Concatenations: Difference between revisions

From nftables wiki
Jump to navigation Jump to search
(add example concatenations)
(Use "dnat to".)
 
(11 intermediate revisions by 3 users not shown)
Line 1: Line 1:
Since Linux kernel 4.1, nftables supports concatenations.
Since Linux kernel 4.1, nftables supports concatenations.


This new feature allows you to put two or more selectors together to perform very fast lookups by combining them with [[sets]], [[dictionaries]] and [[maps]].
This new feature allows you to put two or more selectors together to perform very fast lookups in [[sets]], [[maps]], [[Verdict_Maps_(vmaps) | vmaps]] and [[meters]].


= Literal sets =
 
= Anonymous sets =


<source lang="bash">
<source lang="bash">
Line 9: Line 10:
</source>
</source>


So if the packet is source IP address AND destination IP address AND TCP destination port match:
So if the packet's source IP address AND destination IP address AND level 4 protocol match:


* 1.1.1.1 and 2.2.2.2 and TCP.
* 1.1.1.1 and 2.2.2.2 and TCP.
Line 19: Line 20:
nftables updates the counter for this rule and then accepts the packet.
nftables updates the counter for this rule and then accepts the packet.


= Dictionary declarations =


The following example creates the ''whitelist'' dictionary using a concatenation of two selectors:
= Named verdict maps =
 
The following example creates the ''whitelist'' vmap using a concatenation of two selectors:


<source lang="bash">
<source lang="bash">
Line 27: Line 29:
</source>
</source>


Once you create the dictionary, you can use it from a rule that creates the following concatenation:
Once you create the vmap, you can use it from a rule that creates the following concatenation:


<source lang="bash">
<source lang="bash">
Line 33: Line 35:
</source>
</source>


Thus, the rule above looks up for a verdict based on the source IP address AND the TCP destination port.
The rule above looks up a verdict based on the source IP address AND the TCP destination port.


Since the dictionary is initially empty, you can dynamically populate this dictionary with elements through:
The verdict map is initially empty. You can dynamically populate it with elements:


<source lang="bash">
<source lang="bash">
Line 41: Line 43:
</source>
</source>


= Literal maps =
When declaring concatenations, you can use [[Sets | generic sets options]], such as the '''typeof''' keyword and the '''counter''' feature:
 
<source lang="bash">
table inet fmytable {
set myset {
typeof ip daddr . tcp dport
counter
elements = { 1.1.1.4 . 22 counter packets 0 bytes 0,
    1.1.1.5 . 23 counter packets 0 bytes 0,
    1.1.1.6 . 24 counter packets 0 bytes 0 }
}
}
</source>
 
 
= Anonymous maps =


The rule below determines the destination IP address that is used to perform DNAT to the packet based on:
The rule below determines the destination IP address that is used to perform DNAT to the packet based on:
Line 52: Line 69:


<source lang="bash">
<source lang="bash">
% nft add rule ip nat prerouting dnat ip saddr . tcp dport map { 1.1.1.1 . 80 : 192.168.1.100, 2.2.2.2 . 8888 : 192.168.1.101 }
% nft add rule ip nat prerouting dnat to ip saddr . tcp dport map { 1.1.1.1 . 80 : 192.168.1.100, 2.2.2.2 . 8888 : 192.168.1.101 }
</source>
</source>


= Examples =
= Examples =
Line 61: Line 79:
== Network addresses ==
== Network addresses ==


The example below implements a dictionary using network masks as matching element.
The example below implements a vmap using network masks in each element:
 
<source lang="bash">
table inet mytable {
    set myset {
        type ipv4_addr . ipv4_addr
        flags interval
        elements = { 192.168.0.0/16 . 172.16.0.0/25,
                    10.0.0.0/30 . 192.168.1.0/24,
        }
    }
 
    chain mychain {
        ip saddr . ip daddr @myset counter accept
    }
}
</source>
 
 
'''NOTE''': before Linux kernel 5.6 and nftables 0.9.4 the CIDR notation wasn't available, you would need to use a workaround:


<source lang="bash">
<source lang="bash">
Line 85: Line 122:
</source>
</source>


Please note that using strings (for example iifname and oifname) and other variable sized data types is not supported yet.
== Some ipset types ==
 
These ipset types can be implemented in nftables using concatenations. Probably more equivalences exists, it just a matter of combining data types.
Of course, you could implement these as named maps/sets as well.
 
See examples in the [[Moving_from_ipset_to_nftables | moving from ipset to nftables]] page.

Latest revision as of 02:48, 20 April 2021

Since Linux kernel 4.1, nftables supports concatenations.

This new feature allows you to put two or more selectors together to perform very fast lookups in sets, maps, vmaps and meters.


Anonymous sets

% nft add rule ip filter input ip saddr . ip daddr . ip protocol { 1.1.1.1 . 2.2.2.2 . tcp, 1.1.1.1 . 3.3.3.3 . udp} counter accept

So if the packet's source IP address AND destination IP address AND level 4 protocol match:

  • 1.1.1.1 and 2.2.2.2 and TCP.

or

  • 1.1.1.1 and 3.3.3.3 and UDP.

nftables updates the counter for this rule and then accepts the packet.


Named verdict maps

The following example creates the whitelist vmap using a concatenation of two selectors:

% nft add map filter whitelist { type ipv4_addr . inet_service : verdict \; }

Once you create the vmap, you can use it from a rule that creates the following concatenation:

% nft add rule filter input ip saddr . tcp dport vmap @whitelist

The rule above looks up a verdict based on the source IP address AND the TCP destination port.

The verdict map is initially empty. You can dynamically populate it with elements:

% nft add element filter whitelist { 1.2.3.4 . 22 : accept}

When declaring concatenations, you can use generic sets options, such as the typeof keyword and the counter feature:

table inet fmytable {
	set myset {
		typeof ip daddr . tcp dport
		counter
		elements = { 1.1.1.4 . 22 counter packets 0 bytes 0,
			     1.1.1.5 . 23 counter packets 0 bytes 0,
			     1.1.1.6 . 24 counter packets 0 bytes 0 }
	}
}


Anonymous maps

The rule below determines the destination IP address that is used to perform DNAT to the packet based on:

  • the source IP address

AND

  • the destination TCP port
% nft add rule ip nat prerouting dnat to ip saddr . tcp dport map { 1.1.1.1 . 80 : 192.168.1.100, 2.2.2.2 . 8888 : 192.168.1.101 }


Examples

Some concrete example concatenations so you get an idea on how powerful this new feature is.

Network addresses

The example below implements a vmap using network masks in each element:

table inet mytable {
    set myset {
        type ipv4_addr . ipv4_addr
        flags interval
        elements = { 192.168.0.0/16 . 172.16.0.0/25,
                     10.0.0.0/30 . 192.168.1.0/24,
        }
    }

    chain mychain {
        ip saddr . ip daddr @myset counter accept
    }
}


NOTE: before Linux kernel 5.6 and nftables 0.9.4 the CIDR notation wasn't available, you would need to use a workaround:

% nft add rule tablename chainname ip saddr and 255.255.255.0 . ip daddr and 255.255.255.0 vmap { 10.10.10.0 . 10.10.20.0 : accept }

Note that this is not an interval, this is masking the ip saddr and ip daddr, then concate both results. This concatenation is used to lookup for a matching of this the result in the map. This syntax may be compacted in future releases to support CIDR notation.

This could be easily implemented using a named map as well:

% nft add map tablename myMap { type ipv4_addr . ipv4_addr : verdict \; }
% nft add rule tablename chainname ip saddr and 255.255.255.0 . ip saddr and 255.255.255.0 vmap @myMap
% nft add element tablename myMap { 10.10.10.0 . 10.10.20.0 : accept }

Interfaces

The example below checks both input and output interfaces of a forwarded packet.

% nft add rule tablename chainname iif . oif vmap { eth0 . eth1 : accept }

Some ipset types

These ipset types can be implemented in nftables using concatenations. Probably more equivalences exists, it just a matter of combining data types. Of course, you could implement these as named maps/sets as well.

See examples in the moving from ipset to nftables page.