VERDICT STATEMENT ~~~~~~~~~~~~~~~~~ The verdict statement alters control flow in the ruleset and issues policy decisions for packets. [verse] {*accept* | *drop* | *queue* | *continue* | *return*} {*jump* | *goto*} 'chain' *accept* and *drop* are absolute verdicts -- they terminate ruleset evaluation immediately. [horizontal] *accept*:: Terminate ruleset evaluation and accept the packet. The packet can still be dropped later by another hook, for instance accept in the forward hook still allows one to drop the packet later in the postrouting hook, or another forward base chain that has a higher priority number and is evaluated afterwards in the processing pipeline. *drop*:: Terminate ruleset evaluation and drop the packet. The drop occurs instantly, no further chains or hooks are evaluated. It is not possible to accept the packet in a later chain again, as those are not evaluated anymore for the packet. *queue*:: Terminate ruleset evaluation and queue the packet to userspace. Userspace must provide a drop or accept verdict. In case of accept, processing resumes with the next base chain hook, not the rule following the queue verdict. *continue*:: Continue ruleset evaluation with the next rule. This is the default behaviour in case a rule issues no verdict. *return*:: Return from the current chain and continue evaluation at the next rule in the last chain. If issued in a base chain, it is equivalent to the base chain policy. *jump* 'chain':: Continue evaluation at the first rule in 'chain'. The current position in the ruleset is pushed to a call stack and evaluation will continue there when the new chain is entirely evaluated or a *return* verdict is issued. In case an absolute verdict is issued by a rule in the chain, ruleset evaluation terminates immediately and the specific action is taken. *goto* 'chain':: Similar to *jump*, but the current position is not pushed to the call stack, meaning that after the new chain evaluation will continue at the last chain instead of the one containing the goto statement. .Using verdict statements ------------------- # process packets from eth0 and the internal network in from_lan # chain, drop all packets from eth0 with different source addresses. filter input iif eth0 ip saddr 192.168.0.0/24 jump from_lan filter input iif eth0 drop ------------------- PAYLOAD STATEMENT ~~~~~~~~~~~~~~~~~ [verse] 'payload_expression' *set* 'value' The payload statement alters packet content. It can be used for example to set ip DSCP (diffserv) header field or ipv6 flow labels. .route some packets instead of bridging --------------------------------------- # redirect tcp:http from 192.160.0.0/16 to local machine for routing instead of bridging # assumes 00:11:22:33:44:55 is local MAC address. bridge input meta iif eth0 ip saddr 192.168.0.0/16 tcp dport 80 meta pkttype set host ether daddr set 00:11:22:33:44:55 ------------------------------------------- .Set IPv4 DSCP header field --------------------------- ip forward ip dscp set 42 --------------------------- EXTENSION HEADER STATEMENT ~~~~~~~~~~~~~~~~~~~~~~~~~~ [verse] 'extension_header_expression' *set* 'value' The extension header statement alters packet content in variable-sized headers. This can currently be used to alter the TCP Maximum segment size of packets, similar to the TCPMSS target in iptables. .change tcp mss --------------- tcp flags syn tcp option maxseg size set 1360 # set a size based on route information: tcp flags syn tcp option maxseg size set rt mtu --------------- You can also remove tcp options via reset keyword. .remove tcp option --------------- tcp flags syn reset tcp option sack-perm --------------- LOG STATEMENT ~~~~~~~~~~~~~ [verse] *log* [*prefix* 'quoted_string'] [*level* 'syslog-level'] [*flags* 'log-flags'] *log* *group* 'nflog_group' [*prefix* 'quoted_string'] [*queue-threshold* 'value'] [*snaplen* 'size'] *log level audit* The log statement enables logging of matching packets. When this statement is used from a rule, the Linux kernel will print some information on all matching packets, such as header fields, via the kernel log (where it can be read with dmesg(1) or read in the syslog). In the second form of invocation (if 'nflog_group' is specified), the Linux kernel will pass the packet to nfnetlink_log which will send the log through a netlink socket to the specified group. One userspace process may subscribe to the group to receive the logs, see man(8) ulogd for the Netfilter userspace log daemon and libnetfilter_log documentation for details in case you would like to develop a custom program to digest your logs. In the third form of invocation (if level audit is specified), the Linux kernel writes a message into the audit buffer suitably formatted for reading with auditd. Therefore no further formatting options (such as prefix or flags) are allowed in this mode. This is a non-terminating statement, so the rule evaluation continues after the packet is logged. .log statement options [options="header"] |================== |Keyword | Description | Type |prefix| Log message prefix| quoted string |level| Syslog level of logging | string: emerg, alert, crit, err, warn [default], notice, info, debug, audit |group| NFLOG group to send messages to| unsigned integer (16 bit) |snaplen| Length of packet payload to include in netlink message | unsigned integer (32 bit) |queue-threshold| Number of packets to queue inside the kernel before sending them to userspace | unsigned integer (32 bit) |================================== .log-flags [options="header"] |================== | Flag | Description |tcp sequence| Log TCP sequence numbers. |tcp options| Log options from the TCP packet header. |ip options| Log options from the IP/IPv6 packet header. |skuid| Log the userid of the process which generated the packet. |ether| Decode MAC addresses and protocol. |all| Enable all log flags listed above. |============================== .Using log statement -------------------- # log the UID which generated the packet and ip options ip filter output log flags skuid flags ip options # log the tcp sequence numbers and tcp options from the TCP packet ip filter output log flags tcp sequence,options # enable all supported log flags ip6 filter output log flags all ----------------------- REJECT STATEMENT ~~~~~~~~~~~~~~~~ [verse] ____ *reject* [ *with* 'REJECT_WITH' ] 'REJECT_WITH' := *icmp* 'icmp_reject_code' | *icmpv6* 'icmpv6_reject_code' | *icmpx* 'icmpx_reject_code' | *tcp reset* ____ A reject statement is used to send back an error packet in response to the matched packet otherwise it is equivalent to drop so it is a terminating statement, ending rule traversal. This statement is only valid in base chains using the *prerouting*, *input*, *forward* or *output* hooks, and user-defined chains which are only called from those chains. .Keywords may be used to reject when specifying the ICMP code [options="header"] |================== |Keyword | Value |net-unreachable | 0 |host-unreachable | 1 |prot-unreachable| 2 |port-unreachable| 3 |frag-needed| 4 |net-prohibited| 9 |host-prohibited| 10 |admin-prohibited| 13 |=================== .keywords may be used to reject when specifying the ICMPv6 code [options="header"] |================== |Keyword |Value |no-route| 0 |admin-prohibited| 1 |addr-unreachable| 3 |port-unreachable| 4 |policy-fail| 5 |reject-route| 6 |================== The ICMPvX Code type abstraction is a set of values which overlap between ICMP and ICMPv6 Code types to be used from the inet family. .keywords may be used when specifying the ICMPvX code [options="header"] |================== |Keyword |Value |no-route| 0 |port-unreachable| 1 |host-unreachable| 2 |admin-prohibited| 3 |================= The common default ICMP code to reject is *port-unreachable*. Note that in bridge family, reject statement is only allowed in base chains which hook into input or prerouting. COUNTER STATEMENT ~~~~~~~~~~~~~~~~~ A counter statement sets the hit count of packets along with the number of bytes. [verse] *counter* *packets* 'number' *bytes* 'number' *counter* { *packets* 'number' | *bytes* 'number' } CONNTRACK STATEMENT ~~~~~~~~~~~~~~~~~~~ The conntrack statement can be used to set the conntrack mark and conntrack labels. [verse] *ct* {*mark* | *event* | *label* | *zone*} *set* 'value' The ct statement sets meta data associated with a connection. The zone id has to be assigned before a conntrack lookup takes place, i.e. this has to be done in prerouting and possibly output (if locally generated packets need to be placed in a distinct zone), with a hook priority of *raw* (-300). Unlike iptables, where the helper assignment happens in the raw table, the helper needs to be assigned after a conntrack entry has been found, i.e. it will not work when used with hook priorities equal or before -200. .Conntrack statement types [options="header"] |================== |Keyword| Description| Value |event| conntrack event bits | bitmask, integer (32 bit) |helper| name of ct helper object to assign to the connection | quoted string |mark| Connection tracking mark | mark |label| Connection tracking label| label |zone| conntrack zone| integer (16 bit) |================== .save packet nfmark in conntrack -------------------------------- ct mark set meta mark -------------------------------- .set zone mapped via interface ------------------------------ table inet raw { chain prerouting { type filter hook prerouting priority raw; ct zone set iif map { "eth1" : 1, "veth1" : 2 } } chain output { type filter hook output priority raw; ct zone set oif map { "eth1" : 1, "veth1" : 2 } } } ------------------------------------------------------ .restrict events reported by ctnetlink -------------------------------------- ct event set new,related,destroy -------------------------------------- NOTRACK STATEMENT ~~~~~~~~~~~~~~~~~ The notrack statement allows one to disable connection tracking for certain packets. [verse] *notrack* Note that for this statement to be effective, it has to be applied to packets before a conntrack lookup happens. Therefore, it needs to sit in a chain with either prerouting or output hook and a hook priority of -300 (*raw*) or less. See SYNPROXY STATEMENT for an example usage. META STATEMENT ~~~~~~~~~~~~~~ A meta statement sets the value of a meta expression. The existing meta fields are: priority, mark, pkttype, nftrace. + [verse] *meta* {*mark* | *priority* | *pkttype* | *nftrace* | *broute*} *set* 'value' A meta statement sets meta data associated with a packet. + .Meta statement types [options="header"] |================== |Keyword| Description| Value |priority | TC packet priority| tc_handle |mark| Packet mark | mark |pkttype | packet type | pkt_type |nftrace | ruleset packet tracing on/off. Use *monitor trace* command to watch traces| 0, 1 |broute | broute on/off. packets are routed instead of being bridged| 0, 1 |========================== LIMIT STATEMENT ~~~~~~~~~~~~~~~ [verse] ____ *limit rate* [*over*] 'packet_number' */* 'TIME_UNIT' [*burst* 'packet_number' *packets*] *limit rate* [*over*] 'byte_number' 'BYTE_UNIT' */* 'TIME_UNIT' [*burst* 'byte_number' 'BYTE_UNIT'] 'TIME_UNIT' := *second* | *minute* | *hour* | *day* 'BYTE_UNIT' := *bytes* | *kbytes* | *mbytes* ____ A limit statement matches at a limited rate using a token bucket filter. A rule using this statement will match until this limit is reached. It can be used in combination with the log statement to give limited logging. The optional *over* keyword makes it match over the specified rate. The *burst* value influences the bucket size, i.e. jitter tolerance. With packet-based *limit*, the bucket holds exactly *burst* packets, by default five. If you specify packet *burst*, it must be a non-zero value. With byte-based *limit*, the bucket's minimum size is the given rate's byte value and the *burst* value adds to that, by default zero bytes. .limit statement values [options="header"] |================== |Value | Description | Type |packet_number | Number of packets | unsigned integer (32 bit) |byte_number | Number of bytes | unsigned integer (32 bit) |======================== NAT STATEMENTS ~~~~~~~~~~~~~~ [verse] ____ *snat* [[*ip* | *ip6*] [ *prefix* ] *to*] 'ADDR_SPEC' [*:*'PORT_SPEC'] ['FLAGS'] *dnat* [[*ip* | *ip6*] [ *prefix* ] *to*] 'ADDR_SPEC' [*:*'PORT_SPEC'] ['FLAGS'] *masquerade* [*to :*'PORT_SPEC'] ['FLAGS'] *redirect* [*to :*'PORT_SPEC'] ['FLAGS'] 'ADDR_SPEC' := 'address' | 'address' *-* 'address' 'PORT_SPEC' := 'port' | 'port' *-* 'port' 'FLAGS' := 'FLAG' [*,* 'FLAGS'] 'FLAG' := *persistent* | *random* | *fully-random* ____ The nat statements are only valid from nat chain types. + The *snat* and *masquerade* statements specify that the source address of the packet should be modified. While *snat* is only valid in the postrouting and input chains, *masquerade* makes sense only in postrouting. The dnat and redirect statements are only valid in the prerouting and output chains, they specify that the destination address of the packet should be modified. You can use non-base chains which are called from base chains of nat chain type too. All future packets in this connection will also be mangled, and rules should cease being examined. The *masquerade* statement is a special form of snat which always uses the outgoing interface's IP address to translate to. It is particularly useful on gateways with dynamic (public) IP addresses. The *redirect* statement is a special form of dnat which always translates the destination address to the local host's one. It comes in handy if one only wants to alter the destination port of incoming traffic on different interfaces. When used in the inet family (available with kernel 5.2), the dnat and snat statements require the use of the ip and ip6 keyword in case an address is provided, see the examples below. Before kernel 4.18 nat statements require both prerouting and postrouting base chains to be present since otherwise packets on the return path won't be seen by netfilter and therefore no reverse translation will take place. The optional *prefix* keyword allows to map to map *n* source addresses to *n* destination addresses. See 'Advanced NAT examples' below. .NAT statement values [options="header"] |================== |Expression| Description| Type |address| Specifies that the source/destination address of the packet should be modified. You may specify a mapping to relate a list of tuples composed of arbitrary expression key with address value. | ipv4_addr, ipv6_addr, e.g. abcd::1234, or you can use a mapping, e.g. meta mark map { 10 : 192.168.1.2, 20 : 192.168.1.3 } |port| Specifies that the source/destination port of the packet should be modified. | port number (16 bit) |=============================== .NAT statement flags [options="header"] |================== |Flag| Description |persistent | Gives a client the same source-/destination-address for each connection. |random| In kernel 5.0 and newer this is the same as fully-random. In earlier kernels the port mapping will be randomized using a seeded MD5 hash mix using source and destination address and destination port. |fully-random| If used then port mapping is generated based on a 32-bit pseudo-random algorithm. |============================= .Using NAT statements --------------------- # create a suitable table/chain setup for all further examples add table nat add chain nat prerouting { type nat hook prerouting priority dstnat; } add chain nat postrouting { type nat hook postrouting priority srcnat; } # translate source addresses of all packets leaving via eth0 to address 1.2.3.4 add rule nat postrouting oif eth0 snat to 1.2.3.4 # redirect all traffic entering via eth0 to destination address 192.168.1.120 add rule nat prerouting iif eth0 dnat to 192.168.1.120 # translate source addresses of all packets leaving via eth0 to whatever # locally generated packets would use as source to reach the same destination add rule nat postrouting oif eth0 masquerade # redirect incoming TCP traffic for port 22 to port 2222 add rule nat prerouting tcp dport 22 redirect to :2222 # inet family: # handle ip dnat: add rule inet nat prerouting dnat ip to 10.0.2.99 # handle ip6 dnat: add rule inet nat prerouting dnat ip6 to fe80::dead # this masquerades both ipv4 and ipv6: add rule inet nat postrouting meta oif ppp0 masquerade ------------------------ .Advanced NAT examples ---------------------- # map prefixes in one network to that of another, e.g. 10.141.11.4 is mangled to 192.168.2.4, # 10.141.11.5 is mangled to 192.168.2.5 and so on. add rule nat postrouting snat ip prefix to ip saddr map { 10.141.11.0/24 : 192.168.2.0/24 } # map a source address, source port combination to a pool of destination addresses and ports: add rule nat postrouting dnat to ip saddr . tcp dport map { 192.168.1.2 . 80 : 10.141.10.2-10.141.10.5 . 8888-8999 } # The above example generates the following NAT expression: # # [ nat dnat ip addr_min reg 1 addr_max reg 10 proto_min reg 9 proto_max reg 11 ] # # which expects to obtain the following tuple: # IP address (min), source port (min), IP address (max), source port (max) # to be obtained from the map. The given addresses and ports are inclusive. # This also works with named maps and in combination with both concatenations and ranges: table ip nat { map ipportmap { typeof ip saddr : interval ip daddr . tcp dport flags interval elements = { 192.168.1.2 : 10.141.10.1-10.141.10.3 . 8888-8999, 192.168.2.0/24 : 10.141.11.5-10.141.11.20 . 8888-8999 } } chain prerouting { type nat hook prerouting priority dstnat; policy accept; ip protocol tcp dnat ip to ip saddr map @ipportmap } } @ipportmap maps network prefixes to a range of hosts and ports. The new destination is taken from the range provided by the map element. Same for the destination port. Note the use of the "interval" keyword in the typeof description. This is required so nftables knows that it has to ask for twice the amount of storage for each key-value pair in the map. ": ipv4_addr . inet_service" would allow associating one address and one port with each key. But for this case, for each key, two addresses and two ports (The minimum and maximum values for both) have to be stored. ------------------------ TPROXY STATEMENT ~~~~~~~~~~~~~~~~ Tproxy redirects the packet to a local socket without changing the packet header in any way. If any of the arguments is missing the data of the incoming packet is used as parameter. Tproxy matching requires another rule that ensures the presence of transport protocol header is specified. [verse] *tproxy to* 'address'*:*'port' *tproxy to* {'address' | *:*'port'} This syntax can be used in *ip/ip6* tables where network layer protocol is obvious. Either IP address or port can be specified, but at least one of them is necessary. [verse] *tproxy* {*ip* | *ip6*} *to* 'address'[*:*'port'] *tproxy to :*'port' This syntax can be used in *inet* tables. The *ip/ip6* parameter defines the family the rule will match. The *address* parameter must be of this family. When only *port* is defined, the address family should not be specified. In this case the rule will match for both families. .tproxy attributes [options="header"] |================= | Name | Description | address | IP address the listening socket with IP_TRANSPARENT option is bound to. | port | Port the listening socket with IP_TRANSPARENT option is bound to. |================= .Example ruleset for tproxy statement ------------------------------------- table ip x { chain y { type filter hook prerouting priority mangle; policy accept; tcp dport ntp tproxy to 1.1.1.1 accept udp dport ssh tproxy to :2222 accept } } table ip6 x { chain y { type filter hook prerouting priority mangle; policy accept; tcp dport ntp tproxy to [dead::beef] accept udp dport ssh tproxy to :2222 accept } } table inet x { chain y { type filter hook prerouting priority mangle; policy accept; tcp dport 321 tproxy to :22 accept tcp dport 99 tproxy ip to 1.1.1.1:999 accept udp dport 155 tproxy ip6 to [dead::beef]:smux accept } } ------------------------------------- Note that the tproxy statement is non-terminal to allow post-processing of packets. This allows packets to be logged for debugging as well as updating the mark to ensure that packets are delivered locally through policy routing rules. .Example ruleset for tproxy statement with logging and meta mark ------------------------------------- table inet x { chain y { type filter hook prerouting priority mangle; policy accept; udp dport 9999 goto { tproxy to :1234 log prefix "packet tproxied: " meta mark set 1 accept log prefix "no socket on port 1234 or not transparent?: " drop } } } ------------------------------------- As packet headers are unchanged, packets might be forwarded instead of delivered locally. As mentioned above, this can be avoided by adding policy routing rules and the packet mark. .Example policy routing rules for local redirection ---------------------------------------------------- ip rule add fwmark 1 lookup 100 ip route add local 0.0.0.0/0 dev lo table 100 ---------------------------------------------------- This is a change in behavior compared to the legacy iptables TPROXY target which is terminal. To terminate the packet processing after the tproxy statement, remember to issue a verdict as in the example above. SYNPROXY STATEMENT ~~~~~~~~~~~~~~~~~~ This statement will process TCP three-way-handshake parallel in netfilter context to protect either local or backend system. This statement requires connection tracking because sequence numbers need to be translated. [verse] *synproxy* [*mss* 'mss_value'] [*wscale* 'wscale_value'] ['SYNPROXY_FLAGS'] .synproxy statement attributes [options="header"] |================= | Name | Description | mss | Maximum segment size announced to clients. This must match the backend. | wscale | Window scale announced to clients. This must match the backend. |================= .synproxy statement flags [options="header"] |================= | Flag | Description | sack-perm | Pass client selective acknowledgement option to backend (will be disabled if not present). | timestamp | Pass client timestamp option to backend (will be disabled if not present, also needed for selective acknowledgement and window scaling). |================= .Example ruleset for synproxy statement --------------------------------------- Determine tcp options used by backend, from an external system tcpdump -pni eth0 -c 1 'tcp[tcpflags] == (tcp-syn|tcp-ack)' port 80 & telnet 192.0.2.42 80 18:57:24.693307 IP 192.0.2.42.80 > 192.0.2.43.48757: Flags [S.], seq 360414582, ack 788841994, win 14480, options [mss 1460,sackOK, TS val 1409056151 ecr 9690221, nop,wscale 9], length 0 Switch tcp_loose mode off, so conntrack will mark out-of-flow packets as state INVALID. echo 0 > /proc/sys/net/netfilter/nf_conntrack_tcp_loose Make SYN packets untracked. table ip x { chain y { type filter hook prerouting priority raw; policy accept; tcp flags syn notrack } } Catch UNTRACKED (SYN packets) and INVALID (3WHS ACK packets) states and send them to SYNPROXY. This rule will respond to SYN packets with SYN+ACK syncookies, create ESTABLISHED for valid client response (3WHS ACK packets) and drop incorrect cookies. Flags combinations not expected during 3WHS will not match and continue (e.g. SYN+FIN, SYN+ACK). Finally, drop invalid packets, this will be out-of-flow packets that were not matched by SYNPROXY. table ip x { chain z { type filter hook input priority filter; policy accept; ct state invalid, untracked synproxy mss 1460 wscale 9 timestamp sack-perm ct state invalid drop } } --------------------------------------- FLOW STATEMENT ~~~~~~~~~~~~~~ A flow statement allows us to select what flows you want to accelerate forwarding through layer 3 network stack bypass. You have to specify the flowtable name where you want to offload this flow. *flow add @*'flowtable' QUEUE STATEMENT ~~~~~~~~~~~~~~~ This statement passes the packet to userspace using the nfnetlink_queue handler. The packet is put into the queue identified by its 16-bit queue number. Userspace can inspect and modify the packet if desired. Userspace must then drop or re-inject the packet into the kernel. See libnetfilter_queue documentation for details. [verse] ____ *queue* [*flags* 'QUEUE_FLAGS'] [*to* 'queue_number'] *queue* [*flags* 'QUEUE_FLAGS'] [*to* 'queue_number_from' - 'queue_number_to'] *queue* [*flags* 'QUEUE_FLAGS'] [*to* 'QUEUE_EXPRESSION' ] 'QUEUE_FLAGS' := 'QUEUE_FLAG' [*,* 'QUEUE_FLAGS'] 'QUEUE_FLAG' := *bypass* | *fanout* 'QUEUE_EXPRESSION' := *numgen* | *hash* | *symhash* | *MAP STATEMENT* ____ QUEUE_EXPRESSION can be used to compute a queue number at run-time with the hash or numgen expressions. It also allows one to use the map statement to assign fixed queue numbers based on external inputs such as the source ip address or interface names. .queue statement values [options="header"] |================== |Value | Description | Type |queue_number | Sets queue number, default is 0. | unsigned integer (16 bit) |queue_number_from | Sets initial queue in the range, if fanout is used. | unsigned integer (16 bit) |queue_number_to | Sets closing queue in the range, if fanout is used. | unsigned integer (16 bit) |===================== .queue statement flags [options="header"] |================== |Flag | Description |bypass | Let packets go through if userspace application cannot back off. Before using this flag, read libnetfilter_queue documentation for performance tuning recommendations. |fanout | Distribute packets between several queues. |=============================== DUP STATEMENT ~~~~~~~~~~~~~ The dup statement is used to duplicate a packet and send the copy to a different destination. [verse] *dup to* 'device' *dup to* 'address' *device* 'device' .Dup statement values [options="header"] |================== |Expression | Description | Type |address | Specifies that the copy of the packet should be sent to a new gateway.| ipv4_addr, ipv6_addr, e.g. abcd::1234, or you can use a mapping, e.g. ip saddr map { 192.168.1.2 : 10.1.1.1 } |device | Specifies that the copy should be transmitted via device. | string |=================== .Using the dup statement ------------------------ # send to machine with ip address 10.2.3.4 on eth0 ip filter forward dup to 10.2.3.4 device "eth0" # copy raw frame to another interface netdev ingress dup to "eth0" dup to "eth0" # combine with map dst addr to gateways dup to ip daddr map { 192.168.7.1 : "eth0", 192.168.7.2 : "eth1" } ----------------------------------- FWD STATEMENT ~~~~~~~~~~~~~ The fwd statement is used to redirect a raw packet to another interface. It is only available in the netdev family ingress and egress hooks. It is similar to the dup statement except that no copy is made. You can also specify the address of the next hop and the device to forward the packet to. This updates the source and destination MAC address of the packet by transmitting it through the neighboring layer. This also decrements the ttl field of the IP packet. This provides a way to effectively bypass the classical forwarding path, thus skipping the fib (forwarding information base) lookup. [verse] *fwd to* 'device' *fwd* [*ip* | *ip6*] *to* 'address' *device* 'device' .Using the fwd statement ------------------------ # redirect raw packet to device netdev ingress fwd to "eth0" # forward packet to next hop 192.168.200.1 via eth0 device netdev ingress ether saddr set fwd ip to 192.168.200.1 device "eth0" ----------------------------------- SET STATEMENT ~~~~~~~~~~~~~ The set statement is used to dynamically add or update elements in a set from the packet path. The set setname must already exist in the given table and must have been created with one or both of the dynamic and the timeout flags. The dynamic flag is required if the set statement expression includes a stateful object. The timeout flag is implied if the set is created with a timeout, and is required if the set statement updates elements, rather than adding them. Furthermore, these sets should specify both a maximum set size (to prevent memory exhaustion), and their elements should have a timeout (so their number will not grow indefinitely) either from the set definition or from the statement that adds or updates them. The set statement can be used to e.g. create dynamic blacklists. Dynamic updates are also supported with maps. In this case, the *add* or *update* rule needs to provide both the key and the data element (value), separated via ':'. [verse] {*add* | *update*} *@*'setname' *{* 'expression' [*timeout* 'timeout'] [*comment* 'string'] *}* .Example for simple blacklist ----------------------------- # declare a set, bound to table "filter", in family "ip". # Timeout and size are mandatory because we will add elements from packet path. # Entries will timeout after one minute, after which they might be # re-added if limit condition persists. nft add set ip filter blackhole \ "{ type ipv4_addr; flags dynamic; timeout 1m; size 65536; }" # declare a set to store the limit per saddr. # This must be separate from blackhole since the timeout is different nft add set ip filter flood \ "{ type ipv4_addr; flags dynamic; timeout 10s; size 128000; }" # whitelist internal interface. nft add rule ip filter input meta iifname "internal" accept # drop packets coming from blacklisted ip addresses. nft add rule ip filter input ip saddr @blackhole counter drop # add source ip addresses to the blacklist if more than 10 tcp connection # requests occurred per second and ip address. nft add rule ip filter input tcp flags syn tcp dport ssh \ add @flood { ip saddr limit rate over 10/second } \ add @blackhole { ip saddr } \ drop # inspect state of the sets. nft list set ip filter flood nft list set ip filter blackhole # manually add two addresses to the blackhole. nft add element filter blackhole { 10.2.3.4, 10.23.1.42 } ----------------------------------------------- MAP STATEMENT ~~~~~~~~~~~~~ The map statement is used to lookup data based on some specific input key. [verse] ____ 'expression' *map* *{* 'MAP_ELEMENTS' *}* 'MAP_ELEMENTS' := 'MAP_ELEMENT' [*,* 'MAP_ELEMENTS'] 'MAP_ELEMENT' := 'key' *:* 'value' ____ The 'key' is a value returned by 'expression'. // XXX: Write about where map statement can be used (list of statements?) .Using the map statement ------------------------ # select DNAT target based on TCP dport: # connections to port 80 are redirected to 192.168.1.100, # connections to port 8888 are redirected to 192.168.1.101 nft add rule ip nat prerouting dnat tcp dport map { 80 : 192.168.1.100, 8888 : 192.168.1.101 } # source address based SNAT: # packets from net 192.168.1.0/24 will appear as originating from 10.0.0.1, # packets from net 192.168.2.0/24 will appear as originating from 10.0.0.2 nft add rule ip nat postrouting snat to ip saddr map { 192.168.1.0/24 : 10.0.0.1, 192.168.2.0/24 : 10.0.0.2 } ------------------------ VMAP STATEMENT ~~~~~~~~~~~~~~ The verdict map (vmap) statement works analogous to the map statement, but contains verdicts as values. [verse] ____ 'expression' *vmap* *{* 'VMAP_ELEMENTS' *}* 'VMAP_ELEMENTS' := 'VMAP_ELEMENT' [*,* 'VMAP_ELEMENTS'] 'VMAP_ELEMENT' := 'key' *:* 'verdict' ____ .Using the vmap statement ------------------------- # jump to different chains depending on layer 4 protocol type: nft add rule ip filter input ip protocol vmap { tcp : jump tcp-chain, udp : jump udp-chain , icmp : jump icmp-chain } ------------------------ XT STATEMENT ~~~~~~~~~~~~ This represents an xt statement from xtables compat interface. It is a fallback if translation is not available or not complete. [verse] ____ *xt* 'TYPE' 'NAME' 'TYPE' := *match* | *target* | *watcher* ____ Seeing this means the ruleset (or parts of it) were created by *iptables-nft* and one should use that to manage it. *BEWARE:* nftables won't restore these statements.