Network Working Group A. Doria
Internet-Draft LTU
Expires: April 27, 2006 E. Davies
Consultant
F. Kastenholz
Juniper Networks
October 24, 2005
Requirements for Inter-Domain Routing
draft-irtf-routing-reqs-04.txt
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Abstract
These requirements for routing architectures are the product of two
sub-groups with the IRTF Routing Research Group. They represent two
individual and separate views of the problem and of what is required
to fix the problem. While speaking of requirements, the document is
actually a recommendation to anyone who would create a routing
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architecture for the Internet in the coming years.
Table of Contents
1. Background . . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Results from Group A . . . . . . . . . . . . . . . . . . . . . 6
2.1 Group A - Requirements For a Next Generation Routing
and Addressing Architecture . . . . . . . . . . . . . . . 6
2.1.1 Architecture . . . . . . . . . . . . . . . . . . . . . 6
2.1.2 Separable Components . . . . . . . . . . . . . . . . . 6
2.1.3 Scalable . . . . . . . . . . . . . . . . . . . . . . . 7
2.1.4 Lots of Interconnectivity . . . . . . . . . . . . . . 10
2.1.5 Random Structure . . . . . . . . . . . . . . . . . . . 10
2.1.6 Multi-homing . . . . . . . . . . . . . . . . . . . . . 11
2.1.7 Multi-path . . . . . . . . . . . . . . . . . . . . . . 11
2.1.8 Convergence . . . . . . . . . . . . . . . . . . . . . 12
2.1.9 Routing System Security . . . . . . . . . . . . . . . 14
2.1.10 End Host Security . . . . . . . . . . . . . . . . . . 16
2.1.11 Rich Policy . . . . . . . . . . . . . . . . . . . . . 16
2.1.12 Incremental Deployment . . . . . . . . . . . . . . . . 19
2.1.13 Mobility . . . . . . . . . . . . . . . . . . . . . . . 19
2.1.14 Address Portability . . . . . . . . . . . . . . . . . 19
2.1.15 Multi-Protocol . . . . . . . . . . . . . . . . . . . . 20
2.1.16 Abstraction . . . . . . . . . . . . . . . . . . . . . 20
2.1.17 Simplicity . . . . . . . . . . . . . . . . . . . . . . 21
2.1.18 Robustness . . . . . . . . . . . . . . . . . . . . . . 21
2.1.19 Media Independence . . . . . . . . . . . . . . . . . . 22
2.1.20 Stand-alone . . . . . . . . . . . . . . . . . . . . . 22
2.1.21 Safety of Configuration . . . . . . . . . . . . . . . 22
2.1.22 Renumbering . . . . . . . . . . . . . . . . . . . . . 23
2.1.23 Multi-prefix . . . . . . . . . . . . . . . . . . . . . 23
2.1.24 Cooperative Anarchy . . . . . . . . . . . . . . . . . 23
2.1.25 Network Layer Protocols and Forwarding Model . . . . . 23
2.1.26 Routing Algorithm . . . . . . . . . . . . . . . . . . 23
2.1.27 Positive Benefit . . . . . . . . . . . . . . . . . . . 23
2.1.28 Administrative Entities and the IGP/EGP Split . . . . 24
2.2 Non-Requirements . . . . . . . . . . . . . . . . . . . . . 24
2.2.1 Forwarding Table Optimization . . . . . . . . . . . . 24
2.2.2 Traffic Engineering . . . . . . . . . . . . . . . . . 25
2.2.3 Multicast . . . . . . . . . . . . . . . . . . . . . . 25
2.2.4 Quality of Service (QoS) . . . . . . . . . . . . . . . 25
2.2.5 IP Prefix Aggregation . . . . . . . . . . . . . . . . 26
2.2.6 Perfect Safety . . . . . . . . . . . . . . . . . . . . 26
2.2.7 Dynamic Load Balancing . . . . . . . . . . . . . . . . 26
2.2.8 Renumbering of hosts and routers . . . . . . . . . . . 26
2.2.9 Host Mobility . . . . . . . . . . . . . . . . . . . . 27
2.2.10 Backward Compatibility . . . . . . . . . . . . . . . . 27
3. Requirements from Group B . . . . . . . . . . . . . . . . . . 28
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3.1 Group B - Future Domain Routing Requirements . . . . . . . 28
3.2 Underlying Principles . . . . . . . . . . . . . . . . . . 28
3.2.1 Inter-domain and Intra-domain . . . . . . . . . . . . 29
3.2.2 Influences on a Changing Network . . . . . . . . . . . 29
3.2.3 High Level Goals . . . . . . . . . . . . . . . . . . . 30
3.3 High Level User Requirements . . . . . . . . . . . . . . . 34
3.3.1 Organisational Users . . . . . . . . . . . . . . . . . 34
3.3.2 Individual Users . . . . . . . . . . . . . . . . . . . 37
3.4 Mandated Constraints . . . . . . . . . . . . . . . . . . . 38
3.4.1 The Federated Environment . . . . . . . . . . . . . . 38
3.4.2 Working with Different Sorts of Networks . . . . . . . 39
3.4.3 Delivering Diversity . . . . . . . . . . . . . . . . . 39
3.4.4 When will the New Solution be Required? . . . . . . . 40
3.5 Assumptions . . . . . . . . . . . . . . . . . . . . . . . 40
3.6 Functional Requirements . . . . . . . . . . . . . . . . . 42
3.6.1 Topology . . . . . . . . . . . . . . . . . . . . . . . 42
3.6.2 Distribution . . . . . . . . . . . . . . . . . . . . . 43
3.6.3 Addressing . . . . . . . . . . . . . . . . . . . . . . 48
3.6.4 Statistics Support . . . . . . . . . . . . . . . . . . 49
3.6.5 Management Requirements . . . . . . . . . . . . . . . 49
3.6.6 Provability . . . . . . . . . . . . . . . . . . . . . 51
3.6.7 Traffic engineering . . . . . . . . . . . . . . . . . 52
3.6.8 Support for Middleboxes . . . . . . . . . . . . . . . 53
3.7 Performance Requirements . . . . . . . . . . . . . . . . . 53
3.8 Backwards Compatibility (Cutover) and Maintainability . . 54
3.9 Security Requirements . . . . . . . . . . . . . . . . . . 55
3.10 Debatable Issues . . . . . . . . . . . . . . . . . . . . . 57
3.10.1 Network Modeling . . . . . . . . . . . . . . . . . . . 57
3.10.2 System Modeling . . . . . . . . . . . . . . . . . . . 57
3.10.3 One, Two or many Protocols . . . . . . . . . . . . . . 58
3.10.4 Class of Protocol . . . . . . . . . . . . . . . . . . 58
3.10.5 Map Abstraction . . . . . . . . . . . . . . . . . . . 58
3.10.6 Clear Identification for all Entities . . . . . . . . 59
3.10.7 Robustness and redundancy: . . . . . . . . . . . . . . 59
3.10.8 Hierarchy . . . . . . . . . . . . . . . . . . . . . . 59
3.10.9 Control Theory . . . . . . . . . . . . . . . . . . . . 60
3.10.10 Byzantium . . . . . . . . . . . . . . . . . . . . . 60
3.10.11 VPN Support . . . . . . . . . . . . . . . . . . . . 60
3.10.12 End-to-End Reliability . . . . . . . . . . . . . . . 61
3.10.13 End-to-End Transparency . . . . . . . . . . . . . . 61
4. Security Considerations . . . . . . . . . . . . . . . . . . . 62
5. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 63
6. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 64
7. Informative References . . . . . . . . . . . . . . . . . . . . 65
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . 67
Intellectual Property and Copyright Statements . . . . . . . . 69
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1. Background
In 2001, the IRTF Routing Research Group (IRTF RRG) chairs, Abha
Ahuja and Sean Doran, decided to establish a sub-group to look at
requirements for inter-domain routing (IDR). A group of well known
routing experts was assembled to develop requirements for a new
routing architecture. Their mandate was to approach the problem
starting from a blank sheet. This group was free to take any
approach, including a revolutionary approach, in developing
requirements for solving the problems they saw in inter domain
routing.
Simultaneously, an independent effort was started in Sweden with a
similar goal. A team, calling itself Babylon, representing vendors,
service providers, and academia, assembled to understand the history
of inter-domain routing, to research the problems seen by the service
providers, and to develop a proposal of requirements for a follow-on
to the current routing architecture. This group's approach required
an evolutionary approach starting from current routing architecture
and practice. In other words the group limited itself to developing
an evolutionary strategy. The Babylon group was later folded into
the IRTF RRG as Sub-Group B.
One of the questions that arose while the groups were working in
isolation was whether there would be many similarities between their
sets of requirements. That is, would the requirements that grew from
a blank sheet of paper resemble those that started with the
evolutionary approach? As can be seen from reading the two sets of
requirements, there were many areas of fundamental agreement but some
areas of disagreement.
There were suggestions within the RRG that the two teams should work
together to create a single set of requirements. Since these
requirements are only guidelines to future work, however, some felt
that doing so would risk losing content without gaining any
particular advantage. It is not as if any group, for example the
IRTF RRG or the IETF Routing Area, was expected to use these
requirements as written and to create an architecture that met these
requirements. Rather, the requirements, were really strong
recommendations for a way to proceed in creating a new routing
architecture. In the end the decision was made to include the
results of both efforts, side by side, in one document.
This document contains the two requirement sets produced by the
teams. The text has received only slight editorial modifications;
the requirements have been left unaltered.
In reading this document it is important to keep in mind that all of
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these requirements are suggestions, which are laid out to assist
those interested in developing new routing architectures. It is also
important to remember that, while the people working on these
suggestions have done their best to make intelligent suggestions,
there are no guarantees. So a reader of this document should not
treat what it says as absolute, nor treat every suggestion as
necessary. No architecture is expected to fulfill every
'requirement.' Hopefully, though, future architectures will consider
what is offered in this document.
Finally, this document does not make any claims that it is possible
to have a practical solution that meets all the listed requirements.
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2. Results from Group A
This section presents the results of the work done by Sub-Group A of
the IRTF-RRG during 2001- 2002. The work originally appeared under
the title: "Requirements For a Next Generation Routing and Addressing
Architecture" and was edited by Frank Kastenholz.
2.1 Group A - Requirements For a Next Generation Routing and Addressing
Architecture
The requirements presented in this section are not presented in any
order.
2.1.1 Architecture
The new routing and addressing protocols, data structures, and
algorithms need to be developed from a clear, well thought out,
documented, architecture.
The new routing and addressing system must have an architectural
specification which describes all of the routing and addressing
elements, their interactions, what functions the system performs, and
how it goes about performing them. The architectural specification
does not go into issues such as protocol and data structure design.
The architecture should be agnostic with regard to specific
algorithms and protocols.
Doing architecture before doing detailed protocol design is good
engineering practice. This allows the architecture to be reviewed
and commented upon, with changes made as necessary, when it is still
easy to do so. Also, by producing an architecture, the eventual
users of the protocols (the operations community) will have a better
understanding of how the designers of the protocols meant them to be
used.
2.1.2 Separable Components
The architecture must place different functions into separate
components.
Separating functions, capabilities, and so forth, into individual
components and making each component "stand alone" is generally
considered by system architects to be "A Good Thing". It allows
individual elements of the system to be designed and tuned to do
their jobs "very well". It also allows for piecemeal replacement and
upgrading of elements as new technologies and algorithms become
available.
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The architecture must have the ability to replace or upgrade existing
components and to add new ones, without disrupting the remaining
parts of the system. Operators must be able to roll out these
changes and additions incrementally (i.e., no "flag days"). These
abilities are needed to allow the architecture to evolve as the
Internet changes.
The Architecture Specification shall define each of these components,
their jobs, and their interactions.
Some thoughts to consider along these lines are
o Making topology and addressing separate subsystems. This may
allow highly optimized topology management and discovery without
constraining the addressing structure or physical topology in
unacceptable ways.
o Separate "fault detection and healing" from basic topology.
From Mike O'Dell:
"Historically the same machinery is used for both. While
attractive for many reasons, the availability of exogenous
topology information (i.e., the intended topology) should, it
seems, make some tasks easier than the general case of starting
with zero knowledge. It certainly helps with recovery in the
case of constraint satisfaction. In fact, the intended
topology is a powerful way to state certain kinds of policy."
[refs.46]
o Making policy definition and application a separate subsystem,
layered over the others.
The architecture should also separate topology, routing, and
addressing from the application that uses those components. This
implies that applications such as policy definition, forwarding, and
circuit and tunnel management are separate subsystems layered on top
of the basic topology, routing, and addressing systems.
2.1.3 Scalable
Scaling is the primary problem facing the routing and addressing
architecture today. This problem must be solved and it must be
solved for the long term.
The Architecture must support a large and complex network. Ideally,
it will serve our needs for the next 20 years. Unfortunately:
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1. we do not know how big the Internet will grow over that time, and
2. the architecture developed from these requirements may change the
fundamental structure of the Internet and therefore its growth
patterns. This change makes it difficult to predict future
growth patterns of the Internet.
As a result, we can't quantify the requirement in any meaningful way.
Using today's architectural elements as a mechanism for describing
things, we believe that the network could grow to:
1. tens of thousands of AS's
Editor's Note: As of 2005, this level has already been reached
2. tens to hundreds of millions of prefixes, during the lifetime of
this architecture.
These sizes are given as a 'flavor' for how we expect the Internet to
grow. We fully believe that any new architecture may eliminate some
current architectural elements and introduce new ones.
A new routing and addressing architecture designed for a specific
network size would be inappropriate. First, the cost of routing
calculations is based only in part on the number of AS's or prefixes
in the network. The number and locations of the links in the network
is also a significant factor. Second, past predictions of Internet
growth and topology patterns have proven to be wildly inaccurate so
developing an architecture to a specific size goal would at best be
shortsighted.
Editor's note: At the time of these meetings, the BGP statistics
kept at sites such as www.routeviews.org either did not exist or
had been running for only a few months. After 5 years of
recording public internet data trends in AS growth, routing table
growth can be observed (past) with some short term prediction. As
each year of data collection continues the ability to observe and
predict trends improves. This architecture work pointed out the
need for such statistics to improve future routing designs.
Therefore we will not make the scaling requirement based on a
specific network size. Instead, the new routing and addressing
architecture should have the ability to constrain the increase in
load (CPU, memory space and bandwidth, and network bandwidth) on ANY
SINGLE ROUTER to be less than these specific functions:
1. The computational power and memory sizes required to execute the
routing protocol software and to contain the tables must grow
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more slowly than hardware capabilities described by Moore's Law,
doubling every 18 months. Other observations indicate that
memory sizes double every 2 years or so.
2. Network bandwidth and latency are some key constraints on how
fast routing protocol updates can be disseminated (and therefore
how fast the routing system can adapt to changes). Raw network
bandwidth seems to quadruple every 3 years or so. However, it
seems that there are some serious physics problems in going
faster than 40gbits (OC768); we should not expect raw network
link speed to grow much beyond OC768. On the other hand, for
economic reasons, large swathes of the core of the Internet will
still operate at lower speeds, possibly as slow as DS3.
Furthermore, in some sections of the Internet even lower speed
links are found. Corporate access links are often T1, or slower.
Low-speed radio links exist. Intra-domain links may be T1 or
fractional-T1 (or slower).
Therefore, the architecture must not make assumptions about the
bandwidth available.
3. The speeds of high-speed RAMS (SRAMs, used for caches and the
like) are growing, though slowly. Because of their use in caches
and other very specific applications, these RAMs tend to be
small, a few megabits, and the size of these RAMs is not
increasing very rapidly. On the other hand, the speed of "large"
memories (DRAMs) is increasing even slower than that for the high
speed RAMS. This is because the development of these RAMs is
driven by the PC market, where size is very important, and low
speed can be made up for by better caches.
Memory access rates should not be expected to increase
significantly.
1. Editor's Note: Various techniques have significantly
increased memory bandwdith. 800MHz is now possible, compared
with less then 100MHz in 2000. This does not, however,
contradict the next paragraph, but rather just extends the
timescales somewhat.
The growth in resources available to any one router will eventually
slow down. It may even stop. Even so, the network will continue to
grow. The routing and addressing architecture must continue to scale
in even this extreme condition. We cannot continue to add more
computing power to routers forever. Other strategies must be
available. Some possible strategies are hierarchy, abstraction, and
aggregation of topology information.
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2.1.4 Lots of Interconnectivity
The new routing and addressing architecture must be able to cope with
a high degree of interconnectivity in the Internet. That is, there
are large numbers of alternate paths and routes among the various
elements. Mechanisms are required to prevent this interconnectivity
(and continued growth in interconnectivity) from causing tables,
compute time, and routing protocol traffic to grow without bound.
The "cost" to the routing system of an increase in complexity must be
limited in scope; sections of the network that do not see, or do not
care about, the complexity ought not pay the cost of that complexity.
Over the past several years, the Internet has seen an increase in
interconnectivity. Individual end sites (companies, customers, etc),
ISPs, exchange points, and so on, all are connecting to more "other
things". Company's multi-home to multiple ISPs, ISPs peer with more
ISPs, and so on. These connections are made for many reasons, such
as getting more bandwidth, increased reliability and availability,
policy, and so on. However, this increased interconnectivity has a
price. It leads to more scaling problems as it increases the number
of AS paths in the networks.
Any new architecture must assume that the Internet will become a
denser mesh. It must not assume, nor can it dictate, certain
patterns or limits on how various elements of the network
interconnect.
Another facet of this requirement is that there may be multiple
valid, loop free, paths available to a destination. See
Section 2.1.7 for a further discussion.
We wryly note that one of the original design goals of IP was to
support a large, heavily interconnected, network, which would be
highly survivable (such as in the face of a nuclear war).
2.1.5 Random Structure
The routing and addressing architecture must not place any
constraints on or make assumptions about the topology or
connectedness of the elements comprising the Internet. The routing
and addressing architecture must not presume any particular network
structure. The network does not have a "nice" structure. In the
past we used to believe that there was this nice "backbone/tier-1/
tier-2/end-site" sort of hierarchy. This is not so. Therefore, any
new Architecture must not presume any such structure.
Some have proposed that a geographic addressing scheme be used,
requiring exchange points to be situated within each geographic
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'region'. There are many reasons why we believe this to be a bad
approach, but those arguments are irrelevant. The main issue is that
the routing architecture should not presume a specific network
structure.
2.1.6 Multi-homing
The Architecture must provide multi-homing for all elements of the
Internet. That is, multihoming of hosts, subnetworks, end- sites,
"low-level" ISPs, and backbones (i.e. lots of redundant
interconnections) must be supported. Among the reasons to multi-home
are reliability, load sharing, and performance tuning.
The term "multihoming" may be interpreted in its broadest sense --
one "place" has multiple connections or links to another "place".
The architecture must not limit the number of alternate paths to a
multi-homed site.
When multi-homing is used, it must be possible to use one, some (more
than one but less than all), or all of the available paths to the
multi-homed site. The multi-homed site must have the ability to
declare which path(s) are used and under what conditions (for
example, one path may be declared "primary" and the other "backup"
and to be used only when the primary fails).
A current problem in the Internet is that multihoming leads to undue
increases in the size of the BGP routing tables. The new
architecture must support multi-homing without undue routing table
growth.
2.1.7 Multi-path
As a corollary to multi-homing, the Architecture must allow for
multiple paths from a source to a destination to be active at the
same time. These paths need not have the same attributes. Policies
are to be used to disseminate the attributes and to classify traffic
for the different paths.
There must be a rich "language" for specifying the rules for
classifying the traffic and assigning classes of traffic to different
paths (or prohibiting it from certain paths). The rules should allow
traffic to be classified based upon at least the following:
o IPv6 FlowIDs,
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o DSCP values,
o source and/or destination prefixes, or
o random selections at some probability.
A mechanism is needed that allows operators to plan and manage the
traffic load on the various paths. To start, this mechanism can be
semi-automatic or even manual. Eventually it ought to become fully
automatic.
When multi-path forwarding is used, options must be available to
preserve packet ordering where appropriate (such as for individual
TCP connections).
Please refer to Section 2.2.7 for a discussion of dynamic load-
balancing and management over multiple paths.
2.1.8 Convergence
The speed of convergence (also called the "stabilization time") is
the time it takes for a router's routing processes to reach a new,
stable, "solution" (i.e. forwarding information base) after a change
someplace in the network. In effect, what happens is that the output
of the routing calculations stabilizes -- the Nth iteration of the
software produces the same results as the N-1th iteration.
The speed of convergence is generally considered to be a function of
the number of subnetworks in the network and the amount of
connections between those networks. As either number grows, the time
it takes to converge increases.
In addition, a change can "ripple" back and forth through the system.
One change can go through the system, causing some other router to
change its advertised connectivity, causing a new change to ripple
through. These oscillations can take a while to work their way out
of the network. It is also possible that these ripples never die
out. In this situation the routing and addressing system is
unstable; it never converges.
Finally, it is more than likely that the routers comprising the
Internet never converge simply because the Internet is so large and
complex. Assume it takes S seconds for the routers to stabilize on a
solution for any one change to the network. Also assume that changes
occur, on average, every C seconds. Because of the size and
complexity of the Internet, C is now less than S. Therefore, if a
change, C1, occurs at time T, the routing system would stabilize at
time T+S, but a new change, C2, will occur at time T+C, which is
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before T+S. The system will start processing the new change before
it's done with the old.
This is not to say that all routers are constantly processing
changes. The effects of changes are like ripples in a pond. They
spread outward from where they occur. Some routers will be
processing just C1, others C2, others both C1 and C2, and others
neither.
We have two separate scopes over which we can set requirements with
respect to convergence:
1. Single Change
In this requirement a single change of any type (link addition or
deletion, router failure or restart, etc.) is introduced into a
stabilized system. No additional changes are introduced. The
system must re-stabilize within some measure of bounded time.
This requirement is a fairly abstract one as it would be
impossible to test in a real network. Definition of the time
constraints remains an open research issue.
2. System-wide
Defining a single target for maximum convergence time for the
real Internet is absurd. As we mentioned earlier, the Internet
is large enough and diverse enough so that it is quite likely
that new changes are introduced somewhere before the system fully
digests old ones.
So, the first requirement here is that there must be mechanisms to
limit the scope of any one change's visibility and effects. The
number of routers that have to perform calculations in response to a
change is kept small, as is the settling time.
The second requirement is based on the following assumptions
- the scope of a change's visibility and impact can be limited.
That is, routers within that scope know of the change and
recalculate their tables based on the change. Routers outside of
the scope don't see it at all.
- Within any scope, S, network changes are constantly occurring and
the average inter-change interval is Tc seconds.
- There are Rs routers within scope S
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- A subset of the destinations known to the routers in S, Ds, are
impacted by a given change.
- We can state that for Z% of the changes, within Y% of Tc seconds
after a change, C, X% of the Rs routers have their routes to Ds
settled to a useful answer (useful meaning that packets can get to
Ds, thought perhaps not by the optimal path -- this allows some
'hunting' for the optimal solution)
X, Y, Z, are, yet to be defined. Their definition remains a
research issue.
This requirement implies that the scopes can be kept relatively small
in order to minimize Rs and maximize Tc.
The growth rate of the convergence time must not be related to the
growth rate of the Internet as a whole. This implies that the
convergence time either
1. not be a function of basic network elements (such as prefixes and
links/paths), and/or
2. that the Internet be continuously divisible into chunks that
limit the scope and effect of a change, thereby limiting the
number of routers, prefixes, links, and so on, involved in the
new calculations.
2.1.9 Routing System Security
The security of the Internet's routing system is paramount. If the
routing system is compromised or attacked, the entire Internet can
fail. This is unacceptable. Any new Architecture must be secure.
Architectures by themselves are not secure. It is the implementation
of an architecture; its protocols, algorithms, and data structures,
that are secure. These requirements apply primarily to the
implementation. The architecture must provide the elements that the
implementation needs to meet these security requirements. Also, the
architecture must not prevent these security requirements from being
met.
Security means different things to different people. In order for
this requirement to be useful, we must define what we mean by
security. We do this by identifying the attackers and threats we
wish to protect against. They are:
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Masquerading
The system, including its protocols, must be secure against
intruders adopting the identity of other known, trusted, elements
of the routing system and then using that position of trust for
carrying out other attacks. Protocols must use cryptographically
strong authentication.
Denial of Service (DoS) Attacks
The architecture and protocols should be secure against DoS
attacks directed at the routers.
The new architecture and protocols should provide as much
information as it can to allow administrators to track down
sources of DoS and DDoS attacks.
No Bad Data
Any new architecture and protocols must provide protection
against the introduction of bad, erroneous, or misleading, data
by attackers. Of particular importance, an attacker must not be
able to redirect traffic flows, with the intent of
o directing legitimate traffic away from a target, causing a
denial-of-service attack by preventing legitimate data from
reaching its destination,
o directing additional traffic (going to other destinations
which are 'innocent bystanders') to a target, causing the
target to be overloaded, or
o Directing traffic addressed to the target to a place where the
attacker can copy, snoop, alter, or otherwise affect the
traffic.
Topology Hiding
Any new architecture and protocols must provide mechanisms to
allow network owners to hide the details of their internal
topologies, while maintaining the desired levels of service
connectivity and reachability.
Privacy
By "privacy" we mean privacy of the routing protocol exchanges
between routers.
When the routers are on point-to-point links, with routers at
each end, there is no need to encrypt the routing protocol
traffic; there is little possibility of a third party
intercepting the traffic, and if one of the two routers is
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compromised then it doesn't matter. This is not sufficient. We
believe that it is important to have the ability to protect
routing protocol traffic in two cases:
1. When the routers are on a shared network it is possible that
there are hosts on the network that have been compromised.
These hosts could surreptitiously monitor the protocol
traffic.
2. When two routers are exchanging information "at a distance"
(over intervening routers and, possibly, administrative
domains). In this case, the security of the intervening
routers, links, and so on, cannot be assured. Thus, the
ability to encrypt this traffic is important.
Therefore, we believe that the option to encrypt routing protocol
traffic is required.
Data Consistency
A router should be able to detect and recover from any data that
is received from other routers which is inconsistent. That is,
it must not be possible for data from multiple routers, none of
which is malicious, to "break" another router.
Where security mechanisms are provided, they must use methods that
are considered to be cryptographically secure (e.g. using
cryptographically strong encryption and signatures -- no clear text
passwords!).
Use of security features should not be optional (except as required
above). This may be "social engineering" on our part, but we believe
it to be necessary. If a security feature is optional, the
implementation of the feature must default to the "secure" setting.
2.1.10 End Host Security
The Architecture must not prevent individual host-to-host
communications sessions from being secured (i.e. it cannot interfere
with things like IPsec).
2.1.11 Rich Policy
Before setting out Policy requirements, we need to define the term.
Like "security", "policy" means many things to many people. For our
purposes, policy is the set of administrative influences that alter
the path determination and next-hop selection procedures of the
routing software.
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The main motivators for influencing path and next-hop selection seem
to be transit rules, business decisions and load management.
The new architecture must support rich policy mechanisms.
Furthermore, the policy definition and dissemination mechanisms
should be separated from the network topology and connectivity
dissemination mechanisms. Policy provides input to and controls the
generation of the forwarding table and the abstraction, filtering,
aggregation, and dissemination of topology information.
Note that if the architecture is properly divided into subsystems
then at a later time, new policy subsystems that include new features
and capabilities could be developed and installed as needed.
We divide the general area of policy into two sub-categories, routing
information and traffic control. Routing Information Policies
control what routing information is disseminated or accepted, how it
is disseminated, and how routers determine paths and next-hops from
the received information. Traffic Control Policies determine how
traffic is classified and assigned to routes.
2.1.11.1 Routing Information Policies
There must be mechanisms to allow network administrators, operators,
and designers to control receipt and dissemination of routing
information. These controls include, but are not limited to:
- Selecting to which other routers routing information will be
transmitted.
- Specifying the "granularity" and type of transmitted information.
The length of IPv4 prefixes is an example of "granularity".
- Selection and filtering of topology and service information that
is transmitted. This gives different 'views' of internal
structure and topology to different peers.
- Selecting the level of security and authenticity for transmitted
information
- Being able to cause the level of detail that is visible for some
portion of the network to reduce the farther you get from that
part of the network.
- Selecting from whom routing information will be accepted. This
control should be "provisional" in the sense of "accept routes
from "foo" only if there are no others available".
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- Accepting or rejecting routing information based on the path the
information traveled (using the current system as an example, this
would be filtering routes based on an AS appearing anywhere in the
AS path). This control should be "use only if there are no other
paths available".
- Selecting the desired level of "granularity" for received routing
information (this would include, but is not limited to, things
similar in nature to the prefix-length filters widely used in the
current routing and addressing system).
- Selecting the level of security and authenticity of received
information in order for that information to be accepted.
- Determining the treatment of received routing information based on
attributes supplied with the information.
- Applying attributes to routing information that is to be
transmitted and then determining treatment of information (e.g.,
sending it "here" but not "there") based on those tags.
- Selection and filtering of topology and service information that
is received.
2.1.11.2 Traffic Control Policies
The architecture should provide mechanisms that allow network
operators to manage and control the flow of traffic. The traffic
controls should include, but are not limited to:
- The ability to detect and eliminate congestion points in the
network (by re-directing traffic around those points) .
- The ability to develop multiple paths through the network with
different attributes and then assign traffic to those paths based on
some discriminators within the packets (discriminators include, but
are not limited to, IP Addresses or prefixes, DSCP values, and MPLS
labels) .
- The ability to find and use multiple, equivalent, paths through the
network (i.e. they would have the "same" attributes) and allocate
traffic across the paths.
- The ability to accept or refuse traffic based on some traffic
classification (providing, in effect, transit policies).
Traffic classification must at least include the source and
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destination IP addresses (prefixes) and the DSCP value. Other fields
may be supported, such as
o Protocol and port based functions,
o DSCP/QoS tuple (such as ports)
o Per-host operations (i.e. /32s for IPv4 and /128s for IPv6),
o Traffic matrices (e.g., traffic from prefix X and to prefix Y).
2.1.12 Incremental Deployment
The reality of the Internet is that there can be no Internet wide cut
over from one architecture and protocol to another. This means that
any new architecture and protocol must be incrementally deployable;
ISPs must be able to set up small sections of the new architecture,
check it out, and then slowly grow the sections. Eventually, these
sections will "touch" and "squeeze out" the old architecture.
The protocols that implement the Architecture must be able to
interoperate at "production levels" with currently existing routing
protocols. Furthermore, the protocol specifications must define how
the interoperability is done.
We also believe that sections of the Internet will never convert over
to the new architecture. Thus, it is important that the new
architecture and its protocols be able to interoperate with "old
architecture" regions of the network indefinitely.
The architecture's addressing system must not force existing address
allocations to be redone: no renumbering!
2.1.13 Mobility
There are two kinds of mobility; host mobility and network mobility.
Host mobility is when an individual host moves from where it was to
where it is. Network mobility is when an entire network (or
subnetwork) moves.
The architecture must support network level mobility. Please refer
to Section 2.2.9 for a discussion of Host Mobility.
2.1.14 Address Portability
One of the big "hot items" in the current Internet political climate
is portability of IP addresses (both V4 and V6). The short
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explanation is that people do not like to renumber when changing
connection point or provider and do not trust automated renumbering
tools.
The Architecture must provide complete address portability.
2.1.15 Multi-Protocol
The Internet is expected to be "multi-protocol" for at least the next
several years. IPv4 and IPv6 will co-exist in many different ways
during a transition period. The architecture must be able to handle
both IPv4 and IPv6 addresses. Furthermore, protocols that supplant
IPv4 and IPv6 may be developed and deployed during the lifetime of
the architecture. The architecture must be flexible and extensible
enough to handle new protocols as they arise.
Furthermore, the architecture must not assume any given relationships
between a topological element's IPv4 address and its IPv6 address.
The architecture must not assume that all topological elements have
IPv4 addresses/prefixes, nor can it assume that they have IPv6
addresses/prefixes.
The architecture should allow different paths to the same destination
to be used for different protocols, even if all paths can carry all
protocols.
In addition to the addressing technology, the architecture need not
be restricted to only packet based multiplexing/demultiplexing
technology (such as IP); support for other multiplexing/
demultiplexing technologies may be added.
2.1.16 Abstraction
The architecture must provide mechanisms for network designers and
operators to:
o Group elements together for administrative control purposes,
o Hide the internal structure and topology of those groupings for
administrative and security reasons,
o Limit the amount of topology information that is exported from the
groupings in order to control the load placed on external routers,
o Define rules for traffic transiting or terminating in the
grouping.
The architecture must allow the current Autonomous System structure
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to be mapped into any new abstraction schemes.
Mapping mechanisms, algorithms, and techniques must be specified.
2.1.17 Simplicity
The architecture must be simple enough so that someone who is
extremely knowledgeable in routing and who is skilled at creating
straightforward and simple explanations can explain all the important
concepts in less than an hour.
This criterion has been chosen since developing an objective measure
of complexity for an architecture can be very difficult and is out of
scope for this document.
The requirement is that the routing architecture be kept as simple as
possible. This requires careful evaluation of possible features and
functions with a merciless weeding out of those that "might be nice"
but are not necessary.
By keeping the architecture simple, the protocols and software used
to implement the architecture are simpler. This simplicity in turn
leads to:
1. Faster implementation of the protocols. If there are fewer bells
and whistles, then there are fewer things that need to be
implemented.
2. More reliable implementations. With fewer components, there is
less code, reducing bug counts, and fewer interactions between
components that could lead to unforeseen and incorrect behavior.
2.1.18 Robustness
The architecture, and the protocols implementing it, should be
robust. Robustness comes in many different flavors. Some
considerations with regard to robustness include (but are not limited
to):
o Defective (even malicious) trusted routers.
o Network failures. Whenever possible, valid alternate paths are to
be found and used.
o Failures must be localized. That is, the architecture must limit
the "spread" of any adverse effects of a misconfiguration or
failure. Badness must not spread.
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Of course, the general robustness principle of being liberal in
what's accepted and conservative in what's sent must also be applied.
Original Editor's note:
Some of the contributors to this section have argued
that robustness is an aspect of Security. I have
exercised editor's discretion by making it a
separate section. The reason for this is that to
too many people "security" means "protection from
break ins" and "authenticating and encrypting data".
This requirement goes beyond those views.
2.1.19 Media Independence
While it is an article of faith that IP operates over a wide variety
of media (such as Ethernet, X.25, ATM, and so on), IP routing must
take an agnostic view toward any "routing" or "topology" services
that are offered by the medium over which IP is operating. That is,
the new architecture must not be designed to integrate with any
media-specific topology management or routing scheme.
The routing architecture must assume, and must work over, the
simplest possible media.
The routing and addressing architecture can certainly make use of
lower-layer information and services, when and where available, and
to the extent that IP routing wishes.
2.1.20 Stand-alone
The routing architecture and protocols must not rely on other
components of the Internet (such as DNS) for their correct operation.
Routing is the fundamental process by which data "finds its way
around the Internet" and most, if not all, of those other components
rely on routing to properly forward their data. Thus, Routing cannot
rely on any Internet systems, services or capabilities that in turn
rely on Routing. If it did, a dependency loop would result.
2.1.21 Safety of Configuration
The architecture, protocols, and standard implementation defaults
must be such that a router installed "out of the box" with no
configuration etc by the operators will not cause "bad things" to
happen to the rest of the routing system (no dial up customers
advertising routes to 18/8!)
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2.1.22 Renumbering
The routing system must allow topological entities to be renumbered.
2.1.23 Multi-prefix
The architecture must allow topological entities to have multiple
prefixes (or the equivalent under the new architecture).
2.1.24 Cooperative Anarchy
As RFC1726[refs.44] said:
"A major contributor to the Internet's success is the fact that
there is no single, centralized, point of control or promulgator
of policy for the entire network. This allows individual
constituents of the network to tailor their own networks,
environments, and policies to suit their own needs. The
individual constituents must cooperate only to the degree
necessary to ensure that they interoperate."
This decentralization, called "cooperative anarchy", is still a key
feature of the Internet today. The new routing architecture must
retain this feature. There can be no centralized point of control or
promulgator of policy for the entire Internet.
2.1.25 Network Layer Protocols and Forwarding Model
For the purposes of backward compatibility, any new routing and
addressing architecture and protocols must work with IPv4 and IPv6
using the traditional "hop by hop" forwarding and packet-based
multiplex/demultiplex models. However, the architecture need not be
restricted to these models. Additional forwarding and multiplex/
demultiplex models may be added.
2.1.26 Routing Algorithm
The architecture should not require a particular routing algorithm
family. That is to say, the architecture should be agnostic about
link-state, distance-vector, or path-vector routing algorithms.
2.1.27 Positive Benefit
Finally, the architecture must show benefits in terms of increased
stability, decreased operational costs, and increased functionality
and lifetime, over the current schemes. This benefit must remain
even after the inevitable costs of developing and debugging the new
protocols, enduring the inevitable instabilities as things get shaken
out, and so on.
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2.1.28 Administrative Entities and the IGP/EGP Split
We explicitly recognize that the Internet consists of resources under
control of multiple administrative entities. Each entity must be
able to manage its own portion of the Internet as it sees fit.
Moreover, the constraints that can be imposed on routing and
addressing on the portion of the Internet under the control of one
administration may not be feasibly extended to cover multiple
administrations. Therefore, we recognize a natural and inevitable
split between routing and addressing that is under a single
administrative control and routing and addressing that involves
multiple administrative entities. Moreover, while there may be
multiple administrative authorities, the administrative authority
boundaries may be complex and overlapping, rather than being a strict
hierarchy.
Furthermore, there may be multiple levels of administration, each
with its own level of policy and control. For example, a large
network might have "continental-level" administrations covering its
European and Asian operations, respectively. There would also be
that network's "inter-continental" administration covering the
Europe-to-Asia links. Finally, there would be the "Internet" level
in the administrative structure (analogous to the "exterior" concept
in the current routing architecture).
Thus, we believe that the administrative structure of the Internet
must be extensible to many levels (more than the two provided by the
current IGP/EGP split). The interior/exterior property is not
absolute. The interior/exterior property of any point in the network
is relative; a point on the network is interior with respect to some
points on the network and exterior with respect to others.
Administrative entities may not trust each other; some may be almost
actively hostile toward each other. The architecture must
accommodate these models. Furthermore, the architecture must not
require any particular level of trust among administrative entities.
2.2 Non-Requirements
The following are not required or are non-goals. This should not be
taken to mean that these issues must not be addressed by a new
architecture. Rather, addressing these issues or not is purely an
optional matter for the architects.
2.2.1 Forwarding Table Optimization
We believe that it is not necessary for the architecture to minimize
the size of the forwarding tables (FIBS). Current memory sizes,
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speeds, and prices, along with processor and ASIC capabilities allow
forwarding tables to be very large, O(E6), and allow fast (100M
lookups/second) tables to be built with little difficulty.
2.2.2 Traffic Engineering
Traffic Engineering is one of those terms that has become terribly
overloaded. If you ask N people what traffic engineering is, you get
something like N! disjoint answers. Therefore, we elect not to
require "traffic engineering", per se. Instead, we have endeavored
to determine what the ultimate intent is when operators "traffic
engineer" their networks and then make those capabilities an inherent
part of the system.
2.2.3 Multicast
The new architecture is not designed explicitly to be an inter-domain
multicast routing architecture. However, given the notable lack of a
viable, robust, and widely deployed inter-domain multicast routing
architecture, the architecture should not hinder the development and
deployment of inter-domain multicast routing without adverse effect
on meeting the other requirements.
We do note however that one respected network sage [refs.47] has said
(roughly)
"When you see a bunch of engineers standing around congratulating
themselves for solving some particularly ugly problem in
networking, go up to them, whisper "multicast", jump back, and
watch the fun begin..."
2.2.4 Quality of Service (QoS)
The Architecture concerns itself primarily with disseminating network
topology information so that routers may select paths to destinations
and build appropriate forwarding tables. QoS is not a part of this
function and we make no requirements with respect to QoS.
However, QoS is an area of great and evolving interest. It is
reasonable to expect that in the not too distant future,
sophisticated QoS facilities will be deployed in the Internet. Any
new architecture and protocols should be developed with an eye toward
these future evolutions. Extensibility mechanisms, allowing future
QoS routing and signaling protocols to "piggy- back" on top of the
basic routing system are desired.
We do require the ability to assign attributes to entities and then
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do path generation and selection based on those attributes. Some may
call this QoS.
2.2.5 IP Prefix Aggregation
There is no specific requirement that CIDR-style IP Prefix
aggregation be done by the new architecture. Address allocation
policies, societal pressure, and the random growth and structure of
the Internet have all conspired to make prefix aggregation
extraordinarily difficult, if not impossible. This means that large
numbers of prefixes will be sloshing about in the routing system and
that forwarding tables will grow quite big. This is a cost that we
believe must be borne.
Nothing in this non-requirement should be interpreted as saying that
prefix aggregation is explicitly prohibited. CIDR-style IP Prefix
aggregation might be used as a mechanism to meet other requirements,
such as scaling.
2.2.6 Perfect Safety
Making the system impossible to mis-configure is, we believe, not
required. The checking, constraints, and controls necessary to
achieve this could, we believe, prevent operators from performing
necessary tasks in the face of unforeseen circumstances.
However, safety is always a "good thing", and any results from
research in this area should certainly be taken into consideration
and, where practical, incorporated into the new routing architecture.
2.2.7 Dynamic Load Balancing
Past history has shown that using the routing system to perform
highly dynamic load balancing among multiple more-or-less-equal paths
usually ends up causing all kinds of instability, etc, in the
network. Thus, we do not require such a capability.
However, this is an area that is ripe for additional research, and
some believe that the capability will be necessary in the future.
Thus, the architecture and protocols should be "malleable" enough to
allow development and deployment of dynamic load balancing
capabilities, should we ever figure out how to do it.
2.2.8 Renumbering of hosts and routers
We believe that the routing system is not required to "do
renumbering" of hosts and routers. That's an IP issue.
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Of course, the routing and addressing architecture must be able to
deal with renumbering when it happens.
2.2.9 Host Mobility
In the Internet Architecture, host-mobility is handled on a per-host
basis by a dedicated, Mobile-IP protocol [refs.45]. Traffic destined
for a mobile-host is explicitly forwarded by dedicated relay agents.
Mobile-IP [refs.45] adequately solves the host- mobility problem and
we do not see a need for any additional requirements in this area.
Of course, the new architecture must not impede or conflict with
Mobile-IP.
2.2.10 Backward Compatibility
For the purposes of development of the architecture, we assume that
there is a 'clean slate'. Unless specified in Section 2.1, there are
no explicit requirements that elements, concepts, or mechanisms of
the current routing architecture be carried forward into the new one.
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3. Requirements from Group B
The following is the result of the work done by Sub-Group B of the
IRTF-RRG in 2001-2002. It was originally released under the title:
"Future Domain Routing Requirements" and was edited by Avri Doria and
Elwyn Davies.
3.1 Group B - Future Domain Routing Requirements
It is generally accepted that there are major shortcomings in the
inter-domain routing of the Internet today and that these may result
in meltdown within an unspecified period of time. Remedying these
shortcomings will require extensive research to tie down the exact
failure modes that lead to these shortcomings and identify the best
techniques to remedy the situation.
Changes in the nature and quality of the services that users want
from the Internet are difficult to provide within the current
framework, as they impose requirements never foreseen by the original
architects of the Internet routing system.
The kind of radical changes that have to be accommodated are
epitomized by the advent of IPv6 and the application of IP mechanisms
to private commercial networks that offer specific service guarantees
beyond the best-effort services of the public Internet. Major
changes to the inter-domain routing system are inevitable to provide
an efficient underpinning for the radically changed and increasingly
commercially-based networks that rely on the IP protocol suite.
3.2 Underlying Principles
Although inter-domain routing is seen as the major source of
problems, the interactions with intra-domain routing, and the
constraints that confining changes to the inter-domain arena would
impose, mean that we should consider the whole area of routing as an
integrated system. This is done for two reasons:
- Requirements should not presuppose the solution. A continued
commitment to the current definitions and split between inter-
domain and intra-domain routing would constitute such a
presupposition. Therefore this part of the document uses the name
Future Domain Routing(FDR).
- It is necessary to acknowledge how intertwined inter-domain and
intra-domain routing are within today's routing architecture.
We are aware that using the term "domain routing" is already fraught
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with danger because of possible misinterpretation due to prior usage.
The meaning of "domain routing" will be developed implicitly
throughout the document, but a little advance explicit definition of
the word 'domain' is required, as well as some explanation on the
scope of 'routing'.
This document uses "domain" in a very broad sense, to mean any
collection of systems or domains that come under a common authority
that determines the attributes defining, and the policies
controlling, that collection. The use of domain in this manner is
very similar to the concept of region that was put forth by John
Wroclawski in his Metanet model [Wroclawski95]. The idea includes
the notion that certain attributes will characterize the behavior of
the systems within a domain and that there will be borders between
domains. The idea of domain presented here does not presuppose that
two domains will have the same behavior. Nor does it presuppose
anything about the hierarchical nature of domains. Finally, it does
not place restrictions on the nature of the attributes that might be
used to determine membership in a domain. Since today's routing
domains are an example of the concept of domains in this document,
there has been no attempt to create a new term.
Current practice in routing system design stresses the need to
separate the concerns of the control plane and the forwarding plane
in a router. This document will follow this practice, but we still
use the term "routing" as a global portmanteau to cover all aspects
of the system. Specifically, however, routing will be used to mean
the process of discovering, interpreting, and distributing
information about the logical and topological structure of the
network.
3.2.1 Inter-domain and Intra-domain
Throughout this section the terms intra-domain and inter-domain will
be used. These should be understood as relative terms. In all cases
of domains, there will be a set of network systems that are within
that domain; routing between these systems will be termed intra-
domain. In some cases there will be routing between domains, which
will be termed inter-domain. It is possible that the routing
exchange between two network systems can be viewed as intra-domain
from one perspective and as inter-domain from another perspective.
3.2.2 Influences on a Changing Network
The development of the Internet is likely to be driven by a number of
changes that will affect the organization and the usage of the
network, including:
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- Ongoing evolution of the commercial relationships between
(connectivity) service providers, leading to changes in the way in
which peering between providers is organized and the way in which
transit traffic is routed.
- Requirements for traffic engineering within and between domains
including coping with multiple paths between domains
- Addition of a second IP addressing technique through IPv6.
- The use of VPNs and private address space with IPv4 and IPv6
- Evolution of the end-to-end principle to deal with the expanded
role of the Internet, as discussed in [Blumenthal01]. This paper
discusses the possibility that the range of new requirements,
especially the social and techno-political ones that are being
placed on the future, may compromise the Internet's original
design principles. This might cause the Internet to lose some of
its key features, in particular its ability to support new and
unanticipated applications. This discussion is linked to the rise
of new stakeholders in the Internet, especially ISPs; new
government interests; the changing motivations of the ever growing
user base; and the tension between the demand for trustworthy
overall operation and the inability to trust the behaviour of
individual users.
- Incorporation of alternative forwarding techniques such as the
explicit routing (pipes) supplied by the MPLS [RFC3031] and GMPLS
[RFC3471] environments.
- Integration of additional constraints into route determination
from interactions with other layers (e.g. Shared Risk Link Groups
[I-D.many-inference-srlg]).
- Support for alternative and multiple routing techniques that are
better suited to delivering types of content organised in ways
other than into IP addressed packets.
Philosophically, the Internet has the mission of transferring
information from one place to another. Conceptually, this
information is rarely organised into conveniently sized, IP-addressed
packets, and the FDR needs to consider how the information (content)
to be carried is identified, named and addressed. Routing techniques
can then be adapted to handle the expected types of content.
3.2.3 High Level Goals
This section attempts to answer two questions:
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- What are we trying to achieve in a new architecture?
- Why should the Internet community care?
There is a third question that needs to be answered as well, but that
has seldom been explicitly discussed:
- How will we know when we have succeeded?
3.2.3.1 Providing a routing system matched to domain organization
Many of today's routing problems are caused by a routing system that
is not well matched to the organization and policies that it is
trying to support. Our goal is to develop a routing architecture
where even a domain organization that is not envisioned today can be
served by a routing architecture that matches its requirements. We
will know when this goal is achieved when the desired policies,
rules, and organization can be mapped into the routing system in a
natural, consistent, and simply understood way.
3.2.3.2 Supporting a range of different communication services
Today's routing protocols only support a single data forwarding
service that is typically used to deliver a best-effort service in
the public Internet. On the other hand, DiffServ for example, can
construct a number of different bit transport services within the
network. Using some of the per-domain behaviors (PDB)s that have
been discussed in the IETF, it is possible to construct services such
as Virtual Wire [I-D.ietf-diffserv-pdb-vw] and Assured Rate
[I-D.ietf-diffserv-pdb-ar].
Providers today offer rudimentary promises about traffic handling in
the network, for example delay and long-term packet loss guarantees.
This will probably be even more relevant in the future.
Communicating the service characteristics of paths in routing
protocols will be necessary in the near future, and it will be
necessary to be able to route packets according to their service
requirements.
Thus, a goal of this architecture is to allow adequate information
about path service characteristics to be passed between domains and
consequently, to allow the delivery of bit transport services other
than the best-effort datagram connectivity service that is the
current common denominator.
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3.2.3.3 Scaleable well beyond current predictable needs
Any proposed FDR system should scale beyond the size and performance
we can foresee for the next ten years. The previous IDR proposal as
implemented by BGP, has, with some massaging, held up for over ten
years. In that time the Internet has grown far beyond the
predictions that were implied by the original requirements.
Unfortunately, we will only know if we have succeeded in this goal if
the FDR system survives beyond its design lifetime without serious
massaging. Failure will be much easier to spot!
3.2.3.4 Alternative forwarding mechanisms
With the advent of circuit-based technologies (e.g., MPLS [RFC3031]
and GMPLS [RFC3471]) managed by IP routers there are forwarding
mechanisms other than the datagram service that need to be supported
by the routing architecture.
An explicit goal of this architecture is to add support for
forwarding mechanisms other then the current hop-by-hop datagram
forwarding service driven by globally unique IP addresses.
3.2.3.5 Separation of topology map from connectivity service
It is envisioned that an organization can support multiple services
within a single network. These services can, for example, be of
different quality, of different connectivity type, or of different
protocols (e.g. IPv4 and IPv6). For all these services there may be
common domain topology, even though the policies controlling the
routing of information might differ from service to service. Thus, a
goal with this architecture is to support separation between creation
of a domain (or organization) topology map and service creation.
3.2.3.6 Separation between routing and forwarding
The architecture of a router is composed of two main separable parts;
control and forwarding. These components, while inter-dependent,
perform functions that are largely independent of each other.
Control (routing, signaling, and management) is typically done in
software while forwarding typically is done with specialized ASICs or
network processors.
The nature of an IP-based network today is that control and data
protocols share the same network and forwarding regime. This may not
always be the case in future networks, and we should be careful to
avoid building in this sharing as an assumption in the FDR.
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A goal of this architecture is to support full separation of control
and forwarding, and to consider what additional concerns might be
properly considered separately (e.g. adjacency management).
3.2.3.7 Different routing paradigms in different areas of the same
network
A number of routing paradigms have been used or researched, in
addition to the conventional shortest path by hop count paradigm that
is the current mainstay of the Internet. In particular, differences
in underlying transport networks may mean that other kinds of routing
are more relevant, and the perceived need for traffic engineering
will certainly alter the routing chosen in various domains.
Explicitly, one of these routing paradigms should be the current
routing paradigm, so that the new paradigms will inter-operate in a
backward-compatible way with today's system. This will facilitate a
migration strategy that avoids flag days.
3.2.3.8 Protection against denial of service and other security attacks
Currently, existence of a route to a destination effectively implies
that anybody who can get a packet onto the network is entitled to use
that route. Whilst there are limitations to this generalization,
this is a clear invitation to denial of service attacks. A goal of
the FDR system should be to allow traffic to be specifically linked
to whole or partial routes so that a destination or link resources
can be protected from unauthorized use.
3.2.3.9 Provable convergence with verifiable policy interaction
It has been shown both analytically by Griffin et al (see
[Griffin99]) and practically (see [I-D.mcpherson-bgp-route-
oscillation]) that BGP will not converge stably or is only meta-
stable (i.e. will not re-converge in the face of a single failure)
when certain types of policy constraint are applied to categories of
network topology. The addition of policy to the basic distance
vector algorithm invalidates the proofs that could be applied to a
policy free implementation.
It has also been argued that global convergence may no longer be a
necessary goal and that local convergence may be all that is
required.
A goal of the FDR should be to achieve provable convergence of the
protocols used which may involve constraining the topologies and
domains subject to convergence. This will also require vetting the
policies imposed to ensure that they are compatible across domain
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boundaries and result in a consistent policy set.
3.2.3.10 Robustness despite errors and failures
From time to time in the history of the Internet there have been
occurrences where mis-configured routers have destroyed global
connectivity. This should never be possible.
A goal of the FDR is to be robust to configuration errors and
failures. This should probably involve ensuring that the effects of
misconfiguration and failure can be confined to some suitable
locality of the failure or misconfiguration.
3.2.3.11 Simplicity in management
The policy work ([rap-charter02], [snmpconf-charter02] and [policy-
charter02] ) that has been done at IETF provides an architecture that
standardizes and simplifies management of QoS. This kind of
simplicity is needed in a future Domain Routing architecture and its
protocols.
A goal of this architecture is to make configuration and management
of inter-domain routing as simple as possible.
3.2.3.12 The legacy of RFC1126
RFC1126 outlined a set of requirements that were used to guide the
development of BGP. While the network is definitely different then
it was in 1989, many of the same requirements remain. A future
domain routing solution has to support, as its base requirement, the
level of function that is available today. A detailed discussion of
RFC1126 and its requirements can be found in [I-D.irtf-routing-reqs].
Those requirements, while specifically spelled out in that document,
are subsumed by the requirements in this document.
3.3 High Level User Requirements
This section considers the requirements imposed by the target
audience of the FDR both in terms of both organizations that might
own networks that would use FDR, and the human users who will have to
interact with the FDR.
3.3.1 Organisational Users
The organizations that own networks connected to the Internet have
become much more diverse since RFC1126 [RFC1126] was published. In
particular a major part of the network are now owned by commercial
service provider organizations in the business of making profits from
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carrying data traffic.
3.3.1.1 Commercial service providers
The routing system must take into account the commercial service
provider's need for secrecy and security, as well as allowing them to
organize their business as flexibly as possible.
Service providers will often wish to conceal the details of the
network from other connected networks. So far as is possible, the
routing system should not require the service providers to expose
more details of the topology and capability of their networks than is
strictly necessary.
Many service providers will offer contracts to their customers in the
form of Service Level Agreements (SLAs). The routing system must
allow the providers to support these SLAs through traffic engineering
and load balancing as well as multihoming, providing the degree of
resilience and robustness that is needed.
Service providers can be categorized as:
- Global Service Providers (GSPs) whose networks have a global
reach. GSPs may, and usually will, wish to constrain traffic
between their customers to run entirely on their networks. GSPs
will interchange traffic at multiple peering points with other
GSPs, and they will need extensive policy-based controls to
control the interchange of traffic. Peering may be through the
use of dedicated private lines between the partners or,
increasingly, through Internet Exchange Points.
- National, or regional, Service Providers (NSPs) that are similar
to GSPs but typically cover one country. NSPs may operate as a
federation that provides similar reach to a GSP and may wish to be
able to steer traffic preferentially to other federation members
to achieve global reach.
- Local Internet Service Providers (ISPs) operate regionally. They
will typically purchase transit capacity from NSPs or GSPs to
provide global connectivity, but they may also peer with
neighbouring, and sometimes distant, ISPs.
The routing system should be sufficiently flexible to accommodate the
continually changing business relationships of the providers and the
various levels of trustworthiness that they apply to customers and
partners.
Service providers will need to be involved in accounting for Internet
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usage and monitoring the traffic. They may be involved in government
action to tax the usage of the Internet, enforce social mores and
intellectual property rules, or apply surveillance to the traffic to
detect or prevent crime.
3.3.1.2 Enterprises
The leaves of the network domain graph are in many cases networks
supporting a single enterprise. Such networks cover an enormous
range of complexity. Some multi-national companies own networks that
rival the complexity and reach of a GSP, whereas many fall into the
Small Office-Home Office (SOHO) category. The routing system should
allow simple and robust configuration and operation for the SOHO
category, while effectively supporting the larger enterprise.
Enterprises are particularly likely to lack the capability to
configure and manage a complex routing system, and every effort
should be made to provide simple configuration and operation for such
networks.
Enterprises will also need to be able to change their service
provider with ease. While this is predominantly a naming and
addressing issue, the routing system must be able to support seamless
changeover, for example, by coping with a changeover period when both
sets of addresses are in use.
Enterprises will wish to be able to multihome to one or more
providers as one possible means of enhancing the resilience of their
network.
Enterprises will also frequently need to control the trust that they
place both in workers and external connections through firewalls and
similar mid-boxes placed at their external connections.
3.3.1.3 Domestic networks
Increasingly domestic, i.e. non-business home, networks are likely to
be 'always on' and will resemble SOHO enterprises networks with no
special requirements on the routing system.
The routing system must also continue to support dial-up users.
3.3.1.4 Internet Exchange Points
Peering of service providers, academic networks, and larger
enterprises is increasingly happening at specific Internet Exchange
Points where many networks are linked together in a relatively small
physical area. The resources of the exchange may be owned by a
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trusted third party or owned jointly by the connecting networks. The
routing systems should support such exchange points without requiring
the exchange point to either operate as a superior entity with every
connected network logically inferior to it or by requiring the
exchange point to be a member of one (or all) connected networks.
The connecting networks have to delegate a certain amount of trust to
the exchange point operator.
3.3.1.5 Content Providers
Content providers are at one level a special class of enterprise, but
the desire to deliver content efficiently means that a content
provider may provide multiple replicated origin servers or caches
across a network. These may also be provided by a separate content
delivery service. The routing system should facilitate delivering
content from the most efficient location.
3.3.2 Individual Users
This section covers the most important human users of the FDR and
their expected interactions with the system.
3.3.2.1 All end users
The routing system must continue to deliver the current global
connectivity service (i.e. any unique address to any other unique
address, subject to policy constraints) that has always been the
basic aim of the Internet.
End user applications should be able to request, or have requested on
their behalf by agents and policy mechanisms, end-to-end
communication services with QoS characteristics different from the
best-effort service that is the foundation of today's Internet. It
should be possible to request both a single service channel and a
bundle of service channels delivered as a single entity.
3.3.2.2 Network planners
The routing system should allow network planners to plan and
implement a network that can be proved to be stable and will meet
their traffic engineering requirements.
3.3.2.3 Network operators
The routing system should, so far as is possible, be simple to
configure, operate and troubleshoot, behave in a predictable and
stable fashion, and deliver appropriate statistics and events to
allow the network to be managed and upgraded in an efficient and
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timely fashion.
3.3.2.4 Mobile end users
The routing system must support mobile end users. It is clear that
mobility is becoming a predominant mode for network access.
3.4 Mandated Constraints
While many of the requirements to which the protocol must respond are
technical, some aren't. These mandated constraints are those that
are determined by conditions of the world around us. Understanding
these requirements requires an analysis of the world in which these
systems will be deployed. The constraints include those that are
determined by:
- environmental factors,
- geography,
- political boundaries and considerations, and
- technological factors such as the prevalence of different levels
of technology in the developed world compared to those in the
developing or undeveloped world.
3.4.1 The Federated Environment
The graph of the Internet network, with routers and other control
boxes as the nodes and communication links as the edges is today
partitioned administratively into a large number of disjoint domains.
A common administration may have responsibility for one or more
domains that may or may not be adjacent in the graph.
Commercial and policy constraints affecting the routing system will
typically be exercised at the boundaries of these domains where
traffic is exchanged between the domains.
The perceived need for commercial confidentiality will seek to
minimise the control information transferred across these boundaries,
leading to requirements for aggregated information, abstracted maps
of connectivity exported from domains, and mistrust of supplied
information.
The perceived desire for anonymity may require the use of zero-
knowledge security protocols to allow users to access resources
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without exposing their identity.
The requirements should provide the ability for groups of peering
domains to be treated as a complex domain. These complex domains
could have a common administrative policy.
3.4.2 Working with Different Sorts of Networks
The diverse Layer 2 networks over which the layer 3 routing system is
implemented have typically been operated totally independently from
the layer 3 network and often with their own routing mechanisms.
Consideration needs to be given to the desirable degree and nature of
interchange of information between the layers. In particular, the
need for guaranteed robustness through diverse routing layers implies
knowledge of the underlying networks.
Mobile access networks may also impose extra requirements on Layer 3
routing.
3.4.3 Delivering Diversity
The routing system operates at Layer 3 in the network. To achieve
robustness and resilience at this layer requires that, where multiple
diverse routes are employed as part of delivering the resilience, the
routing system at Layer 3 needs to be assured that the Layer 2 and
lower routes are really diverse. The 'diamond problem' is the
simplest form of this problem - a layer 3 provider attempting to
provide diversity buys layer 2 services from two separate providers
who in turn buy layer 1 services from the same provider:
Layer 3 service
/ \
/ \
Layer 2 Layer 2
Provider A Provider B
\ /
\ /
Layer 1 Provider
Now when the backhoe cuts the trench, the Layer 3 provider has no
resilience unless he had taken special steps to verify that the
trench wasn't common. The routing system should facilitate avoidance
of this kind of trap.
Some work is going on to understand the sort of problems that stem
from this requirement, such as the work on Shared Risk Link Groups
[I-D.many-inference-srlg]. Unfortunately, the full generality of the
problem requires diversity be maintained over time between an
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arbitrarily large set of mutually distrustful providers. For some
cases, it may be sufficient for diversity to be checked at
provisioning or route instantiation time, but this remains a hard
problem requiring research work.
3.4.4 When will the New Solution be Required?
There is a full range of opinion on this subject. An informal survey
indicates that the range varies from 2 years to 6 years. And while
there are those, possibly outliers, who think there is no need for a
new routing architecture as well as those who think a new
architecture was needed years ago, the median seems to lie at around
4 years. As in all projections of the future, this is not provable
at this time.
Editors note: The paragraph above was written in 2002, yet could
be written without change in 2005. As with many technical
predictions and schedules, the horizon has remained fixed through
this interval.
3.5 Assumptions
In projecting the requirements for the Future Domain Routing a number
of assumptions have been made. The requirements set out should be
consistent with these assumptions, but there are doubtless a number
of other assumptions that are not explicitly articulated here:
1. The number of hosts today is somewhere in the area of 100
million. With dial-in and NATs, this is likely to become up to
500 million users (see [Netsizer02]). In a number of years,
with wireless accesses and different appliances attaching to the
Internet, we are likely to see a couple of billion (10^9)
'users' on the Internet. The number of globally addressable
hosts is very much dependent on how common NATs will be in the
future.
2. NATs, firewalls, and other middle-boxes exist, and we cannot
assume that they will cease being a presence in the networks.
3. The number of operators in the Internet will probably not grow
very much, as there is a likelihood that operators will tend to
merge. However, as Internet-connectivity expands to new
countries, new operators will emerge and then merge again.
4. At the beginning of 2002, there are around 12000 registered
AS's. With current use of AS's (for e.g., multi-homing) the
number of AS's could be expected to grow to 25000 in about 10
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years.[refs.43] This is down from a previously reported growth
rate of 51% per year.[RFC3221]. Future growth rates are
difficult to predict.
Editor's Note: In the routing report table of 17 September
2005, the total number AS's present in the Internet Routing
Table was 20513. In 3 years this is substantial progress on
the prediction of 25000 AS's. Also, there are signigicantly
more AS's registered then are active at the moment - in
excess of 35000 in 2005.
5. In contrast to the number of operators, the number of domains is
likely to grow significantly. Today, each operator has
different domains within an AS, but this also shows in SLAs and
policies internal to the operator. Making this globally visible
would create a number of domains 10-100 times the number of
AS's, i.e., between 100,000 and 1,000,000.
6. With more and more capacity at the edge of the network the IP
network will expand. Today there are operators with several
thousands of routers, but this is likely to be increased. Some
domain will probably contain tens of thousands of routers.
7. The speed of connections in the (fixed) access will technically
be (almost) unconstrained. However, the cost for the links will
not be negligible so that the apparent speed will be effectively
bounded. Within a number of years some will have multi-gigabit
speed in the access.
8. At the same time, the bandwidth of wireless access still has a
strict upper-bound. Within the foreseeable future each user
will have only a tiny amount of resources available compared to
fixed accesses (10kbps to 2Mbps for UMTS with only a few
achieving the higher figure as the bandwidth is shared between
the active users in a cell and only small cells can actually
reach this speed, but 11Mbps or more for wireless LAN
connections). There may also be requirements for effective use
of bandwidth as low as 2.4 Kbps or lower, in some applications.
9. Assumptions 7 and 8 taken together suggest a minimum span of
bandwidth between 2.4 kbps to 10 Gbps.
10. The speed in the backbone has grown rapidly, and there is no
evidence that the growth will stop in the coming years.
Terabit- speed is likely to be the minimum backbone speed in a
couple of years. The range of bandwidths that need to be
represented will require consideration on how to represent the
values in the protocols.
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11. There have been discussions as to whether Moore's law will
continue to hold for processor speed. If Moore's law does not
hold, then communication circuits might play a more important
role in the future. Also, optical routing is based on circuit
technology, which is the main reason for taking 'circuits' into
account when designing an FDR.
12. However, the datagram model still remains the fundamental model
for the Internet.
13. The number of peering points in the network is likely to grow,
as multi-homing becomes important. Also traffic will become
more locally distributed, which will drive the demand for local
peering.
14. The FDR will achieve the same degree of ubiquity as the current
Internet and IP routing.
3.6 Functional Requirements
This section includes a detailed discussion of new requirements for a
Future Domain Routing architecture. The nth requirement carries the
label "R(n)". As discussed in section 3.2.3.12 a new architecture
must build upon the requirements of the past routing framework and
must, and must not reduce the functionality of the network. A
discussion and analysis of the RFC1126 requirements can be found in
[I-D.irtf-routing-reqs].
3.6.1 Topology
3.6.1.1 Routers should be able to learn and exploit the domain
topology.
R(1) Routers must be able to acquire and hold sufficient information
on the underlying topology of the domain to allow the
establishment of routes on that topology.
R(2) Routers must have the ability to control the establishment of
routes on the underlying topology.
R(3) Routers must be able, where appropriate, to control Sub-IP
mechanisms to support the establishment of routes.
The OSI Inter-Domain Routing Protocol (IDRP)[ISO10747] allowed a
collection of topologically related domains to be replaced by an
aggregate domain object, in a similar way to the Nimrod[Chiappa02]
domain hierarchies. This allowed a route to be more compactly
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represented by a single collection instead of a sequence of
individual domains.
R(4) Routers must, where appropriate, be able to construct
abstractions of the topology that represent an aggregation of
the topological features of some area of the topology.
3.6.1.2 The same topology information should support different path
selection ideas.
The same topology information needs to provide the more flexible
spectrum of path selection methods that we might expect to find in a
future Internet, including, distributed techniques such as hop-by-
hop, shortest path, local optimization constraint-based, class of
service, source address routing, and destination address routing, as
well as the centralized, global optimization constraint-based
'traffic engineering' type (Open constraints should be allowed).
Allowing different path selection techniques will produce a much more
predictable and comprehensible result than the 'clever tricks' that
are currently needed to achieve the same results. Traffic
engineering functions need to be combined.
R(5) Routers must be capable of supporting a small number of
different path selection algorithms
3.6.1.3 Separation of the routing information topology from the data
transport topology.
R(6) The controlling network may be logically separate from the
controlled network.
The two functional 'planes' may physically reside in the same nodes
and share the same links, but this is not the only possibility, and
other options may sometimes be necessary. An example is a pure
circuit switch (that cannot see individual IP packets) combined with
an external controller. Another example may be multiple links
between two routers, where all the links are used for data forwarding
but only one is used for carrying the routing session.
3.6.2 Distribution
3.6.2.1 Distribution mechanisms
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R(7) Relevant changes in the state of the network, including
modifications to the topology and changes in the values of
dynamic capabilities, must be distributed to every entity in
the network that needs them, in a reliable and trusted way, at
the earliest appropriate time after the changes have occurred.
R(8) Information must not be distributed outside areas where it is
needed, or believed to be needed, for the operation of the
routing system.
R(9) Information must be distributed in such a way that it minimizes
the load on the network, consistent with the required response
time of the network to changes.
3.6.2.2 Path advertisement
R(10) The router must be able to acquire and store additional static
and dynamic information that relates to the capabilities of the
topology and its component nodes and links and that can
subsequently be used by path selection methods.
The inter-domain routing system must be able to advertise more kinds
of information than just connectivity and domain paths.
R(11) The Routing System must support service specifications, e.g.
the Service Level Specifications (SLSs) developed by the
Differentiated Services working group. [refs.42]
Careful attention should be paid to ensuring that the distribution of
additional information with path advertisements remains scalable as
domains and the Internet get larger, more numerous, and more
diversified.
R(12) The distribution mechanism used for distributing network state
information must be scalable with respect to the expected size
of domains and the volume and rate of change of dynamic state
that can be expected.
The combination of R(9) and R(12) may result in a compromise between
the responsiveness of the network to change and the overhead of
distributing change notifications. Attempts to respond to very rapid
changes may damage the stability of the routing system.
Possible examples of additional capability information that might be
carried include:
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- QoS information
To allow an ISP to sell predictable end-to-end QoS service to any
destination, the routing system should have information about the
end-to-end QoS. This means that:
R(13) The routing system must be able to support different paths for
different services.
R(14) The routing system must be able to forward traffic on the path
appropriate for the service selected for the traffic, either
according to an explicit marking in each packet (e.g. MPLS
labels, DiffServ PHB's or DSCP values) or implicitly (e.g. the
physical or logical port on which the traffic arrives).
R(15) The routing system should also be able to carry information
about the expected (or actually, promised) characteristics of
the entire path and the price for the service.
(If such information is exchanged at all between network
operators today, it is through bilateral management interfaces,
and not through the routing protocols.)
This would allow for the operator to optimise the choice of path
based on a price/performance trade-off.
In addition to providing dynamic QoS information the system should
be able to use static class-of-service information.
- Security information
Security characteristics of other domains referred to by
advertisements can allow the routing entity to make routing
decisions based on political concerns. The information itself is
assumed to be so secure that it can be trusted.
- Usage and cost information
Usage and cost information can be used for billing and traffic
engineering. In order to support cost-based routing policies for
customers (i.e. peer ISPs), information such as "traffic on this
link or path costs XXX per Gigabyte" needs to be advertised, so
that the customer can choose a more or a less expensive route.
- Monitored performance
Performance information such as delay and drop frequency can be
carried. (This may only be suitable inside a domain because of
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trust considerations). This should support at least the kind of
delay bound contractual terms that are currently being offered by
service providers. Note that these values refer to the outcome of
carrying bits on the path, whereas the QoS information refers to
the proposed behaviour that results in this outcome.
- Multicast information
R(16) The routing system must provide information needed to create
multicast distribution trees. This information must be
provided for one-to-many distribution trees and should be
provided for many-to-many distribution trees.
The actual construction of distribution trees is not necessarily
done by the routing system.
3.6.2.3 Stability of routing information
R(17) The new network architecture must be stable without needing
global convergence, i.e. convergence is a local property.
The degree to which this is possible and the definition of "local"
remain research topics. Restricting the requirement for convergence
to localities will have an effect on all of the other requirements in
this section.
R(18) The distribution and the rate of distribution of changes must
not affect the stability of the routing information. For
example, commencing redistribution of a change before the
previous one has settled must not cause instability.
3.6.2.3.1 Avoiding routing oscillations
R(19) The routing system must minimize oscillations in route
advertisements.
3.6.2.3.2 Providing loop-free routing and forwarding
In line with the separation of routing and forwarding concerns:
R(20) The distribution of routing information must be, so far as is
possible, loop-free.
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R(21) The forwarding information created from this routing
information must seek to minimize persistent loops in the data
forwarding paths.
It is accepted that transient loops may occur during convergence of
the protocol and that there are trade-offs between loop avoidance and
global scalability.
3.6.2.3.3 Detection, notification and repair of failures
R(22) The routing system must provide means for detecting failures of
node equipment or communication links.
R(23) The routing system should be able to coordinate failure
indications from layer 3 mechanisms, from nodal mechanisms
built into the routing system, and from lower-layer mechanisms
that propagate up to Layer 3 in order to determine the root
cause of the failure. This will allow the routing system to
react correctly to the failure by activating appropriate
mitigation and repair mechanisms if required, whilst ensuring
that it does not react if lower layer repair mechanisms are
able to repair or mitigate the fault.
Most layer 3 routing protocols have utilized keepalives or 'hello'
protocols as a means of detecting failures at Layer 3. The keepalive
mechanisms are often complemented by analog mechanisms (e.g. laser
light detection) and hardware mechanisms (e.g. hardware/software
watchdogs) that are built into routing nodes and communication links.
Great care must be taken to make best possible use of the various
failure repair methods available whilst ensuring that only one repair
mechanism at a time is allowed to repair any given fault.
Interactions between, for example, fast reroute mechanisms at layer 3
and SONET/SDH repair at Layer 1 are highly undesirable and are likely
to cause problems in the network.
R(24) Where a network topology and routing system contains multiple
fault repair mechanisms, the responses of these systems to a
detected failure should be coordinated so that the fault is
repaired by the most appropriate means, and no extra repairs
are initiated.
R(25) Where specialized packet exchange mechanisms (e.g. layer 3
keepalive or 'hello' protocol mechanisms) are used to detect
failures, the routing system must allow the configuration of
the rate of transmission of these keepalives. This must
include the capability to turn them off altogether for links
that are deliberately broken when no real user or control
traffic is present (e.g. ISDN links).
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This will allow the operator to compromise between the speed of
failure detection and the proportion of link bandwidth dedicated to
failure detection.
3.6.3 Addressing
3.6.3.1 Support mix of IPv4, IPv6 and other types of addresses
R(26) The routing system must support a mix of different kinds of
addresses.
This mix will include at least IPv4 and IPv6 addresses, and
preferably various types of non-IP addresses too. For instance
networks like SDH/SONET and WDM may prefer to use non-IP addresses.
It may also be necessary to support multiple sets of 'private' (e.g.
RFC1918) addresses when dealing with multiple customer VPNs.
R(27) The routing system should support the use of a single topology
representation to generate routing and forwarding tables for
multiple address families on the same network.
This capability would minimise the protocol overhead when exchanging
routes.
3.6.3.2 Support for domain renumbering/readdressing
R(28) If a domain is subject to address reassignment that would cause
forwarding interruption, then the routing system should support
readdressing (e.g. when a new prefix is given to an old
network, and the change is known in advance) by maintaining
routing during the changeover period [RFC2071],[RFC2072].
3.6.3.3 Multicast and anycast
R(29) The routing system must support multicast addressing, both
within a domain and across multiple domains.
R(30) The routing system should support anycast addressing within a
domain. The routing system may support anycast addressing
across domains.
An open question is whether it is possible or useful to support
anycast addressing between cooperating domains.
3.6.3.4 Address scoping
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R(31) The routing system must support scoping of unicast addresses,
and it should support scoping of multicast and anycast address
types.
The unicast address scoping that is being designed for IPv6 does not
seem to cause any special problems for routing. IPv6 inter-domain
routing handles only IPv6 global addresses, while intra- domain
routing also needs to be aware of the scope of private addresses
Editor's note: the original reference was to site-local addresses
but these have been deprecated by the IETF). Link-local addresses
are never routed at all.
More study may be needed to identify the requirements and solutions
for scoping in a more general sense and for scoping of multicast and
anycast addresses.
3.6.3.5 Mobility support
R(32) The routing system must support system mobility The term
"system" includes anything from an end system to an entire
domain.
We observe that the existing solutions based on re-numbering and/or
tunneling are designed to work with the current routing, so they do
not add any new requirements to future routing. But the requirement
is general, and future solutions may not be restricted to the ones we
have today.
3.6.4 Statistics Support
R(33) Both the routing and forwarding parts of the routing system
must maintain statistical information about the performance of
their functions.
3.6.5 Management Requirements
While the tools of management are outside the scope of routing, the
mechanisms to support the routing architecture and protocols are
within scope.
R(34) Mechanisms to support Operational, Administrative and
Management control of the routing architecture and protocols
must be designed into the original fabric of the architecture.
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3.6.5.1 Simple policy management
The basic aims of this specification are:
- to require less manual configuration than today and
- to satisfy the requirements for both easy handling and maximum
control. That is:
- All the information should be available,
- but should not be visible except for when necessary.
- Policies themselves should be advertised and not only the
result of policy, and
- policy conflict resolution must be provided.
R(35) The routing system must provide management of the system by
means of policies. For example, policies that can be expressed
in terms of the business and services implemented on the
network and reflect the operation of the network in terms of
the services affected.
R(36) The distribution of policies must be amenable to scoping to
protect proprietary policies that are not relevant beyond the
local set of domains.
3.6.5.2 Startup and Maintenance of Routers
A major problem in today's networks is the need to perform initial
configuration on routers from a local interface before a remote
management system can take over. It is not clear that this imposes
any requirements on the routing architecture beyond what is need for
a ZeroConf host.
Similarly, maintenance and upgrade of routers can cause major
disruptions to the network routing because the routing system and
management of routers is not organized to minimize such disruption.
Some improvements have been made, such as graceful restart mechanisms
in protocols, but more needs to be done.
R(37) The routing system and routers should provide mechanisms that
minimize the disruption to the network caused by maintenance
and upgrades of software and hardware. This requirements
recognizes that some of the capabilities needed are outside the
scope of the routing architecture (e.g. minimum impact software
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upgrade).
3.6.6 Provability
R(38) The routing system and its component protocols must be
demonstrated to be locally convergent under the permitted range
of parameter settings and policy options that the operator(s)
can select.
There are various methods for demonstration and proof that include,
but are not limited to: mathematical proof, heuristic, and pattern
recognition. No requirement is made on the method used for
demonstrating local convergence properties.
R(39) Routing protocols employed by the routing system and the
overall routing system should be resistant to bad routing
policy decisions made by operators.
Tools are needed to check compatibility of routing policies. While
these tools are not part of the routing architecture, the mechanisms
to support such tools are.
Routing policies are compatible if their interaction does not cause
instability. A domain or group of domains in a system is defined as
being convergent, either locally or globally, if and only if, after
an exchange of routing information, routing tables reach a stable
state that does not change until the routing policies or the topology
changes again.
To achieve the above-mentioned goals:
R(40) The routing system must provide a mechanism to publish and
communicate policies so that operational coordination and fault
isolation are possible.
Tools are required that verify the stability characteristics of the
routing system in specified parts of Internet. The tools should be
efficient (fast) and have a broad scope of operation (check large
portions of Internet). While these tools are not part of the
architecture, developing them is in the interest of the architecture
and should be defined as a Routing Research Group activity while
research on the architecture is in progress.
Tools analyzing routing policies can be applied statically or
(preferably) dynamically. Dynamic solution requires tools that can
be used for run time checking for oscillations that arise from
policy conflicts. Research is needed to find an efficient solution
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to the dynamic checking of oscillations.
3.6.7 Traffic engineering
The ability to do traffic engineering and to get the feedback from
the network to enable traffic engineering should be included in the
future domain architecture. Traffic engineering is, at base, another
alternative or extension for the path selection mechanisms of the
routing system. No fundamental changes to the requirements are
needed, but the iterative processes involved in traffic engineering
may require some additional capabilities and state in the network.
Traffic engineering typically involves a combination of off-line
network planning and administrative control functions in which the
expected and measured traffic flows are examined, resulting in
changes to static configurations and policies in the routing system.
During operations, these configurations control the actual flow of
traffic and affect the dynamic path selection mechanisms; the
results are measured and fed back into further rounds of network
planning.
3.6.7.1 Support for, and provision of, traffic engineering tools
At present there is an almost total lack of effective traffic
engineering tools, whether in real time for network control or off-
line for network planning. The routing system should encourage the
provision of such tools.
R(41) The routing system must generate statistical and accounting
information in such a way that traffic engineering and network
planning tools can be used in both real time and off-line
planning and management.
3.6.7.2 Support of multiple parallel paths
R(42) The routing system must support the controlled distribution
over multiple links or paths of traffic toward the same
destination. This applies to domains with two or more
connections to the same neighbor domain, and to domains with
connections to more than one neighbor domain. The paths need
not have the same metric.
R(43) The routing system must support forwarding over multiple
parallel paths when available. This support should extend to
cases where the offered traffic is known to exceed the
available capacity of a single link, and to the cases where
load is to be shared over paths for cost or resiliency reasons.
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R(44) Where traffic is forwarded over multiple parallel paths, the
routing system must, so far as is possible, avoid reordering of
packets in individual micro-flows.
R(45) The routing system must have mechanisms to allow the traffic to
be reallocated back onto a single path when multiple paths are
not needed.
R(46) The routing system must support peer-level connectivity as well
as hierarchical connections between domains.
The network is becoming increasingly complex, with private peering
arrangements set up between providers at every level of the hierarchy
of service providers and even by certain large enterprises, in the
form of dedicated extranets.
R(47) The routing system must facilitate traffic engineering of peer
routes so that traffic can be readily constrained to travel as
the network operators desire, allowing optimal use of the
available connectivity.
3.6.8 Support for Middleboxes
One of our assumptions is that NATs and other middle-boxes such as
firewalls, web proxies and address family translators (e.g. IPv4 to
IPv6) are here to stay.
R(48) The routing system should work in conjunction with middle-
boxes, e.g. NAT, to aid in bi-directional connectivity without
compromising the additional opacity and privacy that the
middle-boxes offer.
This problem is closely analogous to the abstraction problem, which
is already under discussion for the interchange of routing
information between domains.
3.7 Performance Requirements
Over the past several years, the performance of the routing system
has frequently been discussed. The requirements that derive from
those discussions are listed below. The specific values for these
performance requirements are left for further discussion.
R(49) The routing system must support domains of at least N systems.
A system is taken to mean either an individual router or a
domain.
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R(50) Local convergence should occur within T units of time.
R(51) The routing system must be 99.9999% available.
R(52) The routing system must be measurably reliable. The measure of
reliability remains a research question.
R(53) The routing system must be locally stable to a measured degree.
The degree of measurabilty remains a research issue.
R(54) The routing system must be globally stable to a measured
degree. The degree of measurabilty remains a research issue.
R(55) The routing system should scale to an indefinitely large number
of domains.
There has been very little data or statistical evidence for many of
the performance claims made in the past. In recent years, several
efforts have been initiated to gather data and do the analyses
required to make scientific assessments of performance issues and
requirements. In order to complete this section of the requirements
analysis, the data and analyses from these studies needs to be
gathered and collated into this document. This work has been started
but has yet to be completed.
3.8 Backwards Compatibility (Cutover) and Maintainability
This area poses a dilemma. On one hand it is an absolute requirement
that:
R(56) The introduction of the routing system must not require any
flag days.
R(57) The network currently in place must continue to run at least as
well as it does now while the new network is being installed
around it.
However, at the same time, it is also an requirement that:
R(58) The new architecture must not be limited by the restrictions
that plague today's network.
It has to be admitted that R(58) is not a well defined requirement,
because we have not fully articulated what the restrictions might be.
Some of these restrictions can be derived by reading the discussions
for the positive requirements above. It would be a useful exercise
to explicitly list all the restrictions and irritations that we wish
to do away with. It would be further useful to determine if these
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restrictions can currently be removed at reasonable cost or whether
we are actually condemned to live with them.
Those restrictions cannot be allowed to become permanent baggage on
the new architecture. If they do, the effort to create a new system
will come to naught. It may, however, be necessary to live with some
of them temporarily for practical reasons while providing an
architecture which will eventually allow them to be removed. The
last three requirements have significance not only for the transition
strategy, but also for the architecture itself. They imply that it
must be possible for an internet such as today's BGP-controlled
network, or one of its AS's, to exist as a domain within the new FDR.
3.9 Security Requirements
As previously discussed, one of the major changes that has overtaken
the Internet since its inception is the erosion of trust between end
users making use of the net, between those users and the suppliers of
services, and between the multiplicity of providers. Hence security,
in all its aspects, will be much more important in the FDR.
It must be possible to secure the routing communication.
R(59) The communicating entities must be able to identify who sent
and who received the information (authentication).
R(60) The communicating entities must be able to verify that the
information has not been changed on the way (integrity).
Security is more important in inter-domain routing where the operator
has no control over the other domains, then in intra-domain routing
where all the links and the nodes are under the administration of the
operator and can be expected to share a trust relationship. This
property of intra-domain trust, however, should not be taken for
granted:
R(61) Routing communications must be secured by default, but an
operator must have the option to relax this requirement within
a domain where analysis indicates that other means (such as
physical security) provide an acceptable alternative.
R(62) The routing communication mechanism must be robust against
denial-of-service attacks.
Further considerations that may impose further requirements include:
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- whether no one else but the intended recipient is able to access
(privacy) or understand (confidentiality) the information,
- whether it is possible to verify that all the information has been
received (non-repudiation),
- whether there is a need to separate security of routing from
security of forwarding, and
- whether traffic flow security is needed (i.e. whether there is
value in concealing who can connect to whom, and what volumes of
data are exchanged).
Securing the BGP session, as done today, only secures the exchange of
messages from the peering domain, not the content of the information.
In other words, we can confirm that the information we got is what
our neighbor really sent us, but we do not know whether this
information (that originated in some remote domain) is true or not.
A decision has to be made on whether to rely on chains of trust (we
trust our peers who trust their peers who..), or whether we also need
authentication and integrity of the information end-to-end. This
information includes both routes and addresses. There has been
interest in having digital signatures on originated routes as well as
countersignatures by address authorities to confirm that the
originator has authority to advertise the prefix. Even understanding
who can confirm the authority is non-trivial, as it might be the
provider who delegated the prefix (with a whole chain of authority
back to ICANN) or it may be an address registry. Where a prefix
delegated by a provider is being advertised through another provider
as in multi-homing, both may have to be involved to confirm that the
prefix may be advertised through the provider who doesn't have any
interest in the prefix!
R(63) The routing system must cooperate with the security policies of
middle-boxes whenever possible.
This is likely to involve further requirements for abstraction of
information. For example, a firewall that is seeking to minimize
interchange of information that could lead to a security breach. The
effect of such changes on the end-to-end principle should be
carefully considered as discussed in [Blumenthal01].
R(64) The routing system must be capable of complying with local
legal requirement for interception of communication.
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3.10 Debatable Issues
This section covers issues that need to be considered and resolved in
deciding on a Future Domain Routing architecture. While they can't
be described as requirements, they do affect the types of solution
that are acceptable. The discussions included below are very open-
ended.
3.10.1 Network Modeling
The mathematical model that underlies today's routing system uses a
graph representation of the network. Hosts, routers and other
processing boxes are represented by nodes and communications links by
arcs. This is a topological model in that routing does not need to
directly model the physical length of the links or the position of
the nodes; the model can be transformed to provide a convenient
picture of the network by adjusting the lengths of the arcs and the
layout of the nodes. The connectivity is preserved and routing is
unaffected by this transformation.
The routing algorithms in traditional routing protocols utilize a
small number of results from graph theory. It is only recently that
additional results have been employed to support constraint-based
routing for traffic engineering.
The naturalness of this network model and the 'fit' of the graph
theoretical methods may have tended to blind us to alternative
representations and inhibited us from seeking alternative strands of
theoretical thinking that might provide improved results.
We should not allow this habitual behavior to stop us looking for
alternative representations and algorithms; topological revolutions
are possible and allowed, at least in theory.
3.10.2 System Modeling
The assumption that object modeling of a system is an essential first
step to creating a new system is still novel in this context.
Frequently the object modeling effort becomes an end in itself and
does not lead to system creation. But there is a balance, and a lot
that can be discovered in an ongoing effort to model a system such as
the future Domain Douting system. It is recommended that this
process be included in the requirements. It should not, however, be
a gating event to all other work.
Some of the most important realizations will occur during the process
of determining the following:
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- Object classification
- Relationships and containment
- Roles and Rules
3.10.3 One, Two or many Protocols
There has been a lot of discussion of whether the FDR protocol
solution should consist of one (probably new) protocol, two (intra-
and inter-domain) protocols, or many protocols. While it might be
best to have one protocol that handles all situations, this seems
improbable. On the other hand, maintaining the 'strict' division
evident in the network today between the IGP and EGP has been
effectively argued elsewhere as being too restrictive an approach.
Given this, and the fact that there are already many routing
protocols in use, the only possible answer seems to be that the
architecture should support many protocols. It remains an open
issue, one for the solution, to determine if a new protocol needs to
be designed in order to support the highest goals of this
architecture. The expectation is that a new protocol will be needed.
3.10.4 Class of Protocol
If a new protocol is required to support the FDR architecture, the
question remains open as to what kind of protocol this ought to be.
It is our expectation that a map distribution protocol will be
required to augment the current path-vector protocol and shortest
path first protocols.
3.10.5 Map Abstraction
Assuming that a map distribution protocol, as defined in [RFC1992]
is required, what are the requirements on this protocol? If every
detail is advertised throughout the Internet, there will be a lot of
information. Scalable solutions require abstraction.
- If we summarise too much, some information will be lost on the
way.
- If we summarise too little, then more information than required is
available, contributing to scaling limitations.
- One can allow more summarisation, if there also is a mechanism to
query for more details within policy limits.
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- The basic requirement is not that the information shall be
advertised, but rather that the information shall be available to
those who need it. We should not presuppose a solution where
advertising is the only possible mechanism.
3.10.6 Clear Identification for all Entities
As in all other fields, the words used to refer to concepts and to
describe operations about routing are important. Rather than
describe concepts using terms that are inaccurate or rarely used in
the real world of networking, it is necessary to make an effort to
use the correct words. Many networking terms are used casually, and
the result is a partial or incorrect understanding of the underlying
concept. Entities such as nodes, interfaces, sub-networks, tunnels,
and the grouping concepts such as AS's, domains, areas, and regions,
need to be clearly identified and defined to avoid confusion.
There is also a need to separate identifiers (what or who) from
locators (where) from routes (how to reach).
Editors Note: Work is ongoing in the shim6 working group of the
IETF on this sort of separation. This works needs to be taken
into account on any new routing architecture.
3.10.7 Robustness and redundancy:
The routing association between two domains should survive even if
some individual connection between two routers goes down.
The "session" should operate between logical "routing entities" on
each domain side, and not necessarily be bound to individual routers
or addresses. Such a logical entity can be physically distributed
over multiple network elements. Or it can reside in a single router,
which would default to the current situation.
3.10.8 Hierarchy
A more flexible hierarchy with more levels and recursive groupings in
both upward and downward directions allows more structured routing.
The consequence is that no single level will get too big for routers
to handle.
On the other hand, it appears that the real world Internet is
becoming less hierarchical, so that it will be increasingly difficult
to use hierarchy to control scaling.
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Note that groupings can look different depending on which aspect we
use to define them. A DiffServ area, an MPLS domain, a trusted
domain, a QoS area, a multicast domain, etc, do not always coincide.
But neither are they strict hierarchical subsets of each other. The
basic distinction at each level is "this grouping versus everything
outside".
3.10.9 Control Theory
Is it possible to apply a control theory framework to analyze the
stability of the control system of the whole network domain, for e.g.
convergence speed and the frequency response, and then use the
results from that analysis to set the timers and other protocol
parameters?
Control theory could also play a part is QoS Routing, by modifying
current link state protocols with link costs dependent on load and
feedback. Control theory is often used to increase the stability of
dynamic systems.
It might be possible to construct a new, totally dynamic routing
protocol solely on a control theoretic basis, as opposed to the
current protocols that are based in graph theory and static in
nature.
3.10.10 Byzantium
Is solving the Byzantine Generals problem a requirement? This is the
problem of reaching a consensus among distributed units if some of
them give misleading answers. The current intra-domain routing
system is, at one level, totally intolerant of misleading
information. However, the effect of different sorts of misleading or
incorrect information has vastly varying results, from total collapse
to purely local disconnection of a single domain. This sort of
behavior is not very desirable.
There are, possibly, other network robustness issues that must be
researched and resolved.
3.10.11 VPN Support
Today BGP is also used for VPNs, for example as described in RFC2547
[RFC2547].
Internet routing and VPN routing have different purposes and most
often exchange different information between different devices. Most
Internet routers do not need to know VPN-specific information. The
concepts should be clearly separated.
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But when it comes to the mechanisms, VPN routing can share the same
protocol as ordinary Internet routing; it can use a separate instance
of the same protocol or it can use a different protocol. All
variants are possible and have their own merits. These requirements
are silent on this issue.
3.10.12 End-to-End Reliability
The existing Internet architecture neither requires nor provides end-
to-end reliability of control information dissemination. There is,
however, a requirement for end-to-end reliability of control
information distribution, i.e. the ends of the VPN established need
to have a acknowledgment of the success in setting up the VPN. While
it is not necessarily the function of a routing architecture to
provide end-to-end reliability for this kind of purpose, we must be
clear that end-to-end reliability becomes a requirement if the
network has to support such reliable control signaling. There may be
other requirements that derive from requiring the FDR to support
reliable control signaling.
3.10.13 End-to-End Transparency
The introduction of private addressing schemes, Network Address
Translators, and firewalls has significantly reduced the end-to-end
transparency of the network. In many cases the network is also no
longer symmetric, so that communication between two addresses is
possible if the communication session originates from one end but not
from the other. This impedes the deployment of new peer-to-peer
services and some 'push' services where the server in a client-
server arrangement originates the communication session. Whether a
new routing system either can or should seek to restore this
transparency is an open issue.
A related issue is the extent to which end user applications should
seek to control the routing of communications to the rest of the
network.
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4. Security Considerations
We address security issues in the individual requirements. We do
require that the architecture and protocols developed against this
set of requirements be "secure". Discussion of specific security
issues can be found in the following sections:
o Group A: Routing System Security - Section 2.1.9
o Group A: End Host Security - Section 2.1.10
o Group A: Routing Information Policies - Section 2.1.11.1
o Group A: Abstraction - Section 2.1.16
o Group A: Robustness - Section 2.1.18
o Group B: Protection against denial of service and other security
attacks - Section 3.2.3.8
o Group B: Commercial service providers - Section 3.3.1.1
o Group B: The Federated Environment - Section 3.4.1
o Group B: Path advertisement - Section 3.6.2.2
o Group B: Security Requirements - Section 3.9
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5. IANA Considerations
This document is a set of requirements from which a new routing and
addressing architecture may be developed. From that architecture, a
new protocol, or set of protocols, may be developed.
While this note poses no new tasks for IANA, the architecture and
protocols developed from this document probably will have issues to
be dealt with by IANA.
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6. Acknowledgments
This document is the combined efforts of two groups in the IRTF.
Group A which was formed by the IRTF Routing Research chairs and
Group B which was self formed and later was folded into the IRTF
Routing Research Group. Each group has it own set of
acknowledgments.
Group A Acknolwedgements
This originated in the IRTF Routing Research Group's sub-group on
Inter-domain routing requirements. The members of the group are:
Abha Ahuja Danny McPherson
J. Noel Chiappa David Meyer
Sean Doran Mike O'Dell
JJ Garcia-Luna-Aceves Andrew Partan
Susan Hares Radia Perlman
Geoff Huston Yakov Rehkter
Frank Kastenholz John Scudder
Dave Katz Curtis Villamizar
Tony Li Dave Ward
We also appreciate the comments and review received from Ran
Atkinson, Howard Berkowitz, Randy Bush, Avri Doria, Jeffery Haas,
Dmitri Krioukov, Russ White, and Alex Zinin. Special thanks to
Yakov Rehkter for contributing text and to Noel Chiappa.
Group B Acknowledgements
The draft is derived from work originally produced by Babylon.
Babylon was a loose association of individuals from academia,
service providers and vendors whose goal was to discuss issues in
Internet routing with the intention of finding solutions for those
problems.
The individual members who contributed materially to this draft
are: Anders Bergsten, Howard Berkowitz, Malin Carlzon, Lenka Carr
Motyckova, Elwyn Davies, Avri Doria, Pierre Fransson, Yong Jiang,
Dmitri Krioukov, Tove Madsen, Olle Pers, and Olov Schelen.
Thanks also go to the members of Babylon and others who did
substantial reviews of this material. Specifically we would like
to acknowledge the helpful comments and suggestions of the
following individuals: Loa Andersson, Tomas Ahlstrom, Erik Aman,
Thomas Eriksson, Niklas Borg, Nigel Bragg, Thomas Chmara, Krister
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Edlund, Owe Grafford, Torbjorn Lundberg, Jasminko Mulahusic,
Florian-Daniel Otel, Bernhard Stockman, Tom Worster, Roberto
Zamparo.
In addition, the authors are indebted to the folks who wrote all
the references we have consulted in putting this paper together.
This includes not only the references explicitly listed below, but
also those who contributed to the mailing lists we have been
participating in for years.
Finally, it is the editors who are responsible for any lack of
clarity, any errors, glaring omissions or misunderstandings.
7. Informative References
[Blumenthal01]
Blumenthal, M. and D. Clark, "Rethinking the design of the
Internet: The end to end arguments vs. the brave new
world", May 2001,
<http://ana-www.lcs.mit.edu/anaweb/papers.html>.
[Chiappa02]
Chiappa, N., "A New IP Routing and Addressing
Architecture", Jul 1991,
<http://ana-3.lcs.mit.edu/~jnc/nimrod/overview.txt>.
[Griffin99]
Griffin, T. and G. Wilfong, "An Analysis of BGP
Convergence Properties", SIGCOMM , 1999.
[I-D.ietf-diffserv-pdb-ar]
Seddigh, N., Nandy, B., and J. Heinanen, "An Assured Rate
Per-Domain Behaviour for Differentiated Services",
draft-ietf-diffserv-pdb-ar-00 (work in progress),
Feb 2001.
[I-D.ietf-diffserv-pdb-vw]
Jacobson, V., Nichols, K., and K. Poduri, "The 'Virtual
Wire' Behavior Aggregate", draft-ietf-diffserv-pdb-vw-00
(work in progress), Jul 2000.
[I-D.irtf-routing-reqs]
Doria, A., "Analysis of IDR requirements and History",
draft-irtf-routing-history-00 (work in progress),
December 2003.
[I-D.many-inference-srlg]
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"Inference of Shared Risk Link Groups",
draft-many-inference-srlg-00 (work in progress), Feb 2001.
[I-D.mcpherson-bgp-route-oscillation]
McPherson, D., Gill, V., Walton, D., and A. Retana, "BGP
Persistent Route Oscillation Condition",
draft-mcpherson-bgp-route-oscillation-00 (work in
progress), Dec 2000.
[ISO10747]
ISO/IEC, "Protocol for Exchange of Inter-Domain Routeing
Information among Intermediate Systems to support
Forwarding of ISO 8473 PDUs", International Standard
10747 ISO/IEC JTC 1, Switzerland, 1993.
[Netsizer02]
"Telcordia Technologies Netsizer web site", 2002,
<http://www.telcordia.com/research/netsizer/>.
[RFC1126] Little, M., "Goals and Functional Requirements for Inter-
Autonomous System Routing", RFC 1126, Jul 1989.
[RFC1992] Castineyra, I., Chiappa, N., and M. Steenstrup, "The
Nimrod Routing Architecture", RFC 1992, Aug 1996.
[RFC2071] Ferguson, P. and H. Berkowitz, "Network Renumbering
Overview: Why would I want it and what is it anyway?",
RFC 2071, Jan 1997.
[RFC2072] Berkowitz, H., "Router Renumbering Guide", RFC 2072,
Jan 1997.
[RFC2547] Rosen, E. and Y. Rekhter, "BGP/MPLS VPNs", RFC 2547,
Mar 1999.
[RFC3031] Rosen, E., "Multiprotocol Label Switching Architecture",
RFC 3031, Jan 2001.
[RFC3221] Huston, G., "Commentary on Inter-Domain Routing in the
Internet", RFC 3221, Dec 2001.
[RFC3471] Ashwood-Smith, P., "Generalized MPLS - Signaling
Functional Description",
draft-ietf-mpls-generalized-signaling-01 (work in
progress), Nov 2000.
[Wroclawski95]
Wroclowski, J., "The Metanet White Paper - Workshop on
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Research Directions for the Next Generation Internet",
1995.
[policy-charter02]
Internet Engineering Task Force, "IETF Policy working
group", , 2002,
<http://www.ietf.org/html.charters/policy-charter.html>.
[rap-charter02]
Internet Engineering Task Force, "IETF Resource Allocation
Protocol working group", , 2002,
<http://www.ietf.org/html.charters/rap-charter.html>.
[refs.42] Grossman, D., "New Terminology and Clarifications for
Diffserv", draft-ietf-diffserv-new-terms-08 (work in
progress), Jan 2002.
[refs.43] Broido, A., Nemeth, E., Claffy, K., and C. Elves,
"Internet Expansion, Refinement and Churn", Presentation
at Nanog , Feb 2002.
[refs.44] Partridge, C. and F. Kastenholz, "Technical Criteria for
Choosing IP The Next Generation (IPng)", RFC 1726,
Dec 1994.
[refs.45] Perkins, C., "IP Mobility Support.", RFC 2002, Oct 1996.
[refs.46] O'Dell, M., "Private Communication", 2001.
[refs.47] Clark, D., "Quote reportedly from IETF Plenary
discussion", 1991.
[snmpconf-charter02]
Internet Engineering Task Force, "IETF Configuration
management with SNMP working group", , 2002,
<http://www.ietf.org/html.charters/snmpconf-charter.html>.
Authors' Addresses
Avri Doria
LTU
Lulea 971 87
Sweden
Phone: +1 401 663 5024
Email: avri@acm.org
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Elwyn B. Davies
Consultant
Soham, Cambs
UK
Phone: +44 7889 488 335
Email: elwynd@dial.pipex.com
Frank Kastenholz
Juniper Networks
10 Technology Park
Westford, MA 01886
USA
Phone: +1 978 589 0286
Email: fkastenholz@juniper.net
URI:
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Acknowledgment
Funding for the RFC Editor function is currently provided by the
Internet Society.
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