From 8eb2da5fbb1012eafcae0e7f3a56cb6ac716b872 Mon Sep 17 00:00:00 2001 From: Andy Polyakov Date: Sun, 19 May 2013 21:53:14 +0200 Subject: [PATCH] ghash-sparcv9.pl: update from master. --- crypto/modes/asm/ghash-sparcv9.pl | 247 +++++++++++++++++++++++++++++- 1 file changed, 244 insertions(+), 3 deletions(-) diff --git a/crypto/modes/asm/ghash-sparcv9.pl b/crypto/modes/asm/ghash-sparcv9.pl index 70e7b044a3..0365e0f1ff 100644 --- a/crypto/modes/asm/ghash-sparcv9.pl +++ b/crypto/modes/asm/ghash-sparcv9.pl @@ -36,6 +36,15 @@ # references to input data and Z.hi updates to achieve 12 cycles # timing. To anchor to something else, sha1-sparcv9.pl spends 11.6 # cycles to process one byte on UltraSPARC pre-Tx CPU and ~24 on T1. +# +# October 2012 +# +# Add VIS3 lookup-table-free implementation using polynomial +# multiplication xmulx[hi] and extended addition addxc[cc] +# instructions. 4.52/7.63x improvement on T3/T4 or in absolute +# terms 7.90/2.14 cycles per byte. On T4 multi-process benchmark +# saturates at ~15.5x single-process result on 8-core processor, +# or ~20.5GBps per 2.85GHz socket. $bits=32; for (@ARGV) { $bits=64 if (/\-m64/ || /\-xarch\=v9/); } @@ -66,6 +75,10 @@ $Htbl="%i1"; $inp="%i2"; $len="%i3"; +$code.=<<___ if ($bits==64); +.register %g2,#scratch +.register %g3,#scratch +___ $code.=<<___; .section ".text",#alloc,#execinstr @@ -321,10 +334,238 @@ gcm_gmult_4bit: restore .type gcm_gmult_4bit,#function .size gcm_gmult_4bit,(.-gcm_gmult_4bit) -.asciz "GHASH for SPARCv9, CRYPTOGAMS by " +___ + +{{{ +# Straightforward 128x128-bit multiplication using Karatsuba algorithm +# followed by pair of 64-bit reductions [with a shortcut in first one, +# which allowed to break dependency between reductions and remove one +# multiplication from critical path]. While it might be suboptimal +# with regard to sheer number of multiplications, other methods [such +# as aggregate reduction] would require more 64-bit registers, which +# we don't have in 32-bit application context. + +($Xip,$Htable,$inp,$len)=map("%i$_",(0..3)); + +($Hhl,$Hlo,$Hhi,$Xlo,$Xhi,$xE1,$sqr, $C0,$C1,$C2,$C3,$V)= + (map("%o$_",(0..5,7)),map("%g$_",(1..5))); + +($shl,$shr)=map("%l$_",(0..7)); + +# For details regarding "twisted H" see ghash-x86.pl. +$code.=<<___; +.globl gcm_init_vis3 +.align 32 +gcm_init_vis3: + save %sp,-$frame,%sp + + ldx [%i1+0],$Hhi + ldx [%i1+8],$Hlo + mov 0xE1,$Xhi + mov 1,$Xlo + sllx $Xhi,57,$Xhi + srax $Hhi,63,$C0 ! broadcast carry + addcc $Hlo,$Hlo,$Hlo ! H<<=1 + addxc $Hhi,$Hhi,$Hhi + and $C0,$Xlo,$Xlo + and $C0,$Xhi,$Xhi + xor $Xlo,$Hlo,$Hlo + xor $Xhi,$Hhi,$Hhi + stx $Hlo,[%i0+8] ! save twisted H + stx $Hhi,[%i0+0] + + sethi %hi(0xA0406080),$V + sethi %hi(0x20C0E000),%l0 + or $V,%lo(0xA0406080),$V + or %l0,%lo(0x20C0E000),%l0 + sllx $V,32,$V + or %l0,$V,$V ! (0xE0·i)&0xff=0xA040608020C0E000 + stx $V,[%i0+16] + + ret + restore +.type gcm_init_vis3,#function +.size gcm_init_vis3,.-gcm_init_vis3 + +.globl gcm_gmult_vis3 +.align 32 +gcm_gmult_vis3: + save %sp,-$frame,%sp + + ldx [$Xip+8],$Xlo ! load Xi + ldx [$Xip+0],$Xhi + ldx [$Htable+8],$Hlo ! load twisted H + ldx [$Htable+0],$Hhi + + mov 0xE1,%l7 + sllx %l7,57,$xE1 ! 57 is not a typo + ldx [$Htable+16],$V ! (0xE0·i)&0xff=0xA040608020C0E000 + + xor $Hhi,$Hlo,$Hhl ! Karatsuba pre-processing + xmulx $Xlo,$Hlo,$C0 + xor $Xlo,$Xhi,$C2 ! Karatsuba pre-processing + xmulx $C2,$Hhl,$C1 + xmulxhi $Xlo,$Hlo,$Xlo + xmulxhi $C2,$Hhl,$C2 + xmulxhi $Xhi,$Hhi,$C3 + xmulx $Xhi,$Hhi,$Xhi + + sll $C0,3,$sqr + srlx $V,$sqr,$sqr ! ·0xE0 [implicit &(7<<3)] + xor $C0,$sqr,$sqr + sllx $sqr,57,$sqr ! ($C0·0xE1)<<1<<56 [implicit &0x7f] + + xor $C0,$C1,$C1 ! Karatsuba post-processing + xor $Xlo,$C2,$C2 + xor $sqr,$Xlo,$Xlo ! real destination is $C1 + xor $C3,$C2,$C2 + xor $Xlo,$C1,$C1 + xor $Xhi,$C2,$C2 + xor $Xhi,$C1,$C1 + + xmulxhi $C0,$xE1,$Xlo ! ·0xE1<<1<<56 + xor $C0,$C2,$C2 + xmulx $C1,$xE1,$C0 + xor $C1,$C3,$C3 + xmulxhi $C1,$xE1,$C1 + + xor $Xlo,$C2,$C2 + xor $C0,$C2,$C2 + xor $C1,$C3,$C3 + + stx $C2,[$Xip+8] ! save Xi + stx $C3,[$Xip+0] + + ret + restore +.type gcm_gmult_vis3,#function +.size gcm_gmult_vis3,.-gcm_gmult_vis3 + +.globl gcm_ghash_vis3 +.align 32 +gcm_ghash_vis3: + save %sp,-$frame,%sp + + ldx [$Xip+8],$C2 ! load Xi + ldx [$Xip+0],$C3 + ldx [$Htable+8],$Hlo ! load twisted H + ldx [$Htable+0],$Hhi + + mov 0xE1,%l7 + sllx %l7,57,$xE1 ! 57 is not a typo + ldx [$Htable+16],$V ! (0xE0·i)&0xff=0xA040608020C0E000 + + and $inp,7,$shl + andn $inp,7,$inp + sll $shl,3,$shl + prefetch [$inp+63], 20 + sub %g0,$shl,$shr + + xor $Hhi,$Hlo,$Hhl ! Karatsuba pre-processing +.Loop: + ldx [$inp+8],$Xlo + brz,pt $shl,1f + ldx [$inp+0],$Xhi + + ldx [$inp+16],$C1 ! align data + srlx $Xlo,$shr,$C0 + sllx $Xlo,$shl,$Xlo + sllx $Xhi,$shl,$Xhi + srlx $C1,$shr,$C1 + or $C0,$Xhi,$Xhi + or $C1,$Xlo,$Xlo +1: + add $inp,16,$inp + sub $len,16,$len + xor $C2,$Xlo,$Xlo + xor $C3,$Xhi,$Xhi + prefetch [$inp+63], 20 + + xmulx $Xlo,$Hlo,$C0 + xor $Xlo,$Xhi,$C2 ! Karatsuba pre-processing + xmulx $C2,$Hhl,$C1 + xmulxhi $Xlo,$Hlo,$Xlo + xmulxhi $C2,$Hhl,$C2 + xmulxhi $Xhi,$Hhi,$C3 + xmulx $Xhi,$Hhi,$Xhi + + sll $C0,3,$sqr + srlx $V,$sqr,$sqr ! ·0xE0 [implicit &(7<<3)] + xor $C0,$sqr,$sqr + sllx $sqr,57,$sqr ! ($C0·0xE1)<<1<<56 [implicit &0x7f] + + xor $C0,$C1,$C1 ! Karatsuba post-processing + xor $Xlo,$C2,$C2 + xor $sqr,$Xlo,$Xlo ! real destination is $C1 + xor $C3,$C2,$C2 + xor $Xlo,$C1,$C1 + xor $Xhi,$C2,$C2 + xor $Xhi,$C1,$C1 + + xmulxhi $C0,$xE1,$Xlo ! ·0xE1<<1<<56 + xor $C0,$C2,$C2 + xmulx $C1,$xE1,$C0 + xor $C1,$C3,$C3 + xmulxhi $C1,$xE1,$C1 + + xor $Xlo,$C2,$C2 + xor $C0,$C2,$C2 + brnz,pt $len,.Loop + xor $C1,$C3,$C3 + + stx $C2,[$Xip+8] ! save Xi + stx $C3,[$Xip+0] + + ret + restore +.type gcm_ghash_vis3,#function +.size gcm_ghash_vis3,.-gcm_ghash_vis3 +___ +}}} +$code.=<<___; +.asciz "GHASH for SPARCv9/VIS3, CRYPTOGAMS by " .align 4 ___ -$code =~ s/\`([^\`]*)\`/eval $1/gem; -print $code; + +# Purpose of these subroutines is to explicitly encode VIS instructions, +# so that one can compile the module without having to specify VIS +# extentions on compiler command line, e.g. -xarch=v9 vs. -xarch=v9a. +# Idea is to reserve for option to produce "universal" binary and let +# programmer detect if current CPU is VIS capable at run-time. +sub unvis3 { +my ($mnemonic,$rs1,$rs2,$rd)=@_; +my %bias = ( "g" => 0, "o" => 8, "l" => 16, "i" => 24 ); +my ($ref,$opf); +my %visopf = ( "addxc" => 0x011, + "addxccc" => 0x013, + "xmulx" => 0x115, + "xmulxhi" => 0x116 ); + + $ref = "$mnemonic\t$rs1,$rs2,$rd"; + + if ($opf=$visopf{$mnemonic}) { + foreach ($rs1,$rs2,$rd) { + return $ref if (!/%([goli])([0-9])/); + $_=$bias{$1}+$2; + } + + return sprintf ".word\t0x%08x !%s", + 0x81b00000|$rd<<25|$rs1<<14|$opf<<5|$rs2, + $ref; + } else { + return $ref; + } +} + +foreach (split("\n",$code)) { + s/\`([^\`]*)\`/eval $1/ge; + + s/\b(xmulx[hi]*|addxc[c]{0,2})\s+(%[goli][0-7]),\s*(%[goli][0-7]),\s*(%[goli][0-7])/ + &unvis3($1,$2,$3,$4) + /ge; + + print $_,"\n"; +} + close STDOUT; -- 2.25.1