gated is available from http://www.gated.org. Appendix B, A gated Reference, provides information about downloading and compiling the software. In this section, we use gated release 3.5.5, the version of gated that is currently available without restrictions. There are other, newer versions of gated available to members of the Gated Consortium. If you plan to build products based on gated or you plan to do research on routing protocols using gated, you should join the consortium. For the purposes of this book, release 3.5.5 is fine.
gated reads its configuration from the /etc/gated.conf file. The configuration commands in the file resemble C code. All statements end with a semicolon, and associated statements are grouped together by curly braces. This structure makes it simple to see what parts of the configuration are associated with each other, which is important when multiple protocols are configured in the same file. In addition to structure in the language, the /etc/gated.conf file also has a structure.
The different configuration statements, and the order in which these statements must appear, divide gated.conf into sections: option statements, interface statements, definition statements, protocol statements, static statements, control statements, and aggregate statements. Entering a statement out of order causes an error when parsing the file.
Two other types of statements do not fall into any of these categories. They are directive statements and trace statements. These can occur anywhere in the gated.conf file and do not directly relate to the configuration of any protocol. These statements provide instructions to the parser, and instructions to control tracing from within the configuration file.
The gated configuration commands are summarized in Table 7.2 The table lists each command by name, identifies the statement type, and provides a very short synopsis of each command's function. The entire command language is covered in detail in Appendix B.
Statement | Type | Function |
---|---|---|
%directory | directive | Sets the directory for include files |
%include | directive | Includes a file into gated.conf |
traceoptions | trace | Specifies which events are traced |
options | option | Defines gated options |
interfaces | interface | Defines interface options |
autonomoussystem | definition | Defines the AS number |
routerid | definition | Defines the originating router for BGP or OSPF |
martians | definition | Defines invalid destination addresses |
snmp | protocol | Enables reporting to SNMP |
rip | protocol | Enables RIP |
hello | protocol | Enables Hello protocol |
isis | protocol | Enables ISIS protocol |
kernel | protocol | Configures kernel interface options |
ospf | protocol | Enables OSPF protocol |
redirect | protocol | Removes routes installed by ICMP |
egp | protocol | Enables EGP |
bgp | protocol | Enables BGP |
icmp | protocol | Configures the processing of general ICMP packets |
static | static | Defines static routes |
import | control | Defines what routes are accepted |
export | control | Defines what routes are advertised |
aggregate | aggregate | Controls route aggregation |
generate | aggregate | Controls creation of a default route |
Just from this brief description, you can see that the gated configuration language has many commands. The language provides configuration control for several different protocols and additional commands to configure the added features of gated itself. All of this can be confusing.
To avoid confusion, don't try to understand the details of everything offered by gated. Your routing environment will not use all of these protocols and features. Even if you are providing the gateway at the border between two anonymous systems, you will probably only run two routing protocols: one interior protocol and one exterior protocol. Only those commands that relate to your actual configuration need to be included in your configuration file. As you read this section, skip the things you don't need. For example, if you don't use the BGP protocol, don't study the bgp statement. When you do need more details about a specific statement, look it up in Appendix B. With this in mind, let's look at some sample configurations.
The details in Appendix B may make gated configuration appear more complex than it is. gated's rich command language can be confusing, as can its support for multiple protocols and the fact that it often provides a few ways to do the same thing. But some realistic examples will show that individual configurations do not need to be complex.
The basis for the sample configurations is the network in Figure 7.4 We have installed a new router that provides our backbone with direct access to the Internet, and we have decided to install new routing protocols. We'll configure a host to listen to RIP-2 updates, an interior gateway to run RIP-2 and OSPF, and an exterior gateway to run OSPF and BGP.
Gateway cashew interconnects subnet 172.16.9.0 and subnet 172.16.1.0. To hosts on subnet 9, it advertises itself as the default gateway, because it is the gateway to the outside world. It uses RIP-2 to advertise routes on subnet 9. On subnet 1, gateway cashew advertises itself as the gateway to subnet 9 using OSPF.
Gateway brazil provides subnet 1 with access to the Internet through autonomous system 164. Because gateway brazil provides access to the Internet, it announces itself as the default gateway to the other systems on subnet 1 using OSPF. To the external autonomous system, it uses BGP to announce itself as the path to the internal networks it learns about through OSPF.
Let's look at the routing configuration of host macadamia, gateway cashew, and gateway brazil.
The host routing configuration is very simple. The rip yes statement enables RIP, and that's all that is really required to run RIP. That basic configuration should work for any system that runs RIP. The additional clauses enclosed in curly braces modify the basic RIP configuration. We use a few clauses to create a more interesting example. Here is the RIP-2 configuration for host macadamia:
# # enable rip, don't broadcast updates, # listen for RIP-2 updates on the multicast address, # check that the updates are authentic. # rip yes { nobroadcast ; interface 172.16.9.23 version 2 multicast authentication simple "REALstuff" ; } ;
This sample file shows the basic structure of gated.conf
configuration statements. Lines beginning with a sharp sign (#) are
comments.
[12]
All statements end with semicolons. Clauses associated with a
configuration statement can span multiple lines and are enclosed in
curly braces ({}
). In the example, the nobroadcast
and
interface
clauses apply directly to the rip statement. The
version
, multicast
, and authentication
keywords
are part of the interface clause.
[12] Comments can also be enclosed between a \* and a *\.
The keyword nobroadcast
prevents the host from broadcasting
its own RIP updates. The default is nobroadcast
when the
system has one network interface and broadcast
when it has
more than one. The nobroadcast
keyword performs the same
function as the -q command-line option does for
routed. However, gated can do much more than routed,
as the next clause shows.
The interface
clause defines interface parameters for RIP. The
parameters associated with this clause say that RIP-2 updates
will be received via the RIP-2 multicast address on interface
172.16.9.23, and that authentic updates will contain the password
REALstuff
. For RIP-2, simple
authentication is a clear-text
password up to 16 bytes long. This is not intended to protect the
system from malicious actions; it is only intended to protect the
routers from a configuration accident. If a user mistakenly sets his
system up as a RIP supplier, he is very unlikely to accidently enter
the correct password into his configuration. Stronger authentication
will soon be available in the form of a Message Digest 5 (MD5)
cryptographic checksum by specifying md5
in the authentication
clause.
Gateway configurations are more complicated than the simple host configuration shown above. Gateways always have multiple interfaces and occasionally run multiple routing protocols. Our first sample configuration is for the interior gateway between subnet 9 and the central backbone, subnet 1. It uses RIP-2 on subnet 9 to announce routes to the UNIX hosts. It uses OSPF on subnet 1 to exchange routes with the other gateways. Here's the configuration of gateway cashew:
# Don't time-out subnet 9 interfaces { interface 172.16.9.1 passive ; } ; # Define the OSPF router id routerid 172.16.1.9 ; # Enable RIP-2; announce OSPF routes to # subnet 9 with a cost of 5. rip yes { broadcast ; defaultmetric 5 ; interface 172.16.9.1 version 2 multicast authentication simple "REALstuff" ; } ; # Enable OSPF; subnet 1 is the backbone area; # use password authentication. ospf yes { backbone { authtype simple ; interface 172.16.1.9 { priority 5 ; authkey "It'sREAL" ; } ; } ; } ;
The interfaces
statement defines routing characteristics for
the network interfaces. The keyword passive
in the interface
clause is used here, just as we have seen it used before, to create a
permanent static route that will not be removed from the routing
table. In this case, the permanent route is through a directly
attached network interface. Normally when gated thinks an
interface is malfunctioning, it increases the cost of the interface by
giving it a high-cost preference value (120) to reduce the probability
of a gateway routing data through a non-operational interface.
gated determines that an interface is malfunctioning when it does
not receive routing updates on that interface. We don't want
gated to downgrade the 172.16.9.1 interface, even if it does
think the interface is malfunctioning, because our router is the only
path to subnet 9. That's why this configuration includes the clause
interface 172.16.9.1 passive
.
The routerid
statement defines the router identifier for OSPF.
Unless it is explicitly defined in the configuration file, gated
uses the address of the first interface it encounters as the default
router identifier address. Here we specify the address of the interface
that actually speaks OSPF as the OSPF router identifier.
In the previous example we discussed all the clauses on the rip
statement except one - the defaultmetric
clause.
The defaultmetric
clause defines the RIP metric used
to advertise routes learned from other routing protocols.
This gateway runs both OSPF and RIP-2. We wish to
advertise the routes learned via OSPF to our RIP clients, and to do that, a
metric is required. We choose a RIP cost of 5. If the
defaultmetric
clause is not used, routes learned from OSPF are
not advertised to the RIP clients.
[13]
This statement is required for our configuration.
[13] This is not strictly true. The routes are advertised with a cost of 16, meaning that the destinations are unreachable.
The ospf yes
statement enables OSPF. The first clause
associated with this statement is backbone
. It states that the
router is part of the OSPF backbone area. Every ospf yes
statement must have at least one associated area clause. It can define
a specific area, e.g., area 2
, but at least one router must be
in the backbone area. While the OSPF backbone is area 0, it cannot be
specified as area 0
; it must be specified with the keyword
backbone
. In our sample configuration, subnet 1 is the
backbone and all routers attached to it are in the backbone area. It
is possible for a single router to attach to multiple areas with a
different set of configuration parameters for each area. Notice how
the nested curly braces group the clauses together. The remaining
clauses in the configuration file are directly associated with the
backbone area clause.
The authtype simple ;
clause says that simple, password-based
authentication is used in the backbone area. Two choices, simple
and
none
, are available for authtype in GateD 3.5.5. none
means no
authentication is used. simple
means that the correct
eight-character password must be used or the update will be rejected. Password
authentication is used only to protect against accidents. It is not
intended to protect against malicious actions. Stronger authentication
based on MD5 is being developed.
The interface that connects this router to the backbone area is defined
by the interface clause. It has two associated subclauses. The
authkey "It'sREAL" ;
clause defines the password used for
simple authentication by this interface. The priority 5 ;
clause defines the priority used by this router when the backbone is
electing a designated router. The higher the priority number, the less
likely a router will be elected as the designated router. Use
priority
to steer the election toward the most capable
routers.
The configuration for gateway brazil is the most complex because it runs both OSPF and BGP. The configuration file for gateway brazil is:
# Defines our AS number for BGP autonomoussystem 249; # Defines the OSPF router id routerid 172.16.1.1; # Disable RIP rip no; # Enable BGP bgp yes { preference 50 ; group type external peeras 164 { peer 10.6.0.103 ; peer 10.20.0.72 ; }; }; # Enable OSPF; subnet 1 is the backbone area; # use password authentication. ospf yes { backbone { authtype simple ; interface 172.16.1.1 { priority 10 ; authkey "It'sREAL" ; } ; } ; }; # Announce routes learned from OSPF and route # to directly connected network via BGP to AS 164 export proto bgp as 164 { proto direct ; proto ospf ; }; # Announce routes learned via BGP from # AS number 164 to our OSPF area. export proto ospfase type 2 { proto bgp as 164 { all ; }; };
This configuration enables both BGP and OSPF, and sets certain
protocol-specific parameters. BGP needs to know the AS number, which
is 249 for nuts-net. OSPF needs to know the router identifier
address. We set it to the address of the router interface that runs
OSPF. The AS number and the router identifier are defined early in the
configuration because autonomoussystem
and routerid
are definition statements, and therefore must occur before the first
protocol statement. Refer back to
Table 7.2
for the various statement types.
The first protocol statement is the one that turns RIP off. We don't
want to run RIP and the default for gated is to turn RIP on.
Therefore we explicitly disable RIP with the rip no ;
statement.
BGP is enabled by the egp yes
statement, which also defines a
few additional BGP parameters. The preference 50 ;
clause
tells gated to set the preference for routes received via BGP to
50. The default for these routes is 170. By changing the preference to 50,
we make the routes highly favored. Setting a preference value of 50
allows BGP routes to override static routes, though they will not
override routes learned from OSPF. This is solely for the purpose
of illustration. You probably don't want to make an external route
highly preferred. See
Table 7.1
for the list of
default preferences.
The group
clause sets parameters for all of the BGP peers in the
group. The clause defines the type of BGP connection being created. The
example is a classic external routing protocol connection, and the
external autonomous system we are connecting to is AS number 164.
gated can create five different types of BGP sessions, but only
one, type external
, is used to directly communicate with an
external autonomous system. The other four group types are used for
internal BGP (IBGP).
[14]
IBGP is simply an acronym used for BGP when it is used to move routing
information around inside of an autonomous system. In our example we
use it to move routing information between autonomous systems.
[14] See Appendix B for information on all group types.
The BGP neighbors from which updates are accepted are indicated by the
peer clauses. Each peer is a member of
the group. Everything related to the group, such as the AS number,
applies to every system in the group. To accept updates from any system, use
allow
in place of the list of peers.
The OSPF protocol is enabled by the ospf yes statement. The configuration of OSPF on this router is the same as it is for other routers in the backbone area. The only parameter that has been changed from the previous example is the priority number. Because this route has a particularly heavy load, we have decided to make it slightly less preferred for the designated router election.
The export statements control the routes that gated advertises to
other routers. The first export statement directs gated to use
BGP (proto bgp
) to advertise to autonomous system 164 (as
164
) any directly connected networks (proto direct
) and any
routes learned from OSPF (proto ospf
). Notice that the AS
number specified in this statement is not the AS number of
nuts-net. It is the autonomous system number of the external
system. The first line of the export statement defines to whom we are
advertising. The proto clauses located within the curly braces define
what we are advertising.
The second export statement announces the routes learned from the
external autonomous system. The routes are received via BGP and are
advertised via OSPF. Because these are routes from an external
autonomous system, they are advertised as autonomous system
external (ASE) routes. That's why the export statement specifies
ospfase
as the protocol through which the routes are
announced. The type 2
parameter defines the type of external
routes that are being advertised. There are two types supported by
gated. Type 2 routes are those learned from an exterior gateway
protocol that does not provide a routing metric comparable to the OSPF
metric. These routes are advertised with the cost of reaching the
border router. In this case, the routes are advertised with the OSPF
cost of reaching gateway brazil. Type 1 routes are those learned from
an external protocol that does provide a metric directly comparable to
the OSPF metric. In that case, the metric from the external protocol
is added to the cost of reaching the border router when routes are
advertised.
The source of the routes advertised in the second export statement is
the BGP connection (proto bgp
) to autonomous system 164
(as 164
). The proto clause is qualified with an optional
route filter. A route filter is used to select the routes from a
specific source. The filter can list
networks with associated netmasks to select an individual destination. In
the example, the keyword all
is used to select all routes
received via BGP, which is, in fact, the default.
All of the routes received from an external autonomous system could
produce a very large routing table. Individual routes are useful when
you have multiple border routers that can reach the outside world.
However, if you have only one border router, a default route may be all
that is needed. To export a default route, insert an options
gendefault ;
statement in the beginning of the configuration
file.
[15]
This tells gated to generate a default route
when the system peers with a BGP neighbor. Next, replace the second export statement in the sample file with the following export statement:
[15] The
generate
statement is an alternative way to create a default route. See Appendix B for details.
# Announce a default route when peering # with a BGP neighbor. export proto ospfase type 2 { proto default ; };
This export statement tells gated to advertise the border router as the default gateway, but only when it has an active connection to the external system.
These few examples show that gated.conf files are usually small and easy to read. Use gated if you need to run a routing protocol on your computer. It allows you to use the same software and the same configuration language on all of your hosts, interior gateways, and exterior gateways.
Test the configuration file before you try to use it. The gated configuration syntax is complex and it is easy to make a mistake. Create your new configuration in a test file; test the new configuration; then move the test configuration to /etc/gated.conf. Here's how.
Assume that a configuration file called test.conf has already been created. It is tested using -f and -c on the command line:
%gated -c -f test.conf trace.test
The -f option tells gated to read the configuration from the named file instead of from /etc/gated.conf. In the sample it reads the configuration from test.conf. The -c option tells gated to read the configuration file and check for syntax errors. When gated finishes reading the file, it terminates; it does not modify the routing table. The -c option turns on tracing, so specify a trace file or the trace data will be displayed on your terminal. In the sample we specified trace.test as the trace file. The -c option also produces a snapshot of the state of gated after reading the configuration file and writes the snapshot to /usr/tmp/gated_dump. You don't need to be superuser or to terminate the active gated process to run gated when the -c option is used.
The dump and the trace file (trace.test) can then be examined for errors and other information. When you're confident that the configuration is correct, become superuser and move your new configuration (test.conf) to /etc/gated.conf.
An alternative command for testing the configuration file is gdc, though it must be run by the root user. It includes features for checking and installing a new configuration. gdc uses three different configuration files. The current configuration is /etc/gated.conf. The previous configuration is stored in /etc/gated.conf-. The "next" configuration is stored in /etc/gated.conf+, which is normally the configuration that needs to be tested. Here's how gdc tests a configuration:
#cp test.conf /etc/gated.conf+
#gdc checknew
configuration file /etc/gated.conf+ checks out okay #gdc newconf
#gdc restart
gated not currently running gdc: /etc/gated was started
In this sample the test configuration was copied to /etc/gated.conf+ and tested with the gdc checknew command. If syntax problems are found in the file, a warning message is displayed and the detailed error messages are written to /usr/tmp/gated_parse. There were no syntax errors in the example so we make the test file the current configuration with the gdc newconf command. This command moves the current configuration to gated.conf- and moves the new configuration (gated.conf+) to the current configuration. The gdc restart command terminates gated if it is currently running - it was not in the example - and starts a new copy of gated using the new configuration.
As with any routing software, gated should be included in your startup file. Some systems come with the code to start gated included in the startup file. If your system doesn't, you'll need to add it. If you already have code in your startup file that runs routed, replace it with code to run gated. gated and routed should not be running at the same time.
Our imaginary gateway, almond, is a Solaris system with code in the /etc/init.d/inetinit file that starts routed. We comment out those lines, and add these lines:
if [ -f /usr/sbin/gated -a -f /etc/gated.conf ]; then /usr/sbin/gated; echo -n 'gated' > /dev/console fi
This code assumes that gated is installed in /usr/sbin and that the configuration file is named /etc/gated.conf. The code checks that gated is present, and that the configuration file /etc/gated.conf exists. If both files are found, gated begins.
The code checks for a configuration file because gated usually runs with one. If gated is started without a configuration file, it checks the routing table for a default route. If it doesn't find one, it starts RIP; otherwise, it just uses the default route. Create an /etc/gated.conf file even if you only want to run RIP. The configuration file documents your routing configuration and protects you if the default configuration of gated changes in the future.