| .TH IPPOOL 5 |
| .SH NAME |
| ippool, ippool.conf \- IP Pool file format |
| .SH DESCRIPTION |
| The file ippool.conf is used with ippool(8) to configure address pools for |
| use with ipnat(8) and ipf(8). |
| .PP |
| There are four different types of address pools that can be configured |
| through ippool.conf. The various types are presented below with a brief |
| description of how they are used: |
| .PP |
| .HP |
| dstlist |
| .IP |
| destination list - is a collection of IP addresses with an optional |
| network interface name that can be used with either redirect (rdr) rules |
| in ipnat.conf(5) or as the destination in ipf.conf(5) for policy based |
| routing. |
| .HP |
| group-map |
| .IP |
| group maps - support the srcgrpmap and dstgrpmap call functions in |
| ipf.conf(5) by providing a list of addresses or networks rule group |
| numbers to start processing them with. |
| .HP |
| hash |
| .IP |
| hash tables - provide the means for performing a very efficient |
| lookup address or network when there is expected to be only one |
| exact match. These are best used with more static sets of addresses |
| so they can be sized optimally. |
| .HP |
| pool |
| .IP |
| address pools - are an alternative to hash tables that can perform just |
| as well in most circumstances. In addition, the address pools allow for |
| heirarchical matching, so it is possible to define a subnet as matching |
| but then exclude specific addresses from it. |
| .SS |
| Evolving Configuration |
| .PP |
| Over time the configuration syntax used by ippool.conf(5) has evolved. |
| Originally the syntax used was more verbose about what a particular |
| value was being used for, for example: |
| .PP |
| .nf |
| table role = ipf type = tree number = 100 |
| { 1.1.1.1/32; !2.2.0.0/16; 2.2.2.0/24; ef00::5/128; }; |
| .fi |
| .PP |
| This is rather long winded. The evolution of the configuration syntax |
| has also replaced the use of numbers with names, although numbers can |
| still be used as can be seen here: |
| .PP |
| .nf |
| pool ipf/tree (name "100";) |
| { 1.1.1.1/32; !2.2.0.0/16; 2.2.2.0/24; ef00::5/128; }; |
| .fi |
| .PP |
| Both of the above examples produce the same configuration in the kernel |
| for use with ipf.conf(5). |
| .PP |
| Newer options for use in ippool.conf(5) will only be offered in the new |
| configuration syntax and all output using "ippool -l" will also be in the |
| new configuration syntax. |
| .SS |
| IPFilter devices and pools |
| .PP |
| To cater to different administration styles, ipool.conf(5) allows you to |
| tie a pool to a specific role in IPFilter. The recognised role names are: |
| .HP |
| ipf |
| .IP |
| pools defined for role "ipf" are available for use with all rules that are |
| found in ipf.conf(5) except for auth rules. |
| .HP |
| nat |
| .IP |
| pools defined for role "nat" are available for use with all rules that are |
| found in ipnat.conf(5). |
| .HP |
| auth |
| .IP |
| pools defined for role "auth" are available only for use with "auth" rules |
| that are found in ipf.conf(5) |
| .HP |
| all |
| .IP |
| pools that are defined for the "all" role are available to all types of |
| rules, be they NAT rules in ipnat.conf(5) or firewall rules in ipf.conf(5). |
| .SH Address Pools |
| .PP |
| An address pool can be used in ipf.conf(5) and ipnat.conf(5) for matching |
| the source or destination address of packets. They can be referred to either |
| by name or number and can hold an arbitrary number of address patterns to |
| match. |
| .PP |
| An address pool is considered to be a "tree type". In the older configuration |
| style, it was necessary to have "type=tree" in ippool.conf(5). In the new |
| style configuration, it follows the IPFilter device with which the pool |
| is being configured. |
| Now it is the default if left out. |
| .PP |
| For convenience, both IPv4 and IPv6 addresses can be stored in the same |
| address pool. It should go without saying that either type of packet can |
| only ever match an entry in a pool that is of the same address family. |
| .PP |
| The address pool searches the list of addresses configured for the best |
| match. The "best match" is considered to be the match that has the highest |
| number of bits set in the mask. Thus if both 2.2.0.0/16 and 2.2.2.0/24 are |
| present in an address pool, the addres 2.2.2.1 will match 2.2.2.0/24 and |
| 2.2.1.1 will match 2.2.0.0/16. The reason for this is to allow exceptions |
| to be added through the use of negative matching. In the following example, |
| the pool contains "2.2.0.0/16" and "!2.2.2.0/24", meaning that all packets |
| that match 2.2.0.0/16, except those that match 2.2.2.0/24, will be considered |
| as a match for this pool. |
| .PP |
| table role = ipf type = tree number = 100 |
| { 1.1.1.1/32; 2.2.0.0/16; !2.2.2.0/24; ef00::5/128; }; |
| .PP |
| For the sake of clarity and to aid in managing large numbers of addresses |
| inside address pools, it is possible to specify a location to load the |
| addresses from. To do this simply use a "file://" URL where you would |
| specify an actual IP address. |
| .PP |
| .nf |
| pool ipf/tree (name rfc1918;) { file:///etc/ipf/rfc1918; }; |
| .fi |
| .PP |
| The contents of the file might look something like this: |
| .PP |
| .nf |
| # RFC 1918 networks |
| 10.0.0.0/8 |
| !127.0.0.0/8 |
| 172.16.0.0/12 |
| 192.168.0.0/24 |
| .fi |
| .PP |
| In this example, the inclusion of the line "!127.0.0.0/8" is, strictly |
| speaking not correct and serves only as an example to show that negative |
| matching is also supported in this file. |
| .PP |
| Another format that ippool(8) recognises for input from a file is that |
| from whois servers. In the following example, output from a query to a |
| WHOIS server for information about which networks are associated with |
| the name "microsoft" has been saved in a file named "ms-networks". |
| There is no need to modify the output from the whois server, so using |
| either the whois command or dumping data directly from it over a TCP |
| connection works perfectly file as input. |
| .PP |
| .nf |
| pool ipf/tree (name microsoft;) { whois file "/etc/ipf/ms-networks"; }; |
| .fi |
| .PP |
| And to then block all packets to/from networks defined in that file, |
| a rule like this might be used: |
| .PP |
| .nf |
| block in from pool/microsoft to any |
| .fi |
| .PP |
| Note that there are limitations on the output returned by whois servers |
| so be aware that their output may not be 100% perfect for your goal. |
| .SH Destination Lists |
| .PP |
| Destination lists are provided for use primarily with NAT redirect rules |
| (rdr). Their purpose is to allow more sophisticated methods of selecting |
| which host to send traffic to next than the simple round-robin technique |
| that is present with with "round-robin" rules in ipnat.conf(5). |
| .PP |
| When building a list of hosts to use as a redirection list, it is |
| necessary to list each host to be used explicitly. Expressing a |
| collection of hosts as a range or a subnet is not supported. With each |
| address it is also possible to specify a network interface name. The |
| network interface name is ignored by NAT when using destination lists. |
| The network itnerface name is currently only used with policy based |
| routing (use of "to"/"dup-to" in ipf.conf(5)). |
| .PP |
| Unlike the other directives that can be expressed in this file, destination |
| lists must be written using the new configuration syntax. Each destination |
| list must have a name associated with it and a next hop selection policy. |
| Some policies have further options. The currently available selection |
| policies are: |
| .HP |
| round-robin |
| .IP |
| steps through the list of hosts configured with the destination list |
| one by one |
| .HP |
| random |
| .IP |
| the next hop is chosen by random selection from the list available |
| .HP |
| src-hash |
| .IP |
| a hash is made of the source address components of the packet |
| (address and port number) and this is used to select which |
| next hop address is used |
| .HP |
| dst-hash |
| .IP |
| a hash is made of the destination address components of the packet |
| (address and port number) and this is used to select which |
| next hop address is used |
| .HP |
| hash |
| .IP |
| a hash is made of all the address components in the packet |
| (addresses and port numbers) and this is used to select which |
| next hop address is used |
| .HP |
| weighted |
| .IP |
| selecting a weighted policy for destination selection needs further |
| clarification as to what type of weighted selection will be used. |
| The sub-options to a weighted policy are: |
| .RS |
| .HP |
| connection |
| .IP |
| the host that has received the least number of connections is selected |
| to be the next hop. When all hosts have the same connection count, |
| the last one used will be the next address selected. |
| .RE |
| .PP |
| The first example here shows 4 destinations that are used with a |
| round-robin selection policy. |
| .PP |
| .nf |
| pool nat/dstlist (name servers; policy round-robin;) |
| { 1.1.1.2; 1.1.1.4; 1.1.1.5; 1.1.1.9; }; |
| .fi |
| .PP |
| In the following example, the destination is chosen by whichever has |
| had the least number of connections. By placing the interface name |
| with each address and saying "all/dstlist", the destination list can |
| be used with both ipnat.conf(5) and ipf.conf(5). |
| .PP |
| .nf |
| pool all/dstlist (name servers; policy weighted connection;) |
| { bge0:1.1.1.2; bge0:1.1.1.4; bge1:1.1.1.5; bge1:1.1.1.9; }; |
| .fi |
| .SH Group maps |
| .PP |
| Group maps are provided to allow more efficient processing of packets |
| where there are a larger number of subnets and groups of rules for those |
| subnets. Group maps are used with "call" rules in ipf.conf(5) that |
| use the "srcgrpmap" and "dstgrpmap" functions. |
| .PP |
| A group map declaration must mention which group is the default group |
| for all matching addresses to be applied to. Then inside the list of |
| addresses and networks for the group, each one may optionally have |
| a group number associated with it. A simple example like this, where |
| the first two entries would map to group 2020 but 5.0.0.0/8 sends |
| rule processing to group 2040. |
| .PP |
| .nf |
| group-map out role = ipf number = 2010 group = 2020 |
| { 2.2.2.2/32; 4.4.0.0/16; 5.0.0.0/8, group = 2040; }; |
| .fi |
| .PP |
| An example that outlines the real purpose of group maps is below, |
| where each one of the 12 subnets is mapped to a different group |
| number. This might be because each subnet has its own policy and |
| rather than write a list of twelve rules in ipf.conf(5) that match |
| the subnet and branch off with a head statement, a single rule can |
| be used with this group map to achieve the same result. |
| .PP |
| .nf |
| group-map ( name "2010"; in; ) |
| { 192.168.1.0/24, group = 10010; 192.168.2.0/24, group = 10020; |
| 192.168.3.0/24, group = 10030; 192.168.4.0/24, group = 10040; |
| 192.168.5.0/24, group = 10050; 192.168.6.0/24, group = 10060; |
| 192.168.7.0/24, group = 10070; 192.168.8.0/24, group = 10080; |
| 192.168.9.0/24, group = 10090; 192.168.10.0/24, group = 10100; |
| 192.168.11.0/24, group = 10110; 192.168.12.0/24, group = 10120; |
| }; |
| .fi |
| .PP |
| The limitation with group maps is that only the source address or the |
| destination address can be used to map the packet to the starting group, |
| not both, in your ipf.conf(5) file. |
| .SH Hash Tables |
| .PP |
| The hash table is operationally similar to the address pool. It is |
| used as a store for a collection of address to match on, saving the |
| need to write a lengthy list of rules. As with address pools, searching |
| will attempt to find the best match - an address specification with the |
| largest contiguous netmask. |
| .PP |
| Hash tables are best used where the list of addresses, subnets and |
| networks is relatively static, which is something of a contrast to |
| the address pool that can work with either static or changing |
| address list sizes. |
| .PP |
| Further work is still needed to have IPFilter correctly size and tune |
| the hash table to optimise searching. The goal is to allow for small to |
| medium sized tables to achieve close to O(1) for either a positive or |
| negative match, in contrast to the address pool, which is O(logn). |
| .PP |
| The following two examples build the same table in the kernel, using |
| the old configuration format (first) and the new one (second). |
| .PP |
| .nf |
| table role=all type=hash name=servers size=5 |
| { 1.1.1.2/32; 1.1.1.3/32; 11.23.44.66/32; }; |
| |
| pool all/hash (name servers; size 5;) |
| { 1.1.1.2; 1.1.1.3; 11.23.44.66; }; |
| .fi |
| .SH FILES |
| /dev/iplookup |
| .br |
| /etc/ippool.conf |
| .br |
| /etc/hosts |
| .SH SEE ALSO |
| ippool(8), hosts(5), ipf(5), ipf(8), ipnat(8) |