#! /usr/bin/env perl # Copyright 1995-2018 The OpenSSL Project Authors. All Rights Reserved. # # Licensed under the OpenSSL license (the "License"). You may not use # this file except in compliance with the License. You can obtain a copy # in the file LICENSE in the source distribution or at # https://www.openssl.org/source/license.html # require 'x86asm.pl'; # &asm_init([,$i386only]); # &function_begin("foo"); # ... # &function_end("foo"); # &asm_finish $out=(); $i386=0; # AUTOLOAD is this context has quite unpleasant side effect, namely # that typos in function calls effectively go to assembler output, # but on the pros side we don't have to implement one subroutine per # each opcode... sub ::AUTOLOAD { my $opcode = $AUTOLOAD; die "more than 4 arguments passed to $opcode" if ($#_>3); $opcode =~ s/.*:://; if ($opcode =~ /^push/) { $stack+=4; } elsif ($opcode =~ /^pop/) { $stack-=4; } &generic($opcode,@_) or die "undefined subroutine \&$AUTOLOAD"; } # record_function_hit(int) writes a byte with value one to the given offset of # |BORINGSSL_function_hit|, but only if BORINGSSL_DISPATCH_TEST is defined. # This is used in impl_dispatch_test.cc to test whether the expected assembly # functions are triggered by high-level API calls. sub ::record_function_hit { my($index)=@_; &preprocessor_ifdef("BORINGSSL_DISPATCH_TEST"); &push("ebx"); &push("edx"); &call(&label("pic")); &set_label("pic"); &blindpop("ebx"); &lea("ebx",&DWP("BORINGSSL_function_hit+$index"."-".&label("pic"),"ebx")); &mov("edx", 1); &movb(&BP(0, "ebx"), "dl"); &pop("edx"); &pop("ebx"); &preprocessor_endif(); } sub ::emit { my $opcode=shift; if ($#_==-1) { push(@out,"\t$opcode\n"); } else { push(@out,"\t$opcode\t".join(',',@_)."\n"); } } sub ::LB { $_[0] =~ m/^e?([a-d])x$/o or die "$_[0] does not have a 'low byte'"; $1."l"; } sub ::HB { $_[0] =~ m/^e?([a-d])x$/o or die "$_[0] does not have a 'high byte'"; $1."h"; } sub ::stack_push{ my $num=$_[0]*4; $stack+=$num; &sub("esp",$num); } sub ::stack_pop { my $num=$_[0]*4; $stack-=$num; &add("esp",$num); } sub ::blindpop { &pop($_[0]); $stack+=4; } sub ::wparam { &DWP($stack+4*$_[0],"esp"); } sub ::swtmp { &DWP(4*$_[0],"esp"); } sub ::bswap { if ($i386) # emulate bswap for i386 { &comment("bswap @_"); &xchg(&HB(@_),&LB(@_)); &ror (@_,16); &xchg(&HB(@_),&LB(@_)); } else { &generic("bswap",@_); } } # These are made-up opcodes introduced over the years essentially # by ignorance, just alias them to real ones... sub ::movb { &mov(@_); } sub ::xorb { &xor(@_); } sub ::rotl { &rol(@_); } sub ::rotr { &ror(@_); } sub ::exch { &xchg(@_); } sub ::halt { &hlt; } sub ::movz { &movzx(@_); } sub ::pushf { &pushfd; } sub ::popf { &popfd; } # 3 argument instructions sub ::movq { my($p1,$p2,$optimize)=@_; if ($optimize && $p1=~/^mm[0-7]$/ && $p2=~/^mm[0-7]$/) # movq between mmx registers can sink Intel CPUs { &::pshufw($p1,$p2,0xe4); } else { &::generic("movq",@_); } } # SSE>2 instructions my %regrm = ( "eax"=>0, "ecx"=>1, "edx"=>2, "ebx"=>3, "esp"=>4, "ebp"=>5, "esi"=>6, "edi"=>7 ); sub ::pextrd { my($dst,$src,$imm)=@_; if ("$dst:$src" =~ /(e[a-dsd][ixp]):xmm([0-7])/) { &::data_byte(0x66,0x0f,0x3a,0x16,0xc0|($2<<3)|$regrm{$1},$imm); } else { &::generic("pextrd",@_); } } sub ::pinsrd { my($dst,$src,$imm)=@_; if ("$dst:$src" =~ /xmm([0-7]):(e[a-dsd][ixp])/) { &::data_byte(0x66,0x0f,0x3a,0x22,0xc0|($1<<3)|$regrm{$2},$imm); } else { &::generic("pinsrd",@_); } } sub ::pshufb { my($dst,$src)=@_; if ("$dst:$src" =~ /xmm([0-7]):xmm([0-7])/) { &data_byte(0x66,0x0f,0x38,0x00,0xc0|($1<<3)|$2); } else { &::generic("pshufb",@_); } } sub ::palignr { my($dst,$src,$imm)=@_; if ("$dst:$src" =~ /xmm([0-7]):xmm([0-7])/) { &::data_byte(0x66,0x0f,0x3a,0x0f,0xc0|($1<<3)|$2,$imm); } else { &::generic("palignr",@_); } } sub ::pclmulqdq { my($dst,$src,$imm)=@_; if ("$dst:$src" =~ /xmm([0-7]):xmm([0-7])/) { &::data_byte(0x66,0x0f,0x3a,0x44,0xc0|($1<<3)|$2,$imm); } else { &::generic("pclmulqdq",@_); } } sub ::rdrand { my ($dst)=@_; if ($dst =~ /(e[a-dsd][ixp])/) { &::data_byte(0x0f,0xc7,0xf0|$regrm{$dst}); } else { &::generic("rdrand",@_); } } sub ::rdseed { my ($dst)=@_; if ($dst =~ /(e[a-dsd][ixp])/) { &::data_byte(0x0f,0xc7,0xf8|$regrm{$dst}); } else { &::generic("rdrand",@_); } } sub rxb { local *opcode=shift; my ($dst,$src1,$src2,$rxb)=@_; $rxb|=0x7<<5; $rxb&=~(0x04<<5) if($dst>=8); $rxb&=~(0x01<<5) if($src1>=8); $rxb&=~(0x02<<5) if($src2>=8); push @opcode,$rxb; } sub ::vprotd { my $args=join(',',@_); if ($args =~ /xmm([0-7]),xmm([0-7]),([x0-9a-f]+)/) { my @opcode=(0x8f); rxb(\@opcode,$1,$2,-1,0x08); push @opcode,0x78,0xc2; push @opcode,0xc0|($2&7)|(($1&7)<<3); # ModR/M my $c=$3; push @opcode,$c=~/^0/?oct($c):$c; &::data_byte(@opcode); } else { &::generic("vprotd",@_); } } sub ::endbranch { &::data_byte(0xf3,0x0f,0x1e,0xfb); } # label management $lbdecor="L"; # local label decoration, set by package $label="000"; sub ::islabel # see is argument is a known label { my $i; foreach $i (values %label) { return $i if ($i eq $_[0]); } $label{$_[0]}; # can be undef } sub ::label # instantiate a function-scope label { if (!defined($label{$_[0]})) { $label{$_[0]}="${lbdecor}${label}${_[0]}"; $label++; } $label{$_[0]}; } sub ::LABEL # instantiate a file-scope label { $label{$_[0]}=$_[1] if (!defined($label{$_[0]})); $label{$_[0]}; } sub ::static_label { &::LABEL($_[0],$lbdecor.$_[0]); } sub ::set_label_B { push(@out,"@_:\n"); } sub ::set_label { my $label=&::label($_[0]); &::align($_[1]) if ($_[1]>1); &::set_label_B($label); $label; } sub ::wipe_labels # wipes function-scope labels { foreach $i (keys %label) { delete $label{$i} if ($label{$i} =~ /^\Q${lbdecor}\E[0-9]{3}/); } } # subroutine management sub ::function_begin { &function_begin_B(@_); $stack=4; &push("ebp"); &push("ebx"); &push("esi"); &push("edi"); } sub ::function_end { &pop("edi"); &pop("esi"); &pop("ebx"); &pop("ebp"); &ret(); &function_end_B(@_); $stack=0; &wipe_labels(); } sub ::function_end_A { &pop("edi"); &pop("esi"); &pop("ebx"); &pop("ebp"); &ret(); $stack+=16; # readjust esp as if we didn't pop anything } sub ::asciz { my @str=unpack("C*",shift); push @str,0; while ($#str>15) { &data_byte(@str[0..15]); foreach (0..15) { shift @str; } } &data_byte(@str) if (@str); } sub ::asm_finish { &file_end(); my $comment = "//"; $comment = ";" if ($win32); print <<___; $comment This file is generated from a similarly-named Perl script in the BoringSSL $comment source tree. Do not edit by hand. ___ if ($win32) { print <<___ unless $masm; \%include "ring_core_generated/prefix_symbols_nasm.inc" \%ifidn __OUTPUT_FORMAT__, win32 ___ print @out; print <<___ unless $masm; \%else ; Work around https://bugzilla.nasm.us/show_bug.cgi?id=3392738 ret \%endif ___ } else { my $target; if ($elf) { $target = "defined(__ELF__)"; } elsif ($macosx) { $target = "defined(__APPLE__)"; } else { die "unknown target"; } print <<___; #include #if !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86) && $target ___ print @out; print <<___; #endif // !defined(OPENSSL_NO_ASM) && defined(OPENSSL_X86) && $target ___ } } sub ::asm_init { my ($type,$cpu)=@_; $i386=$cpu; $elf=$cpp=$coff=$aout=$macosx=$win32=$mwerks=$android=0; if (($type eq "elf")) { $elf=1; require "x86gas.pl"; } elsif (($type eq "elf-1")) { $elf=-1; require "x86gas.pl"; } elsif (($type eq "a\.out")) { $aout=1; require "x86gas.pl"; } elsif (($type eq "coff" or $type eq "gaswin")) { $coff=1; require "x86gas.pl"; } elsif (($type eq "win32n")) { $win32=1; require "x86nasm.pl"; } elsif (($type eq "win32")) { $win32=1; $masm=1; require "x86masm.pl"; } elsif (($type eq "macosx")) { $aout=1; $macosx=1; require "x86gas.pl"; } elsif (($type eq "android")) { $elf=1; $android=1; require "x86gas.pl"; } else { print STDERR <<"EOF"; Pick one target type from elf - Linux, FreeBSD, Solaris x86, etc. a.out - DJGPP, elder OpenBSD, etc. coff - GAS/COFF such as Win32 targets win32n - Windows 95/Windows NT NASM format macosx - Mac OS X EOF exit(1); } $pic=0; for (@ARGV) { $pic=1 if (/\-[fK]PIC/i); } &file(); } sub ::hidden {} 1;