#!/bin/sh # # Shorewall 3.2 -- /usr/share/shorewall/functions LIBVERSION=30105 # # Message to stderr # error_message() # $* = Error Message { echo " $@" >&2 } # Function to truncate a string -- It uses 'cut -b -' # rather than ${v:first:last} because light-weight shells like ash and # dash do not support that form of expansion. # truncate() # $1 = length { cut -b -${1} } # # Split a colon-separated list into a space-separated list # split() { local ifs=$IFS IFS=: set -- $1 echo $* IFS=$ifs } # # Search a list looking for a match -- returns zero if a match found # 1 otherwise # list_search() # $1 = element to search for , $2-$n = list { local e=$1 while [ $# -gt 1 ]; do shift [ "x$e" = "x$1" ] && return 0 done return 1 } # # Return a space separated list of values matching # list_walk() # $1 = element to search for, $2-$n = list { local e=$1 result= while [ $# -gt 1 ]; do shift case $1 in $e*) result="$result ${1##$e}" ;; esac done echo $result } # # Functions to count list elements # - - - - - - - - - - - - - - - - # Whitespace-separated list # list_count1() { echo $# } # # Comma-separated list # list_count() { list_count1 $(separate_list $1) } # # Conditionally produce message # progress_message() # $* = Message { [ $VERBOSE -gt 1 ] && echo "$@" } progress_message2() # $* = Message { [ $VERBOSE -gt 0 ] && echo "$@" } progress_message3() # $* = Message { [ $VERBOSE -ge 0 ] && echo "$@" } # # Suppress all output for a command # qt() { "$@" >/dev/null 2>&1 } # # Determine if Shorewall is "running" # shorewall_is_started() { qt $IPTABLES -L shorewall -n } # # Perform variable substitution on the passed argument and echo the result # expand() # $@ = contents of variable which may be the name of another variable { eval echo \"$@\" } # # Perform variable substitition on the values of the passed list of variables # expandv() # $* = list of variable names { local varval while [ $# -gt 0 ]; do eval varval=\$${1} eval $1=\"$varval\" shift done } # # Add whitespace after "!" # fix_bang() { local result= while [ $# -gt 0 ]; do case $1 in !*) result="$result ! ${1#!}" ;; *) result="$result $1" ;; esac shift done echo $result } # # Echos the fully-qualified name of the calling shell program # my_pathname() { cd $(dirname $0) echo $PWD/$(basename $0) } # # Set default config path # ensure_config_path() { local F=/usr/share/shorewall/configpath if [ -z "$CONFIG_PATH" ]; then [ -f $F ] || { echo " ERROR: $F does not exist"; exit 2; } . $F fi } # # Find a File -- For relative file name, look first in $SHOREWALL_DIR then in /etc/shorewall # find_file() { local saveifs= directory case $1 in /*) echo $1 ;; *) if [ -n "$SHOREWALL_DIR" -a -f $SHOREWALL_DIR/$1 ]; then echo $SHOREWALL_DIR/$1 else saveifs=$IFS IFS=: for directory in $CONFIG_PATH; do if [ -f $directory/$1 ]; then echo $directory/$1 IFS=$saveifs return fi done IFS=$saveifs echo /etc/shorewall/$1 fi ;; esac } # # Get fully-qualified name of file # resolve_file() # $1 = file name { local pwd=$PWD case $1 in /*) echo $1 ;; ./*) echo ${pwd}${1#.} ;; ../*) cd .. echo ${PWD}${1#..} cd $pwd ;; *) echo $pwd/$1 ;; esac } ## # Source a user exit file if it exists # run_user_exit() # $1 = file name { local user_exit=$(find_file $1) if [ -f $user_exit ]; then progress_message "Processing $user_exit ..." . $user_exit fi } # # Replace commas with spaces and echo the result # separate_list() { local list="$@" local part local newlist local firstpart local lastpart local enclosure case "$list" in *,|,*|*,,*|*[[:space:]]*) # # There's been whining about us not catching embedded white space in # comma-separated lists. This is an attempt to snag some of the cases. # # The 'TERMINATOR' function will be set by the 'firewall' script to # either 'startup_error' or 'fatal_error' depending on the command and # command phase # [ -n "$TERMINATOR" ] && \ $TERMINATOR "Invalid comma-separated list \"$@\"" echo "WARNING -- invalid comma-separated list \"$@\"" >&2 ;; *\[*\]*) # # Where we need to embed comma-separated lists within lists, we enclose them # within square brackets # firstpart=${list%%\[*} lastpart=${list#*\[} enclosure=${lastpart%%\]*} lastpart=${lastpart#*\]} case $lastpart in \,*) case $firstpart in *\,) echo "$(separate_list ${firstpart%,}) [$enclosure] $(separate_list ${lastpart#,})" ;; *) echo "$(separate_list $firstpart)[$enclosure] $(separate_list ${lastpart#,})" ;; esac ;; *) case $firstpart in *\,) echo "$(separate_list ${firstpart%,}) [$enclosure]$(separate_list $lastpart)" ;; *) echo "$(separate_list $firstpart)[$enclosure]$(separate_list $lastpart)" ;; esac ;; esac return ;; esac list="$@" part="${list%%,*}" newlist="$part" while [ "x$part" != "x$list" ]; do list="${list#*,}"; part="${list%%,*}"; newlist="$newlist $part"; done echo "$newlist" } # # Load a Kernel Module # loadmodule() # $1 = module name, $2 - * arguments { local modulename=$1 local modulefile local suffix moduleloader=modprobe if ! qt mywhich modprobe; then moduleloader=insmod fi if [ -z "$(lsmod | grep $modulename)" ]; then shift for suffix in $MODULE_SUFFIX ; do modulefile=$MODULESDIR/${modulename}.${suffix} if [ -f $modulefile ]; then case $moduleloader in insmod) insmod $modulefile $* ;; *) modprobe $modulename $* ;; esac return fi done fi } # # Reload the Modules # reload_kernel_modules() { [ -z "$MODULESDIR" ] && MODULESDIR=/lib/modules/$(uname -r)/kernel/net/ipv4/netfilter while read command; do eval $command done } # # Load kernel modules required for Shorewall # load_kernel_modules() { save_modules_dir=$MODULESDIR [ -z "$MODULESDIR" ] && \ MODULESDIR=/lib/modules/$(uname -r)/kernel/net/ipv4/netfilter modules=$(find_file modules) if [ -f $modules -a -d $MODULESDIR ]; then progress_message "Loading Modules..." . $modules fi MODULESDIR=$save_modules_dir } # # Call this function to assert MUTEX with Shorewall. If you invoke the # /sbin/shorewall program while holding MUTEX, you should pass "nolock" as # the first argument. Example "shorewall nolock refresh" # # This function uses the lockfile utility from procmail if it exists. # Otherwise, it uses a somewhat race-prone algorithm to attempt to simulate the # behavior of lockfile. # mutex_on() { local try=0 local lockf=/var/lib/shorewall/lock MUTEX_TIMEOUT=${MUTEX_TIMEOUT:-60} if [ $MUTEX_TIMEOUT -gt 0 ]; then [ -d /var/lib/shorewall ] || mkdir -p /var/lib/shorewall if qt mywhich lockfile; then lockfile -${MUTEX_TIMEOUT} -r1 ${lockf} else while [ -f ${lockf} -a ${try} -lt ${MUTEX_TIMEOUT} ] ; do sleep 1 try=$((${try} + 1)) done if [ ${try} -lt ${MUTEX_TIMEOUT} ] ; then # Create the lockfile echo $$ > ${lockf} else echo "Giving up on lock file ${lockf}" >&2 fi fi fi } # # Call this function to release MUTEX # mutex_off() { rm -f /var/lib/shorewall/lock } # # Determine which version of mktemp is present (if any) and set MKTEMP accortingly: # # None - No mktemp # BSD - BSD mktemp (Mandrake) # STD - mktemp.org mktemp # find_mktemp() { local mktemp=`mywhich mktemp 2> /dev/null` if [ -n "$mktemp" ]; then if qt mktemp -V ; then MKTEMP=STD else MKTEMP=BSD fi else MKTEMP=None fi } # # create a temporary file. If a directory name is passed, the file will be created in # that directory. Otherwise, it will be created in a temporary directory. # mktempfile() { [ -z "$MKTEMP" ] && find_mktemp if [ $# -gt 0 ]; then case "$MKTEMP" in BSD) mktemp $1/shorewall.XXXXXX ;; STD) mktemp -p $1 shorewall.XXXXXX ;; None) > $1/shorewall-$$ && echo $1/shorewall-$$ ;; *) echo " ERROR:Internal error in mktempfile" >&2 ;; esac else case "$MKTEMP" in BSD) mktemp /tmp/shorewall.XXXXXX ;; STD) mktemp -t shorewall.XXXXXX ;; None) rm -f /tmp/shorewall-$$ > /tmp/shorewall-$$ && echo /tmp/shorewall-$$ ;; *) echo " ERROR:Internal error in mktempfile" >&2 ;; esac fi } # # create a temporary directory # mktempdir() { [ -z "$MKTEMP" ] && find_mktemp case "$MKTEMP" in STD) mktemp -td shorewall.XXXXXX ;; None|BSD) # # Not all versions of the BSD mktemp support the -d option under Linux # mkdir /tmp/shorewall-$$ && chmod 700 /tmp/shorewall-$$ && echo /tmp/shorewall-$$ ;; *) echo " ERROR:Internal error in mktempdir" >&2 ;; esac } # # Read a file and handle "INCLUDE" directives # read_file() # $1 = file name, $2 = nest count { local first rest if [ -f $1 ]; then while read first rest; do if [ "x$first" = "xINCLUDE" ]; then if [ $2 -lt 4 ]; then read_file $(find_file $(expand ${rest%#*})) $(($2 + 1)) else echo " WARNING: INCLUDE in $1 ignored (nested too deeply)" >&2 fi else echo "$first $rest" fi done < $1 else [ -n "$TERMINATOR" ] && $TERMINATOR "No such file: $1" echo "WARNING -- No such file: $1" fi } # # Function for including one file into another # INCLUDE() { . $(find_file $(expand $@)) } # # Strip comments and blank lines from a file and place the result in the # temporary directory # strip_file() # $1 = Base Name of the file, $2 = Full Name of File (optional) { local fname [ $# = 1 ] && fname=$(find_file $1) || fname=$2 if [ -f $fname ]; then read_file $fname 0 | cut -d'#' -f1 | grep -v '^[[:space:]]*$' > $TMP_DIR/$1 else > $TMP_DIR/$1 fi } # # Note: The following set of IP address manipulation functions have anomalous # behavior when the shell only supports 32-bit signed arithmatic and # the IP address is 128.0.0.0 or 128.0.0.1. # # # So that emacs doesn't get lost, we use $LEFTSHIFT rather than << # LEFTSHIFT='<<' # # Convert an IP address in dot quad format to an integer # decodeaddr() { local x local temp=0 local ifs=$IFS IFS=. for x in $1; do temp=$(( $(( $temp $LEFTSHIFT 8 )) | $x )) done echo $temp IFS=$ifs } # # convert an integer to dot quad format # encodeaddr() { addr=$1 local x local y=$(($addr & 255)) for x in 1 2 3 ; do addr=$(($addr >> 8)) y=$(($addr & 255)).$y done echo $y } # # Enumerate the members of an IP range -- When using a shell supporting only # 32-bit signed arithmetic, the range cannot span 128.0.0.0. # # Comes in two flavors: # # ip_range() - produces a mimimal list of network/host addresses that spans # the range. # # ip_range_explicit() - explicitly enumerates the range. # ip_range() { local first last l x y z vlsm case $1 in !*) # # Let iptables complain if it's a range # echo $1 return ;; [0-9]*.*.*.*-*.*.*.*) ;; *) echo $1 return ;; esac first=$(decodeaddr ${1%-*}) last=$(decodeaddr ${1#*-}) if [ $first -gt $last ]; then fatal_error "Invalid IP address range: $1" fi l=$(( $last + 1 )) while [ $first -le $last ]; do vlsm= x=31 y=2 z=1 while [ $(( $first % $y )) -eq 0 -a $(( $first + $y )) -le $l ]; do vlsm=/$x x=$(( $x - 1 )) z=$y y=$(( $y * 2 )) done echo $(encodeaddr $first)$vlsm first=$(($first + $z)) done } ip_range_explicit() { local first last case $1 in [0-9]*.*.*.*-*.*.*.*) ;; *) echo $1 return ;; esac first=$(decodeaddr ${1%-*}) last=$(decodeaddr ${1#*-}) if [ $first -gt $last ]; then fatal_error "Invalid IP address range: $1" fi while [ $first -le $last ]; do echo $(encodeaddr $first) first=$(($first + 1)) done } # # Netmask from CIDR # ip_netmask() { local vlsm=${1#*/} [ $vlsm -eq 0 ] && echo 0 || echo $(( -1 $LEFTSHIFT $(( 32 - $vlsm )) )) } # # Network address from CIDR # ip_network() { local decodedaddr=$(decodeaddr ${1%/*}) local netmask=$(ip_netmask $1) echo $(encodeaddr $(($decodedaddr & $netmask))) } # # The following hack is supplied to compensate for the fact that many of # the popular light-weight Bourne shell derivatives don't support XOR ("^"). # ip_broadcast() { local x=$(( 32 - ${1#*/} )) [ $x -eq 0 ] && echo -1 || echo $(( $(( 1 $LEFTSHIFT $x )) - 1 )) } # # Calculate broadcast address from CIDR # broadcastaddress() { local decodedaddr=$(decodeaddr ${1%/*}) local netmask=$(ip_netmask $1) local broadcast=$(ip_broadcast $1) echo $(encodeaddr $(( $(($decodedaddr & $netmask)) | $broadcast ))) } # # Test for network membership # in_network() # $1 = IP address, $2 = CIDR network { local netmask=$(ip_netmask $2) test $(( $(decodeaddr $1) & $netmask)) -eq $(( $(decodeaddr ${2%/*}) & $netmask )) } # # Netmask to VLSM # ip_vlsm() { local mask=$(decodeaddr $1) local vlsm=0 local x=$(( 128 $LEFTSHIFT 24 )) # 0x80000000 while [ $(( $x & $mask )) -ne 0 ]; do [ $mask -eq $x ] && mask=0 || mask=$(( $mask $LEFTSHIFT 1 )) # Not all shells shift 0x80000000 left properly. vlsm=$(($vlsm + 1)) done if [ $(( $mask & 2147483647 )) -ne 0 ]; then # 2147483647 = 0x7fffffff echo "Invalid net mask: $1" >&2 else echo $vlsm fi } # # Chain name base for an interface -- replace all periods with underscores in the passed name. # The result is echoed (less trailing "+"). # chain_base() #$1 = interface { local c=${1%%+} while true; do case $c in *.*) c="${c%.*}_${c##*.}" ;; *-*) c="${c%-*}_${c##*-}" ;; *%*) c="${c%\%*}_${c##*%}" ;; *) echo ${c:=common} return ;; esac done } # # Loosly Match the name of an interface # if_match() # $1 = Name in interfaces file - may end in "+" # $2 = Full interface name - may also end in "+" { local pattern=${1%+} case $1 in *+) test "x$(echo $2 | truncate ${#pattern} )" = "x${pattern}" ;; *) test "x$1" = "x$2" ;; esac } # # Source IP range # source_ip_range() # $1 = Address or Address Range { case $1 in *.*.*.*-*.*.*.*) case $1 in !*) iprange_echo "! --src-range ${1#!}" ;; *) iprange_echo "--src-range $1" ;; esac ;; !+*) echo "-m set ! $(get_set_flags ${1#!} src)" ;; +*) echo "-m set $(get_set_flags $1 src)" ;; *) echo "-s $1" ;; esac } # # Destination IP range # dest_ip_range() # $1 = Address or Address Range { case $1 in *.*.*.*-*.*.*.*) case $1 in !*) iprange_echo "! --dst-range ${1#!}" ;; *) iprange_echo "--dst-range $1" ;; esac ;; !+*) echo "-m set ! $(get_set_flags ${1#!} dst)" ;; +*) echo "-m set $(get_set_flags $1 dst)" ;; *) echo "-d $1" ;; esac } both_ip_ranges() # $1 = Source address or range, $2 = dest address or range { local rangeprefix= setprefix= rangematch= setmatch= case $1 in *.*.*.*-*.*.*.*) rangeprefix="-m iprange" rangematch="--src-range $1" ;; !+*) setprefix="-m set" setmatch="! $(get_set_flags ${1#!} src)" ;; +*) setprefix="-m set" setmatch="$(get_set_flags $1 src)" ;; *) rangematch="-s $1" ;; esac case $2 in *.*.*.*-*.*.*.*) rangeprefix="-m iprange" rangematch="$rangematch --dst-range $2" ;; !+*) setprefix="-m set" match="$setmatch ! $(get_set_flags ${2#!} dst)" ;; +*) setprefix="-m set" setmatch="$setmatch $(get_set_flags $2 dst)" ;; *) rangematch="$rangematch -d $2" ;; esac echo "$rangeprefix $rangematch $setprefix $setmatch" } # # Find the value 'dev' in the passed arguments then echo the next value # find_device() { while [ $# -gt 1 ]; do [ "x$1" = xdev ] && echo $2 && return shift done } # # Find the value 'via' in the passed arguments then echo the next value # find_gateway() { while [ $# -gt 1 ]; do [ "x$1" = xvia ] && echo $2 && return shift done } # # Find the value 'peer' in the passed arguments then echo the next value up to # "/" # find_peer() { while [ $# -gt 1 ]; do [ "x$1" = xpeer ] && echo ${2%/*} && return shift done } # # Find the interfaces that have a route to the passed address - the default # route is not used. # find_rt_interface() { ip route ls | while read addr rest; do case $addr in */*) in_network ${1%/*} $addr && echo $(find_device $rest) ;; default) ;; *) if [ "$addr" = "$1" -o "$addr/32" = "$1" ]; then echo $(find_device $rest) fi ;; esac done } # # Try to find the gateway through an interface looking for 'nexthop' find_nexthop() # $1 = interface { echo $(find_gateway `ip route ls | grep "[[:space:]]nexthop.* $1"`) } # # Find the default route's interface # find_default_interface() { ip route ls | while read first rest; do [ "$first" = default ] && echo $(find_device $rest) && return done } # # Echo the name of the interface(s) that will be used to send to the # passed address # find_interface_by_address() { local dev="$(find_rt_interface $1)" local first rest [ -z "$dev" ] && dev=$(find_default_interface) [ -n "$dev" ] && echo $dev } # # Find the interface with the passed MAC address # find_interface_by_mac() { local mac=$1 first second rest dev ip link ls | while read first second rest; do case $first in *:) dev=$second ;; *) if [ "$second" = $mac ]; then echo ${dev%:} return fi esac done } # # Find interface address--returns the first IP address assigned to the passed # device # find_first_interface_address() # $1 = interface { # # get the line of output containing the first IP address # addr=$(ip -f inet addr show $1 2> /dev/null | grep 'inet .* global' | head -n1) # # If there wasn't one, bail out now # [ -n "$addr" ] || fatal_error "Can't determine the IP address of $1" # # Strip off the trailing VLSM mask (or the peer IP in case of a P-t-P link) # along with everything else on the line # echo $addr | sed 's/inet //;s/\/.*//;s/ peer.*//' } # # Find interface addresses--returns the set of addresses assigned to the passed # device # find_interface_addresses() # $1 = interface { ip -f inet addr show $1 | grep inet | sed 's/inet //;s/\/.*//;s/ peer.*//' } # # echo the list of networks routed out of a given interface # get_routed_networks() # $1 = interface name { local address local rest ip route show dev $1 2> /dev/null | while read address rest; do if [ "x$address" = xdefault ]; then error_message "WARNING: default route ignored on interface $1" else [ "$address" = "${address%/*}" ] && address="${address}/32" echo $address fi done } # # Internal version of 'which' # mywhich() { local dir for dir in $(split $PATH); do if [ -x $dir/$1 ]; then echo $dir/$1 return 0 fi done return 2 } # # Set the Shorewall state # set_state () # $1 = state { echo "$1 ($(date))" > /var/lib/shorewall/state } # # Determine which optional facilities are supported by iptables/netfilter # determine_capabilities() { qt $IPTABLES -t nat -L -n && NAT_ENABLED=Yes || NAT_ENABLED= qt $IPTABLES -t mangle -L -n && MANGLE_ENABLED=Yes || MANGLE_ENABLED= CONNTRACK_MATCH= MULTIPORT= XMULTIPORT= POLICY_MATCH= PHYSDEV_MATCH= IPRANGE_MATCH= RECENT_MATCH= OWNER_MATCH= IPSET_MATCH= CONNMARK= CONNMARK_MATCH= RAW_TABLE= IPP2P_MATCH= LENGTH_MATCH= CLASSIFY_TARGET= ENHANCED_REJECT= USEPKTTYPE= qt $IPTABLES -N fooX1234 qt $IPTABLES -A fooX1234 -m conntrack --ctorigdst 192.168.1.1 -j ACCEPT && CONNTRACK_MATCH=Yes qt $IPTABLES -A fooX1234 -p tcp -m multiport --dports 21,22 -j ACCEPT && MULTIPORT=Yes qt $IPTABLES -A fooX1234 -p tcp -m multiport --dports 21:22 -j ACCEPT && XMULTIPORT=Yes qt $IPTABLES -A fooX1234 -m policy --pol ipsec --mode tunnel --dir in -j ACCEPT && POLICY_MATCH=Yes qt $IPTABLES -A fooX1234 -m physdev --physdev-in eth0 -j ACCEPT && PHYSDEV_MATCH=Yes qt $IPTABLES -A fooX1234 -m iprange --src-range 192.168.1.5-192.168.1.124 -j ACCEPT && IPRANGE_MATCH=Yes qt $IPTABLES -A fooX1234 -m recent --update -j ACCEPT && RECENT_MATCH=Yes qt $IPTABLES -A fooX1234 -m owner --uid-owner 0 -j ACCEPT && OWNER_MATCH=Yes qt $IPTABLES -A fooX1234 -m connmark --mark 2 -j ACCEPT && CONNMARK_MATCH=Yes qt $IPTABLES -A fooX1234 -p tcp -m ipp2p --ipp2p -j ACCEPT && IPP2P_MATCH=Yes qt $IPTABLES -A fooX1234 -m length --length 10:20 -j ACCEPT && LENGTH_MATCH=Yes qt $IPTABLES -A fooX1234 -j REJECT --reject-with icmp-host-prohibited && ENHANCED_REJECT=Yes qt $IPTABLES -t mangle -N fooX1234 qt $IPTABLES -t mangle -A fooX1234 -j CONNMARK --save-mark && CONNMARK=Yes qt $IPTABLES -t mangle -A fooX1234 -j CLASSIFY --set-class 1:1 && CLASSIFY_TARGET=Yes qt $IPTABLES -t mangle -F fooX1234 qt $IPTABLES -t mangle -X fooX1234 qt $IPTABLES -t raw -L -n && RAW_TABLE=Yes if qt mywhich ipset; then qt ipset -X fooX1234 # Just in case something went wrong the last time if qt ipset -N fooX1234 iphash ; then if qt $IPTABLES -A fooX1234 -m set --set fooX1234 src -j ACCEPT; then qt $IPTABLES -D fooX1234 -m set --set fooX1234 src -j ACCEPT IPSET_MATCH=Yes fi qt ipset -X fooX1234 fi fi qt $IPTABLES -A fooX1234 -m pkttype --pkt-type broadcast -j ACCEPT && USEPKTTYPE=Yes qt $IPTABLES -F fooX1234 qt $IPTABLES -X fooX1234 } report_capability() # $1 = Capability Description , $2 Capability Setting (if any) { local setting= [ "x$2" = "xYes" ] && setting="Available" || setting="Not available" echo " " $1: $setting } report_capabilities() { if [ $VERBOSE -gt 1 ]; then echo "Shorewall has detected the following iptables/netfilter capabilities:" report_capability "NAT" $NAT_ENABLED report_capability "Packet Mangling" $MANGLE_ENABLED report_capability "Multi-port Match" $MULTIPORT [ -n "$MULTIPORT" ] && report_capability "Extended Multi-port Match" $XMULTIPORT report_capability "Connection Tracking Match" $CONNTRACK_MATCH report_capability "Packet Type Match" $USEPKTTYPE report_capability "Policy Match" $POLICY_MATCH report_capability "Physdev Match" $PHYSDEV_MATCH report_capability "Packet length Match" $LENGTH_MATCH report_capability "IP range Match" $IPRANGE_MATCH report_capability "Recent Match" $RECENT_MATCH report_capability "Owner Match" $OWNER_MATCH report_capability "Ipset Match" $IPSET_MATCH report_capability "CONNMARK Target" $CONNMARK report_capability "Connmark Match" $CONNMARK_MATCH report_capability "Raw Table" $RAW_TABLE report_capability "IPP2P Match" $IPP2P_MATCH report_capability "CLASSIFY Target" $CLASSIFY_TARGET report_capability "Extended REJECT" $ENHANCED_REJECT fi [ -n "$PKTTYPE" ] || USEPKTTYPE= } # Add IP Aliases # add_ip_aliases() # $* = List of addresses { local addresses external interface inet cidr rest val arping=$(mywhich arping) address_details() { # # Folks feel uneasy if they don't see all of the same # decoration on these IP addresses that they see when their # distro's net config tool adds them. In an attempt to reduce # the anxiety level, we have the following code which sets # the VLSM and BRD from an existing address in the same networks # # Get all of the lines that contain inet addresses with broadcast # ip -f inet addr show $interface 2> /dev/null | grep 'inet.*brd' | while read inet cidr rest ; do case $cidr in */*) if in_network $external $cidr; then echo "/${cidr#*/} brd $(broadcastaddress $cidr)" break fi ;; esac done } do_one() { val=$(address_details) ip addr add ${external}${val} dev $interface $label [ -n "$arping" ] && qt $arping -U -c 2 -I $interface $external echo "$external $interface" >> $STATEDIR/nat [ -n "$label" ] && label="with $label" progress_message " IP Address $external added to interface $interface $label" } progress_message "Adding IP Addresses..." while [ $# -gt 0 ]; do external=$1 interface=$2 label= if [ "$interface" != "${interface%:*}" ]; then label="${interface#*:}" interface="${interface%:*}" label="label $interface:$label" fi shift 2 list_search $external $(find_interface_addresses $interface) || do_one done } detect_gateway() # $1 = interface { local interface=$1 # # First assume that this is some sort of point-to-point interface # gateway=$( find_peer $(ip addr ls $interface ) ) # # Maybe there's a default route through this gateway already # [ -n "$gateway" ] || gateway=$(find_gateway $(ip route ls dev $interface)) # # Last hope -- is there a load-balancing route through the interface? # [ -n "$gateway" ] || gateway=$(find_nexthop $interface) # # Be sure we found one # [ -n "$gateway" ] && echo $gateway } # # Disable IPV6 # disable_ipv6() { local foo="$(ip -f inet6 addr ls 2> /dev/null)" if [ -n "$foo" ]; then if qt mywhich ip6tables; then ip6tables -P FORWARD DROP ip6tables -P INPUT DROP ip6tables -P OUTPUT DROP ip6tables -F ip6tables -X ip6tables -A OUTPUT -o lo -j ACCEPT ip6tables -A INPUT -i lo -j ACCEPT else error_message "WARNING: DISABLE_IPV6=Yes in shorewall.conf but this system does not appear to have ip6tables" fi fi } # # Add a logging rule. # log_rule_limit() # $1 = log level, $2 = chain, $3 = display Chain $4 = disposition , $5 = rate limit $6=log tag $7=command $... = predicates for the rule { local level=$1 local chain=$2 local displayChain=$3 local disposition=$4 local rulenum= local limit="${5:-$LOGLIMIT}" local tag=${6:+$6 } local command=${7:--A} local prefix local base=$(chain_base $displayChain) shift 7 if [ -n "$tag" -a -n "$LOGTAGONLY" ]; then displayChain=$tag tag= fi if [ -n "$LOGRULENUMBERS" ]; then eval rulenum=\$${base}_logrules rulenum=${rulenum:-1} prefix="$(printf "$LOGFORMAT" $displayChain $rulenum $disposition)${tag}" rulenum=$(($rulenum + 1)) eval ${base}_logrules=$rulenum else prefix="$(printf "$LOGFORMAT" $displayChain $disposition)${tag}" fi if [ ${#prefix} -gt 29 ]; then prefix="$(echo $prefix | truncate 29)" error_message "WARNING: Log Prefix shortened to \"$prefix\"" fi case $level in ULOG) run_iptables $command $chain $@ $limit -j ULOG $LOGPARMS --ulog-prefix "$prefix" ;; *) run_iptables $command $chain $@ $limit -j LOG $LOGPARMS --log-level $level --log-prefix "$prefix" ;; esac if [ $? -ne 0 ] ; then [ -z "$STOPPING" ] && { stop_firewall; exit 2; } fi } log_rule() # $1 = log level, $2 = chain, $3 = disposition , $... = predicates for the rule { local level=$1 local chain=$2 local disposition=$3 shift 3 log_rule_limit $level $chain $chain $disposition "$LOGLIMIT" "" -A $@ } delete_tc1() { clear_one_tc() { tc qdisc del dev $1 root 2> /dev/null tc qdisc del dev $1 ingress 2> /dev/null } run_user_exit tcclear run_ip link list | \ while read inx interface details; do case $inx in [0-9]*) clear_one_tc ${interface%:} ;; *) ;; esac done } SHOREWALL_LIBRARY=Loaded