here's as far we have got.
Tony Bates
Tue May 24 17:25:22 CEST 1994
Find below the latest draft of RIPE-81++. This trys to incorperate the changes
mentioned and also proposes the interas-in and interas-out syntax we suggested
with some explainatory text. Other changes are more general with
a big tidy of syntax and all additions as per "time to converge" paper.
The one caveat to this is the components part has only minor changes which we
hope make it more readable now without having to do a major re-write. For our
part we are now going to stand back from it for a few days and take in all the
comments. These will then be edited in for sending out to the RIPE list as
agreed.
Please also note that whilst the ascii version is fine for annotating and
comments the postscript version may be more readable especially for the syntax
formats as they now look.
The postscript version is available from
ftp.ripe.net:ripe/drafts/ripe-81++.ps
Regards,
--Tony.
Representation of IP Routing Policies
in a Routing Registry
(ripe-81++)
DRAFT DRAFT DRAFT
Tony Bates
Elise Gerich
Laurent Joncheray
Jean-Michel Jouanigot
Daniel Karrenberg
Marten Terpstra
Jessica Yu
Document-ID: ripe-1nn
Obsoletes: ripe-81
May, 1994
ABSTRACT
This document is an update to the original `ripe-
81'[1] proposal for representing and storing routing
polices within the RIPE database. It incorporates
several extensions proposed by Merit Inc.[2] and gives
details of a generalised IP routing policy representa-
tion to be used by all Internet routing registries. It
acts as both tutorial and provides details of database
objects and attributes that use and make up a routing
registry.
ripe-1nn.txt May, 1994
- 2 -
Table of Contents
1 Introduction ................................................ ?
2 Organisation of this Document ............................... ?
3 General Representation of Policy Information ................ ?
4 The Routing Registry and the RIPE Database .................. ?
5 The Route Object ............................................ ?
6 The Autonomous System Object ................................ ?
7 The AS Macro Object ......................................... ?
8 The Community Object ........................................ ?
9 Representation of Routing Policies .......................... ?
10 References ................................................. ?
11 Authors Addresses .......................................... ?
Appendix A - Syntax for the "aut-num" object .................. ?
Appendix B - Syntax for the "community" object ................ ?
Appendix C - Syntax for the "as-macro" object ................. ?
Appendix D - Syntax for the "route" object .................... ?
Appendix E - Motivations for RIPE-81++ ........................ ?
Appendix F - Transition strategy from RIPE-81 to RIPE-81++ .... ?
ripe-1nn.txt May, 1994
- 3 -
1. Introduction
This document is a much revised version of the RIPE routing registry
document known as ripe-81[1]. Since its inception in February, 1993
and the establishment of the RIPE routing registry, several addi-
tions and clarifications have come to light which can be better
presented in a single updated document rather than separate addenda.
Some of the text remains the same the as the original ripe-81 docu-
ment keeping its tutorial style mixed with details of the RIPE data-
base objects relating to routing policy representation. However
this document does not repeat the background and historical remarks
in ripe-81. For these please refer to the original document. It
should be noted that whilst this document specifically references
the RIPE database and the RIPE routing registry one can easily read
"Regional routing registry" in place of RIPE as this representation
is certainly general and flexible enough to be used outside of the
RIPE community incorporating many ideas and features from other
routing registries in this update.
As you can see this document has a new RIPE document identification
number but can also be referred to as ripe-81++. Appendix E summar-
ises the changes from ripe-81 plus the motivation for these changes.
We would like to acknowledge many people for help with this docu-
ment. Specifically, Peter Lothberg who was a co-author of the ori-
ginal ripe-81 document for his many ideas and Gilles Farrache. We
would also like to thank the RIPE routing working group for their
review and comment. Finally, we like to thank Merit Inc. for many
constructive comments and ideas and making the routing registry a
worldwide Internet service. We would also like to acknowledge the
funding provided by the PRIDE project run in conjunction with the
RARE Technical Program, RIPE and the RIPE NCC without which this
paper would not have been possible.
2. Organisation of this Paper
This paper acts as both a basic tutorial for understanding routing
policy and provides details of objects and attributes used within an
Internet routing registry to store routing policies. Section 3
describes general issues about IP routing policies and their
representation in routing registries. Experienced readers may wish
to skip this section. Section 4 provides an overview of the RIPE
database, its basic concepts, schema and objects which make up the
database itself. It highlights the way in which the RIPE database
splits routing information from allocation information. Sections 5,
6, 7 and 8 detail all the objects associated with routing policy
representation. Section 9 gives a fairly extensive "walk through"
of how these objects are used for expressing routing policy and the
general principles behind their use. Section 10 provides a list of
references used throughout this document. Appendix A, B, C and D
document the formal syntax for the database objects and attributes.
Appendix E details the main changes from ripe-81 and motivations for
these changes. Appendix F tackles the issues of transition from
ripe-1nn.txt May, 1994
- 4 -
ripe-81 to ripe-81++.
ripe-1nn.txt May, 1994
- 5 -
3. General Representation of Policy Information
Networks, Network Operators and Autonomous Systems
Throughout this document an effort is made to be consistent with
terms so as not to confuse the reader.
When we talk about "networks" we mean physical networks which have a
unique classless IP network number: Layer 3 entities. We do not mean
organisations.
We call the organisations operating networks "network operators".
For the sake of the examples we divide network operators into two
categories: "service providers" and "customers". A "service pro-
vider" is a network operator who operates a network to provide
Internet services to different organisations, its "customers". The
distinction between service providers and customers is not clear
cut. A national research networking organisation frequently acts as
a service provider to Universities and other academic organisations,
but in most cases it buys international connectivity from another
service provider. A University networking department is a customer
of the research networking organisation but in turn may regard
University departments as its customers.
An Autonomous System (AS) is a group of IP networks having a single
clearly defined routing policy which is run by one or more network
operators. Inside ASes IP packets are routed using one or more Inte-
rior Routing Protocols (IGPs). In most cases interior routing deci-
sions are based on metrics derived from technical parameters like
topology, link speeds and load(1).
ASes exchange routing information with other ASes using Exterior
Routing Protocols (EGPs). Exterior routing decisions are frequently
based on policy based rules rather than purely on technical parame-
ters. Tools are needed to configure complex policies and to commun-
icate those policies between ASes while still ensuring proper opera-
tion of the Internet as a whole. Some EGPs like BGP-3 [8] and BGP-4
[9] provide tools to filter routing information according to policy
rules and more. None of them provides a mechanism to publish or com-
municate the policies themselves. Yet this is critical for opera-
tional coordination and fault isolation among network operators and
thus for the operation of the global Internet as a whole. This
document describes a "Routing Registry" providing this functional-
ity.
_________________________
(1) The entity we refer to as an AS is frequently and
more generally called a routing domain with the AS just
being an implementation vehicle. We have decided to use
the term AS exclusively because it relates more direct-
ly with the database objects and routing tools. By us-
ing only one term we hope to reduce the number of con-
cepts and to avoid confusion. The academically inclined
reader may forgive us.
ripe-1nn.txt May, 1994
- 6 -
Routing Policies
The exchange of routing information between ASes is subject to rout-
ing policies. Consider the case of two ASes, X and Y exchanging
routing information:
NET1 ...... ASX <---> ASY ....... NET2
ASX knows how to reach a network called NET1. It does not matter
whether NET1 is belonging to ASX or some other AS which exchanges
routing information with ASX either directly or indirectly; we just
assume that ASX knows how to direct packets towards NET1. Likewise
ASY knows how to reach NET2.
In order for traffic from NET2 to NET1 to flow between ASX and ASY,
ASX has to announce NET1 to ASY using an external routing protocol.
This states that ASX is willing to accept traffic directed to NET1
from ASY. Policy thus comes into play first in the decision of ASX
to announce NET1 to ASY.
In addition ASY has to accept this routing information and use it.
It is ASY's privilege to either use or disregard the information
that ASX is willing to accept traffic for NET1. ASY might decide not
to use this information if it does not want to send traffic to NET1
at all or if it considers another route more appropriate to reach
NET1.
So in order for traffic in the direction of NET1 to flow between ASX
and ASY, ASX must announce it to ASY and ASY must accept it from
ASX:
resulting packet flow towards NET1
<<===================================
|
|
announce NET1 | accept NET1
--------------> + ------------->
|
AS X | AS Y
|
<------------- + <--------------
accept NET2 | announce NET2
|
|
resulting packet flow towards NET2
===================================>>
Ideally, and seldom practically, the announcement and acceptance
policies of ASX and ASY are identical.
ripe-1nn.txt May, 1994
- 7 -
In order for traffic towards NET2 to flow, announcement and accep-
tance of NET2 must be in place the other way round. For almost all
applications connectivity in just one direction is not useful at
all.
It is important to realise that with current destination based for-
warding technology routing policies must eventually be expressed in
these terms. It is relatively easy to formulate reasonable policies
in very general terms which CANNOT be expressed in terms of announc-
ing and accepting networks. With current technology such policies
are almost always impossible to implement.
Usually policies are not configured for each network separately but
for groups of networks. In practise these groups are almost always
defined by the networks forming one or more ASes.
Routing Policy limitations
The generic example of a reasonable but un-implementable routing is
a split of already joined packet streams based on something other
than destination address. Once traffic for the same destination
network passes the same router, or the same AS at our level of
abstraction, it will take exactly the same route to the destina-
tion(2).
In a concrete example AS Z might be connected to the outside world
by two links. AS Z wishes to reserve these links for different
kinds of traffic, let's call them black and white traffic. For this
purpose the management of AS Z keeps two lists of ASes, the black
and the white list. Together these lists comprise all ASes in the
world reachable from AS Z.
"W"
<--->
... AS Z .... NET 3
<--->
"B"
It is quite possible to implement the policy for traffic originating
in AS Z: AS Z will only accept announcements for networks in white
ASes on the white link and will only accept announcements for net-
works in black ASes on the black link. This causes traffic from
networks within AS Z towards white ASes to use the white link and
likewise traffic for black ASes to use the black link.
Note that this way of implementing things makes it necessary to
decide on the colour of each new AS which appears before traffic can
be sent to it from AS Z. A way around this would be to accept only
_________________________
(2) Disregarding special cases like "type of service"
routing, load sharing and routing instabilities.
ripe-1nn.txt May, 1994
- 8 -
white announcements via the white link and to accept all but white
announcements on the black link. That way traffic from new ASes
would automatically be sent down the black link and AS Z management
would only need to keep the list of white ASes rather than two
lists.
Now for the unimplementable part of the policy. This concerns
traffic towards AS Z. Consider the following topology:
B AS ---) "W"
W AS ---) --->
B AS ---)>> AS A ---> ... AS Z .... NET 3
B AS ---) --->
W AS ---) "B"
As seen from AS Z there are both black and white ASes "behind" AS A.
Since ASes can make routing decisions based on destination only, AS
A and all ASes between AS A and the two links connecting AS Z can
only make the same decision for traffic directed at a network in AS
Z, say NET 3. This means that traffic from both black and white
ASes towards NET 3 will follow the same route once it passes through
AS A. This will either be the black or the white route depending on
the routing policies of AS A and all ASes between it and AS Z.
The important thing to note is that unless routing and forwarding
decisions can be made based on both source and destination
addresses, policies like the "black and white" example cannot be
implemented in general because "once joined means joined forever".
Access Policies
Access policies contrary to routing policies are not necessarily
defined in terms of ASes. The very simplest type of access policy is
to block packets from a specific network S from being forwarded to
another network D. A common example is when some inappropriate use
of resources on network D has been made from network S and the prob-
lem has not been resolved yet. Other examples of access policies
might be resources only accessible to networks belonging to a par-
ticular disciplinary group or community of interest. While most of
these policies are better implemented at the host or application
level, network level access policies do exist and are a source of
connectivity problems which are sometimes hard to diagnose. There-
fore they should also be documented in the routing registry accord-
ing to similar requirements as outlined above.
Routing v Allocation information
The RIPE database contains both routing registry and address space
allocation registry information. In the past the database schema
combined this information. Because RIPE was tasked with running both
an allocation and routing registry it seemed natural to initially
ripe-1nn.txt May, 1994
- 9 -
combine these functions. However, experience has shown that a clear
separation of routing information from allocation is desirable.
Often the maintainer of the routing information is not the same as
the maintainer of the allocation information. Also, in other parts
of the world there are different registries for each kind of infor-
mation.
Whilst the actual routing policy objects will be introduced in the
next section it is worthy of note that a transition from the current
objects will be required. This is described with in Appendix F.
This split in information represents a significant change in the
representational model of the RIPE database. Appendix E expands on
the reasons for this a little more.
Tools
The network operators will need a series of tools for policy rout-
ing. Some tools are already available to perform some of the tasks.
Most notably, the PRIDE tools [3] from the PRIDE project started in
September 1993 as well as others produced by Merit Inc [4] and CERN
[5].
These tools will enable them to use the routing policy stored in the
RIPE routing registry to perform such tasks as check actual routing
against policies defined, ensure consistency of policies set by dif-
ferent operators, and simulate the effects of policy changes.
Work continues on producing more useful tools to service the Inter-
net community.
ripe-1nn.txt May, 1994
- 10 -
4. The Routing Registry and the RIPE Database
One of the activities of RIPE is to maintain a database of Euro-
pean IP networks, DNS domains and their contact persons along with
various other kinds of network management information. The database
content is public and can be queried using the whois protocol as
well as retrieved as a whole. This supports NICs/NOCs all over
Europe and beyond to perform their respective tasks.
The RIPE database combines both allocation registry and routing
registry functions. The RIPE allocation registry contains data
about address space allocated to specific enterprises and/or
delegated to local registries as well as data about the domain name
space. The allocation registry is described in separate documents
[6,7] and outside the scope of this document.
Database Objects
Each object in the database describes a single entity in the real
world. This basic principle means that information about that
entity should only be represented in the corresponding data-
base object and not be repeated in other objects. The whois ser-
vice can automatically display referenced objects where appropriate.
The types of objects stored in the RIPE database are summarised in
the table below:
R Object Describes References
____________________________________________________________________
B person contact persons
A inetnum IP address space person
A domain DNS domain person
R aut-num autonomous system person
(aut-num,community)
R as-macro a group of autonomous systems person, aut-num
R community community person
R route a route being announced aut-num, community
R clns CLNS address space and routing person
The first column indicates whether the object is part of the alloca-
tion registry (A), the routing registry (R) or both (B). The last
column indicates the types of objects referenced by the particular
type of object. It can be seen that almost all objects reference
contact persons.
Objects are described by attributes value pairs, one per line.
Objects are separated by empty lines. An attribute that consists
ripe-1nn.txt May, 1994
- 11 -
of multiple lines should have the attribute name repeated on
consecutive lines. The information stored about network 192.87.45.0
consists of three objects, one network object and two person
objects and looks like this:
inetnum: 192.87.45.0
netname: RIPE-NCC
descr: RIPE Network Coordination Centre
descr: Amsterdam, Netherlands
country: NL
admin-c: Daniel Karrenberg
tech-c: Marten Terpstra
rev-srv: ns.ripe.net
rev-srv: ns.eu.net
notify: ops at ripe.net
changed: tony at ripe.net 940110
source: RIPE
person: Daniel Karrenberg
address: RIPE Network Coordination Centre (NCC)
address: Kruislaan 409
address: NL-1098 SJ Amsterdam
address: Netherlands
phone: +31 20 592 5065
fax-no: +31 20 592 5090
e-mail: dfk at ripe.net
nic-hdl: DK58
changed: ripe-dbm at ripe.net 920826
source: RIPE
person: Marten Terpstra
address: RIPE Network Coordination Centre (NCC)
address: PRIDE Project
address: Kruislaan 409
address: NL-1098 SJ Amsterdam
address: Netherlands
phone: +31 20 592 5064
fax-no: +31 20 592 5090
e-mail: Marten.Terpstra at ripe.net
nic-hdl: MT2
notify: marten at ripe.net
changed: marten at ripe.net 931230
source: RIPE
Objects are stored and retrieved in this tag/value format. The RIPE
NCC does not provide differently formatted reports because any
desired format can easily be produced from this generic one.
ripe-1nn.txt May, 1994
- 12 -
Routing Registry Objects
The main objects comprising the routing registry are "aut-num" and
"route", describing an autonomous system and a route respectively.
It should be noted that routes not described in the routing registry
should never be routed in the Internet itself.
The autonomous system (aut-num) object provides contact information
for the AS and describes the routing policy of that AS. The routing
policy is described by enumerating all neighbouring ASes with which
routing information is exchanged. For each neighbour the routing
policy is described in terms of exactly what is being sent
(announced) and allowed in (accepted). It is important to note that
this is exactly the part of the global policy over which an AS has
direct control. Thus each aut-num object describes what can indeed
be implemented and enforced locally by the AS concerned. Combined
together all the aut-num objects provide the global routing graph
and permit to deduce the exact routing policy between any two ASes.
While the aut-num objects describe how routing information is pro-
pagated, the route object describes a single route injected into the
external routing mesh. The route object references the AS injecting
(originating) the route and thereby indirectly provides contact
information for the originating AS. This reference also provides the
primary way of grouping routes into larger collections. This is
necessary because describing routing policy on the level of single
routes would be awkward to impractical given the number of routes in
the Internet which is about 20,000 at the time of this writing.
Thus routing policy is most often defined for groups of routes by
originating AS. This method of grouping is well supported by
current exterior routing protocols. The route object also refer-
ences community objects described below to provide another method of
grouping routes. Modification of aut-num object itself and the
referencing by route objects is strictly protected to provide net-
work operators control over the routing policy description and the
routes originated by their ASes.
Sometimes even keeping track of groups of routes at the AS level is
cumbersome. Consider the case of policies described at the transit
provider level which apply transitively to all customers of the
transit provider. Therefore another level of grouping is provided by
the as-macro object which provides groups of ASes which can be
referenced in routing policies just like single ASes. Membership of
as-macro groups is also strictly controlled.
Sometimes there is a need to group routes on different criteria than
ASes for purposes like statistics or local access policies. This is
provided by the community object. A community object is much like
an AS but without a routing policy. It just describes a group of
routes. This is not supported at all by exterior routing protocols
and depending on aggregation of routes may not be generally usable
to define routing policies. It is suitable for local policies and
non-routing related purposes.
ripe-1nn.txt May, 1994
- 13 -
These routing related objects will be described in detail in the
sections below.
ripe-1nn.txt May, 1994
- 14 -
5. The Route Object
As stated in the previous chapter routing and address space alloca-
tion information are now clearly separated. This is performed with
the introduction of the route object. The route object will contain
all the information regarding a routing announcement.
All routing related attributes are removed from the inetnum object.
Some old attributes are obsoleted: connect, routpr-l, bdryg-l, nsf-
in, nsf-out, gateway). The currently useful routing attributes are
moved to the route object: aut-sys becomes origin, ias-int is
encoded in the component attribute and comm-list simply moves. See
[6] for detail of the "inetnum" object definition.
The information in the old inetnum object
inetnum: 192.87.45.0
netname: RIPE-NCC
descr: RIPE Network Coordination Centre
descr: Amsterdam, Netherlands
country: NL
admin-c: Daniel Karrenberg
tech-c: Marten Terpstra
connect: RIPE NSF WCW
aut-sys: AS3333
comm-list: SURFNET
ias-int: 192.87.45.80 AS1104
ias-int: 192.87.45.6 AS2122
ias-int: 192.87.45.254 AS2600
rev-srv: ns.ripe.net
rev-srv: ns.eu.net
notify: ops at ripe.net
changed: tony at ripe.net 940110
source: RIPE
will be distributed over two objects:
ripe-1nn.txt May, 1994
- 15 -
inetnum: 192.87.45.0
netname: RIPE-NCC
descr: RIPE Network Coordination Centre
descr: Amsterdam, Netherlands
country: NL
admin-c: Daniel Karrenberg
tech-c: Marten Terpstra
rev-srv: ns.ripe.net
rev-srv: ns.eu.net
notify: ops at ripe.net
changed: tony at ripe.net 940110
source: RIPE
route: 192.87.45.0/24
descr: RIPE Network Coordination Centre
origin: AS3333
comm-list: SURFNET
component: 192.87.45.80/32 AS1104
component: 192.87.45.6/32 AS2122
component: 192.87.45.254/32 AS2600
changed: dfk at ripe.net 940427
source: RIPE
The route object is used to represent a single route originated into
the Internet routing mesh. The actual syntax is given in Appendix
D. However, there are several important aspects of the attributes
worthy of note.
The value of the route attribute will be a classless address. It
represents the exact route being injected into the routing mesh.
The representation of classless addresses is described in [10].
The value of the origin attribute will be an AS reference of the
form AS1234 referring to an aut-num object. It represents the AS
injecting this route into the routing mesh. The "aut-num" object
(see below) thus referenced provides all the contact information for
this route.
Special cases: There can only be a single originating AS in each
route object. However in todays Internet sometimes a route is
injected by more than one AS. In the routing registry this is
represented by multiple route objects. This situation is poten-
tially dangerous as it can create conflicting routing policies for
that route and requires coordination between the originating ASes.
This is a departure from the one route (net), one AS principle of
the ripe-81 routing registry. The consequences for the different
tools based in the routing registry need to be evaluated and
ripe-1nn.txt May, 1994
- 16 -
possibly additional consistency checking of the database is needed.
The component attributes describe components of an aggregate route
which go to make up the aggregate route itself. The component attri-
bute is not used for routing itself as an advisory for routing
information. See the examples below for a more detailed explana-
tion.
The examples below will illustrate the usage of the route object
further. Suppose three chunks of address space of 2 different
enterprises. represented by the following inetnum objects:
Examples
inetnum: 193.0.1.0
netname: ENT-1
descr: Enterprise 1
...
inetnum: 193.0.8.0
netname: ENT-2
descr: Enterprise 2
...
inetnum: 193.0.9.0
netname: ENT-2-SPEC
descr: Enterprise 2
...
Supposing that the Enterprises have their own AS numbers straight
application of routing without aggregation would yield:
route: 193.0.1.0/24
descr: Enterprise 1
origin: AS1
...
route: 193.0.8.0/24
descr: Enterprise 2
origin: AS2
...
route: 193.0.9.0/24
descr: Enterprise 2
origin: AS2
...
NB: This representation can be achieved by straight translation from
ripe-1nn.txt May, 1994
- 17 -
the ripe-81 representation. See Appendix F for more details.
Homogeneous Aggregation
The two chunks of address space of Enterprise 2 can be represented
by one aggregate route turning two route objects into one and poten-
tially saving routing table space for one route.
route: 193.0.8.0/2
descr: Enterprise 2
origin: AS2
...
Note that AS2 can also decide to originate all routes mentioned so
far, two 24-bit prefixes and one 23-bit prefix. This case would be
represented by storing all three route objects in the database. In
this particular example the additional routes will not add any func-
tionality however and only increase the amount of routes announced
unnecessarily.
Heterogeneous Aggregation
Consider the following case however:
route: 193.0.8.0/24
descr: Enterprise 2
origin: AS2
...
route: 193.0.9.0/24
descr: Enterprise 2 / Special
origin: AS2
comm-list: SPECIAL
...
Now the prefix 193.0.9.0/24 belongs to community SPECIAL (this com-
munity may well not be relevant to routing) and the other prefix
originated by AS2 does not. If AS2 aggregates these prefixes into
the 193.0.8.0/23 prefix, routing policies based on the community
value SPECIAL cannot be implemented in general, because there is no
way to distinguish between the special and the not-so-special parts
of AS2. If another AS has the policy to accept only routes to
members of community SPECIAL it cannot implement it, because accept-
ing the route to 193.0.8.0/23 would also route to 193.0.8.0/24 and
not accepting this route would lose connectivity to the special part
193.0.9.0/24. We call aggregate routes consisting of components
belonging to different communities or even different ASes "hetero-
geneous aggregates".
ripe-1nn.txt May, 1994
- 18 -
In many instances the problems introduced by heterogeneous aggre-
gates are not relevant because they break no routing policies. In
our example it might be that no-one cares that part of AS2 is spe-
cial after all. However AS2 cannot know this before making the deci-
sion without examining all routing policies in the routing registry.
And even if AS2 did this some other AS later on may want to use the
fact that AS2 is special. So there has to be a way for AS2 to docu-
ment this even if it does not originate the route to 193.0.9.0/24
any more. This can be done with the "component" attribute of the
route object. The aggregate route to 193.0.8.0/23 could now be
registered as:
route: 193.0.8.0/23
descr: Enterprise 2
origin: AS2
component: 193.0.8.0/24 AS2
component: 193.0.9.0/24 AS2 SPECIAL
...
The component attribute lists in order the prefix of the component,
the autonomous system and the list of communities. Components which
belong to the same AS and communities as the route itself need not
be generally listed as this information is redundant. With the help
of the component attributes other ASes can find out if their routing
policies are implementable. Also consistency checks of the routing
registry can be done. Components referencing prefixes which are
described by either route or inetnum objects in the registries
should be avoided. Again, it should be noted that components them-
selves are not used for routing.
Proxy Aggregation
The next step of aggregation are aggregates consisting of more than
one AS. This generally means one AS is aggregating on behalf of
another. It is called proxy aggregation. Proxy aggregation should be
done with great care and always coordinators with other providers
announcing the same route.
Consider the following:
route: 193.0.0.0/20
descr: All routes known by AS1 in a single package
origin: AS1
component: 193.0.1.0/24 AS1
component: 193.0.8.0/24 AS2
component: 193.0.9.0/24 AS2 SPECIAL
...
If AS1 announced no other routes to a single homed neighbouring AS,
ripe-1nn.txt May, 1994
- 19 -
that neighbour can in general either take that route or leave it but
not differentiate between AS1 and AS2.
Note: If the neighbor was previously configured to accept routes
originating in AS2 but not in AS1 they lose connectivity to AS2 as
well. This means that proxy aggregation has to be done carefully
and in a well coordinated fashion. The component information in the
route object can help to achieve that.
Aggregates with Holes
If we assume that the world of our example still consists of only
three chunks of address space the aggregate above contains what are
called holes, parts of an aggregate that are not reachable via the
originator of the route. From the routing information itself one
cannot tell whether these are holes and what part of the route falls
inside one. The only way to tell is to send a packet there and see
whether it gets to the destination, or an ICMP message is received
back, or there is silence. On the other hand announcing aggregates
with holes is quite legitimate. Consider a 16-bit aggregate with
only one 24-bit prefix unreachable. The savings in routing table
size by far outweigh the hole problem.
For operational reasons however it is very useful to register these
holes in the routing registry. Consider the case where a remote net-
work operator experiences connectivity problems to addresses inside
an aggregate route. If the packets are getting to the AS announcing
the aggregate and there are no more specific routes, the normal
cause of action is to get in touch with the originating AS of the
aggregate route and ask them to fix the problem. If the address
falls into a hole this is futile. Therefore problem diagnosis can be
sped up and unnecessary calls prevented by registering the holes in
the routing registry. In our example the representation would be:
route: 193.0.0.0/20
descr: All routes known by AS1
origin: AS1
component: 193.0.0.0/24 HOLE
component: 193.0.2.0/23 HOLE
component: 193.0.4.0/22 HOLE
component: 193.0.8.0/24 AS2
component: 193.0.9.0/24 AS2 SPECIAL
component: 193.0.10.0/23 HOLE
component: 193.0.12.0/22 HOLE
...
Multiple Proxy Aggregation
Finally suppose that AS2 decides to announce the same aggregate,
they would add the following route object to the registry:
ripe-1nn.txt May, 1994
- 20 -
route: 193.0.0.0/20
descr: All routes known by AS2
origin: AS2
component: 193.0.0.0/24 HOLE
component: 193.0.2.0/23 HOLE
component: 193.0.4.0/22 HOLE
component: 193.0.9.0/24 AS2 SPECIAL
component: 193.0.10.0/23 HOLE
component: 193.0.12.0/22 HOLE
...
AS per the update procedures below both AS1 and AS2 will be notified
that there already is a route to the same prefix in the registry.
This multiple proxy aggregation is very dangerous to do if the com-
ponents of the route are not the same. It is still dangerous when
the components are consistent but connectivity to the components
varies widely between the originators.
Route object update procedures
Adding a route object will be guarded by use of the AS guardian
files[12]. The actual implementation of this is outside the scope
of this document. A route object will only be added if the class-
less address value of the route attribute will appear in the guar-
dian file of the origin AS mentioned. This guarantees that an AS
guardian has full control over the registration of the routes it
announces.
Any AS added or deleted from the components of a route object will
be notified of the event by e-mail to the AS guardian. This guaran-
tees that ASes are notified if some of their address space gets
aggregated somewhere.
Any community added or deleted from the components of a route object
will be notified of the event by e-mail to the community guardian.
It should be noted that adding community information to component
attributes should be done with some caution. One should check with
the community guardian before doing this.
What is an Inter-AS network ?
An inter-AS network(3) exists for the purpose of passing traffic and
routing information between different autonomous systems. The most
_________________________
(3) Inter-AS IP networks are those networks are
currently called FIXes, IXFs, DMZs, NAPs, GIX and many
other acronyms.
ripe-1nn.txt May, 1994
- 21 -
simple example of an inter-AS network is a point-to-point link, con-
necting exactly two ASes. Each end of such a link is connected to
an interface of router belonging to each of the autonomous systems.
More complex examples are broadcast type networks with multiple
interfaces connecting multiple ASes with the possibility of more
than one connection per AS. Consider the following example of three
routers 1, 2 and 3 with interfaces a through f connected by two
inter-AS networks X and Y: Consider the following example of three
routers 1, 2 and 3 with interfaces a through f connected by two
inter-AS networks X and Y:
X Y
a1b --- c2d --- e3f
Suppose that network X is registered in the routing registry as part
of AS1 and net Y as part of AS3. If traffic passes from left to
right prtraceroute will report the following sequence of interfaces
and ASes:
a in AS1
c in AS1
e in AS3
The traceroute algorithm enumerates only the receiving interfaces on
the way to the destination. In the example this leads to the pas-
sage of AS2 going unnoticed. This is confusing to the user and will
also generate exceptions when the path found is checked against the
routing registry.
For operational monitoring tools such as prtraceroute it is neces-
sary to know which interface on an inter-AS network belongs to which
AS. If AS information is not known about interfaces on an inter-AS
network, tools like prtraceroute cannot determine correctly which
ASes are being traversed.
ripe-1nn.txt May, 1994
- 22 -
Format
All interfaces on inter-AS networks will be described in the com-
ponent part of the route object. This is done by specifying a 32
bit prefix (host address). For example:
route: 192.87.45.0/24
descr: RIPE Network Coordination Centre
origin: AS3333
component: 192.87.45.80/32 AS1104
component: 192.87.45.6/32 AS2122
component: 192.87.45.254/32 AS2600
changed: dfk at ripe.net 940427
source: RIPE
describes a route to a DMZ network which lives in AS3333. There are
three interfaces in different ASes.
ripe-1nn.txt May, 1994
- 23 -
6. The Autonomous System Object
Autonomous Systems
An Autonomous System (AS) is a group of IP networks run by one or
more network operators which has a single and clearly defined rout-
ing policy.
An AS has a unique number associated with it which is used both in
exchange of exterior routing information and as an identifier of the
AS itself. Exterior routing protocols such as BGP and EGP are used
to exchange routing information between ASes.
In routing terms an AS will normally use one or more interior gate-
way protocols (IGPs) in conjunction with some sort of common agreed
metrics when exchanging network information within its own AS.
The term AS is often confused or even misused as a convenient way of
grouping together a set of networks which belong under the same
administrative umbrella even if within that group of networks there
are various different routing policies. We provide the "community"
concept for such use. ASes can strictly have only one single rout-
ing policy.
The creation of an AS should be done in a conscious and well coordi-
nated manner to avoid creating ASes for the sake of it, perhaps
resulting in the worst case scenario of one AS per routing announce-
ment. It should be noted that there is a limited number of AS
numbers available. Also creating an AS may well increase the number
of AS paths modern EGPs will have to keep track of. This aggravates
what is known as "the routing table growth problem". This may mean
that by applying the general rules for the creation and allocation
of an AS below, some re-engineering may well be needed. However,
this may be the only way to actually implement the desired routing
policy anyway. The creation and allocation of an AS should be done
with the following recommendations in mind:
o Creation of an AS is only required when exchanging routing
information with other ASes. Some router implementations make
use of an AS number as a form of tagging to identify the rout-
ing process. However, it should be noted that this tag does
not need to be unique unless routing information is indeed
exchanged with other ASes.
o For a simple case of customer networks connected to a single
service provider, the IP network should normally be a member of
the service providers AS. In terms of routing policy the IP
network has exactly the same policy as the service provider and
there is no need to make any distinction in routing informa-
tion. This idea may at first seem slightly alien to some, but
it highlights the clear distinction in the use of the AS number
ripe-1nn.txt May, 1994
- 24 -
as a representation of routing policy as opposed to some form
of administrative use.
o If a network operator connects to more than one AS with dif-
ferent routing policies then they need to create their own AS.
In the case of multi-homed customer networks connected to two
service providers there are at least two different routing pol-
icies to a given customer network. At this point the customer
networks will be part of a single AS and this AS would be dis-
tinct from either of the service providers ASes. This allows
the customer the ability of having a different representation
of policy and preference to the different service providers.
This is the ONLY case where a network operator should create
its own AS number.
o As a general rule one should always try to populate the AS with
as many routes as possible, providing all routes conform to the
same routing policy.
Each AS is represented in the RIPE database by both an AS object and
the route objects representing the routes originated by the AS. The
AS object stores descriptive, administrative and contact information
about the AS as well as the routing policies of the AS in relation
to all neighbouring ASes.
The origin attributes of the route objects define the set of routes
originated by the AS. Each route object can have exactly one origin
attribute. Route objects can only be created and updated by the
"guardian" of the AS and not by those immediately responsible for
the particular routes referenced therein. This ensures that opera-
tors, especially service providers, remain in control of AS routing
announcements.
The AS object itself is used to represent a description of adminis-
trative details and the routing policies of the AS itself. The AS
object definition is depicted as follows.
ripe-1nn.txt May, 1994
- 25 -
Example:
aut-num: AS1104
descr: NIKHEF-H Autonomous system
as-in: from AS1213 100 accept AS1213
as-in: from AS1913 100 accept AS1913
as-in: from AS1755 150 accept ANY
as-out: to AS1213 announce ANY
as-out: to AS1913 announce ANY
as-out: to AS1755 announce AS1104 AS1913 AS1213
tech-c: Rob Blokzijl
admin-c: Eric Wassenaar
guardian: as-guardian at nikhef.nl
changed: ripe-dbm at ripe.net 920910
source: RIPE
See Appendix A for a complete syntax definition of the "aut-num"
object.
It should be noted that this representation provides two things:
o a set of routes.
o a description of administrative details and routing policies.
The set of routes can be used to generate network list based confi-
guration information as well as configuration information for exte-
rior routing protocols knowing about ASes. This means an AS can be
defined and is useful even if it does not use routing protocols
which know about the AS concept!
ripe-1nn.txt May, 1994
- 26 -
Preferences on Inter-AS connections - "interas-in/interas-out".
Often two ASes will have more than one physical connection between
them. In practice certain local policies my be placed on these
inter-AS connections as agreed by the two ASes. If we look at the
simple example below.
Example:
LINK1
+----------+
|a b|
AS1------AS2 AS3-----AS4
|c d|
+----------+
LINK2
It may be that AS2 prefers to get to AS3 on LINK1 (a and b being the
interface addresses of this link) and to AS4 on LINK2 (c and d being
the interface addresses of this link) with LINK2 as a backup for
AS3. Whilst this is purely of local information and at the AS level
will have no significance per se to any other ASes except AS2 and
AS3 this may be useful to represent. The way this is done is by
using the attributes "interas-in" and "interas-out". The exact syn-
tax is given in Appendix A. However, if we follow this example
through in terms of AS2 we would represent this policy as follows:
Example:
aut-num: AS2
as-in: from AS3 10 accept AS3 AS4
as-out: to AS3 announce AS1 AS2
interas-in: from AS3 a b 5 accept AS3
interas-in: from AS3 a b 15 accept AS4
interas-in: from AS3 c d 10 accept AS4
...
Here we see additional local link based information in terms of the
IP addresses of the link (in this example represented by a and b and
c and d respectively). It should be noted that the preference on
interas-in attributes is only of relevance to other interas-in lines
and not to as-in lines. Of course this type on inter-AS policy
should always be bilaterally-laterally agreed to avoid asymmetry and
in practice there may need to be corresponding interas-in attributes
in the policy representation of AS3. It should also be noted that
there are no interas-out attributes defined. In this case the gen-
eral policy is assumed.
The key difference between interas-in/interas-out and as-in/as-in
attributes is the former describes a local inter-AS policy and the
ripe-1nn.txt May, 1994
- 27 -
latter the general inter-AS policy as seen by other ASes. The gen-
eral policy should always be defined. The local inter-AS policy
should only be defined when such a policy really exists and the
implications of setting such policies is fully understood.
ripe-1nn.txt May, 1994
- 28 -
How to describe the exclusion policy of a certain AS - "as-exclude"
Some ASes have a routing policy based on the exclusion of certain
routes if for whatever reason a certain AS is used as transit.
Whilst, this is in general not good practice as it makes implicit
assumptions on topology with asymmetry a possible outcome if not
coordinated, this case needs to be accommodated within the routing
policy representation.
The way this is achieved is by making use of the "as-exclude" attri-
bute. The precise syntax of this attribute can be found in Appendix
A along with the rest of the defined syntax for the "aut-num"
object. However, some explanation of the use of this attribute is
useful. If we have the following example topology.
Example:
AS4--------AS3
| | |
| | |
AS1--------AS2--------AS5
With a simple corresponding policy like so:
Example:
aut-num: AS1
as-in: from AS2 100 accept ANY
as-out: to AS2 announce AS1
as-exclude: exclude AS4 to ANY
....
We see an interesting policy. What this says in simple terms is AS1
doesn't want to reach anything if it transit AS4. This can be a per-
fectly valid policy. However, it should be realised that for what-
ever reason AS2 decides to route to AS3 via AS4 then immediately AS1
has no connectivity to AS3 or if AS1 is running default to AS2 pack-
ets from AS1 will still flow via AS4. The important point about this
is that whilst AS1 can advise its neighbours of its policy it has no
direct control on how it can enforce this policy to neighbours
upstream.
Another interesting scenario to highlight the unexpected result of
using such an "as-exclude" policy. If we assume in the above example
AS2 preferred AS4 to reach AS3 and AS1 did not use default routing
then as stated AS1 would have no connectivity to AS3. Now lets sup-
pose that for example the link between AS2 and AS4 went down for
some reason. Like so:
ripe-1nn.txt May, 1994
- 29 -
Example:
AS4--------AS3
|
|
AS1--------AS2--------AS5
Suddenly AS1 now has connectivity to AS3. This unexpected behavior
should be considered when created policies based on the "as-exclude"
attribute.
The second problem with this type of policy is the potential of
asymmetry. In the original example we saw the correct policy from
AS1's point of view but if ASes with connectivity through AS4 do not
use a similar policy you have asymmetric traffic and policy. If an
AS uses such a policy they must be aware of the consequences of its
use. Namely that the specified routes which transit the AS (i.e.
routing announcements with this AS in the AS path information) in
question will be excluded. If not coordinated this can easily cause
asymmetry or even worse loss of connectivity to unknown ASes behind
(or in front for that matter) the transit AS in question. With this
in mind this attribute can only be viewed as a form of advisory to
other service providers. However, this does not preclude its use
with policy based tools if the attribute exists.
By having the ability to specify a route keyword based on any of the
four notations given in the syntax it allows the receiving AS to
specify what routes it wishes to exclude through a given transit AS
to a network granularity.
ripe-1nn.txt May, 1994
- 30 -
7. AS Macros
It may be difficult to keep track of each and every new AS that is
represented in the routing registry. A convenient way around this
is to define an `AS Macro' which essentially is a convenient way to
group ASes. This is done so that each and every AS guardian does not
have to add a new AS to it's routing policy as described by the as-
in and as-out attributes of it's AS object.
However, it should be noted that this creates an implicit trust on
the guardian of the AS-Macro.
An AS-Macro can be used in <routing policy expressions> for the
"as-in" and "as-out" attributes in the aut-num object. The AS-Macro
object is then used to derive the list or group of ASes.
A simple example would be something like:
Example:
aut-num: AS786
as-in: from AS1755 100 accept AS-EBONE AND NOT AS1104
as-in: from AS1755 100 accept AS-EBONE AND NOT AS1104
as-out to AS1755 announce AS786
.....
Where the as-macro object for AS-EBONE is as follows:
as-macro: AS-EBONE
descr: ASes routed by EBONE
as-list: AS2121 AS1104 AS2600 AS2122
as-list: AS1103 AS1755 AS2043
guardian: guardian at ebone.net
......
So the policy would be evaluated to:
aut-num: AS786
as-in: from AS1755 100 accept (AS2121 OR AS1104 OR AS2600 OR AS2122
as-in: from AS1755 100 accept AS1103 OR AS1755 OR AS2043) AND NOT AS1104
......
See Appendix C for a definition on the AS-Macro syntax.
ripe-1nn.txt May, 1994
- 31 -
8. The Community Object
A community is a group of routes that cannot be represented by an AS
or a group of ASes. It is in some circumstances useful to define a
group of routes that have something in common. This could be a spe-
cial access policy to a supercomputer centre, a group of routes used
for a specific mission, or a disciplinary group that is scattered
among several autonomous systems. Also these communities could be
useful to group routes for the purpose of network statistics.
Communities do not exchange routing information, since they do not
represent an autonomous system. More specifically, communities do
not define routing policies, but access or usage policies. However,
they can de used as in conjunction with an ASes routing policy to
define a set of routes the AS sets routing policy for.
Communities should be defined in a strict manner, to avoid creating
as many communities as there are routes, or even worse. Communities
should be defined following the two rules below;
o Communities must have a global meaning. Communities that have
no global meaning, are used only in a local environment and
should be avoided.
o Communities must not be defined to express non-local policies.
It should be avoided that a community is created because some
other organisation forces a policy upon your organisation.
Communities must only be defined to express a policy defined by
your organisation.
Community examples
There are some clear examples of communities:
BACKBONE -
all customers of a given backbone service provider even though
they can have various different routing policies and hence
belong to different ASes. This would be extremely useful for
statistics collection.
HEPNET -
the High Energy Physics community partly shares infrastructure
with other organisations, and the institutes it consists of are
scattered all over Europe, often being part of a non HEPNET
autonomous system. To allow statistics, access or part of a
routing policy , a community HEPNET, consisting of all routes
that are part of HEPNET, conveniently groups all these routes.
ripe-1nn.txt May, 1994
- 32 -
NSFNET -
the National Science Foundation Network imposes an acceptable
use policy on routes that wish to make use of it. A community
NSFNET could imply the set of routes that comply with this pol-
icy.
MULTI -
a large multinational corporation that does not have its own
internal infrastructure, but connects to the various parts of
its organisations by using local service providers that connect
them all together, may decide to define a community to restrict
access to their networks, only by networks that are part of
this community. This way a corporate network could be defined
on shared infrastructure. Also, this community could be used by
any of the service providers to do statistics for the whole of
the corporation, for instance to do topology or bandwidth plan-
ning.
Similar to Autonomous systems, each community is represented in the
RIPE database by both a community object and community tags on the
route objects representing the routes belonging to the community.
The community object stores descriptive, administrative and contact
information about the community.
The community tags on the route objects define the set of routes
belonging to a community. A route can have multiple community tags.
The community tags can only be created and updated by the "guardian"
of the community and not by those directly responsible for the par-
ticular network. This ensures that guardians remain in control of
community membership.
Here's an example of how this might be represented in terms of the
community tags within the network object. We have an example where
the route 192.16.199.0/24 has a single routing policy (i.e. that of
AS 1104), but is part of several different communities of interest.
We use the tag "comm-list" to represent the list of communities
associated with this route. NIKHEF-H uses the service provider
SURFNET (a service provider with customers with more than one rout-
ing policy), is also part of the High Energy Physics community as
well as having the ability to access the Supercomputer at CERN(4).
_________________________
(4) The community `CERN-SUPER', is somewhat national,
but is intended as an example of a possible use of an
access policy constraint.
ripe-1nn.txt May, 1994
- 33 -
Example:
route: 192.16.199.0/24
descr: Local Ethernet
descr: NIKHEF section H
origin: AS1104
comm-list: HEPNET CERN-SUPER SURFNET
changed: ripe-dbm at ripe.net 920604
source: RIPE
In the above examples some communities have been defined. The com-
munity object itself will take the following format:
Example:
community: SURFNET
descr: Dutch academic research network
authority: SURFnet B.V.
guardian: comm-guardian at surfnet.nl
admin-c: Erik-Jan Bos
tech-c: Erik-Jan Bos
changed: ripe-dbm at ripe.net 920604
source: RIPE
For a complete explanation of the syntax please refer to Appendix B.
ripe-1nn.txt May, 1994
- 34 -
9. Representation of Routing Policies
Routing policies of an AS are represented in the autonomous system
object. Initially we show some examples, so the reader is familiar
with the concept of how routing information is represented, used and
derived. Refer to Appendix A, for the full syntax of the "aut-num"
object.
The topology of routing exchanges is represented by listing how
routing information is exchanged with each neighbouring AS. This is
done separately for both incoming and outgoing routing information.
In order to provide backup and back door paths a relative cost is
associated with incoming routing information.
Example 1:
AS1------AS2
This specifies a simple routing exchange of two presumably isolated
ASes. Even if either of them has routing information about routes
in ASes other than AS1 and AS2, none of that will be announced to
the other.
aut-num: AS1
as-out: to AS2 announce AS1
as-in: from AS2 100 accept AS2
aut-num: AS2
as-out: to AS1 announce AS2
as-in: from AS1 100 accept AS1
The number 100 in the in-bound specifications is a relative cost,
which is used for backup and back door routes. The absolute value is
of no significance. The relation between different values within the
same AS object is. A lower value means a lower cost. This is cons-
ciously similar to the cost based preference scheme used with DNS MX
RRs.
Example 2:
Now suppose that AS2 is connected to one more AS, besides AS1, and
let's call that AS3:
AS1------AS2------AS3
ripe-1nn.txt May, 1994
- 35 -
In this case there are two reasonable routing policies:
a) AS2 just wants to exchange traffic with both AS1 and AS3 itself
without passing traffic between AS1 and AS3.
b) AS2 is willing to pass traffic between AS3 and AS1, thus acting
as a transit AS
Example 2a:
In the first case AS1's representation in the routing registry will
remain unchanged as will be the part of AS2's representation
describing the routing exchange with AS1. A description of the addi-
tional routing exchange with AS3 will be added to AS2's representa-
tion:
aut-num: AS1
as-out: to AS2 announce AS1
as-in: from AS2 100 accept AS2
aut-num: AS2
as-out: to AS1 announce AS2
as-in: from AS1 100 accept AS1
as-out: to AS3 announce AS2
as-in: from AS3 100 accept AS3
aut-num: AS3
as-out: to AS2 announce AS3
as-in: from AS2 100 accept AS2
Note that in this example, AS2 keeps full control over its
resources. Even if AS3 and AS1 were to allow each others routes in
from AS2, the routing information would not flow because AS2 is not
announcing it(5).
Example 2b:
If contrary to the previous case, AS1 and AS3 are supposed to have
connectivity to each other via AS2, all AS objects have to change:
_________________________
(5) Of course AS1 and AS3 could just send traffic to
each other to AS2 even without AS2 announcing the
routes, hoping that AS2 will forward it correctly. Such
questionable practices however are beyond the scope of
this document.
ripe-1nn.txt May, 1994
- 36 -
aut-num: AS1
as-out: to AS2 announce AS1
as-in: from AS2 100 accept AS2 AS3
aut-num: AS2
as-out: to AS1 announce AS2 AS3
as-in: from AS1 100 accept AS1
as-out: to AS3 announce AS2 AS1
as-in: from AS3 100 accept AS3
aut-num: AS3
as-out: to AS2 announce AS3
as-in: from AS2 100 accept AS1 AS2
Note that the amount of routing information exchanged with a neigh-
bour AS is defined in terms of routes belonging to ASes. In BGP
terms this is the AS where the routing information originates and
the originating AS information carried in BGP could be used to
implement the desired policy. However, using BGP or the BGP AS-path
information is not required to implement the policies thus speci-
fied. Configurations based on route lists can easily be generated
from the database. The AS path information, provided by BGP can
then be used as an additional checking tool as desired.
The specification understands one special expression and this can be
expressed as a boolean expressions:
ANY - means any routing information known. For output this means
that all routes an AS knows about are announced. For input it
means that anything is accepted from the neighbour AS.
ripe-1nn.txt May, 1994
- 37 -
Example 3:
AS4 is a stub customer AS, which only talks to service provider
AS123.
|
|
-----AS123------AS4
|
|
aut-num: AS4
as-out: to AS123 announce AS4
as-in: from AS123 100 accept ANY
aut-num: AS123
as-in: from AS4 100 accept AS4
as-out: to AS4 announce ANY
<further neighbours>
Since AS4 has no other way to reach the outside world than AS123 it
is not strictly necessary for AS123 to send routing information to
AS4. AS4 can simply send all traffic for which it has no explicit
routing information to AS123 by default. This strategy is called
default routing. It is expressed in the routing registry by adding
one or more default tags to the autonomous system which uses this
strategy. In the example above this would look like:
aut-num: AS4
as-out: to AS123 announce AS4
default: AS123 100
aut-num: AS123
as-in: from AS4 100 accept AS4
<further neighbours>
ripe-1nn.txt May, 1994
- 38 -
Example 4:
AS4 now connects to a different operator, AS5. AS5 uses AS123 for
outside connectivity but has itself no direct connection to AS123.
AS5 traffic to and from AS123 thus has to pass AS4. AS4 agrees to
act as a transit AS for this traffic.
|
|
-----AS123------AS4-------AS5
|
|
aut-num: AS4
as-out: to AS123 announce AS4 AS5
as-in: from AS123 100 accept ANY
as-out: to AS5 announce ANY
as-in: from AS5 50 accept AS5
aut-num: AS5
as-in: from AS4 100 accept ANY
as-out: to AS4 announce AS5
aut-num: AS123
as-in: from AS4 100 accept AS4 AS5
as-out: to AS4 announce ANY
<further neighbours>
Now AS4 has two sources of external routing information. AS5 which
provides only information about its own routes and AS123 which pro-
vides information about the external world. Note that AS4 accepts
information about AS5 from both AS123 and AS5 although AS5 informa-
tion cannot come from AS123 since AS5 is connected only via AS4
itself. The lower cost of 50 for the announcement from AS5 itself
compared to 100 from AS123 ensures that AS5 is still believed even
in case AS123 will unexpectedly announce AS5.
In this example too, default routing can be used by AS5 much like in
the previous example. AS4 can also use default routing towards
AS123:
ripe-1nn.txt May, 1994
- 39 -
aut-num: AS4
as-out: to AS123 announce AS4 AS5
default: AS123 11
as-in: from AS5 50 accept AS5
Note no announcements to AS5, they default to us.
aut-num: AS5
as-out: to AS4 announce AS5
default: AS4 100
aut-num: AS123
as-in: from AS4 100 announce AS4 AS5
<further neighbours>
Note that the relative cost associated with default routing is
totally separate from the relative cost associated with in-bound
announcements. The default route will never be taken if an explicit
route is known to the destination. Thus an explicit route can never
have a higher cost than the default route. The relative cost asso-
ciated with the default route is only useful in those cases where
one wants to configure multiple default routes for redundancy.
Note also that in this example the configuration using default
routes has a subtly different behavior than the one with explicit
routes: In case the AS4-AS5 link fails AS4 will send traffic to AS5
to AS123 when using the default configuration. Normally this makes
not much difference as there will be no answer and thus little
traffic. With certain datagram applications which do not require
acknowledgments however, significant amounts of traffic may be use-
lessly directed at AS123. Similarly default routing should not be
used if there are stringent security policies which proscribe any
traffic intended for AS5 to ever touch AS123.
Generally it can be said that default routing should only be used in
very simple topologies. Once the situation gets more complex using
default routes can lead to unexpected results or even defeat the
routing policies established when links fail. As an example consider
how Example 5a) below could be implemented using default routing.
ripe-1nn.txt May, 1994
- 40 -
Example 5:
In a different example AS4 has a private connection to AS6 which in
turn is connected to the service provider AS123:
|
|
-----AS123------AS4
| |
| |
| |
AS6 ---------+
There are a number of policies worth examining in this case:
a) AS4 and AS6 wish to exchange traffic between themselves
exclusively via the private link between themselves; such
traffic should never pass through the backbone (AS123). The
link should never be used for transit traffic, i.e. traffic not
both originating in and destined for AS4 and AS6.
b) AS4 and AS6 wish to exchange traffic between themselves via the
private link between themselves. Should the link fail, traffic
between AS4 and AS6 should be routed via AS123. The link
should never be used for transit traffic.
c) AS4 and AS6 wish to exchange traffic between themselves via the
private link between themselves. Should the link fail, traffic
between AS4 and AS6 should be routed via AS123. Should the
connection between AS4 and AS123 fail, traffic from AS4 to des-
tinations behind AS123 can pass through the private link and
AS6's connection to AS123.
d) AS4 and AS6 wish to exchange traffic between themselves via the
private link between themselves. Should the link fail, traffic
between AS4 and AS6 should be routed via AS123. Should the
backbone connection of either AS4 or AS6 fail, the traffic of
the disconnected AS should flow via the other AS's backbone
connection.
ripe-1nn.txt May, 1994
- 41 -
Example 5a:
aut-num: AS4
as-in: from AS123 100 accept NOT AS6
as-out: to AS123 announce AS4
as-in: from AS6 50 accept AS6
as-out: to AS6 announce AS4
aut-num: AS123
as-in: from AS4 100 accept AS4
as-out: to AS4 announce ANY
as-in: from AS6 100 accept AS6
as-out: to AS6 announce ANY
<further neighbours>
aut-num: AS6
as-in: from AS123 100 accept NOT AS4
as-out: to AS123 announce AS6
as-in: from AS4 50 accept AS4
as-out: to AS4 announce AS6
Note that here the configuration is slightly inconsistent. AS123
will announce AS6 to AS4 and AS4 to AS6. These announcements will be
filtered out on the receiving end. This will implement the desired
policy. Consistency checking tools might flag these cases however.
ripe-1nn.txt May, 1994
- 42 -
Example 5b:
aut-num: AS4
as-in: from AS123 100 accept ANY
as-out: to AS123 announce AS4
as-in: from AS6 50 accept AS6
as-out: AS6 AS4
aut-num: AS123
as-in: AS4 100 AS4
as-out: AS4 ANY
as-in: AS6 100 AS6
as-out: AS6 ANY
<further neighbours>
aut-num: AS6
as-in: from AS123 100 accept ANY
as-out: to AS123 announce AS6
as-in: from AS4 50 accept AS4
as-out: to AS4 announce AS6
The thing to note here is that in the ideal operational case, `all
links working' AS4 will receive announcements for AS6 from both
AS123 and AS6 itself. In this case the announcement from AS6 will
be preferred because of its lower cost and thus the private link
will be used as desired. AS6 is configured as a mirror image.
ripe-1nn.txt May, 1994
- 43 -
Example 5c:
The new feature here is that should the connection between AS4 and
AS123 fail, traffic from AS4 to destinations behind AS123 can pass
through the private link and AS6's connection to AS123.
aut-num: AS4
as-in: from AS123 100 accept ANY
as-out: to AS123 announce AS4
as-in: from AS6 50 accept AS6
as-in: from AS6 110 accept ANY
as-out: to AS6 AS4
aut-num: AS123
as-in: from AS4 1 accept AS4
as-out: to AS4 announce ANY
as-in: from AS6 1 accept AS6
as-in: from AS6 2 accept AS4
as-out: to AS6 announce ANY
<further neighbours>
aut-num: AS6
as-in: from AS123 100 accept ANY
as-out: to AS123 AS6 announce AS4
as-in: from AS4 50 accept AS4
as-out: to AS4 announce ANY
Note that it is important to make sure to propagate routing informa-
tion for both directions in backup situations like this. Connec-
tivity in just one direction is not useful at all for almost all
applications.
Note also that in case the AS6-AS123 connection breaks, AS6 will
only be able to talk to AS4. The symmetrical case (5d) is left as an
exercise to the reader.
ripe-1nn.txt May, 1994
- 44 -
10. References
[1] Bates, T., Jouanigot, J-M., Karrenberg, D., Lothberg, P.,
Terpstra, M., "Representation of IP Routing Policies in the
RIPE Database", RIPE-81, February 1993.
[2] Merit Network Inc.,"Representation of Complex Routing Policies
of an Autonomous System", DRAFT, March, 1994.
[3] PRIDE Tools Release 1.
See ftp.ripe.net:pride/tools/pride-tools-1.tar.Z.
[4] Merit Inc. RRDB Tools.
See rrdb.merit.edu:pub/meritrr/*
[5] The Network List Compiler.
See dxcoms.cern.ch:pub/ripe-routing-wg/nlc-2.2d.tar
[6] Lord, A., Terpstra, M., "RIPE Database Template for Networks
and Persons", DRAFT, May 1994.
[7] Karrenberg, D., "RIPE Database Template for Domains", RIPE-49,
April 1992.
[8] Lougheed, K., Rekhter, Y., "A Border Gateway Protocol 3 (BGP-
3)", RFC1267, October 1991.
[9] Rekhter, Y., Li, T., "A Border Gateway Protocol 4 (BGP-4)",
INTERNET-DRAFT, draft-ietf-bgp-bgp4-10.txt, May 1994.
[10] Bates, T., Karrenberg, D., Terpstra, M., "Support for Classless
Internet Addresses in the RIPE Database", DRAFT, May 1994.
[11] Karrenberg, D., "Authorisation and Notification of Changes in
the RIPE Database", RIPE-96, October 1993.
[12] Bates, T., "Support of Guarded fields within the RIPE Data-
base", ripe-108, February 1994.
ripe-1nn.txt May, 1994
- 45 -
11. Author's Addresses
Tony Bates
RARE/PRIDE Project
c/o RIPE Network Coordination Centre
Kruislaan 409
NL-1098 SJ Amsterdam
The Netherlands
+31 20 592 5064
T.Bates at ripe.net
Elise Gerich
The University of Michigan
Merit Computer Network
1075 Beal Avenue
Ann Arbor, MI 48109
USA
+1 313 936 2120
epg at merit.edu
Laurent Joncheray
The University of Michigan
Merit Computer Network
1075 Beal Avenue
Ann Arbor, MI 48109
USA
+1 313 936 2065
lpj at merit.edu
Jean-Michel Jouanigot
CERN, European Laboratory for Particle Physics
CH-1211 Geneva 23
Switzerland
+41 22 767 4417
Jean-Michel.Jouanigot at cern.ch
Daniel Karrenberg
RIPE Network Coordination Centre
Kruislaan 409
NL-1098 SJ Amsterdam
The Netherlands
+31 20 592 5065
D.Karrenberg at ripe.net
ripe-1nn.txt May, 1994
- 46 -
Marten Terpstra
PRIDE Project
c/o RIPE Network Coordination Centre
Kruislaan 409
NL-1098 SJ Amsterdam
The Netherlands
+31 20 592 5064
M.Terpstra at ripe.net
Jessica Yu
The University of Michigan
Merit Computer Network
1075 Beal Avenue
Ann Arbor, MI 48109
USA
+1 313 936 2655
jyy at merit.edu
ripe-1nn.txt May, 1994
- 47 -
Appendix A - Syntax for the aut-num object.
Here is a summary of the tags associated with aut-num object itself
and their status. The first column specifies the attribute, the
second column whether this attribute is mandatory in the aut-num
object, and the third column whether this specific attribute can
occur only once per object [single], or more than once [multiple].
When specifying multiple lines per attribute, the attribute name
must be repeated. See [6] the example for the descr: attribute.
aut-num: [mandatory] [single]
descr: [mandatory] [multiple]
as-in: [optional] [multiple]
as-out: [optional] [multiple]
interas-in: [optional] [multiple]
interas-out: [optional] [multiple]
as-exclude: [optional] [multiple]
default: [optional] [multiple]
tech-c: [mandatory] [multiple]
admin-c: [mandatory] [multiple]
guardian: [mandatory] [single]
remarks: [optional] [multiple]
notify: [optional] [multiple]
maintainer: [optional] [single]
changed: [mandatory] [multiple]
source: [mandatory] [single]
Each attribute has the following syntax:
aut-num:
The autonomous system number. This must be a uniquely allo-
cated autonomous system number from an AS registry (i.e. the
RIPE NCC, the Inter-NIC, etc).
Format:
AS<positive integer between 1 and 65535>
Example:
aut-num: AS1104
Status: mandatory, only one line allowed
descr:
A short description of the Autonomous System.
Format:
free text
Status: mandatory, multiple lines allowed
as-in:
ripe-1nn.txt May, 1994
- 48 -
Example:
descr: NIKHEF section H
descr: Science Park Watergraafsmeer
descr: Amsterdam
A description of accepted routing information between AS peers.
Format:
from <aut-num> <cost> accept <routing policy expression>
The keywords from and accept are optional and can be omit-
ted.
<aut-num> refers to your AS neighbour.
<cost> is a positive integer used to express a relative
cost of routes learned. The lower the cost the more pre-
ferred the route.
<routing policy expression> can take the following for-
mats.
1. A list of one or more ASes, AS Macros, Communities or
Network Lists.
A Network List is a list of network numbers in prefix
length format, separated by commas, and surrounded by
curly brackets.
Examples:
as-in: from AS1103 100 accept AS1103
as-in: from AS786 105 accept AS1103
as-in: from AS786 10 accept AS786 HEPNET
as-in: from AS1755 110 accept AS1103 AS786
as-in: from AS3333 100 accept {192.87.45.0/16, 128.141.0.0/16}
2. A set of KEYWORDS. The following KEYWORD is
currently defined:
ANY this means anything the neighbour AS knows.
3. A logical expression of either 1 or 2 above The
current logical operators are defined as:
AND
OR
NOT
ripe-1nn.txt May, 1994
- 49 -
NOTE: if no logical operator is given between ASes,
AS-macros, Communities, Network Lists and KEYWORDS it
is implicitly evaluated as an `OR' operation. The OR
can be left out for conciseness.
Rules are grouped together using parenthesis i.e "("
and ")".
Example:
as-in: from AS1755 100 accept ANY AND NOT (AS1234 OR AS513)
as-in: from AS1755 150 accept AS1234 OR {35.0.0.0/8}
A rule can be wrapped over lines providing the
associated <aut-num>, <cost> values and from and
accept keywords are repeated and occur on con-
secutive lines.
Example:
as-in: from AS1755 100 accept ANY AND NOT (AS1234 AS513)
and
as-in: from AS1755 100 accept ANY AND NOT (
as-in: from AS1755 100 accept AS1234 AS513)
are evaluated to the same result. Please note
that the ordering of these continuing lines
matters.
Status: optional, multiple lines allowed
as-out:
A description of generated routing information sent to other AS
peers.
Format:
to <aut-num> announce <routing policy expression
Like in the as-in attribute, the to and announce keywords
are optional and can be omitted.
<aut-num> refers to your AS neighbour.
<routing policy expression> is explained in the as-in
attribute definition above.
Example:
as-out: to AS1104 announce AS978
as-out: to AS1755 announce ANY
as-out: to AS786 announce ANY AND NOT (AS978)
Status: optional, multiple lines allowed
ripe-1nn.txt May, 1994
- 50 -
interas-in:
Describes incoming local preferences on an inter AS connection.
Format:
from <aut-num> <local-info> <pref> accept <routing policy
expression>
The keywords from and accept are optional and can be omit-
ted.
<aut-num> is an autonomous system as defined in as-in.
<local-info> contains the IP address of the local border
router, followed by a space, followed by the IP address of
the remote border router. IP addresses must be in prefix
length format.
<pref> is a preference as defined in as-in. Preferences
are only relevant to other interas-in attributes, not to
as-in attributes.
<routing policy expression> is an expression as defined in
as-in above.
Examples:
interas-in: from AS1104 192.87.45.254/32 192.87.45.80/32 10 accept AS786
interas-in: from AS1104 192.87.45.254/32 192.87.45.79/32 20 accept AS987
Status: optional, multiple lines allowed
interas-out:
Describes outgoing local preferences on an inter AS connection.
Format:
to <aut-num> <local-info> announce <routing policy
expression>
The keywords to and announce are optional and can be omit-
ted.
The definitions of <aut-num>, <local-info>, and <routing
policy expression> are identical to those defined in
interas-in.
Examples:
interas-out: to AS1104 192.87.45.254/32 192.87.45.80/32 announce AS23
interas-out: to AS1104 192.87.45.254/32 192.87.45.79/32 announce AS10
Status: optional, multiple lines allowed
as-exclude:
A list of transit ASes to ignore all routes from.
ripe-1nn.txt May, 1994
- 51 -
Format:
exclude <aut-num> to <exclude-route-keyword>
Keywords exclude and to are optional and can again be
omitted.
<aut-num> refers to the transit AS in question.
an <exclude-route-keyword> can be ONE of the following.
1. <aut-num>
2. AS macro
3. Community
4. ANY
Examples:
as-exclude: exclude AS690 to HEPNET
This means exclude any HEPNET routes which have a route
via AS690.
as-exclude: exclude AS1800 to AS-EUNET
This means exclude any AS-EUNET routes which have a route
via AS1800.
as-exclude: exclude AS1755 to AS1104
This means exclude any AS1104 route which have a route via
AS1755.
as-exclude: exclude AS1104 to ANY
This means exclude all routes which have a route via
AS1104.
Status: optional, multiple lines allowed
default:
An indication of how default routing is done.
Format:
<aut-num> <relative cost> <default-expression>
where <aut-num> is the AS peer you will default route to,
and <relative cost> is the relative cost is a positive
integer used to express a preference for default. There is
no relationship to the cost used in the as-in tag. The AS
peer with the lowest cost is used for default over ones
ripe-1nn.txt May, 1994
- 52 -
with higher costs.
<default-expression> is optional and provides information
on how a default route is selected. It can take the fol-
lowing formats:
1. static. This indicates that a default is statically
configured to this AS peer.
2. A network list with the syntax as described in the
as-in attribute. This indicates that this list of
routes is used to generate a default route. A special
but valid value in this is the special route used by
some routing protocols to indicate default: 0.0.0.0/0
3. default. This is the same as {0.0.0.0/0}. This means
that the routing protocol between these two peers
generates a true default.
Examples:
default: AS1755 10
default: AS786 5 {140.222.0.0/16, 192.87.45.0/24}
default: AS2043 15 default
Status: optional, multiple lines allowed
tech-c:
Full name or uniquely assigned NIC-handle of a technical con-
tact person. This is someone to be contacted for technical
problems such as misconfiguration.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Example:
tech-c: John E Doe
tech-c: JED31
Status: mandatory, multiple lines allowed
admin-c:
Full name or uniquely assigned NIC-handle of an administrative
contact person. In many cases this would be the name of the
guardian.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Example:
admin-c: Joe T Bloggs
admin-c: JTB1
ripe-1nn.txt May, 1994
- 53 -
Status: mandatory, multiple lines allowed
guardian:
Mailbox of the guardian of the Autonomous system.
Format:
<email-address>
The <email-address> should be in RFC822 domain format
wherever possible.
Example:
guardian: as1104-guardian at nikhef.nl
Status: mandatory, only one line and e-mail address allowed
remarks:
Remarks/comments, to be used only for clarification.
Format:
free text
Example:
remarks: Multihomed AS talking to AS1755 and AS786
remarks: Will soon connect to AS1104 also.
Status: optional, multiple lines allowed
notify:
The notify attribute contains an email address to which notifi-
cations of changes to this object should be sent. See also
[11].
Format:
<email-address>
The <email-address> should be in RFC822 domain syntax
wherever possible.
Example:
notify: Marten.Terpstra at ripe.net
Status: optional, multiple lines allowed
maintainer:
The maintainer attribute contains a registered maintainer name.
See also [11].
Format:
<registered maintainer name>
ripe-1nn.txt May, 1994
- 54 -
Example:
maintainer: RIPE-DBM
Status: optional, multiple lines allowed
changed:
Who changed this object last, and when was this change made.
Format:
<email-address> YYMMDD
<email-address> should be the address of the person who
made the last change. YYMMDD denotes the date this change
was made.
Example:
changed: johndoe at terabit-labs.nn 900401
Status: mandatory, multiple lines allowed
source:
Source of the information.
This is used to separate information from different sources
kept by the same database software. For RIPE database entries
the value is fixed to RIPE.
Format:
RIPE
Status: mandatory, only one line allowed
ripe-1nn.txt May, 1994
- 55 -
Appendix B - Syntax details for the community object.
Here is a summary of the tags associated with community object
itself and their status. The first column specifies the attribute,
the second column whether this attribute is mandatory in the commun-
ity object, and the third column whether this specific attribute can
occur only once per object [single], or more than once [multiple].
When specifying multiple lines per attribute, the attribute name
must be repeated. See [6] the example for the descr: attribute.
community: [mandatory] [single]
descr: [mandatory] [multiple]
authority: [mandatory] [single]
guardian: [mandatory] [single]
tech-c: [mandatory] [multiple]
admin-c: [mandatory] [multiple]
remarks: [optional] [multiple]
notify: [optional] [multiple]
maintainer: [optional] [single]
changed: [mandatory] [multiple]
source: [mandatory] [single]
Each attribute has the following syntax:
community:
Name of the community. The name of the community should be
descriptive of the community it describes.
Format:
Upper case text string which cannot start with "AS" or any
of the <routing policy expression> KEYWORDS. See Appendix
A.
Example:
community: WCW
Status: mandatory, only one line allowed
descr:
A short description of the community represented.
Format:
free text
Example:
descr: Science Park Watergraafsmeer
descr: Amsterdam
Status: mandatory, multiple lines allowed
ripe-1nn.txt May, 1994
- 56 -
authority:
The formal authority for this community. This could be an
organisation, institute, committee, etc.
Format:
free text
Example:
authority: WCW LAN Committee
Status: mandatory, only one line allowed
guardian:
Mailbox of the guardian of the community.
Format:
<email-address>
The <email-address> should be in RFC822 domain format
wherever possible.
Example:
guardian: wcw-guardian at nikhef.nl
Status: mandatory, only one line and email address allowed
tech-c:
Full name or uniquely assigned NIC-handle of an technical con-
tact person for this community.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Example:
tech-c: John E Doe
tech-c: JED31
Status: mandatory, multiple lines allowed
admin-c:
Full name or uniquely assigned NIC-handle of an administrative
contact person. In many cases this would be the name of the
guardian.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Example:
admin-c: Joe T Bloggs
admin-c: JTB1
ripe-1nn.txt May, 1994
- 57 -
Status: mandatory, multiple lines allowed
remarks:
Remarks/comments, to be used only for clarification.
Format:
free text
Example:
remarks: Temporary community
remarks: Will be removed after split into ASes
Status: optional, multiple lines allowed
notify:
The notify attribute contains an email address to which notifi-
cations of changes to this object should be send. See also
[11].
Format:
<email-address>
The <email-address> should be in RFC822 domain syntax
wherever possible.
Example:
notify: Marten.Terpstra at ripe.net
Status: optional, multiple lines allowed
maintainer:
The maintainer attribute contains a registered maintainer name.
See also [11].
Format:
<registered maintainer name>
Example:
maintainer: RIPE-DBM
Status: optional, multiple lines allowed
changed:
Who changed this object last, and when was this change made.
Format:
<email-address> YYMMDD
<email-address> should be the address of the person who
made the last change. YYMMDD denotes the date this change
was made.
ripe-1nn.txt May, 1994
- 58 -
Example:
changed: johndoe at terabit-labs.nn 900401
Status: mandatory, multiple lines allowed
source:
Source of the information.
This is used to separate information from different sources
kept by the same database software. For RIPE database entries
the value is fixed to RIPE.
Format:
RIPE
Status: mandatory, only one line allowed
ripe-1nn.txt May, 1994
- 59 -
Appendix C - AS Macros syntax definition.
Here is a summary of the tags associated with as-macro object itself
and their status. The first column specifies the attribute, the
second column whether this attribute is mandatory in the as-macro
object, and the third column whether this specific attribute can
occur only once per object [single], or more than once [multiple].
When specifying multiple lines per attribute, the attribute name
must be repeated. See [6] the example for the descr: attribute.
as-macro: [mandatory] [single]
descr: [mandatory] [multiple]
as-list: [mandatory] [multiple]
guardian: [mandatory] [single]
tech-c: [mandatory] [multiple]
admin-c: [mandatory] [multiple]
remarks: [optional] [multiple]
notify: [optional] [multiple]
maintainer: [optional] [single]
changed: [mandatory] [multiple]
source: [mandatory] [single]
Each attribute has the following syntax:
as-macro:
The name of a macro containing at least two Autonomous Systems
grouped together for ease of administration.
Format:
AS-<string>
The <string> should be in upper case and not contain any
special characters.
Example:
as-macro: AS-EBONE
Status: mandatory, only one line allowed
descr:
A short description of the Autonomous System Macro.
Format:
free text
Example:
descr: Macro for EBONE connected ASes
Status: mandatory, multiple lines allowed
ripe-1nn.txt May, 1994
- 60 -
as-list:
The list of ASes that make up this macro.
Format:
<aut-num> <aut-num> ...
See Appendix A for <aut-num> definition.
Example:
as-list: AS786 AS513 AS1104
Status: mandatory, multiple lines allowed
guardian:
Mailbox of the guardian of this AS macro.
Format:
<email-address>
The <email-address> should be in RFC822 domain format
wherever possible.
Example:
guardian: as-ebone-guardian at ebone.net
Status: mandatory, only one line and e-mail address allowed
tech-c:
Full name or uniquely assigned NIC-handle of a technical con-
tact person for this macro. This is someone to be contacted for
technical problems such as misconfiguration.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Examples:
tech-c: John E Doe
tech-c: JED31
Status: mandatory, multiple lines allowed
admin-c:
Full name or uniquely assigned NIC-handle of an administrative
contact person. In many cases this would be the name of the
guardian.
Format:
<firstname> <initials> <lastname> or <nic-handle>
Examples:
ripe-1nn.txt May, 1994
- 61 -
admin-c: Joe T Bloggs
admin-c: JTB1
Status: mandatory, multiple lines allowed
remarks:
Remarks/comments, to be used only for clarification.
Format:
free text
Example:
remarks: AS321 will be removed from this Macro shortly
Status: optional, multiple lines allowed
notify:
The notify attribute contains an email address to which notifi-
cations of changes to this object should be send. See also
[11].
Format:
<email-address>
The <email-address> should be in RFC822 domain syntax
wherever possible.
Example:
notify: Marten.Terpstra at ripe.net
Status: optional, multiple lines allowed
maintainer:
The maintainer attribute contains a registered maintainer name.
See also [11].
Format:
<registered maintainer name>
Example:
maintainer: RIPE-DBM
Status: optional, multiple lines allowed
changed:
Who changed this object last, and when was this change made.
Format:
<email-address> YYMMDD
ripe-1nn.txt May, 1994
- 62 -
<email-address> should be the address of the person who
made the last change. YYMMDD denotes the date this change
was made.
Example:
changed: johndoe at terabit-labs.nn 900401
Status: mandatory, multiple lines allowed
source:
Source of the information.
This is used to separate information from different sources
kept by the same database software. For RIPE database entries
the value is fixed to RIPE.
Format:
RIPE
Status: mandatory, only one line allowed
ripe-1nn.txt May, 1994
- 63 -
Appendix D - Syntax for the "route" object.
There is a summary of the tags associated with community object
itself and their status. The first column specifies the attribute,
the second column whether this attribute is mandatory in the commun-
ity object, and the third column whether this specific attribute can
occur only once per object [single], or more than once [multiple].
When specifying multiple lines per attribute, the attribute name
must be repeated. See [6] the example for the descr: attribute.
route: [mandatory] [single]
descr: [mandatory] [multiple]
origin: [mandatory] [single]
component: [optional] [multiple]
comm-list: [optional] [multiple]
remarks: [optional] [multiple]
notify: [optional] [multiple]
maintainer: [optional] [single]
changed: [mandatory] [multiple]
source: [mandatory] [single]
Each attribute has the following syntax:
route:
Route being announced.
Format:
Classless representation of a route with the RIPE database
known as the "prefix length" representation. See [10] for
more details on classless representations.
Examples:
route: 192.87.45.0/24
This represents addressable bits 192.87.45.0 to
192.87.45.255.
route: 192.1.128.0/17
This represents addressable bits 192.1.128.0 to
192.1.255.255.
Status: mandatory, only one line allowed
origin:
The autonomous system announcing this route.
Format:
<aut-num>
ripe-1nn.txt May, 1994
- 64 -
See appendix A for <aut-num> syntax.
Example:
origin: AS1104
Status: mandatory, only one line allowed
component:
Represents the components which make up the route. Components
in the same AS and in the same communities.need not be listed.
Note components do not need to appear as their own route
objects if there are no more specific routes to them originated
anywhere.
Format:
<route> <component expression>
<route> is a more specific component route.
<component expression> can take the following formats:
1. <aut-num> <community> <community> ...
where the list of communities can be empty.
2. HOLE
Example:
component: 193.0.2.0/24 AS1111
component: 193.0.3.0/24 AS2222 HEP EUNET
component: 193.0.4.0/24 HOLE
Status: mandatory, multiple lines allowed
comm-list:
List of one or more communities this route is part of.
Format:
<community> <community> ...
See Appendix B for <community> definition.
Example:
comm-list: HEP LEP
Status: optional, multiple lines allowed
remarks:
Remarks/comments, to be used only for clarification.
Format:
ripe-1nn.txt May, 1994
- 65 -
free text
Example:
remarks: Multihomed AS talking to AS1755 and AS786
remarks: Will soon connect to AS1104 also.
Status: optional, multiple lines allowed
notify:
The notify attribute contains an email address to which notifi-
cations of changes to this object should be send. See also
[11].
Format:
<email-address>
The <email-address> should be in RFC822 domain syntax
wherever possible.
Example:
notify: Marten.Terpstra at ripe.net
Status: optional, multiple lines allowed
maintainer:
The maintainer attribute contains a registered maintainer name.
See also [11].
Format:
<registered maintainer name>
Example:
maintainer: RIPE-DBM
Status: optional, multiple lines allowed
changed:
Who changed this object last, and when was this change made.
Format:
<email-address> YYMMDD
<email-address> should be the address of the person who
made the last change. YYMMDD denotes the date this change
was made.
Example:
changed: johndoe at terabit-labs.nn 900401
Status: mandatory, multiple lines allowed
ripe-1nn.txt May, 1994
- 66 -
source:
Source of the information.
This is used to separate information from different sources
kept by the same database software. For RIPE database entries
the value is fixed to RIPE.
Format:
RIPE
Status: mandatory, only one line allowed
ripe-1nn.txt May, 1994
- 67 -
Appendix E - Motivations for RIPE-81++
This appendix gives motivations for the major changes in this propo-
sal from ripe-81. (It is not complete yet).
The main goals of the routing registry rework are:
SPLIT
Separate the allocation and routing registry functions into
different database objects. This will facilitate data manage-
ment if the Internet registry and routing registry functions
are separated (like in other parts of the world). It will also
make more clear what is part of the routing registry and who
has authority to change allocation vs. routing data.
CIDR
Add the possibility to specify classless routes in the routing
registry. Classless routes are being used in Internet produc-
tion now. Aggregation information in the routing registry is
necessary for network layer troubleshooting. It is also neces-
sary because aggregation influences routing policies directly.
CALLOC
Add the possibility to allocate address space on classless
boundaries in the allocation registry. This is a way to
preserve address space.
CLEAN
To clean up some of the obsolete and unused parts of the rout-
ing registry.
The major changes are now discussed in turn:
Introduce Classless Addresses
CIDR, CALLOC
Introduce route object.
SPLIT, CIDR and CALLOC.
Delete obsolete attributes from inetnum.
CLEAN.
ripe-1nn.txt May, 1994
- 68 -
Delete RIPE-DB and LOCAL from routing policy expressions.
CLEAN
Allow multiple ASes to originate the same route
Because it is being done. CIDR. Made possible by SPLIT.
ripe-1nn.txt May, 1994
- 69 -
Appendix F - Transition strategy from RIPE-81 to RIPE-81++
Transition from the routing registry described by ripe-81 to the
routing registry described in this document is a straightforward
process once the new registry functions have been implemented in the
database software and are understood by the most commonly used
registry tools. The routing related attributes in the classful inet-
num objects of ripe-81 can be directly translated into new routing
objects. Then these attributes can be deleted from the inetnum
object making that object conform to the new schema.
Proposed transition steps:
1) Implement classless addresses and new object definition in the
database software.
2) Make common tools understand the new schema and prefer it if
both old and new are present.
3) Invite everyone to convert their data to the new format. This
can be encouraged by doing conversions automatically and pro-
posing them to maintainers.
4) At a flag day remove all remaining routing information from the
inetnum objects. Before the flag day all usage of obsoleted
inetnum attributes has to cease and all other routing registry
functions have to be taken over by the new objects and attri-
butes.
The current estimate is that point three can be reached in the Sum-
mer 1994 if the draft is accepted by mid-June. The flag day should
be scheduled 3-4 months after this point.
ripe-1nn.txt May, 1994
-------- Logged at Thu Jun 23 20:42:55 MET DST 1994 ---------
[ rr-impl Archive ]