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mirror of https://github.com/edk2-porting/linux-next.git synced 2024-12-21 11:44:01 +08:00
linux-next/scripts/markup_oops.pl
Kamil Rytarowski cb77f0d623 scripts: Switch to more portable Perl shebang
The default NetBSD package manager is pkgsrc and it installs Perl
along other third party programs under custom and configurable prefix.
The default prefix for binary prebuilt packages is /usr/pkg, and the
Perl executable lands in /usr/pkg/bin/perl.

This change switches "/usr/bin/perl" to "/usr/bin/env perl" as it's
the most portable solution that should work for almost everybody.
Perl's executable is detected automatically.

This change switches -w option passed to the executable with more
modern "use warnings;" approach. There is no functional change to the
default behavior.

While there, drop "require 5" from scripts/namespace.pl (Perl from 1994?).

Signed-off-by: Kamil Rytarowski <n54@gmx.com>
Signed-off-by: Masahiro Yamada <yamada.masahiro@socionext.com>
2017-05-14 11:20:44 +09:00

370 lines
8.1 KiB
Perl
Executable File

#!/usr/bin/env perl
use File::Basename;
use Math::BigInt;
use Getopt::Long;
# Copyright 2008, Intel Corporation
#
# This file is part of the Linux kernel
#
# This program file is free software; you can redistribute it and/or modify it
# under the terms of the GNU General Public License as published by the
# Free Software Foundation; version 2 of the License.
#
# Authors:
# Arjan van de Ven <arjan@linux.intel.com>
my $cross_compile = "";
my $vmlinux_name = "";
my $modulefile = "";
# Get options
Getopt::Long::GetOptions(
'cross-compile|c=s' => \$cross_compile,
'module|m=s' => \$modulefile,
'help|h' => \&usage,
) || usage ();
my $vmlinux_name = $ARGV[0];
if (!defined($vmlinux_name)) {
my $kerver = `uname -r`;
chomp($kerver);
$vmlinux_name = "/lib/modules/$kerver/build/vmlinux";
print "No vmlinux specified, assuming $vmlinux_name\n";
}
my $filename = $vmlinux_name;
# Parse the oops to find the EIP value
my $target = "0";
my $function;
my $module = "";
my $func_offset = 0;
my $vmaoffset = 0;
my %regs;
sub parse_x86_regs
{
my ($line) = @_;
if ($line =~ /EAX: ([0-9a-f]+) EBX: ([0-9a-f]+) ECX: ([0-9a-f]+) EDX: ([0-9a-f]+)/) {
$regs{"%eax"} = $1;
$regs{"%ebx"} = $2;
$regs{"%ecx"} = $3;
$regs{"%edx"} = $4;
}
if ($line =~ /ESI: ([0-9a-f]+) EDI: ([0-9a-f]+) EBP: ([0-9a-f]+) ESP: ([0-9a-f]+)/) {
$regs{"%esi"} = $1;
$regs{"%edi"} = $2;
$regs{"%esp"} = $4;
}
if ($line =~ /RAX: ([0-9a-f]+) RBX: ([0-9a-f]+) RCX: ([0-9a-f]+)/) {
$regs{"%eax"} = $1;
$regs{"%ebx"} = $2;
$regs{"%ecx"} = $3;
}
if ($line =~ /RDX: ([0-9a-f]+) RSI: ([0-9a-f]+) RDI: ([0-9a-f]+)/) {
$regs{"%edx"} = $1;
$regs{"%esi"} = $2;
$regs{"%edi"} = $3;
}
if ($line =~ /RBP: ([0-9a-f]+) R08: ([0-9a-f]+) R09: ([0-9a-f]+)/) {
$regs{"%r08"} = $2;
$regs{"%r09"} = $3;
}
if ($line =~ /R10: ([0-9a-f]+) R11: ([0-9a-f]+) R12: ([0-9a-f]+)/) {
$regs{"%r10"} = $1;
$regs{"%r11"} = $2;
$regs{"%r12"} = $3;
}
if ($line =~ /R13: ([0-9a-f]+) R14: ([0-9a-f]+) R15: ([0-9a-f]+)/) {
$regs{"%r13"} = $1;
$regs{"%r14"} = $2;
$regs{"%r15"} = $3;
}
}
sub reg_name
{
my ($reg) = @_;
$reg =~ s/r(.)x/e\1x/;
$reg =~ s/r(.)i/e\1i/;
$reg =~ s/r(.)p/e\1p/;
return $reg;
}
sub process_x86_regs
{
my ($line, $cntr) = @_;
my $str = "";
if (length($line) < 40) {
return ""; # not an asm istruction
}
# find the arguments to the instruction
if ($line =~ /([0-9a-zA-Z\,\%\(\)\-\+]+)$/) {
$lastword = $1;
} else {
return "";
}
# we need to find the registers that get clobbered,
# since their value is no longer relevant for previous
# instructions in the stream.
$clobber = $lastword;
# first, remove all memory operands, they're read only
$clobber =~ s/\([a-z0-9\%\,]+\)//g;
# then, remove everything before the comma, thats the read part
$clobber =~ s/.*\,//g;
# if this is the instruction that faulted, we haven't actually done
# the write yet... nothing is clobbered.
if ($cntr == 0) {
$clobber = "";
}
foreach $reg (keys(%regs)) {
my $clobberprime = reg_name($clobber);
my $lastwordprime = reg_name($lastword);
my $val = $regs{$reg};
if ($val =~ /^[0]+$/) {
$val = "0";
} else {
$val =~ s/^0*//;
}
# first check if we're clobbering this register; if we do
# we print it with a =>, and then delete its value
if ($clobber =~ /$reg/ || $clobberprime =~ /$reg/) {
if (length($val) > 0) {
$str = $str . " $reg => $val ";
}
$regs{$reg} = "";
$val = "";
}
# now check if we're reading this register
if ($lastword =~ /$reg/ || $lastwordprime =~ /$reg/) {
if (length($val) > 0) {
$str = $str . " $reg = $val ";
}
}
}
return $str;
}
# parse the oops
while (<STDIN>) {
my $line = $_;
if ($line =~ /EIP: 0060:\[\<([a-z0-9]+)\>\]/) {
$target = $1;
}
if ($line =~ /RIP: 0010:\[\<([a-z0-9]+)\>\]/) {
$target = $1;
}
if ($line =~ /EIP is at ([a-zA-Z0-9\_]+)\+0x([0-9a-f]+)\/0x[a-f0-9]/) {
$function = $1;
$func_offset = $2;
}
if ($line =~ /RIP: 0010:\[\<[0-9a-f]+\>\] \[\<[0-9a-f]+\>\] ([a-zA-Z0-9\_]+)\+0x([0-9a-f]+)\/0x[a-f0-9]/) {
$function = $1;
$func_offset = $2;
}
# check if it's a module
if ($line =~ /EIP is at ([a-zA-Z0-9\_]+)\+(0x[0-9a-f]+)\/0x[a-f0-9]+\W\[([a-zA-Z0-9\_\-]+)\]/) {
$module = $3;
}
if ($line =~ /RIP: 0010:\[\<[0-9a-f]+\>\] \[\<[0-9a-f]+\>\] ([a-zA-Z0-9\_]+)\+(0x[0-9a-f]+)\/0x[a-f0-9]+\W\[([a-zA-Z0-9\_\-]+)\]/) {
$module = $3;
}
parse_x86_regs($line);
}
my $decodestart = Math::BigInt->from_hex("0x$target") - Math::BigInt->from_hex("0x$func_offset");
my $decodestop = Math::BigInt->from_hex("0x$target") + 8192;
if ($target eq "0") {
print "No oops found!\n";
usage();
}
# if it's a module, we need to find the .ko file and calculate a load offset
if ($module ne "") {
if ($modulefile eq "") {
$modulefile = `modinfo -F filename $module`;
chomp($modulefile);
}
$filename = $modulefile;
if ($filename eq "") {
print "Module .ko file for $module not found. Aborting\n";
exit;
}
# ok so we found the module, now we need to calculate the vma offset
open(FILE, $cross_compile."objdump -dS $filename |") || die "Cannot start objdump";
while (<FILE>) {
if ($_ =~ /^([0-9a-f]+) \<$function\>\:/) {
my $fu = $1;
$vmaoffset = Math::BigInt->from_hex("0x$target") - Math::BigInt->from_hex("0x$fu") - Math::BigInt->from_hex("0x$func_offset");
}
}
close(FILE);
}
my $counter = 0;
my $state = 0;
my $center = -1;
my @lines;
my @reglines;
sub InRange {
my ($address, $target) = @_;
my $ad = "0x".$address;
my $ta = "0x".$target;
my $delta = Math::BigInt->from_hex($ad) - Math::BigInt->from_hex($ta);
if (($delta > -4096) && ($delta < 4096)) {
return 1;
}
return 0;
}
# first, parse the input into the lines array, but to keep size down,
# we only do this for 4Kb around the sweet spot
open(FILE, $cross_compile."objdump -dS --adjust-vma=$vmaoffset --start-address=$decodestart --stop-address=$decodestop $filename |") || die "Cannot start objdump";
while (<FILE>) {
my $line = $_;
chomp($line);
if ($state == 0) {
if ($line =~ /^([a-f0-9]+)\:/) {
if (InRange($1, $target)) {
$state = 1;
}
}
}
if ($state == 1) {
if ($line =~ /^([a-f0-9][a-f0-9][a-f0-9][a-f0-9][a-f0-9][a-f0-9]+)\:/) {
my $val = $1;
if (!InRange($val, $target)) {
last;
}
if ($val eq $target) {
$center = $counter;
}
}
$lines[$counter] = $line;
$counter = $counter + 1;
}
}
close(FILE);
if ($counter == 0) {
print "No matching code found \n";
exit;
}
if ($center == -1) {
print "No matching code found \n";
exit;
}
my $start;
my $finish;
my $codelines = 0;
my $binarylines = 0;
# now we go up and down in the array to find how much we want to print
$start = $center;
while ($start > 1) {
$start = $start - 1;
my $line = $lines[$start];
if ($line =~ /^([a-f0-9]+)\:/) {
$binarylines = $binarylines + 1;
} else {
$codelines = $codelines + 1;
}
if ($codelines > 10) {
last;
}
if ($binarylines > 20) {
last;
}
}
$finish = $center;
$codelines = 0;
$binarylines = 0;
while ($finish < $counter) {
$finish = $finish + 1;
my $line = $lines[$finish];
if ($line =~ /^([a-f0-9]+)\:/) {
$binarylines = $binarylines + 1;
} else {
$codelines = $codelines + 1;
}
if ($codelines > 10) {
last;
}
if ($binarylines > 20) {
last;
}
}
my $i;
# start annotating the registers in the asm.
# this goes from the oopsing point back, so that the annotator
# can track (opportunistically) which registers got written and
# whos value no longer is relevant.
$i = $center;
while ($i >= $start) {
$reglines[$i] = process_x86_regs($lines[$i], $center - $i);
$i = $i - 1;
}
$i = $start;
while ($i < $finish) {
my $line;
if ($i == $center) {
$line = "*$lines[$i] ";
} else {
$line = " $lines[$i] ";
}
print $line;
if (defined($reglines[$i]) && length($reglines[$i]) > 0) {
my $c = 60 - length($line);
while ($c > 0) { print " "; $c = $c - 1; };
print "| $reglines[$i]";
}
if ($i == $center) {
print "<--- faulting instruction";
}
print "\n";
$i = $i +1;
}
sub usage {
print <<EOT;
Usage:
dmesg | perl $0 [OPTION] [VMLINUX]
OPTION:
-c, --cross-compile CROSS_COMPILE Specify the prefix used for toolchain.
-m, --module MODULE_DIRNAME Specify the module filename.
-h, --help Help.
EOT
exit;
}