Network Mapping
Tom
Eastep
2004-2005
2007
2011
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
.
Why use Network Mapping
Network Mapping is most often used to resolve IP address conflicts.
Suppose that two organizations, A and B, need to be linked and that both
organizations have allocated the 192.168.1.0/24 subnetwork. There is a
need to connect the two networks so that all systems in A can access the
192.168.1.0/24 network in B and vice versa without any
re-addressing.
Solution
Shorewall NETMAP support is designed to supply a solution. The basic
situation is as shown in the following diagram.
While the link between the two firewalls is shown here as a VPN, it
could be any type of interconnection that allows routing of RFC 1918 traffic.
The systems in the top cloud will access the 192.168.1.0/24 subnet
in the lower cloud using addresses in another unused /24. Similarly, the
systems in the bottom cloud will access the 192.168.1.0/24 subnet in the
upper cloud using a second unused /24.
In order to apply this solution:
You must be running Shorewall 2.0.1 Beta 2 or later.
Your kernel must have NETMAP support. 2.6 Kernels have NETMAP
support without patching while 2.4 kernels must be patched using
Patch-O-Matic from netfilter.org.
NETMAP support must be enabled in your kernel
(CONFIG_IP_NF_TARGET_NETMAP=m or CONFIG_IP_NF_TARGET_NETMAP=y).
Your iptables must have NETMAP support. NETMAP support is
available in iptables 1.2.9 and later.
Network mapping is defined using the
/etc/shorewall/netmap file. Columns in this file
are:
TYPE
Must be DNAT or SNAT.
If DNAT, traffic entering INTERFACE and addressed to NET1 has
its destination address rewritten to the corresponding address in
NET2.
If SNAT, traffic leaving INTERFACE with a source address in
NET1 has its source address rewritten to the corresponding address
in NET2.
NET1
Must be expressed in CIDR format (e.g., 192.168.1.0/24).
Beginning with Shorewall 4.4.24, exclusion is
supported.
INTERFACE
A firewall interface. This interface must have been defined in
/etc/shorewall/interfaces.
NET2
A second network expressed in CIDR format.
NET3 (Optional) -
network-address
Added in Shorewall 4.4.11. If specified, qualifies INTERFACE.
It specifies a SOURCE network for DNAT rules and a DESTINATON
network for SNAT rules.
PROTO (Optional - Added in Shorewall
4.4.23.2) -
protocol-number-or-name
Only packets specifying this protocol will have their IP
header modified.
DEST PORT(S) (Optional - Added in
Shorewall 4.4.23.2) -
port-number-or-name-list
Destination Ports. A comma-separated list of Port names (from
services(5)), port numbers or port
ranges; if the protocol is icmp, this column is interpreted as the
destination icmp-type(s). ICMP types may be specified as a numeric
type, a numberic type and code separated by a slash (e.g., 3/4), or
a typename. See http://www.shorewall.net/configuration_file_basics.htm#ICMP.
If the protocol is ipp2p,
this column is interpreted as an ipp2p option without the leading
"--" (example bit for bit-torrent).
If no PORT is given, ipp2p is
assumed.
An entry in this field requires that the PROTO column specify
icmp (1), tcp (6), udp (17), sctp (132) or udplite (136). Use '-' if
any of the following field is supplied.
DEST PORT(S) (Optional - Added in
Shorewall 4.4.23.2) -
port-number-or-name-list
Source port(s). If omitted, any source port is acceptable.
Specified as a comma-separated list of port names, port numbers or
port ranges.
An entry in this field requires that the PROTO column specify
tcp (6), udp (17), sctp (132) or udplite (136). Use '-' if any of
the following fields is supplied.
Referring to the figure above, lets suppose that systems in the top
cloud are going to access the 192.168.1.0/24 network in the bottom cloud
using addresses in 10.10.10.0/24 and that systems in the bottom could will
access 192.168.1.0/24 in the top could using addresses in
10.10.11.0.
You must arrange for routing as follows:
Traffic from the top cloud to 10.10.10.0/24 must be routed
to eth0 on firewall 1.
Firewall 1 must route traffic to 10.10.10.0/24 through
firewall 2.
Traffic from the bottom cloud to 10.10.11.0/24 must be
routed to eth0 on firewall 2.
Firewall 2 must route traffic to 10.10.11.0/24 through
firewall 1.
If you are running Shorewall 4.4.22 or Earlier
The entries in
/etc/shorewall/netmap in
firewall1 would be as follows:
#TYPE NET1 INTERFACE NET2
SNAT 192.168.1.0/24 vpn 10.10.11.0/24 #RULE 1A
DNAT 10.10.11.0/24 vpn 192.168.1.0/24 #RULE 1B
The entry in /etc/shorewall/netmap in
firewall2 would be:
#TYPE NET1 INTERFACE NET2
DNAT 10.10.10.0/24 vpn 192.168.1.0/24 #RULE 2A
SNAT 192.168.1.0/24 vpn 10.10.10.0/24 #RULE 2B
192.168.1.4 in the top cloud connects to 192.168.1.27 in the
bottom cloud
In order to make this connection, the client attempts a
connection to 10.10.10.27. The following table shows how the source
and destination IP addresses are modified as requests are sent and
replies are returned. The RULE column refers to the above
/etc/shorewall/netmap entries and gives the rule
which transforms the source and destination IP addresses to those
shown on the next line.
FROM
TO
SOURCE IP ADDRESS
DESTINATION IP ADDRESS
RULE
192.168.1.4 in upper cloud
Firewall 1
192.168.1.4
10.10.10.27
1A
Firewall 1
Firewall 2
10.10.11.4
10.10.10.27
2A
Firewall 2
192.168.1.27 in lower cloud
10.10.11.4
192.168.1.27
192.168.1.27 in the lower cloud
Firewall 2
192.168.1.27
10.10.11.4
2B
Firewall 2
Firewall 1
10.10.10.27
10.10.11.4
1B
Firewall 1
192.168.1.4 in upper cloud
10.10.10.27
192.168.1.4
See the OpenVPN documentation
for a solution contributed by Nicola Moretti for resolving duplicate
networks in a roadwarrior VPN environment.
If you are running Shorewall 4.4.23 or Later
Beginning with Shorewall 4.4.23, you can
bridge two duplicate networks with one router, provided that your kernel
and iptables include Rawpost Table Support. That
support is used to implement Stateless NAT which allows for performing
DNAT in the rawpost table POSTROUTING and OUTPUT chains and for
performing SNAT in the raw table PREROUTING chain. Using this support,
only firewall1 requires /etc/shorewall/netmap. Two
additional entries are added.
#TYPE NET1 INTERFACE NET2
SNAT 192.168.1.0/24 vpn 10.10.11.0/24
DNAT 10.10.11.0/24 vpn 192.168.1.0/24
SNAT:P 192.168.1.0/24 vpn 10.10.10.0/24
DNAT:T 10.10.10.0/24 vpn 192.168.1.0/24
The last two entries define Stateless NAT
by specifying a chain designator (:P for PREROUTING and :T for
POSTROUTING respectively). See shorewall-netmap (5) for
details.
IPv6
Beginning with Shorewall6 4.4.24, IPv6 support for Netmap is
included. This provides a way to use private IPv6 addresses internally and
still have access to the IPv6 internet.
IPv6 netmap is stateless which means that
there are no Netfilter helpers for applications that need them. As a
consequence, applications that require a helper (FTP, IRC, etc.) may
experience issues.
For IPv6, the chain designator (:P for PREROUTING or :T for
POSTROUTING) is required in the TYPE column. Normally SNAT rules are
placed in the POSTROUTING chain while DNAT rules are placed in
PREROUTING.
To use IPv6 Netmap, your kernel and iptables must include
Rawpost Table Support.
IPv6 Netmap has been verified at shorewall.net using the
configuration shown below.
IPv6 support is supplied from Hurricane Electric; the IPv6 address
block is 2001:470:b:227::/64.
Because of the limitations of IPv6 NETMAP (no Netfilter helpers),
the servers in the DMZ have public addresses in the block
2001:470:b:227::/112. The local LAN uses the private network
fd00:470:b:227::/64 with the hosts autoconfigured using radvd. This block
is allocated from the range (fc00::/7) reserved for Unique Local
Addresses.
The /etc/shorewall6/netmap file is as follows:
#TYPE NET1 INTERFACE NET2 NET3 PROTO DEST SOURCE
# PORT(S) PORT(S)
SNAT:T fd00:470:b:227::/64 HE_IF 2001:470:b:227::/64
DNAT:P 2001:470:b:227::/64!2001:470:b:227::/112\
HE_IF fd00:470:b:227::/64
HE_IF is the logical name for interface sit1. On output, the private
address block is mapped to the public block. Because autoconfiguration is
used, none of the local addresses falls into the range
fd00:470:b:227::/112. That range can therefore be excluded from
DNAT.
While the site local network that was used is very similar to the
public network (only the first word is different), that isn't a
requirement. We could have just as well used
fd00:bad:dead:beef::/64
The MacBook Pro running OS X Lion refused to autoconfigure when
radvd advertised a site-local network
(fec0:470:b:227/64) but worked fine with the unique-local network
(fd00:470:b:227::/64). Note that site-local addresses were deprecated in
RFC3879.
This whole scheme isn't quite as useful as it might appear. Many
IPv6-enabled applications (web browsers, for example) are smart enough
to recognize unique local addresses and will only use IPv6 to
communicate with other such local addresses.