Open Shortest Path First: Difference between revisions

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imported>Howard C. Berkowitz
(details of area and route types, work in progress)
imported>Howard C. Berkowitz
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Combining the standard NSSA and the Cisco totally stubby feture, an area of this type behaves like an NSSA in that it can have an ASBR, but it only accepts default from area 0.0.0.0.
Combining the standard NSSA and the Cisco totally stubby feture, an area of this type behaves like an NSSA in that it can have an ASBR, but it only accepts default from area 0.0.0.0.
==Intra-area behavior==
==Intra-area behavior==
While OSPF, as a whole, is usually called a [[link state]] protocol, there is a separate link state computation for each nonzero area.
===OSPF router initialization===
Each OSPF router must have a router ID unique to the routing domain. This is a 32 bit number that is usually displayed in the dotted decimal notation used for IPv4, but there is no requirement that the router ID be a valid IP address. 
A common source of the router ID is what is variously called a "loopback interface" on the router. If no such software-defined interface exists, there are implementation-specific means to assign one, most commonly the IP address of the first LAN interface on which OSPF initializes.
The best practice, to avoid surprises, is, if the OSPF implementation allows it, to configure an explicit router ID.
===Neighbor relationship===
===Election of designated routers===
===Populating the area link state data base===
===Computing the shortest path tree for the area===


==Subnet and router interface behavior==
==Subnet and router interface behavior==


==References==
==References==

Revision as of 14:49, 29 July 2008

This article is a stub and thus not approved.
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Open Shortest Path First (OSPF) is one of the two nonproprietary and highly scalable interior routing protocols of the Internet, the other being Intermediate System-Intermediate System (ISIS). Its principal specification is RFC 2328.

OSPF is designed for hierarchical routing, from a set of nonzero "edge" areas, to a backbone area, forming a routing domain. Contrary to some misperceptions, there is absolutely no reason not to have multiple OSPF domains (i.e., a backbone area 0.0.0.0 and some number of nonzero areas), connected by a backbone of backbones. Examples of such networks, include, for example, the OSPF domains are continental, and the backbone of backbones is BGP when the policies are complex and static routing when the network is fundamentally hierarchical with 3 or more levels of hierarchy.

Router types

OSPF has some inconsistent ways to refer to "router". As used in this section, a router is a multiple-interface device with interfaces in one or more areas. There is another OSPF usage of the word "router", discussed under "neighbor discovery", that is an attribute of an interface of a router.

Route types

At the highest level, OSPF knows about two kind of routes; an OSPF concept called a virtual route is outside the scope of the immediate discussion.:

Internal routes

These originate inside the domain, and may be intra-area or inter-area.

External routes

External routes are generated from ASBRs that connect the domain to other sources of routing information, including manually generated static routes. In most OSPF implementations, unless otherwise specified, externals are of Type 2: their cost is that of the external interface only. An external route can be configured as Type 1, which means that its cost will be the sum of the external interface cost plus the cost of all internal interfaces traversed from the starting point, through the domain, to the ASBR external interface.

Area organization

OSPF has two basic kinds of areas, always with a 32-bit area identifier. That identifier is usually displayed in the dotted decimal form of an IP address, but it doesn't need to comply with IP addressing rules.

The backbone area must always be 0.0.0.0; the remaining areas can use any other identifier. It can be perfectly reasonable to start with a single OSPF area, but it is unwise to designate that 0.0.0.0, because as soon as another area is needed, you would have to renumber the existing routers into a nonzero area.

Three types of area characteristics are standard; Cisco defined an additional one that is widely used.

Regular area

Connected to area 0.0.0.0 by one or more area border routers, a regular area accepts all types of internal and external routes from area 0.0.0.0, or from autonomous system border routers in the regular area that connect outside it. Advertises both its intra-area routes, and external routes from ASBRs connected to it, to the backbone.

Stub area

Also connected to the backbone via one or more ABRs, it accepts only inter-area routes and a default route generated by the ABR; advertises its intra-area routes to the backbone. It cannot contain an ASBR.

Not-so-stubby area (NSSA)

From one or more ABRs, it accepts only inter-area routes from area 0.0.0.0, to which it advertises its intra-area routes. A NSSA also can contain an ASBR, whose external routes propagate through the area and then, via the ABR, to area 0.0.0.0. HSSAs are defined in RFC 3101.

Totally stubby area

A Cisco proprietary feature that is present in some other implementations, a totally stubby area can have one or more ABRs, to which it advertises its intra-area routes. It accepts only the default routes generated by the ABR(s). Unless it is declared not-so-stubby as well, it cannot contain an ASBR.

Not-so-stubby and totally stubby

Combining the standard NSSA and the Cisco totally stubby feture, an area of this type behaves like an NSSA in that it can have an ASBR, but it only accepts default from area 0.0.0.0.

Intra-area behavior

While OSPF, as a whole, is usually called a link state protocol, there is a separate link state computation for each nonzero area.

OSPF router initialization

Each OSPF router must have a router ID unique to the routing domain. This is a 32 bit number that is usually displayed in the dotted decimal notation used for IPv4, but there is no requirement that the router ID be a valid IP address.

A common source of the router ID is what is variously called a "loopback interface" on the router. If no such software-defined interface exists, there are implementation-specific means to assign one, most commonly the IP address of the first LAN interface on which OSPF initializes.

The best practice, to avoid surprises, is, if the OSPF implementation allows it, to configure an explicit router ID.

Neighbor relationship

Election of designated routers

Populating the area link state data base

Computing the shortest path tree for the area

Subnet and router interface behavior

References