Guides and examples

Configuring an Internet Gateway

An Internet gateway is a host which is managing the access of a private (internal) network to the (external) Internet. When running Linux as a gateway host the correct setup of the required iptables rules is crucial. While there exist dedicated Linux distributions for this task such as OpenWRT or IPFire, it's also possible to use a regular Debian GNU/Linux system and configure it through DebOps. Here a short overview about the basic steps for a simple gateway configuration is given.

The gateway host should have at least two network interfaces connected to the respective networks. In this guide the interface named eth0 will be used as external untrusted interface and eth1 will be used as internal trusted interface.

To follow this guide you should be familiar with DebOps and the way to configure related Ansible variables. If you're not, you may first want to read the Getting Started guide.

Packet Forwarding

The configuration of packet forwarding is done on a per-interface basis. You can use the debops.ferm and debops.ifupdown Ansible roles to configure the respective firewall rules and kernel parameters, or use the debops.ifupdown role to configure network interfaces, which will include packet forwarding rules when necessary, for example for all bridge interfaces.

In case every connection traversing the network boundaries should be explicitly defined, set an empty rule list here:

ferm__rules_forward: []

On the other hand it might be useful to start with a less restrictive forwarding rule list which allows all outgoing traffic:

ferm__rules_forward:
  - chain: 'FORWARD'
    type: 'accept'
    outerface_present: '{{ ferm__external_interfaces }}'
    weight: '10'
    role: 'forward'
    role_weight: '20'
    name: 'external_out'
    comment: 'Forward outgoing traffic to other hosts'
    rule_state: '{{ "present" if (
                      (ferm__forward | d(ferm_forward) | bool) or
                      (ansible_local | d() and ansible_local.ferm | d() and
                       ansible_local.ferm.forward | bool))
                     else "absent" }}'

Once a packet was accepted by the firewall all related packets belonging to the same connection are accepted too. This is defined in the connection_tracking rule which is loaded as part of the ferm__default_rules rule list.

Port Forwarding

If the forward rules above are properly implemented, all external access to a host connected to the internal network is blocked. Still it might be necessary to allow external access to a specific internally hosted service such as a Web server. This can be done by forwarding a port or port range from the gateway's external interface to an internal host. Technically this is called DNAT (Destination Network Address Translation), where the original destination address of a network packet is rewritten to the internal host address.

  • To forward the HTTP port from the gateway to the internal host, a rule such as the following is required:

ferm__host_rules:
  - type: 'dmz'
    name: 'http-forward'
    domain: [ 'ip' ]
    public_ip: '{{ ansible_eth0.ipv4.address }}'
    private_ip: '{{ lookup("dig", "web.internal.example.com") }}'
    protocol: 'tcp'
    ports: [ 80 ]

Note

The 'dmz' type rule template won't modify the source address of a forwarded packet by default. This means that the original source address can still be identified at the internal receiver, however the route leading back to the source address must traverse the gateway again in order to successfully initiate connection tracking.

The optional snat_ip parameter can be used to configure source address translation (SNAT).

INPUT Rules for Services running on the Gateway Host

As an Internet gateway is usually a device which is running 24/7 and being a core part of the network infrastructure, people might want to run additional services on this host. In case these services are also managed by DebOps the respective Ansible roles will ensure that the required firewall rules are added to the ferm__dependent_rules rule list. By default access from all networks is allowed which is not always desired. Below it will be shown how this can be restricted to the internal network attached to eth1.

Example: dnsmasq

The debops.dnsmasq role is providing DNS and DHCP services. Obviously access to these services should only be allowed from the internal network.

  • Define the upstream (external) interface where access should be blocked:

    dnsmasq_upstream_interfaces: [ 'eth0' ]

  • Define the internal interface where the DNS and DHCP services will be provided. This setting would automatically define the necessary iptables INPUT rules for those services to be accessible from the internal network:

    dnsmasq_interfaces:
  - interface: 'eth1'
    name: 'gateway'
    dhcp_range_start: '10'
    dhcp_range_end: '-10'
    dhcp_lease: '24h'

Refer to the debops.dnsmasq role for details.

Example: nginx

Most other DebOps roles which manage applications are able to restrict access through the firewall based on source IP addresses and network ranges. This is typically done by defining a corresponding service_allow variable. In case of debops.nginx this configuration would look as following:

nginx_allow: [ '{{ ansible_eth1.ipv4.network }}/{{ ("0.0.0.0/" + ansible_eth1.ipv4.netmask) | ansible.utils.ipaddr("prefix") }}' ]

This will restrict access to the HTTP service running on the gateway host to the internal IPv4 network which is automatically defined using the ansible_eth1 host fact.

Restrict Outgoing Traffic

Many iptables setups are rather lax when it's about restricting outgoing traffic. By default DebOps will set the iptables OUTPUT policy to ACCEPT which will permit every outgoing connection attempt. However, it is always a good idea to also limit the connections which can be made from within a host, especially if the host is directly connected to the Internet.

Unfortunately debops.ferm doesn't provide any predefined rule lists to restrict outgoing traffic, therefore they need to be custom defined entirely. On the other hand this will be a good example for defining rule lists also for any other purpose.

  • First create an Ansible list with an individually chosen name which will hold the custom output rules. For every outgoing connection which should be allowed to the internal or external network a rule needs to be added. Every template described in the Rule types chapter can be used for the custom rules. The definition below is just a minimal example to show the procedure:

    ferm__custom_rules_filter_output:

  - type: 'accept'
    chain: 'OUTPUT'
    weight: '00'
    weight_class: 'loopback'
    comment: 'Allow connections to loopback'
    name: 'loopback_out'
    outerface: 'lo'
    target: 'ACCEPT'

  - type: 'accept'
    chain: 'OUTPUT'
    weight: '50'
    weight_class: 'any-service'
    comment: 'Allow connections to internal network'
    name: 'internal_out'
    outerface: 'eth1'
    target: 'ACCEPT'

  - type: 'accept'
    chain: 'OUTPUT'
    weight: '03'
    weight_class: 'filter-icmp'
    comment: 'Allow outgoing ICMP requests'
    name: 'icmp_out'
    protocol: 'icmp'
    outerface: 'eth0'
    target: 'ACCEPT'

  - type: 'accept'
    chain: 'OUTPUT'
    weight: '32'
    comment: 'Allow outgoing DNS traffic'
    name: 'dns_out'
    protocol: 'udp'
    dport: 53
    outerface: 'eth0'
    target: 'ACCEPT'

  - type: 'reject'
    chain: 'OUTPUT'
    weight_class: 'any-reject'
    name: 'reject_out'
    comment: 'Reject remaining outgoing traffic'

    The last rule is using The 'reject' type which will reject every packet not explicitly allowed. This will make it easier to figure out missing rules than if the packets would simply be dropped.

  • Reference the custom rule list in one of the main rule list variables ferm__rules, ferm__group_rules or ferm__host_rules. E.g.:

    ferm__host_rules: '{{ ferm__custom_rules_filter_output }}'

    If there are multiple custom rule lists, they can be concatenated with +.

  • Finally set the iptables OUTPUT policy to DROP:

    ferm__default_policy_output: 'DROP'

Block Port Scans

To block port scans there is a predefined rule block_portscans which is not enabled by default. It will remember source addresses which try to reach closed ports and completely blocks access from those addresses for a while. This behaviour can be enabled by setting ferm__mark_portscan:

ferm__mark_portscan: True

To make sure management access to the gateway is not suddenly blocked by the mentioned rule list, trusted addresses must be whitelisted. For example when trying out DebOps in a Vagrant environment the host running vagrant` should be added to the ferm__ansible_controllers variable. Otherwise vagrant ssh might suddenly be blocked by the portscan rule in case a machine port was mistakenly accessed where no service was running:

ferm__ansible_controllers: [ '192.168.121.1' ]

The host running DebOps doesn't explicitly need to be added here as it is automatically being whitelisted.