shorewall_code/Shorewall-perl/Shorewall/Chains.pm
2007-07-26 18:36:18 +00:00

2070 lines
51 KiB
Perl

#
# Shorewall-perl 4.0 -- /usr/share/shorewall-perl/Shorewall/Chains.pm
#
# This program is under GPL [http://www.gnu.org/copyleft/gpl.htm]
#
# (c) 2007 - Tom Eastep (teastep@shorewall.net)
#
# Complete documentation is available at http://shorewall.net
#
# This program is free software; you can redistribute it and/or modify
# it under the terms of Version 2 of the GNU General Public License
# as published by the Free Software Foundation.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program; if not, write to the Free Software
# Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA
#
# This is the low-level iptables module. It provides the basic services
# of chain and rule creation. It is used by the higher level modules such
# as Rules to create iptables-restore input.
#
package Shorewall::Chains;
require Exporter;
use Shorewall::Config;
use Shorewall::Ports;
use Shorewall::Zones;
use Shorewall::IPAddrs;
use strict;
our @ISA = qw(Exporter);
our @EXPORT = qw( STANDARD
NATRULE
BUILTIN
NONAT
NATONLY
REDIRECT
ACTION
MACRO
LOGRULE
NO_RESTRICT
PREROUTE_RESTRICT
INPUT_RESTRICT
OUTPUT_RESTRICT
POSTROUTE_RESTRICT
ALL_RESTRICT
process_comment
push_cmd_mode
pop_cmd_mode
add_command
add_commands
mark_referenced
add_file
add_rule
insert_rule
chain_base
forward_chain
input_chain
output_chain
masq_chain
syn_flood_chain
mac_chain
macrecent_target
dynamic_fwd
dynamic_in
dynamic_out
dynamic_chains
dnat_chain
snat_chain
ecn_chain
first_chains
new_chain
ensure_chain
ensure_filter_chain
ensure_mangle_chain
new_standard_chain
new_builtin_chain
initialize_chain_table
finish_section
setup_zone_mss
newexclusionchain
clearrule
do_proto
mac_match
numeric_value
verify_mark
verify_small_mark
validate_mark
do_test
do_ratelimit
do_user
do_tos
match_source_dev
match_dest_dev
iprange_match
match_source_net
match_dest_net
match_orig_dest
match_ipsec_in
match_ipsec_out
log_rule_limit
log_rule
expand_rule
addnatjump
insertnatjump
get_interface_address
get_interface_addresses
get_interface_bcasts
set_global_variables
create_netfilter_load
create_blacklist_reload
@policy_chains
%chain_table
$nat_table
$mangle_table
$filter_table
$section
%sections
$comment
%targets
);
our @EXPORT_OK = qw( initialize );
our $VERSION = 4.01;
#
# Chain Table
#
# @policy_chains is a list of references to policy chains in the filter table
#
# %chain_table { <table> => { <chain1> => { name => <chain name>
# table => <table name>
# is_policy => 0|1
# is_optionsl => 0|1
# referenced => 0|1
# policy => <policy>
# loglevel => <level>
# synparams => <burst/limit>
# synchain => <name of synparam chain>
# default => <default action>
# policy_chain => <ref to policy chain -- self-reference if this is a policy chain>
# loopcount => <number of open loops in runtime commands>
# cmdcount => <number of client open loops or blocks in runtime commands>
# rules => [ <rule1>
# <rule2>
# ...
# ]
# } ,
# <chain2> => ...
# }
# }
#
# 'is_optional' only applies to policy chains; when true, indicates that this is a provisional policy chain which might be
# replaced. Policy chains created under the IMPLICIT_CONTINUE=Yes option are optional.
#
# Only 'referenced' chains get written to the iptables-restore input.
#
# 'loglevel', 'synparams', 'synchain' and 'default' only apply to policy chains.
#
our @policy_chains;
our %chain_table;
our $nat_table;
our $mangle_table;
our $filter_table;
#
# It is a layer violation to keep information about the rules file sections in this module but in Shorewall, the rules file
# and the filter table are very closely tied. By keeping the information here, we avoid making several other modules dependent
# on Shorewall::Rules.
#
our %sections;
our $section;
our $comment;
use constant { STANDARD => 1, #defined by Netfilter
NATRULE => 2, #Involves NAT
BUILTIN => 4, #A built-in action
NONAT => 8, #'NONAT' or 'ACCEPT+'
NATONLY => 16, #'DNAT-' or 'REDIRECT-'
REDIRECT => 32, #'REDIRECT'
ACTION => 64, #An action (may be built-in)
MACRO => 128, #A Macro
LOGRULE => 256, #'LOG'
};
our %targets;
#
# expand_rule() restrictions
#
use constant { NO_RESTRICT => 0, # FORWARD chain rule - Both -i and -o may be used in the rule
PREROUTE_RESTRICT => 1, # PREROUTING chain rule - -o converted to -d <address list> using main routing table
INPUT_RESTRICT => 4, # INPUT chain rule - -o not allowed
OUTPUT_RESTRICT => 8, # OUTPUT chain rule - -i not allowed
POSTROUTE_RESTRICT => 16, # POSTROUTING chain rule - -i converted to -s <address list> using main routing table
ALL_RESTRICT => 12 # fw->fw rule - neither -i nor -o allowed
};
our $exclseq;
our $iprangematch;
our $chainseq;
our %interfaceaddr;
our %interfaceaddrs;
our %interfacenets;
our %interfacebcasts;
our @builtins = qw(PREROUTING INPUT FORWARD OUTPUT POSTROUTING);
#
# State of the generator.
#
use constant { NULL_STATE => 0 , # Generating neither shell commands nor iptables-restore input
CAT_STATE => 1 , # Generating iptables-restore input
CMD_STATE => 2 }; # Generating shell commands.
our $state;
our $emitted_comment;
#
# Initialize globals -- we take this novel approach to globals initialization to allow
# the compiler to run multiple times in the same process. The
# initialize() function does globals initialization for this
# module and is called from an INIT block below. The function is
# also called by Shorewall::Compiler::compiler at the beginning of
# the second and subsequent calls to that function.
#
sub initialize() {
@policy_chains = ();
%chain_table = ( raw => {} ,
mangle => {},
nat => {},
filter => {} );
$nat_table = $chain_table{nat};
$mangle_table = $chain_table{mangle};
$filter_table = $chain_table{filter};
#
# These get set to 1 as sections are encountered.
#
%sections = ( ESTABLISHED => 0,
RELATED => 0,
NEW => 0
);
#
# Current rules file section.
#
$section = 'ESTABLISHED';
#
# Contents of last COMMENT line.
#
$comment = '';
#
# As new targets (Actions and Macros) are discovered, they are added to the table
#
%targets = ('ACCEPT' => STANDARD,
'ACCEPT+' => STANDARD + NONAT,
'ACCEPT!' => STANDARD,
'NONAT' => STANDARD + NONAT + NATONLY,
'DROP' => STANDARD,
'DROP!' => STANDARD,
'REJECT' => STANDARD,
'REJECT!' => STANDARD,
'DNAT' => NATRULE,
'DNAT-' => NATRULE + NATONLY,
'REDIRECT' => NATRULE + REDIRECT,
'REDIRECT-' => NATRULE + REDIRECT + NATONLY,
'LOG' => STANDARD + LOGRULE,
'CONTINUE' => STANDARD,
'CONTINUE!' => STANDARD,
'QUEUE' => STANDARD,
'QUEUE!' => STANDARD,
'SAME' => NATRULE,
'SAME-' => NATRULE + NATONLY,
'dropBcast' => BUILTIN + ACTION,
'allowBcast' => BUILTIN + ACTION,
'dropNotSyn' => BUILTIN + ACTION,
'rejNotSyn' => BUILTIN + ACTION,
'dropInvalid' => BUILTIN + ACTION,
'allowInvalid' => BUILTIN + ACTION,
'allowinUPnP' => BUILTIN + ACTION,
'forwardUPnP' => BUILTIN + ACTION,
'Limit' => BUILTIN + ACTION,
);
#
# Used to sequence 'exclusion' chains with names 'excl0', 'excl1', ...
#
$exclseq = 0;
#
# Used to suppress duplicate match specifications.
#
$iprangematch = 0;
#
# Sequence for naming temporary chains
#
$chainseq = undef;
#
# Keep track of which interfaces have active 'address', 'addresses' and 'networks' variables
#
%interfaceaddr = ();
%interfaceaddrs = ();
%interfacenets = ();
%interfacebcasts = ();
#
# When true, we've emitted a comment about global variable initialization
#
$emitted_comment = 0;
}
INIT {
initialize;
}
#
# Add a run-time command to a chain. Arguments are:
#
# Chain reference , Command
#
#
# Process a COMMENT line (in $currentline)
#
sub process_comment() {
if ( $capabilities{COMMENTS} ) {
( $comment = $currentline ) =~ s/^\s*COMMENT\s*//;
$comment =~ s/\s*$//;
} else {
warning_message "COMMENT ignored -- requires comment support in iptables/Netfilter";
}
}
#
# Functions to manipulate cmdcount
#
sub push_cmd_mode( $ ) {
$_[0]->{cmdcount}++;
}
sub pop_cmd_mode( $ ) {
fatal_error "Internal error in pop_cmd_mode()" if --$_[0]->{cmdcount} < 0;
}
sub add_command($$)
{
my ($chainref, $command) = @_;
push @{$chainref->{rules}}, join ('', ' ' x ( $chainref->{loopcount} + $chainref->{cmdcount} ), $command );
$chainref->{referenced} = 1;
}
sub add_commands {
my $chainref = shift @_;
for my $command ( @_ ) {
push @{$chainref->{rules}}, join ('', ' ' x ( $chainref->{loopcount} + $chainref->{cmdcount} ), $command );
}
$chainref->{referenced} = 1;
}
sub mark_referenced( $ ) {
my $chainref = shift @_;
$chainref->{referenced} = 1;
}
#
# Copy a file into a chain's rules as a set of run-time commands
#
sub add_file( $$ ) {
my $chainref = $_[0];
my $file = find_file $_[1];
if ( -f $file ) {
open EF , '<', $file or fatal_error "Unable to open $file: $!";
add_commands( $chainref,
qq(progress_message "Processing $file..."),
'' );
while ( my $line = <EF> ) {
chomp $line;
add_command $chainref, $line;
}
add_command $chainref, '';
close EF;
}
}
#
# Add a rule to a chain. Arguments are:
#
# Chain reference , Rule
#
sub add_rule($$)
{
my ($chainref, $rule) = @_;
$iprangematch = 0;
if ( $chainref->{loopcount} || $chainref->{cmdcount} ) {
$rule .= " -m comment --comment \\\"$comment\\\"" if $comment;
add_command $chainref , qq(echo "-A $chainref->{name} $rule" >&3);
} else {
$rule .= " -m comment --comment \"$comment\"" if $comment;
push @{$chainref->{rules}}, join( ' ', '-A' , $chainref->{name}, $rule );
$chainref->{referenced} = 1;
}
}
#
# Insert a rule into a chain. Arguments are:
#
# Table , Chain , Rule Number, Rule
#
sub insert_rule($$$)
{
my ($chainref, $number, $rule) = @_;
fatal_error 'Internal Error in insert_rule()' if $chainref->{loopcount} || $chainref->{cmdcount};
$rule .= "-m comment --comment \"$comment\"" if $comment;
splice( @{$chainref->{rules}}, $number - 1, 0, join( ' ', '-A', $chainref->{name}, $rule ) );
$iprangematch = 0;
$chainref->{referenced} = 1;
}
#
# Form the name of a chain.
#
sub chain_base($) {
my $chain = $_[0];
$chain =~ s/^@/at_/;
$chain =~ tr/[.\-%@]/_/;
$chain =~ s/\+$//;
$chain;
}
#
# Forward Chain for an interface
#
sub forward_chain($)
{
chain_base( $_[0] ) . '_fwd';
}
#
# Input Chain for an interface
#
sub input_chain($)
{
chain_base( $_[0] ) . '_in';
}
#
# Output Chain for an interface
#
sub output_chain($)
{
chain_base( $_[0] ) . '_out';
}
#
# Masquerade Chain for an interface
#
sub masq_chain($)
{
chain_base( $_[0] ) . '_masq';
}
#
# Syn_flood_chain -- differs from the other _chain functions in that the argument is a chain table reference
#
sub syn_flood_chain ( $ ) {
'@' . $_[0]->{synchain};
}
#
# MAC Verification Chain for an interface
#
sub mac_chain( $ )
{
chain_base( $_[0] ) . '_mac';
}
sub macrecent_target($)
{
$config{MACLIST_TTL} ? chain_base( $_[0] ) . '_rec' : 'RETURN';
}
#
# Functions for creating dynamic zone rules
#
sub dynamic_fwd( $ )
{
chain_base( $_[0] ) . '_dynf';
}
sub dynamic_in( $ )
{
chain_base( $_[0] ) . '_dyni';
}
sub dynamic_out( $ ) # $1 = interface
{
chain_base( $_[0] ) . '_dyno';
}
sub dynamic_chains( $ ) #$1 = interface
{
my $c = chain_base( $_[0] );
[ $c . '_dyni' , $c . '_dynf' , $c . '_dyno' ];
}
#
# DNAT Chain from a zone
#
sub dnat_chain( $ )
{
chain_base( $_[0] ) . '_dnat';
}
#
# SNAT Chain to an interface
#
sub snat_chain( $ )
{
chain_base( $_[0] ) . '_snat';
}
#
# ECN Chain to an interface
#
sub ecn_chain( $ )
{
chain_base( $_[0] ) . '_ecn';
}
#
# First chains for an interface
#
sub first_chains( $ ) #$1 = interface
{
my $c = chain_base $_[0];
[ $c . '_fwd', $c . '_in' ];
}
#
# Create a new chain and return a reference to it.
#
sub new_chain($$)
{
my ($table, $chain) = @_;
$chain_table{$table}{$chain} = { name => $chain,
rules => [],
table => $table,
loglevel => '',
log => 1,
loopcount => 0,
cmdcount => 0 };
}
#
# Create an anonymous chain
#
sub new_anon_chain( $ ) {
my $chainref = $_[0];
my $seq = $chainseq++;
new_chain( $chainref->{table}, 'chain' . "$seq" );
}
#
#
# Create a chain if it doesn't exist already
#
sub ensure_chain($$)
{
my ($table, $chain) = @_;
my $ref = $chain_table{$table}{$chain};
return $ref if $ref;
new_chain $table, $chain;
}
sub finish_chain_section( $$ );
#
# Create a filter chain if necessary. Optionally populate it with the appropriate ESTABLISHED,RELATED rule(s) and perform SYN rate limiting.
#
sub ensure_filter_chain( $$ )
{
my ($chain, $populate) = @_;
my $chainref = $filter_table->{$chain};
$chainref = new_chain 'filter' , $chain unless $chainref;
if ( $populate and ! $chainref->{referenced} ) {
if ( $section eq 'NEW' or $section eq 'DONE' ) {
finish_chain_section $chainref , 'ESTABLISHED,RELATED';
} elsif ( $section eq 'RELATED' ) {
finish_chain_section $chainref , 'ESTABLISHED';
}
}
$chainref->{referenced} = 1;
$chainref;
}
sub ensure_mangle_chain($) {
my $chain = $_[0];
my $chainref = ensure_chain 'mangle', $chain;
$chainref->{referenced} = 1;
$chainref;
}
#
# Add a builtin chain
#
sub new_builtin_chain($$$)
{
my ( $table, $chain, $policy ) = @_;
my $chainref = new_chain $table, $chain;
$chainref->{referenced} = 1;
$chainref->{policy} = $policy;
$chainref->{builtin} = 1;
}
sub new_standard_chain($) {
my $chainref = new_chain 'filter' ,$_[0];
$chainref->{referenced} = 1;
$chainref;
}
#
# Add all builtin chains to the chain table
#
#
sub initialize_chain_table()
{
for my $chain qw(OUTPUT PREROUTING) {
new_builtin_chain 'raw', $chain, 'ACCEPT';
}
for my $chain qw(INPUT OUTPUT FORWARD) {
new_builtin_chain 'filter', $chain, 'DROP';
}
for my $chain qw(PREROUTING POSTROUTING OUTPUT) {
new_builtin_chain 'nat', $chain, 'ACCEPT';
}
for my $chain qw(PREROUTING INPUT FORWARD OUTPUT POSTROUTING) {
new_builtin_chain 'mangle', $chain, 'ACCEPT';
}
if ( $capabilities{MANGLE_FORWARD} ) {
for my $chain qw( FORWARD POSTROUTING ) {
new_builtin_chain 'mangle', $chain, 'ACCEPT';
}
}
}
#
# Add ESTABLISHED,RELATED rules and synparam jumps to the passed chain
#
sub finish_chain_section ($$) {
my ($chainref, $state ) = @_;
my $chain = $chainref->{name};
add_rule $chainref, "-m state --state $state -j ACCEPT" unless $config{FASTACCEPT};
if ($sections{RELATED} ) {
if ( $chainref->{is_policy} ) {
if ( $chainref->{synparams} ) {
my $synchainref = ensure_chain 'filter', syn_flood_chain $chainref;
if ( $section eq 'DONE' ) {
if ( $chainref->{policy} =~ /^(ACCEPT|CONTINUE|QUEUE)$/ ) {
add_rule $chainref, "-p tcp --syn -j $synchainref->{name}";
}
} else {
add_rule $chainref, "-p tcp --syn -j $synchainref->{name}";
}
}
} else {
my $policychainref = $filter_table->{$chainref->{policychain}};
if ( $policychainref->{synparams} ) {
my $synchainref = ensure_chain 'filter', syn_flood_chain $policychainref;
add_rule $chainref, "-p tcp --syn -j $synchainref->{name}";
}
}
}
}
#
# Do section-end processing
#
sub finish_section ( $ ) {
my $sections = $_[0];
for my $section ( split /,/, $sections ) {
$sections{$section} = 1;
}
for my $zone ( @zones ) {
for my $zone1 ( @zones ) {
my $chainref = $chain_table{'filter'}{"${zone}2${zone1}"};
if ( $chainref->{referenced} ) {
finish_chain_section $chainref, $sections;
}
}
}
}
#
# Helper for set_mss
#
sub set_mss1( $$ ) {
my ( $chain, $mss ) = @_;
my $chainref = ensure_chain 'filter', $chain;
if ( $chainref->{policy} ne 'NONE' ) {
my $match = $capabilities{TCPMSS_MATCH} ? "-m tcpmss --mss $mss: " : '';
insert_rule $chainref, 1, "-p tcp --tcp-flags SYN,RST SYN ${match}-j TCPMSS --set-mss $mss"
}
}
#
# Set up rules to set MSS to and/or from zone "$zone"
#
sub set_mss( $$$ ) {
my ( $zone, $mss, $direction) = @_;
for my $z ( @zones ) {
if ( $direction eq '_in' ) {
set_mss1 "${zone}2${z}" , $mss;
} elsif ( $direction eq '_out' ) {
set_mss1 "${z}2${zone}", $mss;
} else {
set_mss1 "${z}2${zone}", $mss;
set_mss1 "${zone}2${z}", $mss;
}
}
}
#
# Interate over non-firewall zones adding TCPMSS rules as appropriate
#
sub setup_zone_mss() {
for my $zone ( @zones ) {
my $zoneref = $zones{$zone};
set_mss( $zone, $zoneref->{options}{in_out}{mss}, '' ) if $zoneref->{options}{in_out}{mss};
set_mss( $zone, $zoneref->{options}{in}{mss}, '_in' ) if $zoneref->{options}{in}{mss};
set_mss( $zone, $zoneref->{options}{out}{mss}, '_out' ) if $zoneref->{options}{out}{mss};
}
}
sub newexclusionchain() {
my $seq = $exclseq++;
"excl${seq}";
}
sub clearrule() {
$iprangematch = 0;
}
sub validate_proto( $ ) {
my $proto = $_[0];
my $value = $protocols{$proto};
return $value if defined $value;
return $proto if $proto =~ /^(\d+)$/ && $proto <= 65535;
return $proto if $proto eq 'all';
fatal_error "Invalid/Unknown protocol ($proto)";
}
sub validate_portpair( $ ) {
my $portpair = $_[0];
fatal_error "Invalid port range ($portpair)" if $portpair =~ tr/:/:/ > 1;
$portpair = "0$portpair" if substr( $portpair, 0, 1 ) eq ':';
$portpair = "${portpair}65535" if substr( $portpair, -1, 1 ) eq ':';
my @ports = split/:/, $portpair, 2;
for my $port ( @ports ) {
my $value = $services{$port};
unless ( defined $value ) {
$value = $port if $port =~ /^(\d+)$/ && $port <= 65535;
}
fatal_error "Invalid/Unknown port/service ($port)" unless defined $value;
$port = $value;
}
if ( @ports == 2 ) {
fatal_error "Invalid port range ($portpair)" unless $ports[0] < $ports[1];
}
join ':', @ports;
}
sub validate_port_list( $ ) {
my $result = '';
for my $port ( split/,/, $_[0] ) {
my $value = validate_portpair( $port );
$result = $result ? join ',', $result, $value : $value;
}
$result;
}
my %icmp_types = ( any => 'any',
'echo-reply' => 0,
'destination-unreachable' => 3,
'network-unreachable' => '3/0',
'host-unreachable' => '3/1',
'protocol-unreachable' => '3/2',
'port-unreachable' => '3/3',
'fragmentation-needed' => '3/4',
'source-route-failed' => '3/5',
'network-unknown' => '3/6',
'host-unknown' => '3/7',
'network-prohibited' => '3/9',
'host-prohibited' => '3/10',
'TOS-network-unreachable' => '3/11',
'TOS-host-unreachable' => '3/12',
'communication-prohibited' => '3/13',
'host-precedence-violation' => '3/14',
'precedence-cutoff' => '3/15',
'source-quench' => 4,
'redirect' => 5,
'network-redirect' => '5/0',
'host-redirect' => '5/1',
'TOS-network-redirect' => '5/2',
'TOS-host-redirect' => '5/3',
'echo-request' => '8',
'router-advertisement' => 9,
'router-solicitation' => 10,
'time-exceeded' => 11,
'ttl-zero-during-transit' => '11/0',
'ttl-zero-during-reassembly' => '11/1',
'parameter-problem' => 12,
'ip-header-bad' => '12/0',
'required-option-missing' => '12/1',
'timestamp-request' => 13,
'timestamp-reply' => 14,
'address-mask-request' => 17,
'address-mask-reply' => 18 );
sub validate_icmp( $ ) {
my $type = $_[0];
my $value = $icmp_types{$type};
return $value if defined $value;
if ( $type =~ /^(\d+)(\/(\d+))?$/ ) {
return $type if $1 < 256 && ( ! $2 || $3 < 256 );
}
fatal_error "Invalid ICMP Type ($type)"
}
#
# Handle parsing of PROTO, DEST PORT(S) , SOURCE PORTS(S). Returns the appropriate match string.
#
sub do_proto( $$$ )
{
my ($proto, $ports, $sports ) = @_;
#
# Return the number of ports represented by the passed list
#
sub port_count( $ ) {
( $_[0] =~ tr/,:/,:/ ) + 1;
}
my $output = '';
$proto = '' if $proto eq '-';
$ports = '' if $ports eq '-';
$sports = '' if $sports eq '-';
if ( $proto ) {
if ( $proto =~ /^(((tcp|6)((:syn)?))|(udp|17))$/ ) {
if ( $4 ) {
$output = '-p 6 --syn ';
} else {
$proto = $protocols{$proto} if defined $protocols{$proto};
$output = "-p $proto ";
}
my $multiport = 0;
if ( $ports ne '' ) {
if ( $ports =~ tr/,/,/ > 0 || $sports =~ tr/,/,/ > 0 ) {
fatal_error "Port list requires Multiport support in your kernel/iptables ($ports)" unless $capabilities{MULTIPORT};
fatal_error "Too many entries in port list ($ports)" if port_count( $ports ) > 15;
$ports = validate_port_list $ports;
$output .= "-m multiport --dports $ports ";
$multiport = 1;
} else {
$ports = validate_portpair $ports;
$output .= "--dport $ports ";
}
} else {
$multiport = ( ( $sports =~ tr/,/,/ ) > 0 );
}
if ( $sports ne '' ) {
if ( $multiport ) {
fatal_error "Too many entries in port list ($sports)" if port_count( $sports ) > 15;
$sports = validate_port_list $sports;
$output .= "-m multiport --sports $sports ";
} else {
$sports = validate_portpair $sports;
$output .= "--sport $sports ";
}
}
} elsif ( $proto =~ /^(icmp|1)$/i ) {
fatal_error 'Multiple ICMP types are not permitted' if $ports =~ /,/;
$output .= "-p icmp ";
if ( $ports ne '' ) {
$ports = validate_icmp $ports;
$output .= "--icmp-type $ports ";
}
fatal_error 'SOURCE PORT(S) not permitted with ICMP' if $sports ne '';
} elsif ( $proto =~ /^(ipp2p(:(tcp|udp|all))?)$/i ) {
require_capability( 'IPP2P_MATCH' , 'PROTO = ipp2p' , 's' );
$proto = $2 ? $3 : 'tcp';
$ports = 'ipp2p' unless $ports;
$output .= "-p $proto -m ipp2p --$ports ";
} else {
fatal_error "SOURCE/DEST PORT(S) not allowed with PROTO $proto" if $ports ne '' || $sports ne '';
$proto = validate_proto $proto;
$output .= "-p $proto ";
}
} elsif ( $ports ne '' || $sports ne '' ) {
fatal_error "SOURCE/DEST PORT(S) not allowed without PROTO"
}
$output;
}
sub mac_match( $ ) {
my $mac = $_[0];
$mac =~ s/^(!?)~//;
$mac =~ s/^!// if my $invert = ( $1 ? '! ' : '');
$mac =~ tr/-/:/;
"--match mac --mac-source ${invert}$mac ";
}
#
# Convert value to decimal number
#
sub numeric_value ( $ ) {
my $mark = $_[0];
fatal_error "Invalid Numeric Value ($mark)" unless "\L$mark" =~ /^(0x[a-f0-9]+|0[0-7]*|[1-9]\d*)$/;
$mark =~ /^0x/ ? hex $mark : $mark =~ /^0/ ? oct $mark : $mark;
}
#
# Mark validatation functions
#
sub verify_mark( $ ) {
my $mark = $_[0];
my $limit = $config{HIGH_ROUTE_MARKS} ? 0xFFFF : 0xFF;
fatal_error "Invalid Mark or Mask value ($mark)"
unless numeric_value( $mark ) <= $limit;
}
sub verify_small_mark( $ ) {
verify_mark ( (my $mark) = $_[0] );
fatal_error "Mark value ($mark) too large" if numeric_value( $mark ) > 0xFF;
}
sub validate_mark( $ ) {
for ( split '/', $_[0] ) {
verify_mark $_;
}
}
#
# Generate an appropriate -m [conn]mark match string for the contents of a MARK column
#
sub do_test ( $$ )
{
my ($testval, $mask) = @_;
return '' unless $testval and $testval ne '-';
my $invert = $testval =~ s/^!// ? '! ' : '';
my $match = $testval =~ s/:C$// ? "-m connmark ${invert}--mark" : "-m mark ${invert}--mark";
validate_mark $testval;
$testval .= '/0xFF' unless ( $testval =~ '/' );
"$match $testval ";
}
my %norate = ( DROP => 1, REJECT => 1 );
#
# Create a "-m limit" match for the passed LIMIT/BURST
#
sub do_ratelimit( $$ ) {
my ( $rate, $action ) = @_;
return '' unless $rate and $rate ne '-';
fatal_error "Rate Limiting not available with $action" if $norate{$action};
if ( $rate =~ /^(\d+(\/(sec|hour|day))?):(\d+)$/ ) {
"-m limit --limit $1 --limit-burst $4 ";
} elsif ( $rate =~ /^(\d+)(\/(sec|hour|day))?$/ ) {
"-m limit --limit $rate ";
} else {
fatal_error "Invalid rate ($rate)";
}
}
#
# Create a "-m owner" match for the passed USER/GROUP
#
sub do_user( $ ) {
my $user = $_[0];
my $rule = '-m owner ';
return '' unless defined $user and $user ne '-';
if ( $user =~ /^(!)?(.*)\+(.*)$/ ) {
$rule .= "! --cmd-owner $2 " if defined $2 && $2 ne '';
$user = "!$1";
} elsif ( $user =~ /^(.*)\+(.*)$/ ) {
$rule .= "--cmd-owner $2 " if defined $2 && $2 ne '';
$user = $1;
}
if ( $user =~ /^!(.*):(.*)$/ ) {
$rule .= "! --uid-owner $1 " if defined $1 && $1 ne '';
$rule .= "! --gid-owner $2 " if defined $2 && $2 ne '';
} elsif ( $user =~ /^(.*):(.*)$/ ) {
$rule .= "--uid-owner $1 " if defined $1 && $1 ne '';
$rule .= "--gid-owner $2 " if defined $2 && $2 ne '';
} elsif ( $user =~ /^!/ ) {
$rule .= "! --uid-owner $user ";
} else {
$rule .= "--uid-owner $user ";
}
$rule;
}
#
# Create a "-m tos" match for the passed TOS
#
sub do_tos( $ ) {
my $tos = $_[0];
$tos ne '-' ? "-m tos --tos $tos " : '';
}
#
# Match Source Interface
#
sub match_source_dev( $ ) {
my $interface = shift;
my $interfaceref = $interfaces{$interface};
if ( $interfaceref && $interfaceref->{options}{port} ) {
"-i $interfaceref->{bridge} -m physdev --physdev-in $interface ";
} else {
"-i $interface ";
}
}
#
# Match Dest device
#
sub match_dest_dev( $ ) {
my $interface = shift;
my $interfaceref = $interfaces{$interface};
if ( $interfaceref && $interfaceref->{options}{port} ) {
"-o $interfaceref->{bridge} -m physdev --physdev-out $interface ";
} else {
"-o $interface ";
}
}
#
# Avoid generating a second '-m iprange' in a single rule.
#
sub iprange_match() {
my $match = '';
require_capability( 'IPRANGE_MATCH' , 'Address Ranges' , '' );
unless ( $iprangematch ) {
$match = '-m iprange ';
$iprangematch = 1 unless $capabilities{KLUDGEFREE};
}
$match;
}
#
# Get set flags (ipsets).
#
sub get_set_flags( $$ ) {
my ( $setname, $option ) = @_;
my $options = $option;
if ( $setname =~ /^(.*)\[([1-6])\]$/ ) {
$setname = $1;
my $count = $2;
$options .= ",$option" while --$count > 0;
} elsif ( $setname =~ /^(.*)\[(.*)\]$/ ) {
$setname = $1;
$options = $2;
}
$setname =~ s/^\+//;
fatal_error "Invalid ipset name ($setname)" unless $setname =~ /^[a-zA-Z]\w*/;
"--set $setname $options "
}
#
# Match a Source. Currently only handles IP addresses and ranges
#
sub match_source_net( $ ) {
my $net = $_[0];
if ( $net =~ /^(!?)(\d+\.\d+\.\d+\.\d+)-(\d+\.\d+\.\d+\.\d+)$/ ) {
my ($addr1, $addr2) = ( $2, $3 );
$net =~ s/!// if my $invert = $1 ? '! ' : '';
validate_range $addr1, $addr2;
iprange_match . "${invert}--src-range $net ";
} elsif ( $net =~ /^(!?)~(.*)$/ ) {
( $net = $2 ) =~ tr/-/:/;
my $invert = $1 ? '! ' : '';
"-m mac --mac-source ${invert}$net ";
} elsif ( $net =~ /^(!?)\+/ ) {
require_capability( 'IPSET_MATCH' , 'ipset names in Shorewall configuration files' , '' );
join( '', '-m set ', $1 ? '! ' : '', get_set_flags( $net, 'src' ) );
} elsif ( $net =~ /^!/ ) {
$net =~ s/!//;
validate_net $net;
"-s ! $net ";
} else {
validate_net $net;
$net eq ALLIPv4 ? '' : "-s $net ";
}
}
#
# Match a Source. Currently only handles IP addresses and ranges
#
sub match_dest_net( $ ) {
my $net = $_[0];
if ( $net =~ /^(!?)(\d+\.\d+\.\d+\.\d+)-(\d+\.\d+\.\d+\.\d+)$/ ) {
my ($addr1, $addr2) = ( $2, $3 );
$net =~ s/!// if my $invert = $1 ? '! ' : '';
validate_range $addr1, $addr2;
iprange_match . "${invert}--dst-range $net ";
} elsif ( $net =~ /^(!?)\+/ ) {
require_capability( 'IPSET_MATCH' , 'ipset names in Shorewall configuration files' , '');
join( '', '-m set ', $1 ? '! ' : '', get_set_flags( $net, 'dst' ) );
} elsif ( $net =~ /^!/ ) {
$net =~ s/!//;
validate_net $net;
"-d ! $net ";
} else {
validate_net $net;
$net eq ALLIPv4 ? '' : "-d $net ";
}
}
#
# Match original destination
#
sub match_orig_dest ( $ ) {
my $net = $_[0];
return '' if $net eq ALLIPv4;
return '' unless $capabilities{CONNTRACK_MATCH};
if ( $net =~ /^!/ ) {
$net =~ s/!//;
"-m conntrack --ctorigdst ! $net ";
} else {
$net eq ALLIPv4 ? '' : "-m conntrack --ctorigdst $net ";
}
}
#
# Match Source IPSEC
#
sub match_ipsec_in( $$ ) {
my ( $zone , $hostref ) = @_;
my $match = '-m policy --dir in --pol ';
my $zoneref = $zones{$zone};
my $optionsref = $zoneref->{options};
if ( $zoneref->{type} eq 'ipsec4' ) {
$match .= "ipsec $optionsref->{in_out}{ipsec}$optionsref->{in}{ipsec}";
} elsif ( $capabilities{POLICY_MATCH} ) {
$match .= "$hostref->{ipsec} $optionsref->{in_out}{ipsec}$optionsref->{in}{ipsec}";
} else {
'';
}
}
#
# Match Dest IPSEC
#
sub match_ipsec_out( $$ ) {
my ( $zone , $hostref ) = @_;
my $match = '-m policy --dir out --pol ';
my $zoneref = $zones{$zone};
my $optionsref = $zoneref->{options};
if ( $zoneref->{type} eq 'ipsec4' ) {
$match .= "ipsec $optionsref->{in_out}{ipsec}$optionsref->{out}{ipsec}";
} elsif ( $capabilities{POLICY_MATCH} ) {
$match .= "$hostref->{ipsec} $optionsref->{in_out}{ipsec}$optionsref->{out}{ipsec}"
} else {
'';
}
}
#
# Generate a log message
#
sub log_rule_limit( $$$$$$$$ ) {
my ($level, $chainref, $chain, $disposition, $limit, $tag, $command, $predicates ) = @_;
my $prefix;
unless ( $predicates =~ /-m limit / ) {
$limit = $globals{LOGLIMIT} unless $limit && $limit ne '-';
$predicates .= $limit if $limit;
}
if ( $tag ) {
if ( $config{LOGTAGONLY} ) {
$chain = $tag;
$tag = '';
} else {
$tag .= ' ';
}
} else {
$tag = '' unless defined $tag;
}
if ( $globals{LOGRULENUMBERS} ) {
$prefix = (sprintf $config{LOGFORMAT} , $chain , $chainref->{log}++, $disposition ) . $tag;
} else {
$prefix = (sprintf $config{LOGFORMAT} , $chain , $disposition) . $tag;
}
if ( length $prefix > 29 ) {
$prefix = substr $prefix, 0, 29;
warning_message "Log Prefix shortened to \"$prefix\"";
}
if ( $chainref->{loopcount} || $chainref->{cmdcount} ) {
#
# The rule will be converted to an "echo" shell command. We must insure that the
# quotes are preserved in the iptables-input file.
#
if ( $level eq 'ULOG' ) {
$prefix = "-j ULOG $globals{LOGPARMS}--ulog-prefix \\\"$prefix\\\" ";
} else {
$prefix = "-j LOG $globals{LOGPARMS}--log-level $level --log-prefix \\\"$prefix\\\" ";
}
} else {
if ( $level eq 'ULOG' ) {
$prefix = "-j ULOG $globals{LOGPARMS}--ulog-prefix \"$prefix\" ";
} else {
$prefix = "-j LOG $globals{LOGPARMS}--log-level $level --log-prefix \"$prefix\" ";
}
}
if ( $command eq 'add' ) {
add_rule ( $chainref, $predicates . $prefix );
} else {
insert_rule ( $chainref , 1 , $predicates . $prefix );
}
}
sub log_rule( $$$$ ) {
my ( $level, $chainref, $disposition, $predicates ) = @_;
log_rule_limit $level, $chainref, $chainref->{name} , $disposition, $globals{LOGLIMIT}, '', 'add', $predicates;
}
#
# Split a comma-separated source or destination host list but keep [...] together.
#
sub mysplit( $ ) {
my @input = split /,/, $_[0];
return @input unless $_[0] =~ /\[/;
my @result;
while ( @input ) {
my $element = shift @input;
if ( $element =~ /\[/ ) {
while ( substr( $element, -1, 1 ) ne ']' ) {
last unless @input;
$element .= ( ',' . shift @input );
}
fatal_error "Invalid Host List ($_[0])" unless substr( $element, -1, 1 ) eq ']';
}
push @result, $element;
}
@result;
}
#
# Returns the name of the shell variable holding the first address of the passed interface
#
sub interface_address( $ ) {
chain_base( $_[0] ) . '_address';
}
#
# Record that the ruleset requires the first IP address on the passed interface
#
sub get_interface_address ( $ ) {
my ( $interface ) = $_[0];
my $variable = interface_address( $interface );
my $function = interface_is_optional( $interface ) ? 'find_first_interface_address_if_any' : 'find_first_interface_address';
$interfaceaddr{$interface} = "$variable=\$($function $interface)";
"\$$variable";
}
#
# Returns the name of the shell variable holding the broadcast addresses of the passed interface
#
sub interface_bcasts( $ ) {
chain_base( $_[0] ) . '_bcasts';
}
#
# Record that the ruleset requires the broadcast addresses on the passed interface
#
sub get_interface_bcasts ( $ ) {
my ( $interface ) = $_[0];
my $variable = interface_bcasts( $interface );
$interfacebcasts{$interface} = qq($variable="\$(get_interface_bcasts $interface) 255.255.255.255");
"\$$variable";
}
#
# Returns the name of the shell variable holding the addresses of the passed interface
#
sub interface_addresses( $ ) {
chain_base( $_[0] ) . '_addresses';
}
#
# Record that the ruleset requires the IP addresses on the passed interface
#
sub get_interface_addresses ( $ ) {
my ( $interface ) = $_[0];
my $variable = interface_addresses( $interface );
if ( interface_is_optional $interface ) {
$interfaceaddrs{$interface} = qq($variable=\$(find_interface_addresses $interface)\n);
} else {
$interfaceaddrs{$interface} = qq($variable=\$(find_interface_addresses $interface)
[ -n "\$$variable" ] || fatal_error "Unable to determine the IP address(es) of $interface"
);
}
"\$$variable";
}
#
# Returns the name of the shell variable holding the networks routed out of the passed interface
#
sub interface_nets( $ ) {
chain_base( $_[0] ) . '_networks';
}
#
# Record that the ruleset requires the first IP address on the passed interface
#
sub get_interface_nets ( $ ) {
my ( $interface ) = $_[0];
my $variable = interface_nets( $interface );
if ( interface_is_optional $interface ) {
$interfacenets{$interface} = qq($variable=\$(get_routed_networks $interface)\n);
} else {
$interfacenets{$interface} = qq($variable=\$(get_routed_networks $interface)
[ -n "\$$variable" ] || fatal_error "Unable to determine the routes through interface \\"$interface\\""
);
}
"\$$variable";
}
#
# This function provides a uniform way to generate rules (something the original Shorewall sorely needed).
#
# Returns the destination interface specified in the rule, if any.
#
sub expand_rule( $$$$$$$$$$ )
{
my ($chainref , # Chain
$restriction, # Determines what to do with interface names in the SOURCE or DEST
$rule, # Caller's matches that don't depend on the SOURCE, DEST and ORIGINAL DEST
$source, # SOURCE
$dest, # DEST
$origdest, # ORIGINAL DEST
$target, # Target ('-j' part of the rule)
$loglevel , # Log level (and tag)
$disposition, # Primative part of the target (RETURN, ACCEPT, ...)
$exceptionrule # Caller's matches used in exclusion case
) = @_;
my ($iiface, $diface, $inets, $dnets, $iexcl, $dexcl, $onets , $oexcl );
my $chain = $chainref->{name};
#
# Handle Log Level
#
my $logtag;
if ( $loglevel ne '' ) {
( $loglevel, $logtag, my $remainder ) = split( /:/, $loglevel, 3 );
fatal_error "Invalid log tag" if defined $remainder;
if ( $loglevel =~ /^none!?$/i ) {
return if $disposition eq 'LOG';
$loglevel = $logtag = '';
} else {
$loglevel = validate_level( $loglevel );
$logtag = '' unless defined $logtag;
}
} elsif ( $disposition eq 'LOG' ) {
fatal_error "LOG requires a level";
}
#
# Isolate Source Interface, if any
#
if ( $source ) {
if ( $source eq '-' ) {
$source = '';
} elsif ( $source =~ /^([^:]+):([^:]+)$/ ) {
$iiface = $1;
$inets = $2;
} elsif ( $source =~ /\+|~|\..*\./ ) {
$inets = $source;
} else {
$iiface = $source;
}
} else {
$source = '';
}
#
# Verify Interface, if any
#
if ( $iiface ) {
fatal_error "Unknown Interface ($iiface)" unless known_interface $iiface;
if ( $restriction & POSTROUTE_RESTRICT ) {
#
# An interface in the SOURCE column of a masq file
#
fatal_error "Bridge ports may not appear in the SOURCE column of this file" if port_to_bridge( $iiface );
my $networks = get_interface_nets ( $iiface );
add_command( $chainref , join( '', 'for source in ', $networks, '; do' ) );
$rule .= '-s $source ';
#
# While $loopcount > 0, calls to 'add_rule()' will be converted to calls to 'add_command()'
#
$chainref->{loopcount}++;
} else {
fatal_error "Source Interface ($iiface) not allowed when the source zone is $firewall_zone" if $restriction & OUTPUT_RESTRICT;
$rule .= match_source_dev( $iiface );
}
}
#
# Isolate Destination Interface, if any
#
if ( $dest ) {
if ( $dest eq '-' ) {
$dest = '';
} elsif ( ( $restriction & PREROUTE_RESTRICT ) && $dest =~ /^detect:(.*)$/ ) {
#
# DETECT_DNAT_IPADDRS=Yes and we're generating the nat rule
#
my @interfaces = split /\s+/, $1;
if ( @interfaces > 1 ) {
my $list = "";
for my $interface ( @interfaces ) {
$list = join( ' ', $list , get_interface_address( $interface ) );
}
add_command( $chainref , "for address in $list; do" );
$rule .= '-d $address ';
$chainref->{loopcount}++;
} else {
$rule .= join ( '', '-d ', get_interface_address( $interfaces[0] ), ' ' );
}
$dest = '';
} elsif ( $dest =~ /^([^:]+):([^:]+)$/ ) {
$diface = $1;
$dnets = $2;
} elsif ( $dest =~ /\+|~|\..*\./ ) {
$dnets = $dest;
} else {
$diface = $dest;
}
} else {
$dest = '';
}
#
# Verify Destination Interface, if any
#
if ( $diface ) {
fatal_error "Unknown Interface ($diface)" unless known_interface $diface;
if ( $restriction & PREROUTE_RESTRICT ) {
#
# ADDRESS 'detect' in the masq file.
#
fatal_error "Bridge port ($diface) not allowed" if port_to_bridge( $diface );
add_command( $chainref , 'for dest in ' . get_interface_addresses( $diface) . '; do' );
$rule .= '-d $dest ';
$chainref->{loopcount}++;
} else {
fatal_error "Bridge Port ($diface) not allowed in OUTPUT or POSTROUTING rules" if ( $restriction & ( POSTROUTE_RESTRICT + OUTPUT_RESTRICT ) ) && port_to_bridge( $diface );
fatal_error "Destination Interface ($diface) not allowed when the destination zone is $firewall_zone" if $restriction & INPUT_RESTRICT;
if ( $iiface ) {
my $bridge = port_to_bridge( $diface );
fatal_error "Source interface ($iiface) is not a port on the same bridge as the destination interface ( $diface )" if $bridge && $bridge ne source_port_to_bridge( $iiface );
}
$rule .= match_dest_dev( $diface );
}
} else {
$diface = '';
}
if ( $origdest ) {
if ( $origdest eq '-' || ! $capabilities{CONNTRACK_MATCH} ) {
$origdest = '';
} elsif ( $origdest =~ /^detect:(.*)$/ ) {
#
# Either the filter part of a DNAT rule or 'detect' was given in the ORIG DEST column
#
my @interfaces = split /\s+/, $1;
if ( @interfaces > 1 ) {
my $list = "";
for my $interface ( @interfaces ) {
$list = join( ' ', $list , get_interface_address( $interface ) );
}
add_command( $chainref , "for address in $list; do" );
$rule .= '-m conntrack --ctorigdst $address ';
$chainref->{loopcount}++;
} else {
get_interface_address $interfaces[0];
$rule .= join( '', '-m conntrack --ctorigdst $', interface_address ( $interfaces[0] ), ' ' );
}
$origdest = '';
} else {
fatal_error "Invalid ORIGINAL DEST" if $origdest =~ /^([^!]+)?,!([^!]+)$/ || $origdest =~ /.*!.*!/;
if ( $origdest =~ /^([^!]+)?!([^!]+)$/ ) {
#
# Exclusion
#
$onets = $1;
$oexcl = $2;
} else {
$oexcl = '';
$onets = $origdest;
}
unless ( $onets ) {
my @oexcl = mysplit $oexcl;
if ( @oexcl == 1 ) {
$rule .= "-m conntrack --ctorigdst ! $oexcl ";
$oexcl = '';
}
}
}
} else {
$oexcl = '';
}
#
# Determine if there is Source Exclusion
#
if ( $inets ) {
fatal_error "Invalid SOURCE" if $inets =~ /^([^!]+)?,!([^!]+)$/ || $inets =~ /.*!.*!/;
if ( $inets =~ /^([^!]+)?!([^!]+)$/ ) {
$inets = $1;
$iexcl = $2;
} else {
$iexcl = '';
}
unless ( $inets || ( $iiface && $restriction & POSTROUTE_RESTRICT ) ) {
my @iexcl = mysplit $iexcl;
if ( @iexcl == 1 ) {
$rule .= match_source_net "!$iexcl";
$iexcl = '';
}
}
} else {
$iexcl = '';
}
#
# Determine if there is Destination Exclusion
#
if ( $dnets ) {
fatal_error "Invalid DEST" if $dnets =~ /^([^!]+)?,!([^!]+)$/ || $dnets =~ /.*!.*!/;
if ( $dnets =~ /^([^!]+)?!([^!]+)$/ ) {
$dnets = $1;
$dexcl = $2;
} else {
$dexcl = '';
}
unless ( $dnets ) {
my @dexcl = mysplit $dexcl;
if ( @dexcl == 1 ) {
$rule .= match_dest_net "!$dexcl";
$dexcl = '';
}
}
} else {
$dexcl = '';
}
$inets = ALLIPv4 unless $inets;
$dnets = ALLIPv4 unless $dnets;
$onets = ALLIPv4 unless $onets;
if ( $iexcl || $dexcl || $oexcl ) {
#
# We have non-trivial exclusion -- need to create an exclusion chain
#
fatal_error "Exclusion is not possible in ACCEPT+/CONTINUE/NONAT rules" if $disposition eq 'RETURN';
my $echain = newexclusionchain;
#
# Use the current rule and sent all possible matches to the exclusion chain
#
for my $onet ( mysplit $onets ) {
$onet = match_orig_dest $onet;
for my $inet ( mysplit $inets ) {
for my $dnet ( mysplit $dnets ) {
#
# We defer evaluating the source net match to accomodate system without $capabilities{KLUDGEFREE}
#
add_rule $chainref, join( '', $rule, match_source_net( $inet), match_dest_net( $dnet ), $onet, "-j $echain" );
}
}
}
#
# The final rule in the exclusion chain will not qualify the source or destination
#
$inets = ALLIPv4;
$dnets = ALLIPv4;
#
# Create the Exclusion Chain
#
my $echainref = new_chain $chainref->{table}, $echain;
#
# Generate RETURNs for each exclusion
#
for my $net ( mysplit $iexcl ) {
add_rule $echainref, ( match_source_net $net ) . '-j RETURN';
}
for my $net ( mysplit $dexcl ) {
add_rule $echainref, ( match_dest_net $net ) . '-j RETURN';
}
for my $net ( mysplit $oexcl ) {
add_rule $echainref, ( match_orig_dest $net ) . '-j RETURN';
}
#
# Log rule
#
log_rule_limit $loglevel , $echainref , $chain, $disposition , '', $logtag , 'add' , '' if $loglevel;
#
# Generate Final Rule
#
add_rule( $echainref, $exceptionrule . $target ) unless $disposition eq 'LOG';
} else {
#
# No exclusions
#
for my $onet ( mysplit $onets ) {
$onet = match_orig_dest $onet;
for my $inet ( mysplit $inets ) {
#
# We defer evaluating the source net match to accomodate system without $capabilities{KLUDGEFREE}
#
for my $dnet ( mysplit $dnets ) {
if ( $loglevel ne '' ) {
log_rule_limit
$loglevel ,
$chainref ,
$chain,
$disposition ,
'' ,
$logtag ,
'add' ,
join( '', $rule, match_source_net( $inet) , match_dest_net( $dnet ), $onet );
}
unless ( $disposition eq 'LOG' ) {
add_rule
$chainref,
join( '', $rule, match_source_net ($inet), match_dest_net( $dnet ), $onet, $target );
}
}
}
}
}
while ( $chainref->{loopcount} > 0 ) {
$chainref->{loopcount}--;
add_command $chainref, 'done';
}
$diface;
}
#
# If the destination chain exists, then at the end of the source chain add a jump to the destination.
#
sub addnatjump( $$$ ) {
my ( $source , $dest, $predicates ) = @_;
my $destref = $nat_table->{$dest} || {};
if ( $destref->{referenced} ) {
add_rule $nat_table->{$source} , $predicates . "-j $dest";
} else {
clearrule;
}
}
#
# If the destination chain exists, then at the position in the source chain given by $$countref, add a jump to the destination.
#
sub insertnatjump( $$$$ ) {
my ( $source, $dest, $countref, $predicates ) = @_;
my $destref = $nat_table->{$dest} || {};
if ( $destref->{referenced} ) {
insert_rule $nat_table->{$source} , ($$countref)++, $predicates . "-j $dest";
} else {
clearrule;
}
}
sub emit_comment() {
unless ( $emitted_comment ) {
emit ( '#',
'# Establish the values of shell variables used in the following function calls',
'#' );
$emitted_comment = 1;
}
}
#
# Generate setting of global variables
#
sub set_global_variables() {
for ( values %interfaceaddr ) {
emit_comment unless $emitted_comment;
emit $_;
}
for ( values %interfaceaddrs ) {
emit_comment unless $emitted_comment;
emit $_;
}
for ( values %interfacenets ) {
emit_comment unless $emitted_comment;
emit $_;
}
unless ( $capabilities{ADDRTYPE} ) {
emit_comment unless $emitted_comment;
emit 'ALL_BCASTS="$(get_all_bcasts) 255.255.255.255"';
for ( values %interfacebcasts ) {
emit $_;
}
}
}
#
# What follows is the code that generates the input to iptables-restore
#
# We always write the iptables-restore input into a file then pass the
# file to iptables-restore. That way, if things go wrong, the user (and Shorewall support)
# has (have) something to look at to determine the error
#
# We may have to generate part of the input at run-time. The rules array in each chain
# table entry may contain rules (begin with '-A') or shell source. We alternate between
# writing the rules ('-A') into the temporary file to be bassed to iptables-restore
# (CAT_STATE) and and writing shell source into the generated script.
#
# The following two functions are responsible for the state transitions.
#
sub enter_cat_state() {
emit '';
emit 'cat >&3 << __EOF__';
$state = CAT_STATE;
}
sub enter_cmd_state() {
emit_unindented "__EOF__\n" if $state == CAT_STATE;
$state = CMD_STATE;
}
#
# Emits the passed rule (input to iptables-restore) or command
#
sub emitr( $ ) {
my $rule = $_[0];
if ( $rule && substr( $rule, 0, 2 ) eq '-A' ) {
#
# A rule
#
enter_cat_state unless $state == CAT_STATE;
emit_unindented $rule;
} else {
#
# A command
#
enter_cmd_state unless $state == CMD_STATE;
emit $rule;
}
}
#
# Generate the netfilter input
#
sub create_netfilter_load() {
my @table_list;
push @table_list, 'raw' if $capabilities{RAW_TABLE};
push @table_list, 'nat' if $capabilities{NAT_ENABLED};
push @table_list, 'mangle' if $capabilities{MANGLE_ENABLED};
push @table_list, 'filter';
$state = NULL_STATE;
emit ( 'setup_netfilter()',
'{'
);
push_indent;
save_progress_message "Preparing iptables-restore input...";
emit '';
emit 'exec 3>${VARDIR}/.iptables-restore-input';
enter_cat_state;
for my $table ( @table_list ) {
emit_unindented "*$table";
my @chains;
#
# iptables-restore seems to be quite picky about the order of the builtin chains
#
for my $chain ( @builtins ) {
my $chainref = $chain_table{$table}{$chain};
if ( $chainref ) {
emit_unindented ":$chain $chainref->{policy} [0:0]";
push @chains, $chainref;
}
}
#
# First create the chains in the current table
#
for my $chain ( grep $chain_table{$table}{$_}->{referenced} , ( sort keys %{$chain_table{$table}} ) ) {
my $chainref = $chain_table{$table}{$chain};
unless ( $chainref->{builtin} ) {
emit_unindented ":$chainref->{name} - [0:0]";
push @chains, $chainref;
}
}
#
# then emit the rules
#
for my $chainref ( @chains ) {
my $name = $chainref->{name};
for my $rule ( @{$chainref->{rules}} ) {
emitr $rule;
}
}
#
# Commit the changes to the table
#
enter_cat_state unless $state == CAT_STATE;
emit_unindented 'COMMIT';
}
enter_cmd_state;
#
# Now generate the actual iptables-restore command
#
emit( 'exec 3>&-',
'',
'progress_message2 "Running iptables-restore..."',
'',
'cat ${VARDIR}/.iptables-restore-input | $IPTABLES_RESTORE # Use this nonsensical form to appease SELinux',
'if [ $? != 0 ]; then',
' fatal_error "iptables-restore Failed. Input is in ${VARDIR}/.iptables-restore-input"',
"fi\n"
);
pop_indent;
emit "}\n";
}
#
# Generate the netfilter input for refreshing the blacklist
#
sub create_blacklist_reload() {
$state = NULL_STATE;
emit( 'blacklist_reload()',
'{'
);
push_indent;
save_progress_message "Preparing iptables-restore input...";
emit '';
emit 'exec 3>${VARDIR}/.iptables-restore-input';
enter_cat_state;
emit_unindented '*filter';
emit_unindented ':blacklst - [0:0]';
for my $rule ( @{$filter_table->{blacklst}{rules}} ) {
emitr $rule;
}
#
# Commit the changes to the table
#
enter_cat_state unless $state == CAT_STATE;
emit_unindented 'COMMIT';
enter_cmd_state;
#
# Now generate the actual iptables-restore command
#
emit( 'exec 3>&-',
'',
'progress_message2 "Running iptables-restore..."',
'',
'cat ${VARDIR}/.iptables-restore-input | $IPTABLES_RESTORE -n # Use this nonsensical form to appease SELinux',
'if [ $? != 0 ]; then',
' fatal_error "iptables-restore Failed. Input is in ${VARDIR}/.iptables-restore-input"',
"fi\n"
);
pop_indent;
emit "}\n";
}
1;