mul_mont#
prevfs=r2; prevpr=r3; prevlc=r10; prevsp=r11;
rptr=r8; aptr=r9; bptr=r14; nptr=r15;
tptr=r16; // &tp[0]
tp_1=r17; // &tp[-1]
num=r18; len=r19; lc=r20;
topbit=r21; // carry bit from tmp[num]
n0=f6;
m0=f7;
bi=f8;
.align 64
.local bn_mul_mont_general#
.proc bn_mul_mont_general#
bn_mul_mont_general:
.prologue
{ .mmi; .save ar.pfs,prevfs
alloc prevfs=ar.pfs,6,2,0,8
$ADDP aptr=0,in1
.save ar.lc,prevlc
mov prevlc=ar.lc }
{ .mmi; .vframe prevsp
mov prevsp=sp
$ADDP bptr=0,in2
.save pr,prevpr
mov prevpr=pr };;
.body
.rotf alo[6],nlo[4],ahi[8],nhi[6]
.rotr a[3],n[3],t[2]
{ .mmi; ldf8 bi=[bptr],8 // (*bp++)
ldf8 alo[4]=[aptr],16 // ap[0]
$ADDP r30=8,in1 };;
{ .mmi; ldf8 alo[3]=[r30],16 // ap[1]
ldf8 alo[2]=[aptr],16 // ap[2]
$ADDP in4=0,in4 };;
{ .mmi; ldf8 alo[1]=[r30] // ap[3]
ldf8 n0=[in4] // n0
$ADDP rptr=0,in0 }
{ .mmi; $ADDP nptr=0,in3
mov r31=16
zxt4 num=in5 };;
{ .mmi; ldf8 nlo[2]=[nptr],8 // np[0]
shladd len=num,3,r0
shladd r31=num,3,r31 };;
{ .mmi; ldf8 nlo[1]=[nptr],8 // np[1]
add lc=-5,num
sub r31=sp,r31 };;
{ .mfb; and sp=-16,r31 // alloca
xmpy.hu ahi[2]=alo[4],bi // ap[0]*bp[0]
nop.b 0 }
{ .mfb; nop.m 0
xmpy.lu alo[4]=alo[4],bi
brp.loop.imp .L1st_ctop,.L1st_cend-16
};;
{ .mfi; nop.m 0
xma.hu ahi[1]=alo[3],bi,ahi[2] // ap[1]*bp[0]
add tp_1=8,sp }
{ .mfi; nop.m 0
xma.lu alo[3]=alo[3],bi,ahi[2]
mov pr.rot=0x20001f<<16
// ------^----- (p40) at first (p23)
// ----------^^ p[16:20]=1
};;
{ .mfi; nop.m 0
xmpy.lu m0=alo[4],n0 // (ap[0]*bp[0])*n0
mov ar.lc=lc }
{ .mfi; nop.m 0
fcvt.fxu.s1 nhi[1]=f0
mov ar.ec=8 };;
.align 32
.L1st_ctop:
.pred.rel "mutex",p40,p42
{ .mfi; (p16) ldf8 alo[0]=[aptr],8 // *(aptr++)
(p18) xma.hu ahi[0]=alo[2],bi,ahi[1]
(p40) add n[2]=n[2],a[2] } // (p23) }
{ .mfi; (p18) ldf8 nlo[0]=[nptr],8 // *(nptr++)(p16)
(p18) xma.lu alo[2]=alo[2],bi,ahi[1]
(p42) add n[2]=n[2],a[2],1 };; // (p23)
{ .mfi; (p21) getf.sig a[0]=alo[5]
(p20) xma.hu nhi[0]=nlo[2],m0,nhi[1]
(p42) cmp.leu p41,p39=n[2],a[2] } // (p23)
{ .mfi; (p23) st8 [tp_1]=n[2],8
(p20) xma.lu nlo[2]=nlo[2],m0,nhi[1]
(p40) cmp.ltu p41,p39=n[2],a[2] } // (p23)
{ .mmb; (p21) getf.sig n[0]=nlo[3]
(p16) nop.m 0
br.ctop.sptk .L1st_ctop };;
.L1st_cend:
{ .mmi; getf.sig a[0]=ahi[6] // (p24)
getf.sig n[0]=nhi[4]
add num=-1,num };; // num--
{ .mmi; .pred.rel "mutex",p40,p42
(p40) add n[0]=n[0],a[0]
(p42) add n[0]=n[0],a[0],1
sub aptr=aptr,len };; // rewind
{ .mmi; .pred.rel "mutex",p40,p42
(p40) cmp.ltu p41,p39=n[0],a[0]
(p42) cmp.leu p41,p39=n[0],a[0]
sub nptr=nptr,len };;
{ .mmi; .pred.rel "mutex",p39,p41
(p39) add topbit=r0,r0
(p41) add topbit=r0,r0,1
nop.i 0 }
{ .mmi; st8 [tp_1]=n[0]
add tptr=16,sp
add tp_1=8,sp };;
.Louter:
{ .mmi; ldf8 bi=[bptr],8 // (*bp++)
ldf8 ahi[3]=[tptr] // tp[0]
add r30=8,aptr };;
{ .mmi; ldf8 alo[4]=[aptr],16 // ap[0]
ldf8 alo[3]=[r30],16 // ap[1]
add r31=8,nptr };;
{ .mfb; ldf8 alo[2]=[aptr],16 // ap[2]
xma.hu ahi[2]=alo[4],bi,ahi[3] // ap[0]*bp[i]+tp[0]
brp.loop.imp .Linner_ctop,.Linner_cend-16
}
{ .mfb; ldf8 alo[1]=[r30] // ap[3]
xma.lu alo[4]=alo[4],bi,ahi[3]
clrrrb.pr };;
{ .mfi; ldf8 nlo[2]=[nptr],16 // np[0]
xma.hu ahi[1]=alo[3],bi,ahi[2] // ap[1]*bp[i]
nop.i 0 }
{ .mfi; ldf8 nlo[1]=[r31] // np[1]
xma.lu alo[3]=alo[3],bi,ahi[2]
mov pr.rot=0x20101f<<16
// ------^----- (p40) at first (p23)
// --------^--- (p30) at first (p22)
// ----------^^ p[16:20]=1
};;
{ .mfi; st8 [tptr]=r0 // tp[0] is already accounted
xmpy.lu m0=alo[4],n0 // (ap[0]*bp[i]+tp[0])*n0
mov ar.lc=lc }
{ .mfi;
fcvt.fxu.s1 nhi[1]=f0
mov ar.ec=8 };;
// This loop spins in 4*(n+7) ticks on Itanium 2 and should spin in
// 7*(n+7) ticks on Itanium (the one codenamed Merced). Factor of 7
// in latter case accounts for two-tick pipeline stall, which means
// that its performance would be ~20% lower than optimal one. No
// attempt was made to address this, because original Itanium is
// hardly represented out in the wild...
.align 32
.Linner_ctop:
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p30,p32
{ .mfi; (p16) ldf8 alo[0]=[aptr],8 // *(aptr++)
(p18) xma.hu ahi[0]=alo[2],bi,ahi[1]
(p40) add n[2]=n[2],a[2] } // (p23)
{ .mfi; (p16) nop.m 0
(p18) xma.lu alo[2]=alo[2],bi,ahi[1]
(p42) add n[2]=n[2],a[2],1 };; // (p23)
{ .mfi; (p21) getf.sig a[0]=alo[5]
(p16) nop.f 0
(p40) cmp.ltu p41,p39=n[2],a[2] } // (p23)
{ .mfi; (p21) ld8 t[0]=[tptr],8
(p16) nop.f 0
(p42) cmp.leu p41,p39=n[2],a[2] };; // (p23)
{ .mfi; (p18) ldf8 nlo[0]=[nptr],8 // *(nptr++)
(p20) xma.hu nhi[0]=nlo[2],m0,nhi[1]
(p30) add a[1]=a[1],t[1] } // (p22)
{ .mfi; (p16) nop.m 0
(p20) xma.lu nlo[2]=nlo[2],m0,nhi[1]
(p32) add a[1]=a[1],t[1],1 };; // (p22)
{ .mmi; (p21) getf.sig n[0]=nlo[3]
(p16) nop.m 0
(p30) cmp.ltu p31,p29=a[1],t[1] } // (p22)
{ .mmb; (p23) st8 [tp_1]=n[2],8
(p32) cmp.leu p31,p29=a[1],t[1] // (p22)
br.ctop.sptk .Linner_ctop };;
.Linner_cend:
{ .mmi; getf.sig a[0]=ahi[6] // (p24)
getf.sig n[0]=nhi[4]
nop.i 0 };;
{ .mmi; .pred.rel "mutex",p31,p33
(p31) add a[0]=a[0],topbit
(p33) add a[0]=a[0],topbit,1
mov topbit=r0 };;
{ .mfi; .pred.rel "mutex",p31,p33
(p31) cmp.ltu p32,p30=a[0],topbit
(p33) cmp.leu p32,p30=a[0],topbit
}
{ .mfi; .pred.rel "mutex",p40,p42
(p40) add n[0]=n[0],a[0]
(p42) add n[0]=n[0],a[0],1
};;
{ .mmi; .pred.rel "mutex",p44,p46
(p40) cmp.ltu p41,p39=n[0],a[0]
(p42) cmp.leu p41,p39=n[0],a[0]
(p32) add topbit=r0,r0,1 }
{ .mmi; st8 [tp_1]=n[0],8
cmp4.ne p6,p0=1,num
sub aptr=aptr,len };; // rewind
{ .mmi; sub nptr=nptr,len
(p41) add topbit=r0,r0,1
add tptr=16,sp }
{ .mmb; add tp_1=8,sp
add num=-1,num // num--
(p6) br.cond.sptk.many .Louter };;
{ .mbb; add lc=4,lc
brp.loop.imp .Lsub_ctop,.Lsub_cend-16
clrrrb.pr };;
{ .mii; nop.m 0
mov pr.rot=0x10001<<16
// ------^---- (p33) at first (p17)
mov ar.lc=lc }
{ .mii; nop.m 0
mov ar.ec=3
nop.i 0 };;
.Lsub_ctop:
.pred.rel "mutex",p33,p35
{ .mfi; (p16) ld8 t[0]=[tptr],8 // t=*(tp++)
(p16) nop.f 0
(p33) sub n[1]=t[1],n[1] } // (p17)
{ .mfi; (p16) ld8 n[0]=[nptr],8 // n=*(np++)
(p16) nop.f 0
(p35) sub n[1]=t[1],n[1],1 };; // (p17)
{ .mib; (p18) st8 [rptr]=n[2],8 // *(rp++)=r
(p33) cmp.gtu p34,p32=n[1],t[1] // (p17)
(p18) nop.b 0 }
{ .mib; (p18) nop.m 0
(p35) cmp.geu p34,p32=n[1],t[1] // (p17)
br.ctop.sptk .Lsub_ctop };;
.Lsub_cend:
{ .mmb; .pred.rel "mutex",p34,p36
(p34) sub topbit=topbit,r0 // (p19)
(p36) sub topbit=topbit,r0,1
brp.loop.imp .Lcopy_ctop,.Lcopy_cend-16
}
{ .mmb; sub rptr=rptr,len // rewind
sub tptr=tptr,len
clrrrb.pr };;
{ .mmi; and aptr=tptr,topbit
andcm bptr=rptr,topbit
mov pr.rot=1<<16 };;
{ .mii; or nptr=aptr,bptr
mov ar.lc=lc
mov ar.ec=3 };;
.Lcopy_ctop:
{ .mmb; (p16) ld8 n[0]=[nptr],8
(p18) st8 [tptr]=r0,8
(p16) nop.b 0 }
{ .mmb; (p16) nop.m 0
(p18) st8 [rptr]=n[2],8
br.ctop.sptk .Lcopy_ctop };;
.Lcopy_cend:
{ .mmi; mov ret0=1 // signal "handled"
rum 1<<5 // clear um.mfh
mov ar.lc=prevlc }
{ .mib; .restore sp
mov sp=prevsp
mov pr=prevpr,0x1ffff
br.ret.sptk.many b0 };;
.endp bn_mul_mont_general#
a1=r16; a2=r17; a3=r18; a4=r19; a5=r20; a6=r21; a7=r22; a8=r23;
n1=r24; n2=r25; n3=r26; n4=r27; n5=r28; n6=r29; n7=r30; n8=r31;
t0=r15;
ai0=f8; ai1=f9; ai2=f10; ai3=f11; ai4=f12; ai5=f13; ai6=f14; ai7=f15;
ni0=f16; ni1=f17; ni2=f18; ni3=f19; ni4=f20; ni5=f21; ni6=f22; ni7=f23;
.align 64
.skip 48 // aligns loop body
.local bn_mul_mont_8#
.proc bn_mul_mont_8#
bn_mul_mont_8:
.prologue
{ .mmi; .save ar.pfs,prevfs
alloc prevfs=ar.pfs,6,2,0,8
.vframe prevsp
mov prevsp=sp
.save ar.lc,prevlc
mov prevlc=ar.lc }
{ .mmi; add r17=-6*16,sp
add sp=-7*16,sp
.save pr,prevpr
mov prevpr=pr };;
{ .mmi; .save.gf 0,0x10
stf.spill [sp]=f16,-16
.save.gf 0,0x20
stf.spill [r17]=f17,32
add r16=-5*16,prevsp};;
{ .mmi; .save.gf 0,0x40
stf.spill [r16]=f18,32
.save.gf 0,0x80
stf.spill [r17]=f19,32
$ADDP aptr=0,in1 };;
{ .mmi; .save.gf 0,0x100
stf.spill [r16]=f20,32
.save.gf 0,0x200
stf.spill [r17]=f21,32
$ADDP r29=8,in1 };;
{ .mmi; .save.gf 0,0x400
stf.spill [r16]=f22
.save.gf 0,0x800
stf.spill [r17]=f23
$ADDP rptr=0,in0 };;
.body
.rotf bj[8],mj[2],tf[2],alo[10],ahi[10],nlo[10],nhi[10]
.rotr t[8]
// load input vectors padding them to 8 elements
{ .mmi; ldf8 ai0=[aptr],16 // ap[0]
ldf8 ai1=[r29],16 // ap[1]
$ADDP bptr=0,in2 }
{ .mmi; $ADDP r30=8,in2
$ADDP nptr=0,in3
$ADDP r31=8,in3 };;
{ .mmi; ldf8 bj[7]=[bptr],16 // bp[0]
ldf8 bj[6]=[r30],16 // bp[1]
cmp4.le p4,p5=3,in5 }
{ .mmi; ldf8 ni0=[nptr],16 // np[0]
ldf8 ni1=[r31],16 // np[1]
cmp4.le p6,p7=4,in5 };;
{ .mfi; (p4)ldf8 ai2=[aptr],16 // ap[2]
(p5)fcvt.fxu ai2=f0
cmp4.le p8,p9=5,in5 }
{ .mfi; (p6)ldf8 ai3=[r29],16 // ap[3]
(p7)fcvt.fxu ai3=f0
cmp4.le p10,p11=6,in5 }
{ .mfi; (p4)ldf8 bj[5]=[bptr],16 // bp[2]
(p5)fcvt.fxu bj[5]=f0
cmp4.le p12,p13=7,in5 }
{ .mfi; (p6)ldf8 bj[4]=[r30],16 // bp[3]
(p7)fcvt.fxu bj[4]=f0
cmp4.le p14,p15=8,in5 }
{ .mfi; (p4)ldf8 ni2=[nptr],16 // np[2]
(p5)fcvt.fxu ni2=f0
addp4 r28=-1,in5 }
{ .mfi; (p6)ldf8 ni3=[r31],16 // np[3]
(p7)fcvt.fxu ni3=f0
$ADDP in4=0,in4 };;
{ .mfi; ldf8 n0=[in4]
fcvt.fxu tf[1]=f0
nop.i 0 }
{ .mfi; (p8)ldf8 ai4=[aptr],16 // ap[4]
(p9)fcvt.fxu ai4=f0
mov t[0]=r0 }
{ .mfi; (p10)ldf8 ai5=[r29],16 // ap[5]
(p11)fcvt.fxu ai5=f0
mov t[1]=r0 }
{ .mfi; (p8)ldf8 bj[3]=[bptr],16 // bp[4]
(p9)fcvt.fxu bj[3]=f0
mov t[2]=r0 }
{ .mfi; (p10)ldf8 bj[2]=[r30],16 // bp[5]
(p11)fcvt.fxu bj[2]=f0
mov t[3]=r0 }
{ .mfi; (p8)ldf8 ni4=[nptr],16 // np[4]
(p9)fcvt.fxu ni4=f0
mov t[4]=r0 }
{ .mfi; (p10)ldf8 ni5=[r31],16 // np[5]
(p11)fcvt.fxu ni5=f0
mov t[5]=r0 };;
{ .mfi; (p12)ldf8 ai6=[aptr],16 // ap[6]
(p13)fcvt.fxu ai6=f0
mov t[6]=r0 }
{ .mfi; (p14)ldf8 ai7=[r29],16 // ap[7]
(p15)fcvt.fxu ai7=f0
mov t[7]=r0 }
{ .mfi; (p12)ldf8 bj[1]=[bptr],16 // bp[6]
(p13)fcvt.fxu bj[1]=f0
mov ar.lc=r28 }
{ .mfi; (p14)ldf8 bj[0]=[r30],16 // bp[7]
(p15)fcvt.fxu bj[0]=f0
mov ar.ec=1 }
{ .mfi; (p12)ldf8 ni6=[nptr],16 // np[6]
(p13)fcvt.fxu ni6=f0
mov pr.rot=1<<16 }
{ .mfb; (p14)ldf8 ni7=[r31],16 // np[7]
(p15)fcvt.fxu ni7=f0
brp.loop.imp .Louter_8_ctop,.Louter_8_cend-16
};;
// The loop is scheduled for 32*n ticks on Itanium 2. Actual attempt
// to measure with help of Interval Time Counter indicated that the
// factor is a tad higher: 33 or 34, if not 35. Exact measurement and
// addressing the issue is problematic, because I don't have access
// to platform-specific instruction-level profiler. On Itanium it
// should run in 56*n ticks, because of higher xma latency...
.Louter_8_ctop:
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mfi; (p16) nop.m 0 // 0:
(p16) xma.hu ahi[0]=ai0,bj[7],tf[1] // ap[0]*b[i]+t[0]
(p40) add a3=a3,n3 } // (p17) a3+=n3
{ .mfi; (p42) add a3=a3,n3,1
(p16) xma.lu alo[0]=ai0,bj[7],tf[1]
(p16) nop.i 0 };;
{ .mii; (p17) getf.sig a7=alo[8] // 1:
(p48) add t[6]=t[6],a3 // (p17) t[6]+=a3
(p50) add t[6]=t[6],a3,1 };;
{ .mfi; (p17) getf.sig a8=ahi[8] // 2:
(p17) xma.hu nhi[7]=ni6,mj[1],nhi[6] // np[6]*m0
(p40) cmp.ltu p43,p41=a3,n3 }
{ .mfi; (p42) cmp.leu p43,p41=a3,n3
(p17) xma.lu nlo[7]=ni6,mj[1],nhi[6]
(p16) nop.i 0 };;
{ .mii; (p17) getf.sig n5=nlo[6] // 3:
(p48) cmp.ltu p51,p49=t[6],a3
(p50) cmp.leu p51,p49=t[6],a3 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mfi; (p16) nop.m 0 // 4:
(p16) xma.hu ahi[1]=ai1,bj[7],ahi[0] // ap[1]*b[i]
(p41) add a4=a4,n4 } // (p17) a4+=n4
{ .mfi; (p43) add a4=a4,n4,1
(p16) xma.lu alo[1]=ai1,bj[7],ahi[0]
(p16) nop.i 0 };;
{ .mfi; (p49) add t[5]=t[5],a4 // 5: (p17) t[5]+=a4
(p16) xmpy.lu mj[0]=alo[0],n0 // (ap[0]*b[i]+t[0])*n0
(p51) add t[5]=t[5],a4,1 };;
{ .mfi; (p16) nop.m 0 // 6:
(p17) xma.hu nhi[8]=ni7,mj[1],nhi[7] // np[7]*m0
(p41) cmp.ltu p42,p40=a4,n4 }
{ .mfi; (p43) cmp.leu p42,p40=a4,n4
(p17) xma.lu nlo[8]=ni7,mj[1],nhi[7]
(p16) nop.i 0 };;
{ .mii; (p17) getf.sig n6=nlo[7] // 7:
(p49) cmp.ltu p50,p48=t[5],a4
(p51) cmp.leu p50,p48=t[5],a4 };;
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mfi; (p16) nop.m 0 // 8:
(p16) xma.hu ahi[2]=ai2,bj[7],ahi[1] // ap[2]*b[i]
(p40) add a5=a5,n5 } // (p17) a5+=n5
{ .mfi; (p42) add a5=a5,n5,1
(p16) xma.lu alo[2]=ai2,bj[7],ahi[1]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig a1=alo[1] // 9:
(p48) add t[4]=t[4],a5 // p(17) t[4]+=a5
(p50) add t[4]=t[4],a5,1 };;
{ .mfi; (p16) nop.m 0 // 10:
(p16) xma.hu nhi[0]=ni0,mj[0],alo[0] // np[0]*m0
(p40) cmp.ltu p43,p41=a5,n5 }
{ .mfi; (p42) cmp.leu p43,p41=a5,n5
(p16) xma.lu nlo[0]=ni0,mj[0],alo[0]
(p16) nop.i 0 };;
{ .mii; (p17) getf.sig n7=nlo[8] // 11:
(p48) cmp.ltu p51,p49=t[4],a5
(p50) cmp.leu p51,p49=t[4],a5 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mfi; (p17) getf.sig n8=nhi[8] // 12:
(p16) xma.hu ahi[3]=ai3,bj[7],ahi[2] // ap[3]*b[i]
(p41) add a6=a6,n6 } // (p17) a6+=n6
{ .mfi; (p43) add a6=a6,n6,1
(p16) xma.lu alo[3]=ai3,bj[7],ahi[2]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig a2=alo[2] // 13:
(p49) add t[3]=t[3],a6 // (p17) t[3]+=a6
(p51) add t[3]=t[3],a6,1 };;
{ .mfi; (p16) nop.m 0 // 14:
(p16) xma.hu nhi[1]=ni1,mj[0],nhi[0] // np[1]*m0
(p41) cmp.ltu p42,p40=a6,n6 }
{ .mfi; (p43) cmp.leu p42,p40=a6,n6
(p16) xma.lu nlo[1]=ni1,mj[0],nhi[0]
(p16) nop.i 0 };;
{ .mii; (p16) nop.m 0 // 15:
(p49) cmp.ltu p50,p48=t[3],a6
(p51) cmp.leu p50,p48=t[3],a6 };;
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mfi; (p16) nop.m 0 // 16:
(p16) xma.hu ahi[4]=ai4,bj[7],ahi[3] // ap[4]*b[i]
(p40) add a7=a7,n7 } // (p17) a7+=n7
{ .mfi; (p42) add a7=a7,n7,1
(p16) xma.lu alo[4]=ai4,bj[7],ahi[3]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig a3=alo[3] // 17:
(p48) add t[2]=t[2],a7 // (p17) t[2]+=a7
(p50) add t[2]=t[2],a7,1 };;
{ .mfi; (p16) nop.m 0 // 18:
(p16) xma.hu nhi[2]=ni2,mj[0],nhi[1] // np[2]*m0
(p40) cmp.ltu p43,p41=a7,n7 }
{ .mfi; (p42) cmp.leu p43,p41=a7,n7
(p16) xma.lu nlo[2]=ni2,mj[0],nhi[1]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig n1=nlo[1] // 19:
(p48) cmp.ltu p51,p49=t[2],a7
(p50) cmp.leu p51,p49=t[2],a7 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mfi; (p16) nop.m 0 // 20:
(p16) xma.hu ahi[5]=ai5,bj[7],ahi[4] // ap[5]*b[i]
(p41) add a8=a8,n8 } // (p17) a8+=n8
{ .mfi; (p43) add a8=a8,n8,1
(p16) xma.lu alo[5]=ai5,bj[7],ahi[4]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig a4=alo[4] // 21:
(p49) add t[1]=t[1],a8 // (p17) t[1]+=a8
(p51) add t[1]=t[1],a8,1 };;
{ .mfi; (p16) nop.m 0 // 22:
(p16) xma.hu nhi[3]=ni3,mj[0],nhi[2] // np[3]*m0
(p41) cmp.ltu p42,p40=a8,n8 }
{ .mfi; (p43) cmp.leu p42,p40=a8,n8
(p16) xma.lu nlo[3]=ni3,mj[0],nhi[2]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig n2=nlo[2] // 23:
(p49) cmp.ltu p50,p48=t[1],a8
(p51) cmp.leu p50,p48=t[1],a8 };;
{ .mfi; (p16) nop.m 0 // 24:
(p16) xma.hu ahi[6]=ai6,bj[7],ahi[5] // ap[6]*b[i]
(p16) add a1=a1,n1 } // (p16) a1+=n1
{ .mfi; (p16) nop.m 0
(p16) xma.lu alo[6]=ai6,bj[7],ahi[5]
(p17) mov t[0]=r0 };;
{ .mii; (p16) getf.sig a5=alo[5] // 25:
(p16) add t0=t[7],a1 // (p16) t[7]+=a1
(p42) add t[0]=t[0],r0,1 };;
{ .mfi; (p16) setf.sig tf[0]=t0 // 26:
(p16) xma.hu nhi[4]=ni4,mj[0],nhi[3] // np[4]*m0
(p50) add t[0]=t[0],r0,1 }
{ .mfi; (p16) cmp.ltu.unc p42,p40=a1,n1
(p16) xma.lu nlo[4]=ni4,mj[0],nhi[3]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig n3=nlo[3] // 27:
(p16) cmp.ltu.unc p50,p48=t0,a1
(p16) nop.i 0 };;
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mfi; (p16) nop.m 0 // 28:
(p16) xma.hu ahi[7]=ai7,bj[7],ahi[6] // ap[7]*b[i]
(p40) add a2=a2,n2 } // (p16) a2+=n2
{ .mfi; (p42) add a2=a2,n2,1
(p16) xma.lu alo[7]=ai7,bj[7],ahi[6]
(p16) nop.i 0 };;
{ .mii; (p16) getf.sig a6=alo[6] // 29:
(p48) add t[6]=t[6],a2 // (p16) t[6]+=a2
(p50) add t[6]=t[6],a2,1 };;
{ .mfi; (p16) nop.m 0 // 30:
(p16) xma.hu nhi[5]=ni5,mj[0],nhi[4] // np[5]*m0
(p40) cmp.ltu p41,p39=a2,n2 }
{ .mfi; (p42) cmp.leu p41,p39=a2,n2
(p16) xma.lu nlo[5]=ni5,mj[0],nhi[4]
(p16) nop.i 0 };;
{ .mfi; (p16) getf.sig n4=nlo[4] // 31:
(p16) nop.f 0
(p48) cmp.ltu p49,p47=t[6],a2 }
{ .mfb; (p50) cmp.leu p49,p47=t[6],a2
(p16) nop.f 0
br.ctop.sptk.many .Louter_8_ctop };;
.Louter_8_cend:
// above loop has to execute one more time, without (p16), which is
// replaced with merged move of np[8] to GPR bank
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mmi; (p0) getf.sig n1=ni0 // 0:
(p40) add a3=a3,n3 // (p17) a3+=n3
(p42) add a3=a3,n3,1 };;
{ .mii; (p17) getf.sig a7=alo[8] // 1:
(p48) add t[6]=t[6],a3 // (p17) t[6]+=a3
(p50) add t[6]=t[6],a3,1 };;
{ .mfi; (p17) getf.sig a8=ahi[8] // 2:
(p17) xma.hu nhi[7]=ni6,mj[1],nhi[6] // np[6]*m0
(p40) cmp.ltu p43,p41=a3,n3 }
{ .mfi; (p42) cmp.leu p43,p41=a3,n3
(p17) xma.lu nlo[7]=ni6,mj[1],nhi[6]
(p0) nop.i 0 };;
{ .mii; (p17) getf.sig n5=nlo[6] // 3:
(p48) cmp.ltu p51,p49=t[6],a3
(p50) cmp.leu p51,p49=t[6],a3 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mmi; (p0) getf.sig n2=ni1 // 4:
(p41) add a4=a4,n4 // (p17) a4+=n4
(p43) add a4=a4,n4,1 };;
{ .mfi; (p49) add t[5]=t[5],a4 // 5: (p17) t[5]+=a4
(p0) nop.f 0
(p51) add t[5]=t[5],a4,1 };;
{ .mfi; (p0) getf.sig n3=ni2 // 6:
(p17) xma.hu nhi[8]=ni7,mj[1],nhi[7] // np[7]*m0
(p41) cmp.ltu p42,p40=a4,n4 }
{ .mfi; (p43) cmp.leu p42,p40=a4,n4
(p17) xma.lu nlo[8]=ni7,mj[1],nhi[7]
(p0) nop.i 0 };;
{ .mii; (p17) getf.sig n6=nlo[7] // 7:
(p49) cmp.ltu p50,p48=t[5],a4
(p51) cmp.leu p50,p48=t[5],a4 };;
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mii; (p0) getf.sig n4=ni3 // 8:
(p40) add a5=a5,n5 // (p17) a5+=n5
(p42) add a5=a5,n5,1 };;
{ .mii; (p0) nop.m 0 // 9:
(p48) add t[4]=t[4],a5 // p(17) t[4]+=a5
(p50) add t[4]=t[4],a5,1 };;
{ .mii; (p0) nop.m 0 // 10:
(p40) cmp.ltu p43,p41=a5,n5
(p42) cmp.leu p43,p41=a5,n5 };;
{ .mii; (p17) getf.sig n7=nlo[8] // 11:
(p48) cmp.ltu p51,p49=t[4],a5
(p50) cmp.leu p51,p49=t[4],a5 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mii; (p17) getf.sig n8=nhi[8] // 12:
(p41) add a6=a6,n6 // (p17) a6+=n6
(p43) add a6=a6,n6,1 };;
{ .mii; (p0) getf.sig n5=ni4 // 13:
(p49) add t[3]=t[3],a6 // (p17) t[3]+=a6
(p51) add t[3]=t[3],a6,1 };;
{ .mii; (p0) nop.m 0 // 14:
(p41) cmp.ltu p42,p40=a6,n6
(p43) cmp.leu p42,p40=a6,n6 };;
{ .mii; (p0) getf.sig n6=ni5 // 15:
(p49) cmp.ltu p50,p48=t[3],a6
(p51) cmp.leu p50,p48=t[3],a6 };;
.pred.rel "mutex",p40,p42
.pred.rel "mutex",p48,p50
{ .mii; (p0) nop.m 0 // 16:
(p40) add a7=a7,n7 // (p17) a7+=n7
(p42) add a7=a7,n7,1 };;
{ .mii; (p0) nop.m 0 // 17:
(p48) add t[2]=t[2],a7 // (p17) t[2]+=a7
(p50) add t[2]=t[2],a7,1 };;
{ .mii; (p0) nop.m 0 // 18:
(p40) cmp.ltu p43,p41=a7,n7
(p42) cmp.leu p43,p41=a7,n7 };;
{ .mii; (p0) getf.sig n7=ni6 // 19:
(p48) cmp.ltu p51,p49=t[2],a7
(p50) cmp.leu p51,p49=t[2],a7 };;
.pred.rel "mutex",p41,p43
.pred.rel "mutex",p49,p51
{ .mii; (p0) nop.m 0 // 20:
(p41) add a8=a8,n8 // (p17) a8+=n8
(p43) add a8=a8,n8,1 };;
{ .mmi; (p0) nop.m 0 // 21:
(p49) add t[1]=t[1],a8 // (p17) t[1]+=a8
(p51) add t[1]=t[1],a8,1 }
{ .mmi; (p17) mov t[0]=r0
(p41) cmp.ltu p42,p40=a8,n8
(p43) cmp.leu p42,p40=a8,n8 };;
{ .mmi; (p0) getf.sig n8=ni7 // 22:
(p49) cmp.ltu p50,p48=t[1],a8
(p51) cmp.leu p50,p48=t[1],a8 }
{ .mmi; (p42) add t[0]=t[0],r0,1
(p0) add r16=-7*16,prevsp
(p0) add r17=-6*16,prevsp };;
// subtract np[8] from carrybit|tmp[8]
// carrybit|tmp[8] layout upon exit from above loop is:
// t[0]|t[1]|t[2]|t[3]|t[4]|t[5]|t[6]|t[7]|t0 (least significant)
{ .mmi; (p50)add t[0]=t[0],r0,1
add r18=-5*16,prevsp
sub n1=t0,n1 };;
{ .mmi; cmp.gtu p34,p32=n1,t0;;
.pred.rel "mutex",p32,p34
(p32)sub n2=t[7],n2
(p34)sub n2=t[7],n2,1 };;
{ .mii; (p32)cmp.gtu p35,p33=n2,t[7]
(p34)cmp.geu p35,p33=n2,t[7];;
.pred.rel "mutex",p33,p35
(p33)sub n3=t[6],n3 }
{ .mmi; (p35)sub n3=t[6],n3,1;;
(p33)cmp.gtu p34,p32=n3,t[6]
(p35)cmp.geu p34,p32=n3,t[6] };;
.pred.rel "mutex",p32,p34
{ .mii; (p32)sub n4=t[5],n4
(p34)sub n4=t[5],n4,1;;
(p32)cmp.gtu p35,p33=n4,t[5] }
{ .mmi; (p34)cmp.geu p35,p33=n4,t[5];;
.pred.rel "mutex",p33,p35
(p33)sub n5=t[4],n5
(p35)sub n5=t[4],n5,1 };;
{ .mii; (p33)cmp.gtu p34,p32=n5,t[4]
(p35)cmp.geu p34,p32=n5,t[4];;
.pred.rel "mutex",p32,p34
(p32)sub n6=t[3],n6 }
{ .mmi; (p34)sub n6=t[3],n6,1;;
(p32)cmp.gtu p35,p33=n6,t[3]
(p34)cmp.geu p35,p33=n6,t[3] };;
.pred.rel "mutex",p33,p35
{ .mii; (p33)sub n7=t[2],n7
(p35)sub n7=t[2],n7,1;;
(p33)cmp.gtu p34,p32=n7,t[2] }
{ .mmi; (p35)cmp.geu p34,p32=n7,t[2];;
.pred.rel "mutex",p32,p34
(p32)sub n8=t[1],n8
(p34)sub n8=t[1],n8,1 };;
{ .mii; (p32)cmp.gtu p35,p33=n8,t[1]
(p34)cmp.geu p35,p33=n8,t[1];;
.pred.rel "mutex",p33,p35
(p33)sub a8=t[0],r0 }
{ .mmi; (p35)sub a8=t[0],r0,1;;
(p33)cmp.gtu p34,p32=a8,t[0]
(p35)cmp.geu p34,p32=a8,t[0] };;
// save the result, either tmp[num] or tmp[num]-np[num]
.pred.rel "mutex",p32,p34
{ .mmi; (p32)st8 [rptr]=n1,8
(p34)st8 [rptr]=t0,8
add r19=-4*16,prevsp};;
{ .mmb; (p32)st8 [rptr]=n2,8
(p34)st8 [rptr]=t[7],8
(p5)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n3,8
(p34)st8 [rptr]=t[6],8
(p7)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n4,8
(p34)st8 [rptr]=t[5],8
(p9)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n5,8
(p34)st8 [rptr]=t[4],8
(p11)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n6,8
(p34)st8 [rptr]=t[3],8
(p13)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n7,8
(p34)st8 [rptr]=t[2],8
(p15)br.cond.dpnt.few .Ldone };;
{ .mmb; (p32)st8 [rptr]=n8,8
(p34)st8 [rptr]=t[1],8
nop.b 0 };;
.Ldone: // epilogue
{ .mmi; ldf.fill f16=[r16],64
ldf.fill f17=[r17],64
nop.i 0 }
{ .mmi; ldf.fill f18=[r18],64
ldf.fill f19=[r19],64
mov pr=prevpr,0x1ffff };;
{ .mmi; ldf.fill f20=[r16]
ldf.fill f21=[r17]
mov ar.lc=prevlc }
{ .mmi; ldf.fill f22=[r18]
ldf.fill f23=[r19]
mov ret0=1 } // signal "handled"
{ .mib; rum 1<<5
.restore sp
mov sp=prevsp
br.ret.sptk.many b0 };;
.endp bn_mul_mont_8#
.type copyright#,\@object
copyright:
stringz "Montgomery multiplication for IA-64, CRYPTOGAMS by <appro\@openssl.org>"
___
$output=shift and open STDOUT,">$output";
print $code;
close STDOUT;