spectre-meltdown-checker/spectre-meltdown-checker.sh

#! /bin/sh
# Spectre & Meltdown checker
# Stephane Lesimple
VERSION=0.13

# print status function
pstatus()
{
	case "$1" in
		red)    col="\033[101m\033[30m";;
		green)  col="\033[102m\033[30m";;
		yellow) col="\033[103m\033[30m";;
		*)      col="";;
	esac
	/bin/echo -ne "$col $2 \033[0m"
	[ -n "$3" ] && /bin/echo -n " ($3)"
	/bin/echo
}

# The 3 below functions are taken from the extract-linux script, available here:
# https://github.com/torvalds/linux/blob/master/scripts/extract-vmlinux
# The functions have been modified for better integration to this script
# The original header of the file has been retained below

# ----------------------------------------------------------------------
# extract-vmlinux - Extract uncompressed vmlinux from a kernel image
#
# Inspired from extract-ikconfig
# (c) 2009,2010 Dick Streefland <dick@streefland.net>
#
# (c) 2011      Corentin Chary <corentin.chary@gmail.com>
#
# Licensed under the GNU General Public License, version 2 (GPLv2).
# ----------------------------------------------------------------------

check_vmlinux()
{
	file "$1" 2>/dev/null | grep -q ELF || return 1
	return 0
}

try_decompress()
{
        # The obscure use of the "tr" filter is to work around older versions of
        # "grep" that report the byte offset of the line instead of the pattern.

        # Try to find the header ($1) and decompress from here
        for     pos in `tr "$1\n$2" "\n$2=" < "$4" | grep -abo "^$2"`
        do
                pos=${pos%%:*}
                tail -c+$pos "$4" | $3 > $vmlinuxtmp 2> /dev/null
                check_vmlinux "$vmlinuxtmp" && echo "$vmlinuxtmp" && return 0
        done
	return 1
}

extract_vmlinux()
{
	[ -n "$1" ] || return 1
	# Prepare temp files:
	vmlinuxtmp="$(mktemp /tmp/vmlinux-XXX)"

	# Initial attempt for uncompressed images or objects:
	if check_vmlinux "$1"; then
		cat "$1" > "$vmlinuxtmp"
		echo "$vmlinuxtmp"
		return 0
	fi

	# That didn't work, so retry after decompression.
	try_decompress '\037\213\010' xy    gunzip     "$1" && return 0
	try_decompress '\3757zXZ\000' abcde unxz       "$1" && return 0
	try_decompress 'BZh'          xy    bunzip2    "$1" && return 0
	try_decompress '\135\0\0\0'   xxx   unlzma     "$1" && return 0
	try_decompress '\211\114\132' xy    'lzop -d'  "$1" && return 0
	return 1
}

# end of extract-vmlinux functions

/bin/echo -e "\033[1;34mSpectre and Meltdown mitigation detection tool v$VERSION\033[0m"
/bin/echo

# root check

if [ "$(id -u)" -ne 0 ]; then
	/bin/echo -e "\033[31mNote that you should launch this script with root privileges to get accurate information.\033[0m"
	/bin/echo -e "\033[31mWe'll proceed but you might see permission denied errors.\033[0m"
	/bin/echo -e "\033[31mTo run it as root, you can try the following command: sudo $0\033[0m"
	/bin/echo
fi

/bin/echo -e "Checking vulnerabilities against \033[35m"$(uname -s) $(uname -r) $(uname -v) $(uname -m)"\033[0m"
/bin/echo

###########
# SPECTRE 1
/bin/echo -e "\033[1;34mCVE-2017-5753 [bounds check bypass] aka 'Spectre Variant 1'\033[0m"
/bin/echo -n "* Kernel compiled with LFENCE opcode inserted at the proper places: "

status=0
img=''
# try to find the image of the current running kernel
[ -e /boot/vmlinuz-linux       ] && img=/boot/vmlinuz-linux
[ -e /boot/vmlinuz-$(uname -r) ] && img=/boot/vmlinuz-$(uname -r)
[ -e /boot/kernel-$( uname -r) ] && img=/boot/kernel-$( uname -r)
[ -e /boot/bzImage-$(uname -r) ] && img=/boot/bzImage-$(uname -r)
[ -e /boot/kernel-genkernel-$(uname -m)-$(uname -r) ] && img=/boot/kernel-genkernel-$(uname -m)-$(uname -r)
if [ -z "$img" ]; then
	pstatus yellow UNKNOWN "couldn't find your kernel image in /boot, if you used netboot, this is normal"
else
	vmlinux=$(extract_vmlinux $img)
	if [ -z "$vmlinux" -o ! -r "$vmlinux" ]; then
		pstatus yellow UNKNOWN "couldn't extract your kernel from $img"
	elif ! which objdump >/dev/null 2>&1; then
		pstatus yellow UNKNOWN "missing 'objdump' tool, please install it, usually it's in the binutils package"
	else
		# here we disassemble the kernel and count the number of occurences of the LFENCE opcode
		# in non-patched kernels, this has been empirically determined as being around 40-50
		# in patched kernels, this is more around 70-80, sometimes way higher (100+)
		# v0.13: 68 found in a 3.10.23-xxxx-std-ipv6-64 (with lots of modules compiled-in directly), which doesn't have the LFENCE patches,
		# so let's push the threshold to 70.
		# TODO LKML patch is starting to dump LFENCE in favor of the PAUSE opcode, we might need to check that (patch not stabilized yet)
		nb_lfence=$(objdump -D "$vmlinux" | grep -wc lfence)
		if [ "$nb_lfence" -lt 70 ]; then
			pstatus red NO "only $nb_lfence opcodes found, should be >= 70"
			status=1
		else
			pstatus green YES "$nb_lfence opcodes found, which is >= 70"
			status=2
		fi
	fi
fi

/bin/echo -ne "> \033[46m\033[30mSTATUS:\033[0m "
[ "$status" = 0 ] && pstatus yellow UNKNOWN
[ "$status" = 1 ] && pstatus red VULNERABLE
[ "$status" = 2 ] && pstatus green 'NOT VULNERABLE'

###########
# VARIANT 2
/bin/echo
/bin/echo -e "\033[1;34mCVE-2017-5715 [branch target injection] aka 'Spectre Variant 2'\033[0m"
/bin/echo "* Mitigation 1"
/bin/echo -n "*   Hardware (CPU microcode) support for mitigation: "
if [ ! -e /dev/cpu/0/msr ]; then
	# try to load the module ourselves (and remember it so we can rmmod it afterwards)
	modprobe msr 2>/dev/null && insmod_msr=1
fi
if [ ! -e /dev/cpu/0/msr ]; then
	pstatus yellow UNKNOWN "couldn't read /dev/cpu/0/msr, is msr support enabled in your kernel?"
else
	# the new MSR 'SPEC_CTRL' is at offset 0x48
	# here we use dd, it's the same as using 'rdmsr 0x48' but without needing the rdmsr tool
	# if we get a read error, the MSR is not there
	dd if=/dev/cpu/0/msr of=/dev/null bs=8 count=1 skip=9 2>/dev/null
	if [ $? -eq 0 ]; then
		pstatus green YES
	else
		pstatus red NO
	fi
fi

if [ "$insmod_msr" = 1 ]; then
	# if we used modprobe ourselves, rmmod the module
	rmmod msr 2>/dev/null
fi

/bin/echo -n "*   Kernel support for IBRS: "
if [ ! -e /sys/kernel/debug/sched_features ]; then
	# try to mount the debugfs hierarchy ourselves and remember it to umount afterwards
	mount -t debugfs debugfs /sys/kernel/debug 2>/dev/null && mounted_debugfs=1
fi
if [ -e /sys/kernel/debug/ibrs_enabled ]; then
	# if the file is there, we have IBRS compiled-in
	pstatus green YES
	ibrs_supported=1
	ibrs_enabled=$(cat /sys/kernel/debug/ibrs_enabled 2>/dev/null)
elif [ -e /sys/kernel/debug/x86/ibrs_enabled ]; then
	# RedHat uses a different path (see https://access.redhat.com/articles/3311301)
	pstatus green YES
	ibrs_supported=1
	ibrs_enabled=$(cat /sys/kernel/debug/x86/ibrs_enabled 2>/dev/null)
else
	pstatus red NO
fi

/bin/echo -n "*   IBRS enabled for Kernel space: "
# 0 means disabled
# 1 is enabled only for kernel space
# 2 is enabled for kernel and user space
case "$ibrs_enabled" in
	"") [ "$ibrs_supported" = 1 ] && pstatus yellow UNKNOWN || pstatus red NO;;
	0)     pstatus red NO;;
	1 | 2) pstatus green YES;;
	*)     pstatus yellow UNKNOWN;;
esac

/bin/echo -n "*   IBRS enabled for User space: "
case "$ibrs_enabled" in
	"") [ "$ibrs_supported" = 1 ] && pstatus yellow UNKNOWN || pstatus red NO;;
	0 | 1) pstatus red NO;;
	2) pstatus green YES;;
	*) pstatus yellow unknown;;
esac

/bin/echo "* Mitigation 2"
/bin/echo -n "*   Kernel compiled with retpolines: "
# We check the RETPOLINE kernel options
# XXX this doesn't mean the kernel has been compiled with a retpoline-aware gcc
# still looking for a way do detect that ...
if [ -e /proc/config.gz ]; then
	# either the running kernel exports his own config
	if zgrep -q '^CONFIG_RETPOLINE=y' /proc/config.gz; then
		pstatus green YES
		retpoline=1
	else
		pstatus red NO
	fi
elif [ -e /boot/config-$(uname -r) ]; then
	# or we can find a config file in /root with the kernel release name
	if grep  -q '^CONFIG_RETPOLINE=y' /boot/config-$(uname -r); then
		pstatus green YES
		retpoline=1
	else
		pstatus red NO
	fi
else
	pstatus yellow UNKNOWN "couldn't read your kernel configuration"
fi

/bin/echo -ne "> \033[46m\033[30mSTATUS:\033[0m "
if grep -q AMD /proc/cpuinfo; then
	pstatus green "NOT VULNERABLE" "your CPU is not vulnerable as per the vendor"
elif [ "$ibrs_enabled" = 1 -o "$ibrs_enabled" = 2 ]; then
	pstatus green "NOT VULNERABLE" "IBRS mitigates the vulnerability"
elif [ "$retpoline" = 1 ]; then
	pstatus green "NOT VULNERABLE" "retpolines mitigate the vulnerability"
else
	pstatus red VULNERABLE "IBRS hardware + kernel support OR kernel with retpolines are needed to mitigate the vulnerability"
fi

##########
# MELTDOWN
/bin/echo
/bin/echo -e "\033[1;34mCVE-2017-5754 [rogue data cache load] aka 'Meltdown' aka 'Variant 3'\033[0m"
/bin/echo -n "* Kernel supports Page Table Isolation (PTI): "
kpti_support=0
kpti_can_tell=0
if [ -e /proc/config.gz ]; then
	# either the running kernel exports his own config
	kpti_can_tell=1
	if zgrep -q '^\(CONFIG_PAGE_TABLE_ISOLATION=y\|CONFIG_KAISER=y\)' /proc/config.gz; then
		kpti_support=1
	fi
elif [ -e /boot/config-$(uname -r) ]; then
	# or we can find a config file in /root with the kernel release name
	kpti_can_tell=1
	if grep  -q '^\(CONFIG_PAGE_TABLE_ISOLATION=y\|CONFIG_KAISER=y\)' /boot/config-$(uname -r); then
		kpti_support=1
	fi
fi
if [ -e /boot/System.map-$(uname -r) ]; then
	# it's not an elif: some backports don't have the PTI config but still include the patch
	# so we try to find an exported symbol that is part of the PTI patch in System.map
	kpti_can_tell=1
	if grep -qw kpti_force_enabled /boot/System.map-$(uname -r); then
		kpti_support=1
	fi
fi
if [ -n "$vmlinux" ]; then
	# same as above but in case we don't have System.map and only vmlinux, look for the
	# nopti option that is part of the patch (kernel command line option)
	kpti_can_tell=1
	if strings "$vmlinux" | grep -qw nopti; then
		kpti_support=1
	fi
fi

if [ "$kpti_support" = 1 ]; then
	pstatus green YES
elif [ "$kpti_can_tell" = 1 ]; then
	pstatus red NO
else
	pstatus yellow UNKNOWN "couldn't read your kernel configuration"
fi

/bin/echo -n "* PTI enabled and active: "
if grep ^flags /proc/cpuinfo | grep -qw pti; then
	# vanilla PTI patch sets the 'pti' flag in cpuinfo
	pstatus green YES
	kpti_enabled=1
elif grep ^flags /proc/cpuinfo | grep -qw kaiser; then
	# kernel line 4.9 sets the 'kaiser' flag in cpuinfo
	pstatus green YES
	kpti_enabled=1
elif [ -e /sys/kernel/debug/x86/pti_enabled ]; then
	# RedHat Backport creates a dedicated file, see https://access.redhat.com/articles/3311301
	kpti_enabled=$(cat /sys/kernel/debug/x86/pti_enabled 2>/dev/null)
elif dmesg | grep -Eq 'Kernel/User page tables isolation: enabled|Kernel page table isolation enabled'; then
	# if we can't find the flag, grep in dmesg
	kpti_enabled=1
else
	kpti_enabled=0
fi
if [ "$kpti_enabled" = 1 ]; then
	pstatus green YES
else
	pstatus red NO
fi

if [ "$mounted_debugfs" = 1 ]; then
	# umount debugfs if we did mount it ourselves
	umount /sys/kernel/debug
fi

/bin/echo -ne "> \033[46m\033[30mSTATUS:\033[0m "
if grep -q AMD /proc/cpuinfo; then
	pstatus green "NOT VULNERABLE" "your CPU is not vulnerable as per the vendor"
elif [ "$kpti_enabled" = 1 ]; then
	pstatus green "NOT VULNERABLE" "PTI mitigates the vulnerability"
else
	pstatus red "VULNERABLE" "PTI is needed to mitigate the vulnerability"
fi

/bin/echo

[ -n "$vmlinux" -a -f "$vmlinux" ] && rm -f "$vmlinux"