#!/usr/bin/env perl # ==================================================================== # Written by Andy Polyakov 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/. # ==================================================================== # # March 2010 # # The module implements "4-bit" GCM GHASH function and underlying # single multiplication operation in GF(2^128). "4-bit" means that it # uses 256 bytes per-key table [+128 bytes shared table]. Streamed # GHASH performance was measured to be 6.67 cycles per processed byte # on Itanium 2, which is >90% better than Microsoft compiler generated # code. To anchor to something else sha1-ia64.pl module processes one # byte in 5.7 cycles. On Itanium GHASH should run at ~8.5 cycles per # byte. # September 2010 # # It was originally thought that it makes lesser sense to implement # "528B" variant on Itanium 2 for following reason. Because number of # functional units is naturally limited, it appeared impossible to # implement "528B" loop in 4 cycles, only in 5. This would mean that # theoretically performance improvement couldn't be more than 20%. # But occasionally you prove yourself wrong:-) I figured out a way to # fold couple of instructions and having freed yet another instruction # slot by unrolling the loop... Resulting performance is 4.45 cycles # per processed byte and 50% better than "256B" version. On original # Itanium performance should remain the same as the "256B" version, # i.e. ~8.5 cycles. $output=shift and (open STDOUT,">$output" or die "can't open $output: $!"); if ($^O eq "hpux") { $ADDP="addp4"; for (@ARGV) { $ADDP="add" if (/[\+DD|\-mlp]64/); } } else { $ADDP="add"; } for (@ARGV) { $big_endian=1 if (/\-DB_ENDIAN/); $big_endian=0 if (/\-DL_ENDIAN/); } if (!defined($big_endian)) { $big_endian=(unpack('L',pack('N',1))==1); } sub loop() { my $label=shift; my ($p16,$p17)=(shift)?("p63","p63"):("p16","p17"); # mask references to inp # Loop is scheduled for 6 ticks on Itanium 2 and 8 on Itanium, i.e. # in scalable manner;-) Naturally assuming data in L1 cache... # Special note about 'dep' instruction, which is used to construct # &rem_4bit[Zlo&0xf]. It works, because rem_4bit is aligned at 128 # bytes boundary and lower 7 bits of its address are guaranteed to # be zero. $code.=<<___; $label: { .mfi; (p18) ld8 Hlo=[Hi[1]],-8 (p19) dep rem=Zlo,rem_4bitp,3,4 } { .mfi; (p19) xor Zhi=Zhi,Hhi ($p17) xor xi[1]=xi[1],in[1] };; { .mfi; (p18) ld8 Hhi=[Hi[1]] (p19) shrp Zlo=Zhi,Zlo,4 } { .mfi; (p19) ld8 rem=[rem] (p18) and Hi[1]=mask0xf0,xi[2] };; { .mmi; ($p16) ld1 in[0]=[inp],-1 (p18) xor Zlo=Zlo,Hlo (p19) shr.u Zhi=Zhi,4 } { .mib; (p19) xor Hhi=Hhi,rem (p18) add Hi[1]=Htbl,Hi[1] };; { .mfi; (p18) ld8 Hlo=[Hi[1]],-8 (p18) dep rem=Zlo,rem_4bitp,3,4 } { .mfi; (p17) shladd Hi[0]=xi[1],4,r0 (p18) xor Zhi=Zhi,Hhi };; { .mfi; (p18) ld8 Hhi=[Hi[1]] (p18) shrp Zlo=Zhi,Zlo,4 } { .mfi; (p18) ld8 rem=[rem] (p17) and Hi[0]=mask0xf0,Hi[0] };; { .mmi; (p16) ld1 xi[0]=[Xi],-1 (p18) xor Zlo=Zlo,Hlo (p18) shr.u Zhi=Zhi,4 } { .mib; (p18) xor Hhi=Hhi,rem (p17) add Hi[0]=Htbl,Hi[0] br.ctop.sptk $label };; ___ } $code=<<___; .explicit .text prevfs=r2; prevlc=r3; prevpr=r8; mask0xf0=r21; rem=r22; rem_4bitp=r23; Xi=r24; Htbl=r25; inp=r26; end=r27; Hhi=r28; Hlo=r29; Zhi=r30; Zlo=r31; .align 128 .skip 16 // aligns loop body .global gcm_gmult_4bit# .proc gcm_gmult_4bit# gcm_gmult_4bit: .prologue { .mmi; .save ar.pfs,prevfs alloc prevfs=ar.pfs,2,6,0,8 $ADDP Xi=15,in0 // &Xi[15] mov rem_4bitp=ip } { .mii; $ADDP Htbl=8,in1 // &Htbl[0].lo .save ar.lc,prevlc mov prevlc=ar.lc .save pr,prevpr mov prevpr=pr };; .body .rotr in[3],xi[3],Hi[2] { .mib; ld1 xi[2]=[Xi],-1 // Xi[15] mov mask0xf0=0xf0 brp.loop.imp .Loop1,.Lend1-16};; { .mmi; ld1 xi[1]=[Xi],-1 // Xi[14] };; { .mii; shladd Hi[1]=xi[2],4,r0 mov pr.rot=0x7<<16 mov ar.lc=13 };; { .mii; and Hi[1]=mask0xf0,Hi[1] mov ar.ec=3 xor Zlo=Zlo,Zlo };; { .mii; add Hi[1]=Htbl,Hi[1] // &Htbl[nlo].lo add rem_4bitp=rem_4bit#-gcm_gmult_4bit#,rem_4bitp xor Zhi=Zhi,Zhi };; ___ &loop (".Loop1",1); $code.=<<___; .Lend1: { .mib; xor Zhi=Zhi,Hhi };; // modulo-scheduling artefact { .mib; mux1 Zlo=Zlo,\@rev };; { .mib; mux1 Zhi=Zhi,\@rev };; { .mmi; add Hlo=9,Xi;; // ;; is here to prevent add Hhi=1,Xi };; // pipeline flush on Itanium { .mib; st8 [Hlo]=Zlo mov pr=prevpr,0x1ffff };; { .mib; st8 [Hhi]=Zhi mov ar.lc=prevlc br.ret.sptk.many b0 };; .endp gcm_gmult_4bit# ___ ###################################################################### # "528B" (well, "512B" actualy) streamed GHASH # $Xip="in0"; $Htbl="in1"; $inp="in2"; $len="in3"; $rem_8bit="loc0"; $mask0xff="loc1"; ($sum,$rum) = $big_endian ? ("nop.m","nop.m") : ("sum","rum"); sub load_htable() { for (my $i=0;$i<8;$i++) { $code.=<<___; { .mmi; ld8 r`16+2*$i+1`=[r8],16 // Htable[$i].hi ld8 r`16+2*$i`=[r9],16 } // Htable[$i].lo { .mmi; ldf8 f`32+2*$i+1`=[r10],16 // Htable[`8+$i`].hi ldf8 f`32+2*$i`=[r11],16 // Htable[`8+$i`].lo ___ $code.=shift if (($i+$#_)==7); $code.="\t};;\n" } } $code.=<<___; prevsp=r3; .align 32 .skip 16 // aligns loop body .global gcm_ghash_4bit# .proc gcm_ghash_4bit# gcm_ghash_4bit: .prologue { .mmi; .save ar.pfs,prevfs alloc prevfs=ar.pfs,4,2,0,0 .vframe prevsp mov prevsp=sp mov $rem_8bit=ip };; .body { .mfi; $ADDP r8=0+0,$Htbl $ADDP r9=0+8,$Htbl } { .mfi; $ADDP r10=128+0,$Htbl $ADDP r11=128+8,$Htbl };; ___ &load_htable( " $ADDP $Xip=15,$Xip", # &Xi[15] " $ADDP $len=$len,$inp", # &inp[len] " $ADDP $inp=15,$inp", # &inp[15] " mov $mask0xff=0xff", " add sp=-512,sp", " andcm sp=sp,$mask0xff", # align stack frame " add r14=0,sp", " add r15=8,sp"); $code.=<<___; { .mmi; $sum 1<<1 // go big-endian add r8=256+0,sp add r9=256+8,sp } { .mmi; add r10=256+128+0,sp add r11=256+128+8,sp add $len=-17,$len };; ___ for($i=0;$i<8;$i++) { # generate first half of Hshr4[] my ($rlo,$rhi)=("r".eval(16+2*$i),"r".eval(16+2*$i+1)); $code.=<<___; { .mmi; st8 [r8]=$rlo,16 // Htable[$i].lo st8 [r9]=$rhi,16 // Htable[$i].hi shrp $rlo=$rhi,$rlo,4 }//;; { .mmi; stf8 [r10]=f`32+2*$i`,16 // Htable[`8+$i`].lo stf8 [r11]=f`32+2*$i+1`,16 // Htable[`8+$i`].hi shr.u $rhi=$rhi,4 };; { .mmi; st8 [r14]=$rlo,16 // Htable[$i].lo>>4 st8 [r15]=$rhi,16 }//;; // Htable[$i].hi>>4 ___ } $code.=<<___; { .mmi; ld8 r16=[r8],16 // Htable[8].lo ld8 r17=[r9],16 };; // Htable[8].hi { .mmi; ld8 r18=[r8],16 // Htable[9].lo ld8 r19=[r9],16 } // Htable[9].hi { .mmi; rum 1<<5 // clear um.mfh shrp r16=r17,r16,4 };; ___ for($i=0;$i<6;$i++) { # generate second half of Hshr4[] $code.=<<___; { .mmi; ld8 r`20+2*$i`=[r8],16 // Htable[`10+$i`].lo ld8 r`20+2*$i+1`=[r9],16 // Htable[`10+$i`].hi shr.u r`16+2*$i+1`=r`16+2*$i+1`,4 };; { .mmi; st8 [r14]=r`16+2*$i`,16 // Htable[`8+$i`].lo>>4 st8 [r15]=r`16+2*$i+1`,16 // Htable[`8+$i`].hi>>4 shrp r`18+2*$i`=r`18+2*$i+1`,r`18+2*$i`,4 } ___ } $code.=<<___; { .mmi; shr.u r`16+2*$i+1`=r`16+2*$i+1`,4 };; { .mmi; st8 [r14]=r`16+2*$i`,16 // Htable[`8+$i`].lo>>4 st8 [r15]=r`16+2*$i+1`,16 // Htable[`8+$i`].hi>>4 shrp r`18+2*$i`=r`18+2*$i+1`,r`18+2*$i`,4 } { .mmi; add $Htbl=256,sp // &Htable[0] add $rem_8bit=rem_8bit#-gcm_ghash_4bit#,$rem_8bit shr.u r`18+2*$i+1`=r`18+2*$i+1`,4 };; { .mmi; st8 [r14]=r`18+2*$i` // Htable[`8+$i`].lo>>4 st8 [r15]=r`18+2*$i+1` } // Htable[`8+$i`].hi>>4 ___ $in="r15"; @xi=("r16","r17"); @rem=("r18","r19"); ($Alo,$Ahi,$Blo,$Bhi,$Zlo,$Zhi)=("r20","r21","r22","r23","r24","r25"); ($Atbl,$Btbl)=("r26","r27"); $code.=<<___; # (p16) { .mmi; ld1 $in=[$inp],-1 //(p16) *inp-- ld1 $xi[0]=[$Xip],-1 //(p16) *Xi-- cmp.eq p0,p6=r0,r0 };; // clear p6 ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers $code.=<<___; # (p16),(p17) { .mmi; ld1 $xi[0]=[$Xip],-1 //(p16) *Xi-- xor $xi[1]=$xi[1],$in };; //(p17) xi=$xi[i]^inp[i] { .mii; ld1 $in=[$inp],-1 //(p16) *inp-- dep $Atbl=$xi[1],$Htbl,4,4 //(p17) &Htable[nlo].lo and $xi[1]=-16,$xi[1] };; //(p17) nhi=xi&0xf0 .align 32 .LOOP: { .mmi; (p6) st8 [$Xip]=$Zhi,13 xor $Zlo=$Zlo,$Zlo add $Btbl=$xi[1],$Htbl };; //(p17) &Htable[nhi].lo ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers $code.=<<___; # (p16),(p17),(p18) { .mmi; ld8 $Alo=[$Atbl],8 //(p18) Htable[nlo].lo,&Htable[nlo].hi ld8 $rem[0]=[$Btbl],-256 //(p18) Htable[nhi].lo,&Hshr4[nhi].lo xor $xi[1]=$xi[1],$in };; //(p17) xi=$xi[i]^inp[i] { .mfi; ld8 $Ahi=[$Atbl] //(p18) Htable[nlo].hi dep $Atbl=$xi[1],$Htbl,4,4 } //(p17) &Htable[nlo].lo { .mfi; shladd $rem[0]=$rem[0],4,r0 //(p18) Htable[nhi].lo<<4 xor $Zlo=$Zlo,$Alo };; //(p18) Z.lo^=Htable[nlo].lo { .mmi; ld8 $Blo=[$Btbl],8 //(p18) Hshr4[nhi].lo,&Hshr4[nhi].hi ld1 $in=[$inp],-1 } //(p16) *inp-- { .mmi; xor $rem[0]=$rem[0],$Zlo //(p18) Z.lo^(Htable[nhi].lo<<4) mov $Zhi=$Ahi //(p18) Z.hi^=Htable[nlo].hi and $xi[1]=-16,$xi[1] };; //(p17) nhi=xi&0xf0 { .mmi; ld8 $Bhi=[$Btbl] //(p18) Hshr4[nhi].hi ld1 $xi[0]=[$Xip],-1 //(p16) *Xi-- shrp $Zlo=$Zhi,$Zlo,8 } //(p18) Z.lo=(Z.hi<<56)|(Z.lo>>8) { .mmi; and $rem[0]=$rem[0],$mask0xff //(p18) rem=($Zlo^(Htable[nhi].lo<<4))&0xff add $Btbl=$xi[1],$Htbl };; //(p17) &Htable[nhi] ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers for ($i=1;$i<14;$i++) { # Above and below fragments are derived from this one by removing # unsuitable (p??) instructions. $code.=<<___; # (p16),(p17),(p18),(p19) { .mmi; ld8 $Alo=[$Atbl],8 //(p18) Htable[nlo].lo,&Htable[nlo].hi ld8 $rem[0]=[$Btbl],-256 //(p18) Htable[nhi].lo,&Hshr4[nhi].lo shr.u $Zhi=$Zhi,8 } //(p19) Z.hi>>=8 { .mmi; shladd $rem[1]=$rem[1],1,$rem_8bit //(p19) &rem_8bit[rem] xor $Zlo=$Zlo,$Blo //(p19) Z.lo^=Hshr4[nhi].lo xor $xi[1]=$xi[1],$in };; //(p17) xi=$xi[i]^inp[i] { .mmi; ld8 $Ahi=[$Atbl] //(p18) Htable[nlo].hi ld2 $rem[1]=[$rem[1]] //(p19) rem_8bit[rem] dep $Atbl=$xi[1],$Htbl,4,4 } //(p17) &Htable[nlo].lo { .mmi; shladd $rem[0]=$rem[0],4,r0 //(p18) Htable[nhi].lo<<4 xor $Zlo=$Zlo,$Alo //(p18) Z.lo^=Htable[nlo].lo xor $Zhi=$Zhi,$Bhi };; //(p19) Z.hi^=Hshr4[nhi].hi { .mmi; ld8 $Blo=[$Btbl],8 //(p18) Hshr4[nhi].lo,&Hshr4[nhi].hi ld1 $in=[$inp],-1 //(p16) *inp-- shl $rem[1]=$rem[1],48 } //(p19) rem_8bit[rem]<<48 { .mmi; xor $rem[0]=$rem[0],$Zlo //(p18) Z.lo^(Htable[nhi].lo<<4) xor $Zhi=$Zhi,$Ahi //(p18) Z.hi^=Htable[nlo].hi and $xi[1]=-16,$xi[1] };; //(p17) nhi=xi&0xf0 { .mmi; ld8 $Bhi=[$Btbl] //(p18) Hshr4[nhi].hi ld1 $xi[0]=[$Xip],-1 //(p16) *Xi-- shrp $Zlo=$Zhi,$Zlo,8 } //(p18) Z.lo=(Z.hi<<56)|(Z.lo>>8) { .mmi; and $rem[0]=$rem[0],$mask0xff //(p18) rem=($Zlo^(Htable[nhi].lo<<4))&0xff xor $Zhi=$Zhi,$rem[1] //(p19) Z.hi^=rem_8bit[rem]<<48 add $Btbl=$xi[1],$Htbl };; //(p17) &Htable[nhi] ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers } $code.=<<___; # (p17),(p18),(p19) { .mmi; ld8 $Alo=[$Atbl],8 //(p18) Htable[nlo].lo,&Htable[nlo].hi ld8 $rem[0]=[$Btbl],-256 //(p18) Htable[nhi].lo,&Hshr4[nhi].lo shr.u $Zhi=$Zhi,8 } //(p19) Z.hi>>=8 { .mmi; shladd $rem[1]=$rem[1],1,$rem_8bit //(p19) &rem_8bit[rem] xor $Zlo=$Zlo,$Blo //(p19) Z.lo^=Hshr4[nhi].lo xor $xi[1]=$xi[1],$in };; //(p17) xi=$xi[i]^inp[i] { .mmi; ld8 $Ahi=[$Atbl] //(p18) Htable[nlo].hi ld2 $rem[1]=[$rem[1]] //(p19) rem_8bit[rem] dep $Atbl=$xi[1],$Htbl,4,4 };; //(p17) &Htable[nlo].lo { .mmi; shladd $rem[0]=$rem[0],4,r0 //(p18) Htable[nhi].lo<<4 xor $Zlo=$Zlo,$Alo //(p18) Z.lo^=Htable[nlo].lo xor $Zhi=$Zhi,$Bhi };; //(p19) Z.hi^=Hshr4[nhi].hi { .mmi; ld8 $Blo=[$Btbl],8 //(p18) Hshr4[nhi].lo,&Hshr4[nhi].hi shl $rem[1]=$rem[1],48 } //(p19) rem_8bit[rem]<<48 { .mmi; xor $rem[0]=$rem[0],$Zlo //(p18) Z.lo^(Htable[nhi].lo<<4) xor $Zhi=$Zhi,$Ahi //(p18) Z.hi^=Htable[nlo].hi and $xi[1]=-16,$xi[1] };; //(p17) nhi=xi&0xf0 { .mmi; ld8 $Bhi=[$Btbl] //(p18) Hshr4[nhi].hi shrp $Zlo=$Zhi,$Zlo,8 } //(p18) Z.lo=(Z.hi<<56)|(Z.lo>>8) { .mmi; and $rem[0]=$rem[0],$mask0xff //(p18) rem=($Zlo^(Htable[nhi].lo<<4))&0xff xor $Zhi=$Zhi,$rem[1] //(p19) Z.hi^=rem_8bit[rem]<<48 add $Btbl=$xi[1],$Htbl };; //(p17) &Htable[nhi] ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers $code.=<<___; # (p18),(p19) { .mfi; ld8 $Alo=[$Atbl],8 //(p18) Htable[nlo].lo,&Htable[nlo].hi shr.u $Zhi=$Zhi,8 } //(p19) Z.hi>>=8 { .mfi; shladd $rem[1]=$rem[1],1,$rem_8bit //(p19) &rem_8bit[rem] xor $Zlo=$Zlo,$Blo };; //(p19) Z.lo^=Hshr4[nhi].lo { .mfi; ld8 $Ahi=[$Atbl] //(p18) Htable[nlo].hi xor $Zlo=$Zlo,$Alo } //(p18) Z.lo^=Htable[nlo].lo { .mfi; ld2 $rem[1]=[$rem[1]] //(p19) rem_8bit[rem] xor $Zhi=$Zhi,$Bhi };; //(p19) Z.hi^=Hshr4[nhi].hi { .mfi; ld8 $Blo=[$Btbl],8 //(p18) Htable[nhi].lo,&Htable[nhi].hi shl $rem[1]=$rem[1],48 } //(p19) rem_8bit[rem]<<48 { .mfi; shladd $rem[0]=$Zlo,4,r0 //(p18) Z.lo<<4 xor $Zhi=$Zhi,$Ahi };; //(p18) Z.hi^=Htable[nlo].hi { .mfi; ld8 $Bhi=[$Btbl] //(p18) Htable[nhi].hi shrp $Zlo=$Zhi,$Zlo,4 } //(p18) Z.lo=(Z.hi<<60)|(Z.lo>>4) { .mfi; and $rem[0]=$rem[0],$mask0xff //(p18) rem=($Zlo^(Htable[nhi].lo<<4))&0xff xor $Zhi=$Zhi,$rem[1] };; //(p19) Z.hi^=rem_8bit[rem]<<48 ___ push (@xi,shift(@xi)); push (@rem,shift(@rem)); # "rotate" registers $code.=<<___; # (p19) { .mmi; cmp.ltu p6,p0=$inp,$len add $inp=32,$inp shr.u $Zhi=$Zhi,4 } //(p19) Z.hi>>=4 { .mmi; shladd $rem[1]=$rem[1],1,$rem_8bit //(p19) &rem_8bit[rem] xor $Zlo=$Zlo,$Blo //(p19) Z.lo^=Hshr4[nhi].lo add $Xip=9,$Xip };; // &Xi.lo { .mmi; ld2 $rem[1]=[$rem[1]] //(p19) rem_8bit[rem] (p6) ld1 $in=[$inp],-1 //[p16] *inp-- (p6) extr.u $xi[1]=$Zlo,8,8 } //[p17] Xi[14] { .mmi; xor $Zhi=$Zhi,$Bhi //(p19) Z.hi^=Hshr4[nhi].hi (p6) and $xi[0]=$Zlo,$mask0xff };; //[p16] Xi[15] { .mmi; st8 [$Xip]=$Zlo,-8 (p6) xor $xi[0]=$xi[0],$in //[p17] xi=$xi[i]^inp[i] shl $rem[1]=$rem[1],48 };; //(p19) rem_8bit[rem]<<48 { .mmi; (p6) ld1 $in=[$inp],-1 //[p16] *inp-- xor $Zhi=$Zhi,$rem[1] //(p19) Z.hi^=rem_8bit[rem]<<48 (p6) dep $Atbl=$xi[0],$Htbl,4,4 } //[p17] &Htable[nlo].lo { .mib; (p6) and $xi[0]=-16,$xi[0] //[p17] nhi=xi&0xf0 (p6) br.cond.dptk.many .LOOP };; { .mib; st8 [$Xip]=$Zhi };; { .mib; $rum 1<<1 // return to little-endian .restore sp mov sp=prevsp br.ret.sptk.many b0 };; .endp gcm_ghash_4bit# ___ $code.=<<___; .align 128 .type rem_4bit#,\@object rem_4bit: data8 0x0000<<48, 0x1C20<<48, 0x3840<<48, 0x2460<<48 data8 0x7080<<48, 0x6CA0<<48, 0x48C0<<48, 0x54E0<<48 data8 0xE100<<48, 0xFD20<<48, 0xD940<<48, 0xC560<<48 data8 0x9180<<48, 0x8DA0<<48, 0xA9C0<<48, 0xB5E0<<48 .size rem_4bit#,128 .type rem_8bit#,\@object rem_8bit: data1 0x00,0x00, 0x01,0xC2, 0x03,0x84, 0x02,0x46, 0x07,0x08, 0x06,0xCA, 0x04,0x8C, 0x05,0x4E data1 0x0E,0x10, 0x0F,0xD2, 0x0D,0x94, 0x0C,0x56, 0x09,0x18, 0x08,0xDA, 0x0A,0x9C, 0x0B,0x5E data1 0x1C,0x20, 0x1D,0xE2, 0x1F,0xA4, 0x1E,0x66, 0x1B,0x28, 0x1A,0xEA, 0x18,0xAC, 0x19,0x6E data1 0x12,0x30, 0x13,0xF2, 0x11,0xB4, 0x10,0x76, 0x15,0x38, 0x14,0xFA, 0x16,0xBC, 0x17,0x7E data1 0x38,0x40, 0x39,0x82, 0x3B,0xC4, 0x3A,0x06, 0x3F,0x48, 0x3E,0x8A, 0x3C,0xCC, 0x3D,0x0E data1 0x36,0x50, 0x37,0x92, 0x35,0xD4, 0x34,0x16, 0x31,0x58, 0x30,0x9A, 0x32,0xDC, 0x33,0x1E data1 0x24,0x60, 0x25,0xA2, 0x27,0xE4, 0x26,0x26, 0x23,0x68, 0x22,0xAA, 0x20,0xEC, 0x21,0x2E data1 0x2A,0x70, 0x2B,0xB2, 0x29,0xF4, 0x28,0x36, 0x2D,0x78, 0x2C,0xBA, 0x2E,0xFC, 0x2F,0x3E data1 0x70,0x80, 0x71,0x42, 0x73,0x04, 0x72,0xC6, 0x77,0x88, 0x76,0x4A, 0x74,0x0C, 0x75,0xCE data1 0x7E,0x90, 0x7F,0x52, 0x7D,0x14, 0x7C,0xD6, 0x79,0x98, 0x78,0x5A, 0x7A,0x1C, 0x7B,0xDE data1 0x6C,0xA0, 0x6D,0x62, 0x6F,0x24, 0x6E,0xE6, 0x6B,0xA8, 0x6A,0x6A, 0x68,0x2C, 0x69,0xEE data1 0x62,0xB0, 0x63,0x72, 0x61,0x34, 0x60,0xF6, 0x65,0xB8, 0x64,0x7A, 0x66,0x3C, 0x67,0xFE data1 0x48,0xC0, 0x49,0x02, 0x4B,0x44, 0x4A,0x86, 0x4F,0xC8, 0x4E,0x0A, 0x4C,0x4C, 0x4D,0x8E data1 0x46,0xD0, 0x47,0x12, 0x45,0x54, 0x44,0x96, 0x41,0xD8, 0x40,0x1A, 0x42,0x5C, 0x43,0x9E data1 0x54,0xE0, 0x55,0x22, 0x57,0x64, 0x56,0xA6, 0x53,0xE8, 0x52,0x2A, 0x50,0x6C, 0x51,0xAE data1 0x5A,0xF0, 0x5B,0x32, 0x59,0x74, 0x58,0xB6, 0x5D,0xF8, 0x5C,0x3A, 0x5E,0x7C, 0x5F,0xBE data1 0xE1,0x00, 0xE0,0xC2, 0xE2,0x84, 0xE3,0x46, 0xE6,0x08, 0xE7,0xCA, 0xE5,0x8C, 0xE4,0x4E data1 0xEF,0x10, 0xEE,0xD2, 0xEC,0x94, 0xED,0x56, 0xE8,0x18, 0xE9,0xDA, 0xEB,0x9C, 0xEA,0x5E data1 0xFD,0x20, 0xFC,0xE2, 0xFE,0xA4, 0xFF,0x66, 0xFA,0x28, 0xFB,0xEA, 0xF9,0xAC, 0xF8,0x6E data1 0xF3,0x30, 0xF2,0xF2, 0xF0,0xB4, 0xF1,0x76, 0xF4,0x38, 0xF5,0xFA, 0xF7,0xBC, 0xF6,0x7E data1 0xD9,0x40, 0xD8,0x82, 0xDA,0xC4, 0xDB,0x06, 0xDE,0x48, 0xDF,0x8A, 0xDD,0xCC, 0xDC,0x0E data1 0xD7,0x50, 0xD6,0x92, 0xD4,0xD4, 0xD5,0x16, 0xD0,0x58, 0xD1,0x9A, 0xD3,0xDC, 0xD2,0x1E data1 0xC5,0x60, 0xC4,0xA2, 0xC6,0xE4, 0xC7,0x26, 0xC2,0x68, 0xC3,0xAA, 0xC1,0xEC, 0xC0,0x2E data1 0xCB,0x70, 0xCA,0xB2, 0xC8,0xF4, 0xC9,0x36, 0xCC,0x78, 0xCD,0xBA, 0xCF,0xFC, 0xCE,0x3E data1 0x91,0x80, 0x90,0x42, 0x92,0x04, 0x93,0xC6, 0x96,0x88, 0x97,0x4A, 0x95,0x0C, 0x94,0xCE data1 0x9F,0x90, 0x9E,0x52, 0x9C,0x14, 0x9D,0xD6, 0x98,0x98, 0x99,0x5A, 0x9B,0x1C, 0x9A,0xDE data1 0x8D,0xA0, 0x8C,0x62, 0x8E,0x24, 0x8F,0xE6, 0x8A,0xA8, 0x8B,0x6A, 0x89,0x2C, 0x88,0xEE data1 0x83,0xB0, 0x82,0x72, 0x80,0x34, 0x81,0xF6, 0x84,0xB8, 0x85,0x7A, 0x87,0x3C, 0x86,0xFE data1 0xA9,0xC0, 0xA8,0x02, 0xAA,0x44, 0xAB,0x86, 0xAE,0xC8, 0xAF,0x0A, 0xAD,0x4C, 0xAC,0x8E data1 0xA7,0xD0, 0xA6,0x12, 0xA4,0x54, 0xA5,0x96, 0xA0,0xD8, 0xA1,0x1A, 0xA3,0x5C, 0xA2,0x9E data1 0xB5,0xE0, 0xB4,0x22, 0xB6,0x64, 0xB7,0xA6, 0xB2,0xE8, 0xB3,0x2A, 0xB1,0x6C, 0xB0,0xAE data1 0xBB,0xF0, 0xBA,0x32, 0xB8,0x74, 0xB9,0xB6, 0xBC,0xF8, 0xBD,0x3A, 0xBF,0x7C, 0xBE,0xBE .size rem_8bit#,512 stringz "GHASH for IA64, CRYPTOGAMS by " ___ $code =~ s/mux1(\s+)\S+\@rev/nop.i$1 0x0/gm if ($big_endian); $code =~ s/\`([^\`]*)\`/eval $1/gem; print $code; close STDOUT;