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Diffstat (limited to 'app/openssl/crypto/bn/asm/s390x-mont.pl')
| -rw-r--r-- | app/openssl/crypto/bn/asm/s390x-mont.pl | 225 |
1 files changed, 0 insertions, 225 deletions
diff --git a/app/openssl/crypto/bn/asm/s390x-mont.pl b/app/openssl/crypto/bn/asm/s390x-mont.pl deleted file mode 100644 index f61246f5..00000000 --- a/app/openssl/crypto/bn/asm/s390x-mont.pl +++ /dev/null @@ -1,225 +0,0 @@ -#!/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/. -# ==================================================================== - -# April 2007. -# -# Performance improvement over vanilla C code varies from 85% to 45% -# depending on key length and benchmark. Unfortunately in this context -# these are not very impressive results [for code that utilizes "wide" -# 64x64=128-bit multiplication, which is not commonly available to C -# programmers], at least hand-coded bn_asm.c replacement is known to -# provide 30-40% better results for longest keys. Well, on a second -# thought it's not very surprising, because z-CPUs are single-issue -# and _strictly_ in-order execution, while bn_mul_mont is more or less -# dependent on CPU ability to pipe-line instructions and have several -# of them "in-flight" at the same time. I mean while other methods, -# for example Karatsuba, aim to minimize amount of multiplications at -# the cost of other operations increase, bn_mul_mont aim to neatly -# "overlap" multiplications and the other operations [and on most -# platforms even minimize the amount of the other operations, in -# particular references to memory]. But it's possible to improve this -# module performance by implementing dedicated squaring code-path and -# possibly by unrolling loops... - -# January 2009. -# -# Reschedule to minimize/avoid Address Generation Interlock hazard, -# make inner loops counter-based. - -$mn0="%r0"; -$num="%r1"; - -# int bn_mul_mont( -$rp="%r2"; # BN_ULONG *rp, -$ap="%r3"; # const BN_ULONG *ap, -$bp="%r4"; # const BN_ULONG *bp, -$np="%r5"; # const BN_ULONG *np, -$n0="%r6"; # const BN_ULONG *n0, -#$num="160(%r15)" # int num); - -$bi="%r2"; # zaps rp -$j="%r7"; - -$ahi="%r8"; -$alo="%r9"; -$nhi="%r10"; -$nlo="%r11"; -$AHI="%r12"; -$NHI="%r13"; -$count="%r14"; -$sp="%r15"; - -$code.=<<___; -.text -.globl bn_mul_mont -.type bn_mul_mont,\@function -bn_mul_mont: - lgf $num,164($sp) # pull $num - sla $num,3 # $num to enumerate bytes - la $bp,0($num,$bp) - - stg %r2,16($sp) - - cghi $num,16 # - lghi %r2,0 # - blr %r14 # if($num<16) return 0; - cghi $num,96 # - bhr %r14 # if($num>96) return 0; - - stmg %r3,%r15,24($sp) - - lghi $rp,-160-8 # leave room for carry bit - lcgr $j,$num # -$num - lgr %r0,$sp - la $rp,0($rp,$sp) - la $sp,0($j,$rp) # alloca - stg %r0,0($sp) # back chain - - sra $num,3 # restore $num - la $bp,0($j,$bp) # restore $bp - ahi $num,-1 # adjust $num for inner loop - lg $n0,0($n0) # pull n0 - - lg $bi,0($bp) - lg $alo,0($ap) - mlgr $ahi,$bi # ap[0]*bp[0] - lgr $AHI,$ahi - - lgr $mn0,$alo # "tp[0]"*n0 - msgr $mn0,$n0 - - lg $nlo,0($np) # - mlgr $nhi,$mn0 # np[0]*m1 - algr $nlo,$alo # +="tp[0]" - lghi $NHI,0 - alcgr $NHI,$nhi - - la $j,8(%r0) # j=1 - lr $count,$num - -.align 16 -.L1st: - lg $alo,0($j,$ap) - mlgr $ahi,$bi # ap[j]*bp[0] - algr $alo,$AHI - lghi $AHI,0 - alcgr $AHI,$ahi - - lg $nlo,0($j,$np) - mlgr $nhi,$mn0 # np[j]*m1 - algr $nlo,$NHI - lghi $NHI,0 - alcgr $nhi,$NHI # +="tp[j]" - algr $nlo,$alo - alcgr $NHI,$nhi - - stg $nlo,160-8($j,$sp) # tp[j-1]= - la $j,8($j) # j++ - brct $count,.L1st - - algr $NHI,$AHI - lghi $AHI,0 - alcgr $AHI,$AHI # upmost overflow bit - stg $NHI,160-8($j,$sp) - stg $AHI,160($j,$sp) - la $bp,8($bp) # bp++ - -.Louter: - lg $bi,0($bp) # bp[i] - lg $alo,0($ap) - mlgr $ahi,$bi # ap[0]*bp[i] - alg $alo,160($sp) # +=tp[0] - lghi $AHI,0 - alcgr $AHI,$ahi - - lgr $mn0,$alo - msgr $mn0,$n0 # tp[0]*n0 - - lg $nlo,0($np) # np[0] - mlgr $nhi,$mn0 # np[0]*m1 - algr $nlo,$alo # +="tp[0]" - lghi $NHI,0 - alcgr $NHI,$nhi - - la $j,8(%r0) # j=1 - lr $count,$num - -.align 16 -.Linner: - lg $alo,0($j,$ap) - mlgr $ahi,$bi # ap[j]*bp[i] - algr $alo,$AHI - lghi $AHI,0 - alcgr $ahi,$AHI - alg $alo,160($j,$sp)# +=tp[j] - alcgr $AHI,$ahi - - lg $nlo,0($j,$np) - mlgr $nhi,$mn0 # np[j]*m1 - algr $nlo,$NHI - lghi $NHI,0 - alcgr $nhi,$NHI - algr $nlo,$alo # +="tp[j]" - alcgr $NHI,$nhi - - stg $nlo,160-8($j,$sp) # tp[j-1]= - la $j,8($j) # j++ - brct $count,.Linner - - algr $NHI,$AHI - lghi $AHI,0 - alcgr $AHI,$AHI - alg $NHI,160($j,$sp)# accumulate previous upmost overflow bit - lghi $ahi,0 - alcgr $AHI,$ahi # new upmost overflow bit - stg $NHI,160-8($j,$sp) - stg $AHI,160($j,$sp) - - la $bp,8($bp) # bp++ - clg $bp,160+8+32($j,$sp) # compare to &bp[num] - jne .Louter - - lg $rp,160+8+16($j,$sp) # reincarnate rp - la $ap,160($sp) - ahi $num,1 # restore $num, incidentally clears "borrow" - - la $j,0(%r0) - lr $count,$num -.Lsub: lg $alo,0($j,$ap) - slbg $alo,0($j,$np) - stg $alo,0($j,$rp) - la $j,8($j) - brct $count,.Lsub - lghi $ahi,0 - slbgr $AHI,$ahi # handle upmost carry - - ngr $ap,$AHI - lghi $np,-1 - xgr $np,$AHI - ngr $np,$rp - ogr $ap,$np # ap=borrow?tp:rp - - la $j,0(%r0) - lgr $count,$num -.Lcopy: lg $alo,0($j,$ap) # copy or in-place refresh - stg $j,160($j,$sp) # zap tp - stg $alo,0($j,$rp) - la $j,8($j) - brct $count,.Lcopy - - la %r1,160+8+48($j,$sp) - lmg %r6,%r15,0(%r1) - lghi %r2,1 # signal "processed" - br %r14 -.size bn_mul_mont,.-bn_mul_mont -.string "Montgomery Multiplication for s390x, CRYPTOGAMS by <appro\@openssl.org>" -___ - -print $code; -close STDOUT; |