Shorewall Setup Guide Tom Eastep 2004-02-04 2001-2004 Thomas M. Eastep Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.2 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover, and with no Back-Cover Texts. A copy of the license is included in the section entitled GNU Free Documentation License.
Introduction This guide is intended for users who are setting up Shorewall in an environment where a set of public IP addresses must be managed or who want to know more about Shorewall than is contained in the single-address guides. Because the range of possible applications is so broad, the Guide will give you general guidelines and will point you to other resources as necessary. If you run LEAF Bering, your Shorewall configuration is NOT what I release -- I suggest that you consider installing a stock Shorewall lrp from the shorewall.net site before you proceed. Shorewall requires that the iproute/iproute2 package be installed (on RedHat, the package is called iproute). You can tell if this package is installed by the presence of an ip program on your firewall system. As root, you can use the which command to check for this program: [root@gateway root]# which ip /sbin/ip [root@gateway root]# I recommend that you first read through the guide to familiarize yourself with what's involved then go back through it again making your configuration changes. Points at which configuration changes are recommended are flagged with . If you edit your configuration files on a Windows system, you must save them as Unix files if your editor supports that option or you must run them through dos2unix before trying to use them with Shorewall. Similarly, if you copy a configuration file from your Windows hard drive to a floppy disk, you must run dos2unix against the copy before using it with Shorewall. Windows Version of dos2unix Linux Version of dos2unix
Shorewall Concepts The configuration files for Shorewall are contained in the directory /etc/shorewall -- for most setups, you will only need to deal with a few of these as described in this guide. Skeleton files are created during the Shorewall Installation Process. As each file is introduced, I suggest that you look through the actual file on your system -- each file contains detailed configuration instructions and some contain default entries. Shorewall views the network where it is running as being composed of a set of zones. In the default installation, the following zone names are used: Zones Name Description net The Internet loc Your Local Network dmz Demilitarized Zone
Zones are defined in the file /etc/shorewall/zones. Shorewall also recognizes the firewall system as its own zone - by default, the firewall itself is known as fw but that may be changed in the /etc/shorewall/shorewall.conf file. In this guide, the default name (fw) will be used. With the exception of fw, Shorewall attaches absolutely no meaning to zone names. Zones are entirely what YOU make of them. That means that you should not expect Shorewall to do something special because this is the internet zone or because that is the DMZ. Edit the /etc/shorewall/zones file and make any changes necessary. Rules about what traffic to allow and what traffic to deny are expressed in terms of zones. You express your default policy for connections from one zone to another zone in the /etc/shorewall/policy file. You define exceptions to those default policies in the /etc/shorewall/rules. Shorewall is built on top of the Netfilter kernel facility. Netfilter implements a connection tracking function that allows what is often referred to as stateful inspection of packets. This stateful property allows firewall rules to be defined in terms of connections rather than in terms of packets. With Shorewall, you: Identify the source zone. Identify destination zone. If the POLICY from the client's zone to the server's zone is what you want for this client/server pair, you need do nothing further. If the POLICY is not what you want, then you must add a rule. That rule is expressed in terms of the client's zone and the server's zone. Just because connections of a particular type are allowed from zone A to the firewall and are also allowed from the firewall to zone B DOES NOT mean that these connections are allowed from zone A to zone B. It rather means that you can have a proxy running on the firewall that accepts a connection from zone A and then establishes its own separate connection from the firewall to zone B. For each connection request entering the firewall, the request is first checked against the /etc/shorewall/rules file. If no rule in that file matches the connection request then the first policy in /etc/shorewall/policy that matches the request is applied. If that policy is REJECT or DROP the request is first checked against the rules in /etc/shorewall/common.def. The default /etc/shorewall/policy file has the following policies: #SOURCE ZONE DESTINATION ZONE POLICY LOG LIMIT:BURST # LEVEL fw net ACCEPT net all DROP info all all REJECT info The above policy will: allow all connection requests from your local network to the internet drop (ignore) all connection requests from the internet to your firewall or local network and log a message at the info level (here is a description of log levels). reject all other connection requests and log a message at the info level. When a request is rejected, the firewall will return an RST (if the protocol is TCP) or an ICMP port-unreachable packet for other protocols. At this point, edit your /etc/shorewall/policy and make any changes that you wish.
Network Interfaces For the remainder of this guide, we'll refer to the following diagram. While it may not look like your own network, it can be used to illustrate the important aspects of Shorewall configuration. In this diagram: The DMZ Zone consists of systems DMZ 1 and DMZ 2. A DMZ is used to isolate your internet-accessible servers from your local systems so that if one of those servers is compromised, you still have the firewall between the compromised system and your local systems. The Local Zone consists of systems Local 1, Local 2 and Local 3. All systems from the ISP outward comprise the Internet Zone. The simplest way to define zones is to simply associate the zone name (previously defined in /etc/shorewall/zones) with a network interface. This is done in the /etc/shorewall/interfaces file. The firewall illustrated above has three network interfaces. Where Internet connectivity is through a cable or DSL Modem, the External Interface will be the Ethernet adapter that is connected to that Modem (e.g., eth0) unless you connect via Point-to-Point Protocol over Ethernet (PPPoE) or Point-to-Point Tunneling Protocol (PPTP) in which case the External Interface will be a ppp interface (e.g., ppp0). If you connect via a regular modem, your External Interface will also be ppp0. If you connect using ISDN, you external interface will be ippp0. If your external interface is ppp0 or ippp0 then you will want to set CLAMPMSS=yes in /etc/shorewall/shorewall.conf. Your Local Interface will be an Ethernet adapter (eth0, eth1 or eth2) and will be connected to a hub or switch. Your local computers will be connected to the same switch (note: If you have only a single local system, you can connect the firewall directly to the computer using a cross-over cable). Your DMZ Interface will also be an Ethernet adapter (eth0, eth1 or eth2) and will be connected to a hub or switch. Your DMZ computers will be connected to the same switch (note: If you have only a single DMZ system, you can connect the firewall directly to the computer using a cross-over cable). Do not connect the internal and external interface to the same hub or switch except for testing AND you are running Shorewall version 1.4.7 or later. When using these recent versions, you can test using this kind of configuration if you specify the arp_filter option in /etc/shorewall/interfaces for all interfaces connected to the common hub/switch. Using such a setup with a production firewall is strongly recommended against. For the remainder of this Guide, we will assume that: The External Interface is eth0. The Local Interface eth1. The DMZ Interface eth2. The Shorewall default configuration does not define the contents of any zone. To define the above configuration using the /etc/shorewall/interfaces file, that file would might contain: #ZONE INTERFACE BROADCAST OPTIONS net eth0 detect rfc1918 loc eth1 detect dmz eth2 detect Edit the /etc/shorewall/interfaces file and define the network interfaces on your firewall and associate each interface with a zone. If you have a zone that is interfaced through more than one interface, simply include one entry for each interface and repeat the zone name as many times as necessary. Multiple Interfaces to a Zone #ZONE INTERFACE BROADCAST OPTIONS net eth0 detect rfc1918 loc eth1 detect loc eth2 detect You may define more complicated zones using the /etc/shorewall/hosts file but in most cases, that isn't necessary.
Addressing, Subnets and Routing Normally, your ISP will assign you a set of Public IP addresses. You will configure your firewall's external interface to use one of those addresses permanently and you will then have to decide how you are going to use the rest of your addresses. Before we tackle that question though, some background is in order. If you are thoroughly familiar with IP addressing and routing, you may go to the next section. The following discussion barely scratches the surface of addressing and routing. If you are interested in learning more about this subject, I highly recommend IP Fundamentals: What Everyone Needs to Know about Addressing & Routing, Thomas A. Maufer, Prentice-Hall, 1999, ISBN 0-13-975483-0.
IP Addresses IP version 4 (IPv4) addresses are 32-bit numbers. The notation w.x.y.z refers to an address where the high-order byte has value w, the next byte has value x, etc. If we take the address 192.0.2.14 and express it in hexadecimal, we get: C0.00.02.0Eor looking at it as a 32-bit integer C000020E
Subnets You will still hear the terms Class A network, Class B network and Class C network. In the early days of IP, networks only came in three sizes (there were also Class D networks but they were used differently): Class A - netmask 255.0.0.0, size = 2 ** 24 Class B - netmask 255.255.0.0, size = 2 ** 16 Class C - netmask 255.255.255.0, size = 256 The class of a network was uniquely determined by the value of the high order byte of its address so you could look at an IP address and immediately determine the associated netmask. The netmask is a number that when logically ANDed with an address isolates the network number; the remainder of the address is the host number. For example, in the Class C address 192.0.2.14, the network number is hex C00002 and the host number is hex 0E. As the internet grew, it became clear that such a gross partitioning of the 32-bit address space was going to be very limiting (early on, large corporations and universities were assigned their own class A network!). After some false starts, the current technique of subnetting these networks into smaller subnetworks evolved; that technique is referred to as Classless InterDomain Routing (CIDR). Today, any system that you are likely to work with will understand CIDR and Class-based networking is largely a thing of the past. A subnetwork (often referred to as a subnet) is a contiguous set of IP addresses such that: The number of addresses in the set is a power of 2; and The first address in the set is a multiple of the set size. The first address in the subnet is reserved and is referred to as the subnet address. The last address in the subnet is reserved as the subnet's broadcast address. As you can see by this definition, in each subnet of size n there are (n - 2) usable addresses (addresses that can be assigned to hosts). The first and last address in the subnet are used for the subnet address and subnet broadcast address respectively. Consequently, small subnetworks are more wasteful of IP addresses than are large ones. Since n is a power of two, we can easily calculate the Natural Logarithm (log2) of n. For the more common subnet sizes, the size and its natural logarithm are given in the following table: Natural Logarithms n log2 n (32 - log2 n) 8 3 29 16 4 28 32 5 27 64 6 26 128 7 25 256 8 24 512 9 23 1024 10 22 2048 11 21 4096 12 20 8192 13 19 16384 14 18 32768 15 17 65536 16 16
You will notice that the above table also contains a column for (32 - log2 n). That number is the Variable Length Subnet Mask (VLSM) for a network of size n. From the above table, we can derive the following one which is a little easier to use. VLSM Subnet Size VLSM Subnet Mask 8 /29 255.255.255.248 16 /28 255.255.255.240 32 /27 255.255.255.224 64 /26 255.255.255.192 128 /25 255.255.255.128 256 /24 255.255.255.0 512 /23 255.255.254.0 1024 /22 255.255.252.0 2048 /21 255.255.248.0 4096 /20 255.255.240.0 8192 /19 255.255.224.0 16384 /18 255.255.192.0 32768 /17 255.255.128.0 65536 /16 255.255.0.0 2 ** 24 /8 255.0.0.0
Notice that the VLSM is written with a slash (/) -- you will often hear a subnet of size 64 referred to as a slash 26 subnet and one of size 8 referred to as a slash 29. The subnet's mask (also referred to as its netmask) is simply a 32-bit number with the first VLSM bits set to one and the remaining bits set to zero. For example, for a subnet of size 64, the subnet mask has 26 leading one bits: 11111111111111111111111111000000 = FFFFFFC0 = FF.FF.FF.C0 = 255.255.255.192The subnet mask has the property that if you logically AND the subnet mask with an address in the subnet, the result is the subnet address. Just as important, if you logically AND the subnet mask with an address outside the subnet, the result is NOT the subnet address. As we will see below, this property of subnet masks is very useful in routing. For a subnetwork whose address is a.b.c.d and whose Variable Length Subnet Mask is /v, we denote the subnetwork as a.b.c.d/v using CIDR Notation. Example: Subnet Subnet: 10.10.10.0 - 10.10.10.127 Subnet Size: 128 Subnet Address: 10.10.10.0 Broadcast Address: 10.10.10.127 CIDR Notation: 10.10.10.0/25
There are two degenerate subnets that need mentioning; namely, the subnet with one member and the subnet with 2 ** 32 members. /32 and /0 Subnet Size VLSM Length Subnet Mask CIDR Notation 1 32 255.255.255.255 a.b.c.d/32 32 0 0.0.0.0 0.0.0.0/0
So any address a.b.c.d may also be written a.b.c.d/32 and the set of all possible IP addresses is written 0.0.0.0/0. Later in this guide, you will see the notation a.b.c.d/v used to describe the ip configuration of a network interface (the ip utility also uses this syntax). This simply means that the interface is configured with ip address a.b.c.d and with the netmask that corresponds to VLSM /v. 192.0.2.65/29 The interface is configured with IP address 192.0.2.65 and netmask 255.255.255.248. Beginning with Shorewall 1.4.6, /sbin/shorewall supports an ipcalc command that automatically calculates information about a [sub]network. Using the <command>ipcalc </command>command shorewall ipcalc 10.10.10.0/25 CIDR=10.10.10.0/25 NETMASK=255.255.255.128 NETWORK=10.10.10.0 BROADCAST=10.10.10.127 Using the <command>ipcalc</command> command shorewall ipcalc 10.10.10.0 255.255.255.128 CIDR=10.10.10.0/25 NETMASK=255.255.255.128 NETWORK=10.10.10.0 BROADCAST=10.10.10.127
Routing One of the purposes of subnetting is that it forms the basis for routing. Here's the routing table on my firewall (compressed for PDF): [root@gateway root]# netstat -nr Kernel IP routing table Destination Gateway Genmask Flgs MSS Win irtt Iface 192.168.9.1 0.0.0.0 255.255.255.255 UH 40 0 0 texas 206.124.146.177 0.0.0.0 255.255.255.255 UH 40 0 0 eth1 206.124.146.180 0.0.0.0 255.255.255.255 UH 40 0 0 eth3 192.168.3.0 0.0.0.0 255.255.255.0 U 40 0 0 eth3 192.168.2.0 0.0.0.0 255.255.255.0 U 40 0 0 eth1 192.168.1.0 0.0.0.0 255.255.255.0 U 40 0 0 eth2 206.124.146.0 0.0.0.0 255.255.255.0 U 40 0 0 eth0 192.168.9.0 192.0.2.223 255.255.255.0 UG 40 0 0 texas 127.0.0.0 0.0.0.0 255.0.0.0 U 40 0 0 lo 0.0.0.0 206.124.146.254 0.0.0.0 UG 40 0 0 eth0 [root@gateway root]# The device texas is a GRE tunnel to a peer site in the Dallas, Texas area. The first three routes are host routes since they indicate how to get to a single host. In the netstat output this can be seen by the Genmask (Subnet Mask) of 255.255.255.255 and the H in the Flags column. The remainder are net routes since they tell the kernel how to route packets to a subnetwork. The last route is the default route and the gateway mentioned in that route is called the default gateway. When the kernel is trying to send a packet to IP address A, it starts at the top of the routing table and: A is logically ANDed with the Genmask value in the table entry. The result is compared with the Destination value in the table entry. If the result and the Destination value are the same, then: If the Gateway column is non-zero, the packet is sent to the gateway over the interface named in the Iface column. Otherwise, the packet is sent directly to A over the interface named in the iface column. Otherwise, the above steps are repeated on the next entry in the table. Since the default route matches any IP address (A LAND 0.0.0.0 = 0.0.0.0), packets that don't match any of the other routing table entries are sent to the default gateway which is usually a router at your ISP. Lets take an example. Suppose that we want to route a packet to 192.168.1.5. That address clearly doesn't match any of the host routes in the table but if we logically and that address with 255.255.255.0, the result is 192.168.1.0 which matches this routing table entry: 192.168.1.0 0.0.0.0 255.255.255.0 U 40 0 0 eth2 So to route a packet to 192.168.1.5, the packet is sent directly over eth2. One more thing needs to be emphasized -- all outgoing packet are sent using the routing table and reply packets are not a special case. There seems to be a common mis-conception whereby people think that request packets are like salmon and contain a genetic code that is magically transferred to reply packets so that the replies follow the reverse route taken by the request. That isn't the case; the replies may take a totally different route back to the client than was taken by the requests -- they are totally independent.
Address Resolution Protocol (ARP) When sending packets over Ethernet, IP addresses aren't used. Rather Ethernet addressing is based on Media Access Control (MAC) addresses. Each Ethernet device has it's own unique MAC address which is burned into a PROM on the device during manufacture. You can obtain the MAC of an Ethernet device using the ip utility: [root@gateway root]# ip addr show eth0 2: eth0: <BROADCAST,MULTICAST,UP> mtu 1500 qdisc htb qlen 100 link/ether 02:00:08:e3:fa:55 brd ff:ff:ff:ff:ff:ff inet 206.124.146.176/24 brd 206.124.146.255 scope global eth0 inet 206.124.146.178/24 brd 206.124.146.255 scope global secondary eth0 inet 206.124.146.179/24 brd 206.124.146.255 scope global secondary eth0 [root@gateway root]# As you can see from the above output, the MAC is 6 bytes (48 bits) wide. A card's MAC is usually also printed on a label attached to the card itself. Because IP uses IP addresses and Ethernet uses MAC addresses, a mechanism is required to translate an IP address into a MAC address; that is the purpose of the Address Resolution Protocol (ARP). Here is ARP in action: [root@gateway root]# tcpdump -nei eth2 arp tcpdump: listening on eth2 09:56:49.766757 2:0:8:e3:4c:48 0:6:25:aa:8a:f0 arp 42: arp who-has 192.168.1.19 tell 192.168.1.254 09:56:49.769372 0:6:25:aa:8a:f0 2:0:8:e3:4c:48 arp 60: arp reply 192.168.1.19 is-at 0:6:25:aa:8a:f0 2 packets received by filter 0 packets dropped by kernel [root@gateway root]# In this exchange, 192.168.1.254 (MAC 2:0:8:e3:4c:48) wants to know the MAC of the device with IP address 192.168.1.19. The system having that IP address is responding that the MAC address of the device with IP address 192.168.1.19 is 0:6:25:aa:8a:f0. In order to avoid having to exchange ARP information each time that an IP packet is to be sent, systems maintain an ARP cache of IP<->MAC correspondences. You can see the ARP cache on your system (including your Windows system) using the arp command: [root@gateway root]# arp -na ? (206.124.146.177) at 00:A0:C9:15:39:78 [ether] on eth1 ? (192.168.1.3) at 00:A0:CC:63:66:89 [ether] on eth2 ? (192.168.1.5) at 00:A0:CC:DB:31:C4 [ether] on eth2 ? (206.124.146.254) at 00:03:6C:8A:18:38 [ether] on eth0 ? (192.168.1.19) at 00:06:25:AA:8A:F0 [ether] on eth2 The leading question marks are a result of my having specified the n option (Windows arp doesn't allow that option) which causes the arp program to forego IP->DNS name translation. Had I not given that option, the question marks would have been replaced with the FQDN corresponding to each IP address. Notice that the last entry in the table records the information we saw using tcpdump above.
RFC 1918 IP addresses are allocated by the Internet Assigned Number Authority (IANA) who delegates allocations on a geographic basis to Regional Internet Registries (RIRs). For example, allocation for the Americas and for sub-Sahara Africa is delegated to the American Registry for Internet Numbers (ARIN). These RIRs may in turn delegate to national registries. Most of us don't deal with these registrars but rather get our IP addresses from our ISP. It's a fact of life that most of us can't afford as many Public IP addresses as we have devices to assign them to so we end up making use of Private IP addresses. RFC 1918 reserves several IP address ranges for this purpose: 10.0.0.0 - 10.255.255.255 172.16.0.0 - 172.31.255.255 192.168.0.0 - 192.168.255.255 The addresses reserved by RFC 1918 are sometimes referred to as non-routable because the Internet backbone routers don't forward packets which have an RFC-1918 destination address. This is understandable given that anyone can select any of these addresses for their private use. When selecting addresses from these ranges, there's a couple of things to keep in mind: As the IPv4 address space becomes depleted, more and more organizations (including ISPs) are beginning to use RFC 1918 addresses in their infrastructure. You don't want to use addresses that are being used by your ISP or by another organization with whom you want to establish a VPN relationship. So it's a good idea to check with your ISP to see if they are using (or are planning to use) private addresses before you decide the addresses that you are going to use. In this document, external real IP addresses are of the form 192.0.2.x. 192.0.2.0/24 is reserved by RFC 3330 for use as public IP addresses in printed examples. These addresses are not to be confused with addresses in 192.168.0.0/16; as described above, these addresses are reserved by RFC 1918 for private use.
Setting Up Your Network The choice of how to set up your network depends primarily on how many Public IP addresses you have vs. how many addressable entities you have in your network. Regardless of how many addresses you have, your ISP will handle that set of addresses in one of two ways: Routed - Traffic to any of your addresses will be routed through a single gateway address. This will generally only be done if your ISP has assigned you a complete subnet (/29 or larger). In this case, you will assign the gateway address as the IP address of your firewall/router's external interface. Non-routed - Your ISP will send traffic to each of your addresses directly. In the subsections that follow, we'll look at each of these separately. Before we begin, there is one thing for you to check: If you are using the Debian package, please check your shorewall.conf file to ensure that the following are set correctly; if they are not, change them appropriately: NAT_ENABLED=Yes (Shorewall versions earlier than 1.4.6) IP_FORWARDING=On
Routed Let's assume that your ISP has assigned you the subnet 192.0.2.64/28 routed through 192.0.2.65. That means that you have IP addresses 192.0.2.64 - 192.0.2.79 and that your firewall's external IP address is 192.0.2.65. Your ISP has also told you that you should use a netmask of 255.255.255.0 (so your /28 is part of a larger /24). With this many IP addresses, you are able to subnet your /28 into two /29's and set up your network as shown in the following diagram. Here, the DMZ comprises the subnet 192.0.2.64/29 and the Local network is 192.0.2.72/29. The default gateway for hosts in the DMZ would be configured to 192.0.2.66 and the default gateway for hosts in the local network would be 192.0.2.73. Notice that this arrangement is rather wasteful of public IP addresses since it is using 192.0.2.64 and 192.0.2.72 for subnet addresses, 192.0.2.71 and 192.0.2.79 for subnet broadcast addresses and 192.0.2.66 and 168.0.2.73 for internal addresses on the firewall/router. Nevertheless, it shows how subnetting can work and if we were dealing with a /24 rather than a /28 network, the use of 6 IP addresses out of 256 would be justified because of the simplicity of the setup. The astute reader may have noticed that the Firewall/Router's external interface is actually part of the DMZ subnet (192.0.2.64/29). What if DMZ 1 (192.0.2.67) tries to communicate with 192.0.2.65? The routing table on DMZ 1 will look like this: Kernel IP routing table Destination Gateway Genmask Flags MSS Window irtt Iface 192.0.2.64 0.0.0.0 255.255.255.248 U 40 0 0 eth0 0.0.0.0 192.0.2.66 0.0.0.0 UG 40 0 0 eth0 This means that DMZ 1 will send an ARP who-has 192.0.2.65 request and no device on the DMZ Ethernet segment has that IP address. Oddly enough, the firewall will respond to the request with the MAC address of its DMZ Interface!! DMZ 1 can then send Ethernet frames addressed to that MAC address and the frames will be received (correctly) by the firewall/router. It is this rather unexpected ARP behavior on the part of the Linux Kernel that prompts the warning earlier in this guide regarding the connecting of multiple firewall/router interfaces to the same hub or switch. When an ARP request for one of the firewall/router's IP addresses is sent by another system connected to the hub/switch, all of the firewall's interfaces that connect to the hub/switch can respond! It is then a race as to which here-is response reaches the sender first.
Non-routed If you have the above situation but it is non-routed, you can configure your network exactly as described above with one additional twist; simply specify the proxyarp option on all three firewall interfaces in the /etc/shorewall/interfaces file. Most of us don't have the luxury of having enough public IP addresses to set up our networks as shown in the preceding example (even if the setup is routed). For the remainder of this section, assume that your ISP has assigned you IP addresses 192.0.2.176-180 and has told you to use netmask 255.255.255.0 and default gateway 192.0.2.254. Clearly, that set of addresses doesn't comprise a subnetwork and there aren't enough addresses for all of the network interfaces. There are four different techniques that can be used to work around this problem. Source Network Address Translation (SNAT). Destination Network Address Translation (DNAT) also known as Port Forwarding. Proxy ARP. Network Address Translation (NAT) also referred to as One-to-one NAT. Often a combination of these techniques is used. Each of these will be discussed in the sections that follow.
SNAT With SNAT, an internal LAN segment is configured using RFC 1918 addresses. When a host A on this internal segment initiates a connection to host B on the internet, the firewall/router rewrites the IP header in the request to use one of your public IP addresses as the source address. When B responds and the response is received by the firewall, the firewall changes the destination address back to the RFC 1918 address of A and forwards the response back to A. Let's suppose that you decide to use SNAT on your local zone and use public address 192.0.2.176 as both your firewall's external IP address and the source IP address of internet requests sent from that zone. The local zone has been subnetted as 192.168.201.0/29 (netmask 255.255.255.248). The systems in the local zone would be configured with a default gateway of 192.168.201.1 (the IP address of the firewall's local interface). SNAT is configured in Shorewall using the /etc/shorewall/masq file. #INTERFACE SUBNET ADDRESS eth0 192.168.201.0/29 192.0.2.176 This example used the normal technique of assigning the same public IP address for the firewall external interface and for SNAT. If you wanted to use a different IP address, you would either have to use your distributions network configuration tools to add that IP address to the external interface or you could set ADD_SNAT_ALIASES=Yes in /etc/shorewall/shorewall.conf and Shorewall will add the address for you.
DNAT When SNAT is used, it is impossible for hosts on the internet to initiate a connection to one of the internal systems since those systems do not have a public IP address. DNAT provides a way to allow selected connections from the internet. Suppose that your daughter wants to run a web server on her system Local 3. You could allow connections to the internet to her server by adding the following entry in /etc/shorewall/rules: #ACTION SOURCE DEST PROTO DEST SOURCE ORIGINAL # PORT(S) PORT(S) DEST DNAT net loc:192.168.201.4 tcp www If one of your daughter's friends at address A wants to access your daughter's server, she can connect to http://192.0.2.176 (the firewall's external IP address) and the firewall will rewrite the destination IP address to 192.168.201.4 (your daughter's system) and forward the request. When your daughter's server responds, the firewall will rewrite the source address back to 192.0.2.176 and send the response back to A. This example used the firewall's external IP address for DNAT. You can use another of your public IP addresses but Shorewall will not add that address to the firewall's external interface for you.
Proxy ARP The idea behind Proxy ARP is that: A host H behind your firewall is assigned one of your public IP addresses (A), and is assigned the same netmask (M) as the firewall's external interface. The firewall responds to ARP who has requests for A. When H A andissues an ARP who has request for an address in the subnetwork defined by M, the firewall will respond (with the MAC if the firewall interface) to H. Let us suppose that we decide to use Proxy ARP on the DMZ in our example network. Here, we've assigned the IP addresses 192.0.2.177 to system DMZ 1 and 192.0.2.178 to DMZ 2. Notice that we've just assigned an arbitrary RFC 1918 IP address and subnet mask to the DMZ interface on the firewall. That address and netmask isn't relevant - just be sure it doesn't overlap another subnet that you've defined. The Shorewall configuration of Proxy ARP is done using the/etc/shorewall/proxyarp file. #ADDRESS EXTERNAL INTERFACE HAVE ROUTE 192.0.2.177 eth2 eth0 No 192.0.2.178 eth2 eth0 No Because the HAVE ROUTE column contains No, Shorewall will add host routes thru eth2 to 192.0.2.177 and 192.0.2.178. The ethernet interfaces on DMZ 1 and DMZ 2 should be configured to have the IP addresses shown but should have the same default gateway as the firewall itself -- namely 192.0.2.254. In other words, they should be configured just like they would be if they were parallel to the firewall rather than behind it. Do not add the Proxy ARP'ed address(es) (192.0.2.177 and 192.0.2.178 in the above example) to the external interface (eth0 in this example) of the firewall. A word of warning is in order here. ISPs typically configure their routers with a long ARP cache timeout. If you move a system from parallel to your firewall to behind your firewall with Proxy ARP, it will probably be HOURS before that system can communicate with the internet. There are a couple of things that you can try: (Courtesy of Bradey Honsinger) A reading of Stevens' TCP/IP Illustrated, Vol 1 reveals that a
gratuitous ARP packet should cause the ISP's router to refresh their ARP cache (section 4.7). A gratuitous ARP is simply a host requesting the MAC address for its own IP; in addition to ensuring that the IP address isn't a duplicate,... if the host sending the gratuitous ARP has just changed its hardware address..., this packet causes any other host...that has an entry in its cache for the old hardware address to update its ARP cache entry accordingly.
Which is, of course, exactly what you want to do when you switch a host from being exposed to the Internet to behind Shorewall using proxy ARP (or one-to-one NAT for that matter). Happily enough, recent versions of Redhat's iputils package include arping, whose -U flag does just that: arping -U -I <net if> <newly proxied IP> arping -U -I eth0 66.58.99.83 # for exampleStevens goes on to mention that not all systems respond correctly to gratuitous ARPs, but googling for arping -U seems to support the idea that it works most of the time. You can call your ISP and ask them to purge the stale ARP cache entry but many either can't or won't purge individual entries. You can determine if your ISP's gateway ARP cache is stale using ping and tcpdump. Suppose that we suspect that the gateway router has a stale ARP cache entry for 192.0.2.177. On the firewall, run tcpdump as follows: tcpdump -nei eth0 icmp Now from 192.0.2.177, ping the ISP's gateway (which we will assume is 192.0.2.254): ping 192.0.2.254 We can now observe the tcpdump output: 13:35:12.159321 0:4:e2:20:20:33 0:0:77:95:dd:19 ip 98: 192.0.2.177 > 192.0.2.254: icmp: echo request (DF) 13:35:12.207615 0:0:77:95:dd:19 0:c0:a8:50:b2:57 ip 98: 192.0.2.254 > 192.0.2.177 : icmp: echo replyNotice that the source MAC address in the echo request is different from the destination MAC address in the echo reply!! In this case 0:4:e2:20:20:33 was the MAC of the firewall's eth0 NIC while 0:c0:a8:50:b2:57 was the MAC address of DMZ 1. In other words, the gateway's ARP cache still associates 192.0.2.177 with the NIC in DMZ 1 rather than with the firewall's eth0.
One-to-one NAT With one-to-one NAT, you assign local systems RFC 1918 addresses then establish a one-to-one mapping between those addresses and public IP addresses. For outgoing connections SNAT (Source Network Address Translation) occurs and on incoming connections DNAT (Destination Network Address Translation) occurs. Let's go back to our earlier example involving your daughter's web server running on system Local 3. Recall that in this setup, the local network is using SNAT and is sharing the firewall external IP (192.0.2.176) for outbound connections. This is done with the following entry in /etc/shorewall/masq: #INTERFACE SUBNET ADDRESS eth0 192.168.201.0/29 192.0.2.176 Suppose now that you have decided to give your daughter her own IP address (192.0.2.179) for both inbound and outbound connections. You would do that by adding an entry in /etc/shorewall/nat. #EXTERNAL INTERFACE INTERNAL ALL INTERFACES LOCAL 192.0.2.179 eth0 192.168.201.4 No No With this entry in place, you daughter has her own IP address and the other two local systems share the firewall's IP address. Once the relationship between 192.0.2.179 and 192.168.201.4 is established by the nat file entry above, it is no longer appropriate to use a DNAT rule for you daughter's web server -- you would rather just use an ACCEPT rule: #ACTION SOURCE DEST PROTO DEST SOURCE ORIGINAL # PORT(S) PORT(S) DEST ACCEPT net loc:192.168.201.4 tcp www A word of warning is in order here. ISPs typically configure their routers with a long ARP cache timeout. If you move a system from parallel to your firewall to behind your firewall with one-to-one NAT, it will probably be HOURS before that system can communicate with the internet. There are a couple of things that you can try: (Courtesy of Bradey Honsinger) A reading of Stevens' TCP/IP Illustrated, Vol 1 reveals that a
gratuitous ARP packet should cause the ISP's router to refresh their ARP cache (section 4.7). A gratuitous ARP is simply a host requesting the MAC address for its own IP; in addition to ensuring that the IP address isn't a duplicate,... if the host sending the gratuitous ARP has just changed its hardware address..., this packet causes any other host...that has an entry in its cache for the old hardware address to update its ARP cache entry accordingly.
Which is, of course, exactly what you want to do when you switch a host from being exposed to the Internet to behind Shorewall using one-to-one NAT. Happily enough, recent versions of Redhat's iputils package include arping, whose -U flag does just that: arping -U -I <net if> <newly proxied IP> arping -U -I eth0 66.58.99.83 # for exampleStevens goes on to mention that not all systems respond correctly to gratuitous ARPs, but googling for arping -U seems to support the idea that it works most of the time. You can call your ISP and ask them to purge the stale ARP cache entry but many either can't or won't purge individual entries. You can determine if your ISP's gateway ARP cache is stale using ping and tcpdump. Suppose that we suspect that the gateway router has a stale ARP cache entry for 192.0.2.177. On the firewall, run tcpdump as follows: tcpdump -nei eth0 icmp Now from 192.0.2.177, ping the ISP's gateway (which we will assume is 192.0.2.254): ping 192.0.2.254 We can now observe the tcpdump output: 13:35:12.159321 0:4:e2:20:20:33 0:0:77:95:dd:19 ip 98: 192.0.2.177 > 192.0.2.254: icmp: echo request (DF) 13:35:12.207615 0:0:77:95:dd:19 0:c0:a8:50:b2:57 ip 98: 192.0.2.254 > 192.0.2.177 : icmp: echo replyNotice that the source MAC address in the echo request is different from the destination MAC address in the echo reply!! In this case 0:4:e2:20:20:33 was the MAC of the firewall's eth0 NIC while 0:c0:a8:50:b2:57 was the MAC address of DMZ 1. In other words, the gateway's ARP cache still associates 192.0.2.177 with the NIC in DMZ 1 rather than with the firewall's eth0.
Rules With the default policies, your local systems (Local 1-3) can access any servers on the internet and the DMZ can't access any other host (including the firewall). With the exception of DNAT rules which cause address translation and allow the translated connection request to pass through the firewall, the way to allow connection requests through your firewall is to use ACCEPT rules. Since the SOURCE PORT(S) and ORIG. DEST. Columns aren't used in this section, they won't be shown You probably want to allow ping between your zones: #ACTION SOURCE DEST PROTO DEST # PORT(S) ACCEPT net dmz icmp echo-request ACCEPT net loc icmp echo-request ACCEPT dmz loc icmp echo-request ACCEPT loc dmz icmp echo-request Let's suppose that you run mail and pop3 servers on DMZ 2 and a Web Server on DMZ 1. The rules that you would need are: #ACTION SOURCE DEST PROTO DEST COMMENTS # PORT(S) ACCEPT net dmz:192.0.2.178 tcp smtp #Mail from #Internet ACCEPT net dmz:192.0.2.178 tcp pop3 #Pop3 from #Internet ACCEPT loc dmz:192.0.2.178 tcp smtp #Mail from local #Network ACCEPT loc dmz:192.0.2.178 tcp pop3 #Pop3 from local #Network ACCEPT fw dmz:192.0.2.178 tcp smtp #Mail from the #Firewall ACCEPT dmz:192.0.2.178 net tcp smtp #Mail to the #Internet ACCEPT net dmz:192.0.2.177 tcp http #WWW from #Internet ACCEPT net dmz:192.0.2.177 tcp https #Secure WWW #from Internet ACCEPT loc dmz:192.0.2.177 tcp https #Secure WWW #from local #Network If you run a public DNS server on 192.0.2.177, you would need to add the following rules: #ACTION SOURCE DEST PROTO DEST COMMENTS # PORT(S) ACCEPT net dmz:192.0.2.177 udp domain #UDP DNS from #Internet ACCEPT net dmz:192.0.2.177 tcp domain #TCP DNS from #Internet ACCEPT loc dmz:192.0.2.177 udp domain #UDP DNS from #Local Network ACCEPT loc dmz:192.0.2.177 tcp domain #TCP DNS from #Local Network ACCEPT fw dmz:192.0.2.177 udp domain #UDP DNS from #the Firewall ACCEPT fw dmz:192.0.2.177 tcp domain #TCP DNS from #the Firewall ACCEPT dmz:192.0.2.177 net udp domain #UDP DNS to #the Internet ACCEPT dmz:192.0.2.177 net tcp domain #TCPP DNS to #the Internet You probably want some way to communicate with your firewall and DMZ systems from the local network -- I recommend SSH which through its scp utility can also do publishing and software update distribution. #ACTION SOURCE DEST PROTO DEST COMMENTS # PORT(S) ACCEPT loc dmz tcp ssh #SSH to the DMZ ACCEPT net fw tcp ssh #SSH to the #Firewall
Odds and Ends The above discussion reflects my personal preference for using Proxy ARP for my servers in my DMZ and SNAT/NAT for my local systems. I prefer to use NAT only in cases where a system that is part of an RFC 1918 subnet needs to have it's own public IP. If you haven't already, it would be a good idea to browse through /etc/shorewall/shorewall.conf just to see if there is anything there that might be of interest. You might also want to look at the other configuration files that you haven't touched yet just to get a feel for the other things that Shorewall can do. In case you haven't been keeping score, here's the final set of configuration files for our sample network. Only those that were modified from the original installation are shown. /etc/shorewall/interfaces (The options will be very site-specific). #ZONE INTERFACE BROADCAST OPTIONS net eth0 detect rfc1918,routefilter loc eth1 detect dmz eth2 detect The setup described here requires that your network interfaces be brought up before Shorewall can start. This opens a short window during which you have no firewall protection. If you replace detect with the actual broadcast addresses in the entries above, you can bring up Shorewall before you bring up your network interfaces. #ZONE INTERFACE BROADCAST OPTIONS net eth0 192.0.2.255 rfc1918 loc eth1 192.168.201.7 dmz eth2 192.168.202.7 /etc/shorewall/masq - Local Subnet #INTERFACE SUBNET ADDRESS eth0 192.168.201.0/29 192.0.2.176 /etc/shorewall/proxyarp - DMZ #ADDRESS EXTERNAL INTERFACE HAVE ROUTE 192.0.2.177 eth2 eth0 No 192.0.2.178 eth2 eth0 No /etc/shorewall/nat- Daughter's System #EXTERNAL INTERFACE INTERNAL ALL INTERFACES LOCAL 192.0.2.179 eth0 192.168.201.4 No No /etc/shorewall/rules #ACTION SOURCE DEST PROTO DEST COMMENTS # PORT(S) ACCEPT net dmz icmp echo-request ACCEPT net loc icmp echo-request ACCEPT dmz loc icmp echo-request ACCEPT loc dmz icmp echo-request ACCEPT net loc:192.168.201.4 tcp www #Daughter's #Server ACCEPT net dmz:192.0.2.178 tcp smtp #Mail from #Internet ACCEPT net dmz:192.0.2.178 tcp pop3 #Pop3 from #Internet ACCEPT loc dmz:192.0.2.178 tcp smtp #Mail from local #Network ACCEPT loc dmz:192.0.2.178 tcp pop3 #Pop3 from local #Network ACCEPT fw dmz:192.0.2.178 tcp smtp #Mail from the #Firewall ACCEPT dmz:192.0.2.178 net tcp smtp #Mail to the #Internet ACCEPT net dmz:192.0.2.177 tcp http #WWW from #Internet ACCEPT net dmz:192.0.2.177 tcp https #Secure WWW #from Internet ACCEPT loc dmz:192.0.2.177 tcp https #Secure WWW #from local #Network ACCEPT net dmz:192.0.2.177 udp domain #UDP DNS from #Internet ACCEPT net dmz:192.0.2.177 tcp domain #TCP DNS from #Internet ACCEPT loc dmz:192.0.2.177 udp domain #UDP DNS from #Local Network ACCEPT loc dmz:192.0.2.177 tcp domain #TCP DNS from #Local Network ACCEPT fw dmz:192.0.2.177 udp domain #UDP DNS from #the Firewall ACCEPT fw dmz:192.0.2.177 tcp domain #TCP DNS from #the Firewall ACCEPT dmz:192.0.2.177 net udp domain #UDP DNS to #the Internet ACCEPT dmz:192.0.2.177 net tcp domain #TCPP DNS to #the Internet ACCEPT loc dmz tcp ssh #SSH to the DMZ ACCEPT net fw tcp ssh #SSH to the #Firewall
DNS Given the collection of RFC 1918 and public addresses in this setup, it only makes sense to have separate internal and external DNS servers. You can combine the two into a single BIND 9 server using Views. If you are not interested in Bind 9 views, you can go to the next section. Suppose that your domain is foobar.net and you want the two DMZ systems named www.foobar.net and mail.foobar.net and you want the three local systems named "winken.foobar.net, blinken.foobar.net and nod.foobar.net. You want your firewall to be known as firewall.foobar.net externally and it's interface to the local network to be know as gateway.foobar.net and its interface to the dmz as dmz.foobar.net. Let's have the DNS server on 192.0.2.177 which will also be known by the name ns1.foobar.net. The /etc/named.conf file would look like this: options { directory "/var/named"; listen-on { 127.0.0.1 ; 192.0.2.177; }; }; logging { channel xfer-log { file "/var/log/named/bind-xfer.log"; print-category yes; print-severity yes; print-time yes; severity info; }; category xfer-in { xfer-log; }; category xfer-out { xfer-log; }; category notify { xfer-log; }; }; # # This is the view presented to our internal systems # view "internal" { # # These are the clients that see this view # match-clients { 192.168.201.0/29; 192.168.202.0/29; 127.0.0.0/8; 192.0.2.176/32; 192.0.2.178/32; 192.0.2.179/32; 192.0.2.180/32; }; # # If this server can't complete the request, it should use # outside servers to do so # recursion yes; zone "." in { type hint; file "int/root.cache"; }; zone "foobar.net" in { type master; notify no; allow-update { none; }; file "int/db.foobar"; }; zone "0.0.127.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "int/db.127.0.0"; }; zone "201.168.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "int/db.192.168.201"; }; zone "202.168.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "int/db.192.168.202"; }; zone "176.2.0.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "db.192.0.2.176"; }; zone "177.2.0.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "db.192.0.2.177"; }; zone "178.2.0.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "db.192.0.2.178"; }; zone "179.2.0.192.in-addr.arpa" in { type master; notify no; allow-update { none; }; file "db.206.124.146.179"; }; }; # # This is the view that we present to the outside world # view "external" { match-clients { any; }; # # If we can't answer the query, we tell the client so # recursion no; zone "foobar.net" in { type master; notify yes; allow-update {none; }; allow-transfer { <secondary NS IP>; }; file "ext/db.foobar"; }; zone "176.2.0.192.in-addr.arpa" in { type master; notify yes; allow-update { none; }; allow-transfer { <secondary NS IP>; }; file "db.192.0.2.176"; }; zone "177.2.0.192.in-addr.arpa" in { type master; notify yes; allow-update { none; }; allow-transfer { <secondary NS IP>; }; file "db.192.0.2.177"; }; zone "178.2.0.192.in-addr.arpa" in { type master; notify yes; allow-update { none; }; allow-transfer { <secondary NS IP>; }; file "db.192.0.2.178"; }; zone "179.2.0.192.in-addr.arpa" in { type master; notify yes; allow-update { none; }; allow-transfer { <secondary NS IP>; }; file "db.192.0.2.179"; }; }; Here are the files in /var/named (those not shown are usually included in your bind disbribution). db.192.0.2.176 - This is the reverse zone for the firewall's external interface ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.0.2.176/32 ; Filename: db.192.0.2.176 ; ############################################################ @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2001102303 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. @ 604800 IN NS <name of secondary ns>. ; ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 176.2.0.192.in-addr.arpa. 86400 IN PTR firewall.foobar.net. db.192.0.2.177 - Reverse zone www server ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.0.2.177/32 ; Filename: db.192.0.2.177 ; ############################################################ @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2001102303 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. @ 604800 IN NS <name of secondary ns>. ; ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 177.2.0.192.in-addr.arpa. 86400 IN PTR www.foobar.net. db.192.0.2.178 - Reverse zone for the mail server ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.0.2.178/32 ; Filename: db.192.0.2.178 ; ############################################################ @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2001102303 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. @ 604800 IN NS <name of secondary ns>. ; ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 178.2.0.192.in-addr.arpa. 86400 IN PTR mail.foobar.net. db.192.0.2.179 - Reverse zone for Daughter's public web server ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.0.2.179/32 ; Filename: db.192.0.2.179 ; ############################################################ @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2001102303 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. @ 604800 IN NS <name of secondary ns>. ; ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 179.2.0.192.in-addr.arpa. 86400 IN PTR nod.foobar.net. int/db.127.0.0 - Reverse zone for localhost ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 127.0.0.0/8 ; Filename: db.127.0.0 ; ############################################################ @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2001092901 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 1 86400 IN PTR localhost.foobar.net. int/db.192.168.201 - Reverse zone for the local network. This is only shown to internal clients. ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.168.201.0/29 ; Filename: db.192.168.201 ; ############################################################ @ 604800 IN SOA ns1.foobar.net netadmin.foobar.net. ( 2002032501 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 1 86400 IN PTR gateway.foobar.net. 2 86400 IN PTR winken.foobar.net. 3 86400 IN PTR blinken.foobar.net. 4 86400 IN PTR nod.foobar.net. int/db.192.168.202 - Reverse zone for the firewall's DMZ Interface ; ############################################################ ; Start of Authority (Inverse Address Arpa) for 192.168.202.0/29 ; Filename: db.192.168.202 ; ############################################################ @ 604800 IN SOA ns1.foobar.net netadmin.foobar.net. ( 2002032501 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ) ; minimum (1 day) ; ############################################################ ; Specify Name Servers for all Reverse Lookups (IN-ADDR.ARPA) ; ############################################################ @ 604800 IN NS ns1.foobar.net. ; ############################################################ ; Iverse Address Arpa Records (PTR's) ; ############################################################ 1 86400 IN PTR dmz.foobar.net. int/db.foobar - Forward zone for internal clients. ;############################################################## ; Start of Authority for foobar.net. ; Filename: db.foobar ;############################################################## @ 604800 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2002071501 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ); minimum (1 day) ;############################################################ ; foobar.net Nameserver Records (NS) ;############################################################ @ 604800 IN NS ns1.foobar.net. ;############################################################ ; Foobar.net Office Records (ADDRESS) ;############################################################ localhost 86400 IN A 127.0.0.1 firewall 86400 IN A 192.0.2.176 www 86400 IN A 192.0.2.177 ns1 86400 IN A 192.0.2.177 www 86400 IN A 192.0.2.177 gateway 86400 IN A 192.168.201.1 winken 86400 IN A 192.168.201.2 blinken 86400 IN A 192.168.201.3 nod 86400 IN A 192.168.201.4 ext/db.foobar - Forward zone for external clients. ;############################################################## ; Start of Authority for foobar.net. ; Filename: db.foobar ;############################################################## @ 86400 IN SOA ns1.foobar.net. netadmin.foobar.net. ( 2002052901 ; serial 10800 ; refresh (3 hour) 3600 ; retry (1 hour) 604800 ; expire (7 days) 86400 ); minimum (1 day) ;############################################################ ; Foobar.net Nameserver Records (NS) ;############################################################ @ 86400 IN NS ns1.foobar.net. @ 86400 IN NS <secondary NS>. ;############################################################ ; Foobar.net Foobar Wa Office Records (ADDRESS) ;############################################################ localhost 86400 IN A 127.0.0.1 ; ; The firewall itself ; firewall 86400 IN A 192.0.2.176 ; ; The DMZ ; ns1 86400 IN A 192.0.2.177 www 86400 IN A 192.0.2.177 mail 86400 IN A 192.0.2.178 ; ; The Local Network ; nod 86400 IN A 192.0.2.179 ;############################################################ ; Current Aliases for foobar.net (CNAME) ;############################################################ ;############################################################ ; foobar.net MX Records (MAIL EXCHANGER) ;############################################################ foobar.net. 86400 IN A 192.0.2.177 86400 IN MX 0 mail.foobar.net. 86400 IN MX 1 <backup MX>.
Starting and Stopping the Firewall The Installation procedure configures your system to start Shorewall at system boot. The firewall is started using the shorewall start command and stopped using shorewall stop. When the firewall is stopped, routing is enabled on those hosts that have an entry in /etc/shorewall/routestopped. A running firewall may be restarted using the shorewall restart command. If you want to totally remove any trace of Shorewall from your Netfilter configuration, use shorewall clear. Edit the /etc/shorewall/routestopped file and configure those systems that you want to be able to access the firewall when it is stopped. If you are connected to your firewall from the internet, do not issue a shorewall stop command unless you have added an entry for the IP address that you are connected from to /etc/shorewall/routestopped. Also, I don't recommend using shorewall restart; it is better to create an an alternate configuration  and test it using the shorewall try command.