#! /usr/bin/env perl # Copyright 2005-2016 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 $flavour = shift; $output = shift; if ($flavour =~ /\./) { $output = $flavour; undef $flavour; } $win64=0; $win64=1 if ($flavour =~ /[nm]asm|mingw64/ || $output =~ /\.asm$/); $0 =~ m/(.*[\/\\])[^\/\\]+$/; $dir=$1; ( $xlate="${dir}x86_64-xlate.pl" and -f $xlate ) or ( $xlate="${dir}perlasm/x86_64-xlate.pl" and -f $xlate) or die "can't locate x86_64-xlate.pl"; open OUT,"| \"$^X\" \"$xlate\" $flavour \"$output\""; *STDOUT=*OUT; ($arg1,$arg2,$arg3,$arg4)=$win64?("%rcx","%rdx","%r8", "%r9") : # Win64 order ("%rdi","%rsi","%rdx","%rcx"); # Unix order print<<___; .extern OPENSSL_cpuid_setup .hidden OPENSSL_cpuid_setup .section .init call OPENSSL_cpuid_setup .hidden OPENSSL_ia32cap_P .comm OPENSSL_ia32cap_P,16,4 .text .globl OPENSSL_atomic_add .type OPENSSL_atomic_add,\@abi-omnipotent .align 16 OPENSSL_atomic_add: movl ($arg1),%eax .Lspin: leaq ($arg2,%rax),%r8 .byte 0xf0 # lock cmpxchgl %r8d,($arg1) jne .Lspin movl %r8d,%eax .byte 0x48,0x98 # cltq/cdqe ret .size OPENSSL_atomic_add,.-OPENSSL_atomic_add .globl OPENSSL_rdtsc .type OPENSSL_rdtsc,\@abi-omnipotent .align 16 OPENSSL_rdtsc: rdtsc shl \$32,%rdx or %rdx,%rax ret .size OPENSSL_rdtsc,.-OPENSSL_rdtsc .globl OPENSSL_ia32_cpuid .type OPENSSL_ia32_cpuid,\@function,1 .align 16 OPENSSL_ia32_cpuid: .cfi_startproc mov %rbx,%r8 # save %rbx .cfi_register %rbx,%r8 xor %eax,%eax mov %rax,8(%rdi) # clear extended feature flags cpuid mov %eax,%r11d # max value for standard query level xor %eax,%eax cmp \$0x756e6547,%ebx # "Genu" setne %al mov %eax,%r9d cmp \$0x49656e69,%edx # "ineI" setne %al or %eax,%r9d cmp \$0x6c65746e,%ecx # "ntel" setne %al or %eax,%r9d # 0 indicates Intel CPU jz .Lintel cmp \$0x68747541,%ebx # "Auth" setne %al mov %eax,%r10d cmp \$0x69746E65,%edx # "enti" setne %al or %eax,%r10d cmp \$0x444D4163,%ecx # "cAMD" setne %al or %eax,%r10d # 0 indicates AMD CPU jnz .Lintel # AMD specific mov \$0x80000000,%eax cpuid cmp \$0x80000001,%eax jb .Lintel mov %eax,%r10d mov \$0x80000001,%eax cpuid or %ecx,%r9d and \$0x00000801,%r9d # isolate AMD XOP bit, 1<<11 cmp \$0x80000008,%r10d jb .Lintel mov \$0x80000008,%eax cpuid movzb %cl,%r10 # number of cores - 1 inc %r10 # number of cores mov \$1,%eax cpuid bt \$28,%edx # test hyper-threading bit jnc .Lgeneric shr \$16,%ebx # number of logical processors cmp %r10b,%bl ja .Lgeneric and \$0xefffffff,%edx # ~(1<<28) jmp .Lgeneric .Lintel: cmp \$4,%r11d mov \$-1,%r10d jb .Lnocacheinfo mov \$4,%eax mov \$0,%ecx # query L1D cpuid mov %eax,%r10d shr \$14,%r10d and \$0xfff,%r10d # number of cores -1 per L1D .Lnocacheinfo: mov \$1,%eax cpuid and \$0xbfefffff,%edx # force reserved bits to 0 cmp \$0,%r9d jne .Lnotintel or \$0x40000000,%edx # set reserved bit#30 on Intel CPUs and \$15,%ah cmp \$15,%ah # examine Family ID jne .LnotP4 or \$0x00100000,%edx # set reserved bit#20 to engage RC4_CHAR .LnotP4: cmp \$6,%ah jne .Lnotintel and \$0x0fff0ff0,%eax cmp \$0x00050670,%eax # Knights Landing je .Lknights cmp \$0x00080650,%eax # Knights Mill (according to sde) jne .Lnotintel .Lknights: and \$0xfbffffff,%ecx # clear XSAVE flag to mimic Silvermont .Lnotintel: bt \$28,%edx # test hyper-threading bit jnc .Lgeneric and \$0xefffffff,%edx # ~(1<<28) cmp \$0,%r10d je .Lgeneric or \$0x10000000,%edx # 1<<28 shr \$16,%ebx cmp \$1,%bl # see if cache is shared ja .Lgeneric and \$0xefffffff,%edx # ~(1<<28) .Lgeneric: and \$0x00000800,%r9d # isolate AMD XOP flag and \$0xfffff7ff,%ecx or %ecx,%r9d # merge AMD XOP flag mov %edx,%r10d # %r9d:%r10d is copy of %ecx:%edx cmp \$7,%r11d jb .Lno_extended_info mov \$7,%eax xor %ecx,%ecx cpuid bt \$26,%r9d # check XSAVE bit, cleared on Knights jc .Lnotknights and \$0xfff7ffff,%ebx # clear ADCX/ADOX flag .Lnotknights: mov %ebx,8(%rdi) # save extended feature flags mov %ecx,12(%rdi) .Lno_extended_info: bt \$27,%r9d # check OSXSAVE bit jnc .Lclear_avx xor %ecx,%ecx # XCR0 .byte 0x0f,0x01,0xd0 # xgetbv and \$0xe6,%eax # isolate XMM, YMM and ZMM state support cmp \$0xe6,%eax je .Ldone andl \$0x3fdeffff,8(%rdi) # ~(1<<31|1<<30|1<<21|1<<16) # clear AVX512F+BW+VL+FIMA, all of # them are EVEX-encoded, which requires # ZMM state support even if one uses # only XMM and YMM :-( and \$6,%eax # isolate XMM and YMM state support cmp \$6,%eax je .Ldone .Lclear_avx: mov \$0xefffe7ff,%eax # ~(1<<28|1<<12|1<<11) and %eax,%r9d # clear AVX, FMA and AMD XOP bits mov \$0x3fdeffdf,%eax # ~(1<<31|1<<30|1<<21|1<<16|1<<5) and %eax,8(%rdi) # clear AVX2 and AVX512* bits .Ldone: shl \$32,%r9 mov %r10d,%eax mov %r8,%rbx # restore %rbx .cfi_restore %rbx or %r9,%rax ret .cfi_endproc .size OPENSSL_ia32_cpuid,.-OPENSSL_ia32_cpuid .globl OPENSSL_cleanse .type OPENSSL_cleanse,\@abi-omnipotent .align 16 OPENSSL_cleanse: xor %rax,%rax cmp \$15,$arg2 jae .Lot cmp \$0,$arg2 je .Lret .Little: mov %al,($arg1) sub \$1,$arg2 lea 1($arg1),$arg1 jnz .Little .Lret: ret .align 16 .Lot: test \$7,$arg1 jz .Laligned mov %al,($arg1) lea -1($arg2),$arg2 lea 1($arg1),$arg1 jmp .Lot .Laligned: mov %rax,($arg1) lea -8($arg2),$arg2 test \$-8,$arg2 lea 8($arg1),$arg1 jnz .Laligned cmp \$0,$arg2 jne .Little ret .size OPENSSL_cleanse,.-OPENSSL_cleanse .globl CRYPTO_memcmp .type CRYPTO_memcmp,\@abi-omnipotent .align 16 CRYPTO_memcmp: xor %rax,%rax xor %r10,%r10 cmp \$0,$arg3 je .Lno_data .Loop_cmp: mov ($arg1),%r10b lea 1($arg1),$arg1 xor ($arg2),%r10b lea 1($arg2),$arg2 or %r10b,%al dec $arg3 jnz .Loop_cmp neg %rax shr \$63,%rax .Lno_data: ret .size CRYPTO_memcmp,.-CRYPTO_memcmp ___ print<<___ if (!$win64); .globl OPENSSL_wipe_cpu .type OPENSSL_wipe_cpu,\@abi-omnipotent .align 16 OPENSSL_wipe_cpu: pxor %xmm0,%xmm0 pxor %xmm1,%xmm1 pxor %xmm2,%xmm2 pxor %xmm3,%xmm3 pxor %xmm4,%xmm4 pxor %xmm5,%xmm5 pxor %xmm6,%xmm6 pxor %xmm7,%xmm7 pxor %xmm8,%xmm8 pxor %xmm9,%xmm9 pxor %xmm10,%xmm10 pxor %xmm11,%xmm11 pxor %xmm12,%xmm12 pxor %xmm13,%xmm13 pxor %xmm14,%xmm14 pxor %xmm15,%xmm15 xorq %rcx,%rcx xorq %rdx,%rdx xorq %rsi,%rsi xorq %rdi,%rdi xorq %r8,%r8 xorq %r9,%r9 xorq %r10,%r10 xorq %r11,%r11 leaq 8(%rsp),%rax ret .size OPENSSL_wipe_cpu,.-OPENSSL_wipe_cpu ___ print<<___ if ($win64); .globl OPENSSL_wipe_cpu .type OPENSSL_wipe_cpu,\@abi-omnipotent .align 16 OPENSSL_wipe_cpu: pxor %xmm0,%xmm0 pxor %xmm1,%xmm1 pxor %xmm2,%xmm2 pxor %xmm3,%xmm3 pxor %xmm4,%xmm4 pxor %xmm5,%xmm5 xorq %rcx,%rcx xorq %rdx,%rdx xorq %r8,%r8 xorq %r9,%r9 xorq %r10,%r10 xorq %r11,%r11 leaq 8(%rsp),%rax ret .size OPENSSL_wipe_cpu,.-OPENSSL_wipe_cpu ___ { my $out="%r10"; my $cnt="%rcx"; my $max="%r11"; my $lasttick="%r8d"; my $lastdiff="%r9d"; my $redzone=win64?8:-8; print<<___; .globl OPENSSL_instrument_bus .type OPENSSL_instrument_bus,\@abi-omnipotent .align 16 OPENSSL_instrument_bus: mov $arg1,$out # tribute to Win64 mov $arg2,$cnt mov $arg2,$max rdtsc # collect 1st tick mov %eax,$lasttick # lasttick = tick mov \$0,$lastdiff # lastdiff = 0 clflush ($out) .byte 0xf0 # lock add $lastdiff,($out) jmp .Loop .align 16 .Loop: rdtsc mov %eax,%edx sub $lasttick,%eax mov %edx,$lasttick mov %eax,$lastdiff clflush ($out) .byte 0xf0 # lock add %eax,($out) lea 4($out),$out sub \$1,$cnt jnz .Loop mov $max,%rax ret .size OPENSSL_instrument_bus,.-OPENSSL_instrument_bus .globl OPENSSL_instrument_bus2 .type OPENSSL_instrument_bus2,\@abi-omnipotent .align 16 OPENSSL_instrument_bus2: mov $arg1,$out # tribute to Win64 mov $arg2,$cnt mov $arg3,$max mov $cnt,$redzone(%rsp) rdtsc # collect 1st tick mov %eax,$lasttick # lasttick = tick mov \$0,$lastdiff # lastdiff = 0 clflush ($out) .byte 0xf0 # lock add $lastdiff,($out) rdtsc # collect 1st diff mov %eax,%edx sub $lasttick,%eax # diff mov %edx,$lasttick # lasttick = tick mov %eax,$lastdiff # lastdiff = diff .Loop2: clflush ($out) .byte 0xf0 # lock add %eax,($out) # accumulate diff sub \$1,$max jz .Ldone2 rdtsc mov %eax,%edx sub $lasttick,%eax # diff mov %edx,$lasttick # lasttick = tick cmp $lastdiff,%eax mov %eax,$lastdiff # lastdiff = diff mov \$0,%edx setne %dl sub %rdx,$cnt # conditional --$cnt lea ($out,%rdx,4),$out # conditional ++$out jnz .Loop2 .Ldone2: mov $redzone(%rsp),%rax sub $cnt,%rax ret .size OPENSSL_instrument_bus2,.-OPENSSL_instrument_bus2 ___ } sub gen_random { my $rdop = shift; print<<___; .globl OPENSSL_ia32_${rdop} .type OPENSSL_ia32_${rdop},\@abi-omnipotent .align 16 OPENSSL_ia32_${rdop}: mov \$8,%ecx .Loop_${rdop}: ${rdop} %rax jc .Lbreak_${rdop} loop .Loop_${rdop} .Lbreak_${rdop}: cmp \$0,%rax cmove %rcx,%rax ret .size OPENSSL_ia32_${rdop},.-OPENSSL_ia32_${rdop} .globl OPENSSL_ia32_${rdop}_bytes .type OPENSSL_ia32_${rdop}_bytes,\@abi-omnipotent .align 16 OPENSSL_ia32_${rdop}_bytes: xor %rax, %rax # return value cmp \$0,$arg2 je .Ldone_${rdop}_bytes mov \$8,%r11 .Loop_${rdop}_bytes: ${rdop} %r10 jc .Lbreak_${rdop}_bytes dec %r11 jnz .Loop_${rdop}_bytes jmp .Ldone_${rdop}_bytes .align 16 .Lbreak_${rdop}_bytes: cmp \$8,$arg2 jb .Ltail_${rdop}_bytes mov %r10,($arg1) lea 8($arg1),$arg1 add \$8,%rax sub \$8,$arg2 jz .Ldone_${rdop}_bytes mov \$8,%r11 jmp .Loop_${rdop}_bytes .align 16 .Ltail_${rdop}_bytes: mov %r10b,($arg1) lea 1($arg1),$arg1 inc %rax shr \$8,%r8 dec $arg2 jnz .Ltail_${rdop}_bytes .Ldone_${rdop}_bytes: ret .size OPENSSL_ia32_${rdop}_bytes,.-OPENSSL_ia32_${rdop}_bytes ___ } gen_random("rdrand"); gen_random("rdseed"); close STDOUT; # 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