iptables/ip6tables — administration tool for IPv4/IPv6
packet filtering and NAT
iptables [-t table]
{-A|-C|-D|-V} chain
rule-specification
ip6tables [-t table]
{-A|-C|-D|-V} chain
rule-specification
iptables [-t table] -I chain
[rulenum] rule-specification
iptables [-t table] -R chain
rulenum rule-specification
iptables [-t table] -D chain
rulenum
iptables [-t table] -S [chain
[rulenum]]
iptables [-t table]
{-F|-L|-Z} [chain [rulenum]]
[options...]
iptables [-t table] -N
chain
iptables [-t table] -X
[chain]
iptables [-t table] -P chain
target
iptables [-t table] -E
old-chain-name new-chain-name
rule-specification = [matches...] [target]
match = -m matchname [per-match-options]
target = -j targetname
[per-target-options]
Iptables and ip6tables are used to set up, maintain,
and inspect the tables of IPv4 and IPv6 packet filter rules in the Linux
kernel. Several different tables may be defined. Each table contains a
number of built-in chains and may also contain user-defined chains.
Each chain is a list of rules which can match a set of packets.
Each rule specifies what to do with a packet that matches. This is called a
`target', which may be a jump to a user-defined chain in the same table.
A firewall rule specifies criteria for a packet and a target. If
the packet does not match, the next rule in the chain is examined; if it
does match, then the next rule is specified by the value of the target,
which can be the name of a user-defined chain, one of the targets described
in iptables-extensions(8), or one of the special values
ACCEPT, DROP or RETURN.
ACCEPT means to let the packet through. DROP means
to drop the packet on the floor. RETURN means stop traversing this
chain and resume at the next rule in the previous (calling) chain. If the
end of a built-in chain is reached or a rule in a built-in chain with target
RETURN is matched, the target specified by the chain policy
determines the fate of the packet.
There are currently five independent tables (which tables are
present at any time depends on the kernel configuration options and which
modules are present).
- -t, --table
table
- This option specifies the packet matching table which the command should
operate on. If the kernel is configured with automatic module loading, an
attempt will be made to load the appropriate module for that table if it
is not already there.
The tables are as follows:
- filter:
- This is the default table (if no -t option is passed). It contains the
built-in chains INPUT (for packets destined to local sockets),
FORWARD (for packets being routed through the box), and
OUTPUT (for locally-generated packets).
- nat:
- This table is consulted when a packet that creates a new connection is
encountered. It consists of four built-ins: PREROUTING (for
altering packets as soon as they come in), INPUT (for altering
packets destined for local sockets), OUTPUT (for altering
locally-generated packets before routing), and POSTROUTING (for
altering packets as they are about to go out). IPv6 NAT support is
available since kernel 3.7.
- mangle:
- This table is used for specialized packet alteration. Until kernel 2.4.17
it had two built-in chains: PREROUTING (for altering incoming
packets before routing) and OUTPUT (for altering locally-generated
packets before routing). Since kernel 2.4.18, three other built-in chains
are also supported: INPUT (for packets coming into the box itself),
FORWARD (for altering packets being routed through the box), and
POSTROUTING (for altering packets as they are about to go
out).
- raw:
- This table is used mainly for configuring exemptions from connection
tracking in combination with the NOTRACK target. It registers at the
netfilter hooks with higher priority and is thus called before
ip_conntrack, or any other IP tables. It provides the following built-in
chains: PREROUTING (for packets arriving via any network interface)
OUTPUT (for packets generated by local processes)
- security:
- This table is used for Mandatory Access Control (MAC) networking rules,
such as those enabled by the SECMARK and CONNSECMARK
targets. Mandatory Access Control is implemented by Linux Security Modules
such as SELinux. The security table is called after the filter table,
allowing any Discretionary Access Control (DAC) rules in the filter table
to take effect before MAC rules. This table provides the following
built-in chains: INPUT (for packets coming into the box itself),
OUTPUT (for altering locally-generated packets before routing), and
FORWARD (for altering packets being routed through the box).
The options that are recognized by iptables and
ip6tables can be divided into several different groups.
These options specify the desired action to perform. Only one of
them can be specified on the command line unless otherwise stated below. For
long versions of the command and option names, you need to use only enough
letters to ensure that iptables can differentiate it from all other
options.
- -A, --append chain
rule-specification
- Append one or more rules to the end of the selected chain. When the source
and/or destination names resolve to more than one address, a rule will be
added for each possible address combination.
- -C, --check chain
rule-specification
- Check whether a rule matching the specification does exist in the selected
chain. This command uses the same logic as -D to find a matching
entry, but does not alter the existing iptables configuration and uses its
exit code to indicate success or failure.
- -D, --delete chain
rule-specification
- -D, --delete
chain rulenum
- Delete one or more rules from the selected chain. There are two versions
of this command: the rule can be specified as a number in the chain
(starting at 1 for the first rule) or a rule to match.
- -I, --insert
chain [rulenum] rule-specification
- Insert one or more rules in the selected chain as the given rule number.
So, if the rule number is 1, the rule or rules are inserted at the head of
the chain. This is also the default if no rule number is specified.
- -R, --replace chain
rulenum rule-specification
- Replace a rule in the selected chain. If the source and/or destination
names resolve to multiple addresses, the command will fail. Rules are
numbered starting at 1.
- -L, --list
[chain]
- List all rules in the selected chain. If no chain is selected, all chains
are listed. Like every other iptables command, it applies to the specified
table (filter is the default), so NAT rules get listed by
iptables -t nat -n -L
Please note that it is often used with the -n option, in order to
avoid long reverse DNS lookups. It is legal to specify the -Z
(zero) option as well, in which case the chain(s) will be atomically
listed and zeroed. The exact output is affected by the other arguments
given. The exact rules are suppressed until you use
iptables -L -v
or iptables-save(8).
- -S, --list-rules
[chain]
- Print all rules in the selected chain. If no chain is selected, all chains
are printed like iptables-save. Like every other iptables command, it
applies to the specified table (filter is the default).
- -F, --flush
[chain]
- Flush the selected chain (all the chains in the table if none is given).
This is equivalent to deleting all the rules one by one.
- -Z, --zero
[chain [rulenum]]
- Zero the packet and byte counters in all chains, or only the given chain,
or only the given rule in a chain. It is legal to specify the -L,
--list (list) option as well, to see the counters immediately
before they are cleared. (See above.)
- -N, --new-chain
chain
- Create a new user-defined chain by the given name. There must be no target
of that name already.
- -X, --delete-chain
[chain]
- Delete the chain specified. There must be no references to the chain. If
there are, you must delete or replace the referring rules before the chain
can be deleted. The chain must be empty, i.e. not contain any rules. If no
argument is given, it will delete all empty chains in the table. Empty
builtin chains can only be deleted with iptables-nft.
- -P, --policy chain
target
- Set the policy for the built-in (non-user-defined) chain to the given
target. The policy target must be either ACCEPT or
DROP.
- -E, --rename-chain
old-chain new-chain
- Rename the user specified chain to the user supplied name. This is
cosmetic, and has no effect on the structure of the table.
- -h
- Help. Give a (currently very brief) description of the command
syntax.
The following parameters make up a rule specification (as used in
the add, delete, insert, replace and append commands).
- -4, --ipv4
- This option has no effect in iptables and iptables-restore. If a rule
using the -4 option is inserted with (and only with)
ip6tables-restore, it will be silently ignored. Any other uses will throw
an error. This option allows IPv4 and IPv6 rules in a single rule file for
use with both iptables-restore and ip6tables-restore.
- -6, --ipv6
- If a rule using the -6 option is inserted with (and only with)
iptables-restore, it will be silently ignored. Any other uses will throw
an error. This option allows IPv4 and IPv6 rules in a single rule file for
use with both iptables-restore and ip6tables-restore. This option has no
effect in ip6tables and ip6tables-restore.
- [!] -p, --protocol protocol
- The protocol of the rule or of the packet to check. The specified protocol
can be one of tcp, udp, udplite, icmp,
icmpv6,esp, ah, sctp, mh or the special
keyword "all", or it can be a numeric value, representing
one of these protocols or a different one. A protocol name from
/etc/protocols is also allowed. A "!" argument before the
protocol inverts the test. The number zero is equivalent to all.
"all" will match with all protocols and is taken as
default when this option is omitted. Note that, in ip6tables, IPv6
extension headers except esp are not allowed. esp and
ipv6-nonext can be used with Kernel version 2.6.11 or later. The
number zero is equivalent to all, which means that you cannot test
the protocol field for the value 0 directly. To match on a HBH header,
even if it were the last, you cannot use -p 0, but always need
-m hbh.
- [!] -s, --source
address[/mask][,...]
- Source specification. Address can be either a network name, a
hostname, a network IP address (with /mask), or a plain IP
address. Hostnames will be resolved once only, before the rule is
submitted to the kernel. Please note that specifying any name to be
resolved with a remote query such as DNS is a really bad idea. The
mask can be either an ipv4 network mask (for iptables) or a plain
number, specifying the number of 1's at the left side of the network mask.
Thus, an iptables mask of 24 is equivalent to 255.255.255.0.
A "!" argument before the address specification inverts the
sense of the address. The flag --src is an alias for this option.
Multiple addresses can be specified, but this will expand to
multiple rules (when adding with -A), or will cause multiple
rules to be deleted (with -D).
- [!] -d, --destination
address[/mask][,...]
- Destination specification. See the description of the -s (source)
flag for a detailed description of the syntax. The flag --dst is an
alias for this option.
- -m, --match
match
- Specifies a match to use, that is, an extension module that tests for a
specific property. The set of matches make up the condition under which a
target is invoked. Matches are evaluated first to last as specified on the
command line and work in short-circuit fashion, i.e. if one extension
yields false, evaluation will stop.
- -j, --jump
target
- This specifies the target of the rule; i.e., what to do if the packet
matches it. The target can be a user-defined chain (other than the one
this rule is in), one of the special builtin targets which decide the fate
of the packet immediately, or an extension (see EXTENSIONS below).
If this option is omitted in a rule (and -g is not used), then
matching the rule will have no effect on the packet's fate, but the
counters on the rule will be incremented.
- -g, --goto
chain
- This specifies that the processing should continue in a user specified
chain. Unlike the --jump option return will not continue processing in
this chain but instead in the chain that called us via --jump.
- [!] -i, --in-interface name
- Name of an interface via which a packet was received (only for packets
entering the INPUT, FORWARD and PREROUTING chains).
When the "!" argument is used before the interface name, the
sense is inverted. If the interface name ends in a "+", then any
interface which begins with this name will match. If this option is
omitted, any interface name will match.
- [!] -o, --out-interface name
- Name of an interface via which a packet is going to be sent (for packets
entering the FORWARD, OUTPUT and POSTROUTING chains).
When the "!" argument is used before the interface name, the
sense is inverted. If the interface name ends in a "+", then any
interface which begins with this name will match. If this option is
omitted, any interface name will match.
- [!] -f, --fragment
- This means that the rule only refers to second and further IPv4 fragments
of fragmented packets. Since there is no way to tell the source or
destination ports of such a packet (or ICMP type), such a packet will not
match any rules which specify them. When the "!" argument
precedes the "-f" flag, the rule will only match head fragments,
or unfragmented packets. This option is IPv4 specific, it is not available
in ip6tables.
- -c, --set-counters
packets bytes
- This enables the administrator to initialize the packet and byte counters
of a rule (during INSERT, APPEND, REPLACE
operations).
The following additional options can be specified:
- -v, --verbose
- Verbose output. This option makes the list command show the interface
name, the rule options (if any), and the TOS masks. The packet and byte
counters are also listed, with the suffix 'K', 'M' or 'G' for 1000,
1,000,000 and 1,000,000,000 multipliers respectively (but see the
-x flag to change this). For appending, insertion, deletion and
replacement, this causes detailed information on the rule or rules to be
printed. -v may be specified multiple times to possibly emit more
detailed debug statements: Specified twice, iptables-legacy will
dump table info and entries in libiptc, iptables-nft dumps rules in
netlink (VM code) presentation. Specified three times, iptables-nft
will also dump any netlink messages sent to kernel.
- -V, --version
- Show program version and the kernel API used.
- -w, --wait
[seconds]
- Wait for the xtables lock. To prevent multiple instances of the program
from running concurrently, an attempt will be made to obtain an exclusive
lock at launch. By default, the program will exit if the lock cannot be
obtained. This option will make the program wait (indefinitely or for
optional seconds) until the exclusive lock can be obtained.
- -n, --numeric
- Numeric output. IP addresses and port numbers will be printed in numeric
format. By default, the program will try to display them as host names,
network names, or services (whenever applicable).
- -x, --exact
- Expand numbers. Display the exact value of the packet and byte counters,
instead of only the rounded number in K's (multiples of 1000) M's
(multiples of 1000K) or G's (multiples of 1000M). This option is only
relevant for the -L command.
- --line-numbers
- When listing rules, add line numbers to the beginning of each rule,
corresponding to that rule's position in the chain.
- --modprobe=command
- When adding or inserting rules into a chain, use command to load
any necessary modules (targets, match extensions, etc).
iptables uses the /run/xtables.lock file to take an
exclusive lock at launch.
The XTABLES_LOCKFILE environment variable can be used to
override the default setting.
iptables can use extended packet matching and target modules. A
list of these is available in the iptables-extensions(8) manpage.
Various error messages are printed to standard error. The exit
code is 0 for correct functioning. Errors which appear to be caused by
invalid or abused command line parameters cause an exit code of 2, and other
errors cause an exit code of 1.
Bugs? What's this? ;-) Well, you might want to have a look at
http://bugzilla.netfilter.org/ iptables will exit immediately with an
error code of 111 if it finds that it was called as a setuid-to-root
program. iptables cannot be used safely in this manner because it trusts the
shared libraries (matches, targets) loaded at run time, the search path can
be set using environment variables.
This iptables is very similar to ipchains by Rusty Russell.
The main difference is that the chains INPUT and OUTPUT are
only traversed for packets coming into the local host and originating from
the local host respectively. Hence every packet only passes through one of
the three chains (except loopback traffic, which involves both INPUT and
OUTPUT chains); previously a forwarded packet would pass through all
three.
The other main difference is that -i refers to the input
interface; -o refers to the output interface, and both are available
for packets entering the FORWARD chain.
The various forms of NAT have been separated out; iptables
is a pure packet filter when using the default `filter' table, with optional
extension modules. This should simplify much of the previous confusion over
the combination of IP masquerading and packet filtering seen previously. So
the following options are handled differently:
-j MASQ
-M -S
-M -L
There are several other changes in iptables.
iptables-apply(8), iptables-save(8),
iptables-restore(8), iptables-extensions(8),
The packet-filtering-HOWTO details iptables usage for packet
filtering, the NAT-HOWTO details NAT, the netfilter-extensions-HOWTO details
the extensions that are not in the standard distribution, and the
netfilter-hacking-HOWTO details the netfilter internals.
See http://www.netfilter.org/.
Rusty Russell originally wrote iptables, in early consultation
with Michael Neuling.
Marc Boucher made Rusty abandon ipnatctl by lobbying for a generic
packet selection framework in iptables, then wrote the mangle table, the
owner match, the mark stuff, and ran around doing cool stuff everywhere.
James Morris wrote the TOS target, and tos match.
Jozsef Kadlecsik wrote the REJECT target.
Harald Welte wrote the ULOG and NFQUEUE target, the new libiptc,
as well as the TTL, DSCP, ECN matches and targets.
The Netfilter Core Team is: Jozsef Kadlecsik, Pablo Neira Ayuso,
Eric Leblond, Florian Westphal and Arturo Borrero Gonzalez. Emeritus Core
Team members are: Marc Boucher, Martin Josefsson, Yasuyuki Kozakai, James
Morris, Harald Welte and Rusty Russell.
Man page originally written by Herve Eychenne
<rv@wallfire.org>.
This manual page applies to iptables/ip6tables 1.8.9.