#!/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/. # ==================================================================== # # 2.22x RC4 tune-up:-) It should be noted though that my hand [as in # "hand-coded assembler"] doesn't stand for the whole improvement # coefficient. It turned out that eliminating RC4_CHAR from config # line results in ~40% improvement (yes, even for C implementation). # Presumably it has everything to do with AMD cache architecture and # RAW or whatever penalties. Once again! The module *requires* config # line *without* RC4_CHAR! As for coding "secret," I bet on partial # register arithmetics. For example instead of 'inc %r8; and $255,%r8' # I simply 'inc %r8b'. Even though optimization manual discourages # to operate on partial registers, it turned out to be the best bet. # At least for AMD... How IA32E would perform remains to be seen... # As was shown by Marc Bevand reordering of couple of load operations # results in even higher performance gain of 3.3x:-) At least on # Opteron... For reference, 1x in this case is RC4_CHAR C-code # compiled with gcc 3.3.2, which performs at ~54MBps per 1GHz clock. # Latter means that if you want to *estimate* what to expect from # *your* Opteron, then multiply 54 by 3.3 and clock frequency in GHz. # Intel P4 EM64T core was found to run the AMD64 code really slow... # The only way to achieve comparable performance on P4 was to keep # RC4_CHAR. Kind of ironic, huh? As it's apparently impossible to # compose blended code, which would perform even within 30% marginal # on either AMD and Intel platforms, I implement both cases. See # rc4_skey.c for further details... # P4 EM64T core appears to be "allergic" to 64-bit inc/dec. Replacing # those with add/sub results in 50% performance improvement of folded # loop... # As was shown by Zou Nanhai loop unrolling can improve Intel EM64T # performance by >30% [unlike P4 32-bit case that is]. But this is # provided that loads are reordered even more aggressively! Both code # pathes, AMD64 and EM64T, reorder loads in essentially same manner # as my IA-64 implementation. On Opteron this resulted in modest 5% # improvement [I had to test it], while final Intel P4 performance # achieves respectful 432MBps on 2.8GHz processor now. For reference. # If executed on Xeon, current RC4_CHAR code-path is 2.7x faster than # RC4_INT code-path. While if executed on Opteron, it's only 25% # slower than the RC4_INT one [meaning that if CPU µ-arch detection # is not implemented, then this final RC4_CHAR code-path should be # preferred, as it provides better *all-round* performance]. # Intel Core2 was observed to perform poorly on both code paths:-( It # apparently suffers from some kind of partial register stall, which # occurs in 64-bit mode only [as virtually identical 32-bit loop was # observed to outperform 64-bit one by almost 50%]. Adding two movzb to # cloop1 boosts its performance by 80%! This loop appears to be optimal # fit for Core2 and therefore the code was modified to skip cloop8 on # this CPU. # # OpenSolaris OS modifications # # Sun elects to use this software under the BSD license. # # This source originates from OpenSSL file rc4-x86_64.pl at # ftp://ftp.openssl.org/snapshot/openssl-0.9.8-stable-SNAP-20080131.tar.gz # (presumably for future OpenSSL release 0.9.8h), with these changes: # # 1. Added some comments, "use strict", and declared all variables. # # 2. Added OpenSolaris ENTRY_NP/SET_SIZE macros from # /usr/include/sys/asm_linkage.h. # # 3. Changed function name from RC4() to arcfour_crypt_asm() and RC4_set_key() # to arcfour_key_init(), and changed the parameter order for both to that # used by OpenSolaris. # # 4. The current method of using cpuid feature bits 20 (NX) or 28 (HTT) from # function OPENSSL_ia32_cpuid() to distinguish Intel/AMD does not work for # some newer AMD64 processors, as these bits are set on both Intel EM64T # processors and newer AMD64 processors. I replaced this with C code # (function arcfour_crypt_on_intel()) to call cpuid_getvendor() # when executing in the kernel and getisax() when executing in userland. # # 5. Set a new field in the key structure, key->flag to 0 for AMD AMD64 # and 1 for Intel EM64T. This is to select the most-efficient arcfour_crypt() # function to use. # # 6. Removed x86_64-xlate.pl script (not needed for as(1) or gas(1) assemblers). # # 7. Removed unused RC4_CHAR, Lcloop1, and Lcloop8 code. # # 8. Added C function definitions for use by lint(1B). # use strict; my ($code, $dat, $inp, $out, $len, $idx, $ido, $i, @XX, @TX, $YY, $TY); my $output = shift; open STDOUT,">$output"; # # Parameters # # OpenSSL: # void RC4(RC4_KEY *key, unsigned long len, const unsigned char *indata, # unsigned char *outdata); #$dat="%rdi"; # arg1 #$len="%rsi"; # arg2 #$inp="%rdx"; # arg3 #$out="%rcx"; # arg4 # OpenSolaris: # void arcfour_crypt_asm(ARCFour_key *key, uchar_t *in, uchar_t *out, # size_t len); $dat="%rdi"; # arg1 $inp="%rsi"; # arg2 $out="%rdx"; # arg3 $len="%rcx"; # arg4 # # Register variables # # $XX[0] is key->i (aka key->x), $XX[1] is a temporary. # $TX[0] and $TX[1] are temporaries. # $YY is key->j (aka key->y). # $TY is a temporary. # @XX=("%r8","%r10"); @TX=("%r9","%r11"); $YY="%r12"; $TY="%r13"; $code=<<___; #if defined(lint) || defined(__lint) #include "arcfour.h" /* ARGSUSED */ void arcfour_crypt_asm(ARCFour_key *key, uchar_t *in, uchar_t *out, size_t len) {} /* ARGSUSED */ void arcfour_key_init(ARCFour_key *key, uchar_t *keyval, int keyvallen) {} #else #include ENTRY_NP(arcfour_crypt_asm) or $len,$len # If (len == 0) return jne .Lentry ret .Lentry: push %r12 push %r13 / Set $dat to beginning of array, key->arr[0] add \$8,$dat / Get key->j movl -8($dat),$XX[0]#d / Get key->i movl -4($dat),$YY#d / / Use a 4-byte key schedule element array / inc $XX[0]#b movl ($dat,$XX[0],4),$TX[0]#d test \$-8,$len jz .Lloop1 jmp .Lloop8 .align 16 .Lloop8: ___ for ($i=0;$i<8;$i++) { $code.=<<___; add $TX[0]#b,$YY#b mov $XX[0],$XX[1] movl ($dat,$YY,4),$TY#d ror \$8,%rax # ror is redundant when $i=0 inc $XX[1]#b movl ($dat,$XX[1],4),$TX[1]#d cmp $XX[1],$YY movl $TX[0]#d,($dat,$YY,4) cmove $TX[0],$TX[1] movl $TY#d,($dat,$XX[0],4) add $TX[0]#b,$TY#b movb ($dat,$TY,4),%al ___ push(@TX,shift(@TX)); push(@XX,shift(@XX)); # "rotate" registers } $code.=<<___; ror \$8,%rax sub \$8,$len xor ($inp),%rax add \$8,$inp mov %rax,($out) add \$8,$out test \$-8,$len jnz .Lloop8 cmp \$0,$len jne .Lloop1 .Lexit: / / Cleanup and exit code / / --i to undo ++i done at entry sub \$1,$XX[0]#b / set key->i movl $XX[0]#d,-8($dat) / set key->j movl $YY#d,-4($dat) pop %r13 pop %r12 ret .align 16 .Lloop1: add $TX[0]#b,$YY#b movl ($dat,$YY,4),$TY#d movl $TX[0]#d,($dat,$YY,4) movl $TY#d,($dat,$XX[0],4) add $TY#b,$TX[0]#b inc $XX[0]#b movl ($dat,$TX[0],4),$TY#d movl ($dat,$XX[0],4),$TX[0]#d xorb ($inp),$TY#b inc $inp movb $TY#b,($out) inc $out dec $len jnz .Lloop1 jmp .Lexit ret SET_SIZE(arcfour_crypt_asm) ___ # # Parameters # # OpenSSL: # void RC4_set_key(RC4_KEY *key, int len, const unsigned char *data); #$dat="%rdi"; # arg1 #$len="%rsi"; # arg2 #$inp="%rdx"; # arg3 # OpenSolaris: # void arcfour_key_init(ARCFour_key *key, uchar_t *keyval, int keyvallen); $dat="%rdi"; # arg1 $inp="%rsi"; # arg2 $len="%rdx"; # arg3 # Temporaries $idx="%r8"; $ido="%r9"; $code.=<<___; / int arcfour_crypt_on_intel(void); .extern arcfour_crypt_on_intel ENTRY_NP(arcfour_key_init) / Find out if we're running on Intel or something else (e.g., AMD64). / This sets %eax to 1 for Intel, otherwise 0. push %rdi / Save arg1 push %rsi / Save arg2 push %rdx / Save arg3 call arcfour_crypt_on_intel pop %rdx / Restore arg3 pop %rsi / Restore arg2 pop %rdi / Restore arg1 / Save return value in key->flag (1=Intel, 0=AMD) movl %eax,1032($dat) / Set $dat to beginning of array, key->arr[0] lea 8($dat),$dat lea ($inp,$len),$inp neg $len mov $len,%rcx xor %eax,%eax xor $ido,$ido xor %r10,%r10 xor %r11,%r11 / Use a 4-byte data array jmp .Lw1stloop .align 16 .Lw1stloop: / AMD64 (4-byte array) mov %eax,($dat,%rax,4) add \$1,%al jnc .Lw1stloop xor $ido,$ido xor $idx,$idx .align 16 .Lw2ndloop: mov ($dat,$ido,4),%r10d add ($inp,$len,1),$idx#b add %r10b,$idx#b add \$1,$len mov ($dat,$idx,4),%r11d cmovz %rcx,$len mov %r10d,($dat,$idx,4) mov %r11d,($dat,$ido,4) add \$1,$ido#b jnc .Lw2ndloop / Exit code xor %eax,%eax mov %eax,-8($dat) mov %eax,-4($dat) ret SET_SIZE(arcfour_key_init) .asciz "RC4 for x86_64, CRYPTOGAMS by " #endif /* !lint && !__lint */ ___ $code =~ s/#([bwd])/$1/gm; print $code; close STDOUT;