Enhanced Interior Gateway Routing Protocol for OMNeT++
Vladimír Veselý, Jan Bloudíček and Ondřej Ryšavý
Faculty of Information Technology, Brno University of Technology, Božetěchova 2, Brno, Czech Republic
Keywords: Enhanced Interior Gateway Routing Protocol, EIGRP, OMNeT++, Dynamic Routing Protocol, Routing,
Simulation, ANSA.
Abstract: Cisco’s EIGRP is a hybrid routing protocol between distance vector and link-state routing protocols. EIGRP
offers routing based on composite metric, which takes into account multiple factors and allows more
granular and precise routing decisions based on the current state of the network. Cisco released basic
specification of EIGRP as IETF’s RFC draft in the beginning of 2013. This paper introduces one of the first
freely available EIGRP design and a simulation model implementation that can be run and tested within
OMNeT++ discrete event simulator.
1 INTRODUCTION
Network layer serves the purpose of end-to-end data
delivery. Routers employ routing tables to make
correct routing decisions by forwarding hop-by-hop
the packet closer to receiver. Dynamic routing
protocols maintain up-to-date content of routing
tables by exchanging updates about known
networks.
Routing protocols for traditional wired networks
could be divided into three categores: a) distance-
vector where routing is based on information
provided by neighbors and each route has one
attribute representing distance of network from a
given router; b) path-vector which is the same as
distance vector but routes have more than one
attribute; and c) link-state where every router
maintains independent view on topology and
computes the shortest path tree towards all other
nodes. Additional typology of routing protocol is
according to type of deployment: a) interior
gateway protocols (IGP) for routing within one
administrative domain; b) exterior gateway
protocols (EGP) for routing between autonomous
systems (AS). Among typical representants belong:
Routing Information Protocol (RIPv2 for IPv4
(Malkin, 1998), RIPng for IPv6 (Malkin &
Minnear, 1997)) – Distance-vector routing
protocol that works with hop-count as the
metric. Routes with metric 16 or more are
considered unreachable;
Babel (Chroboczek, 2011) – Babel is distance-
vector protocol specialized (but not
exclusively) for wireless networks that have
different metric criteria than wired networks.
Metric may represent cost, number of host or
any other implementation dependent route
atribute. Nevertheless, routes with infinity
metric 0xFFFF are considered unreachable.
Babel currently supports both IPv4 and IPv6;
Intermediate System to Intermediate System
(IS-IS) (Oran, 1990) – The first link-state
protocol ever, which is also capable of working
with different metrics simultaneosly. IS-IS was
originally intended to be used with Connection-
less Mode Network Service Protocol
(concurrent of IP) for ISO/OSI networks,
however, later was developed implementation
for both IPv4 and IPv6 protocols. IS-IS is by
design agnostic to used address-family and
single instance can carry routing updates for
various network protocols. Formerely used IS-
IS metrics were delay and link errorness,
current revision employs only speed of the
link;
Open Shortest Path First (OSPFv2 for IPv4
(Moy, 1998), OSPFv3 for IPv4/6 (Coltun, et
al., 2008)) – OSPF started as IP alternative to
IS-IS and later become industrial standard link-
state routing protocol that has wide-spread
deployment. OSPF uses cost as the metric,
where cost is derived from the interface
bandwidth. OSPF supports only IP routing
updates;
50
Veselý V., Bloudí
ˇ
cek J. and Ryšavý O..
Enhanced Interior Gateway Routing Protocol for OMNeT++.
DOI: 10.5220/0005038400500058
In Proceedings of the 4th International Conference on Simulation and Modeling Methodologies, Technologies and Applications (SIMULTECH-2014),
pages 50-58
ISBN: 978-989-758-038-3
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
Border Gateway Protocol (BGPv4) (Rekhter &
Hares, 2006) – Extends distance-vector idea by
having multiple attributes acompanying the
single prefix update. BGPv4 is currently the
only one EGP that is being used and it is often
refered as policy-control routing protocol.
Enhanced Interior Gateway Protocol (EIGRP) is
the backward compatible successor of previous
Cisco proprietary Interior Gateway Protocol (IGRP).
It is categorized as a hybrid routing protocol which
means that it is a crossover between distance-vector
(topology is known based on announcement from
neighbors) and link-state protocols (instead of
periodic updates, topology changes are propagated
immediately). Down below follows the list of main
beneficial features of EIGRP:
EIGRP employs Diffusing Update Algorithm
(DUAL) (Garcia-Lunes-Aceves, 1993) that
effectively propagates any topology change
and minimizes path recomputational time;
Currently EIGRP is the only routing protocol
that guarantees loop-free topology even during
the time when topology is actively converging
towards a new routing state;
EIGRP leverages its own reliable transport
protocol (even for multicast data transfer);
In the contrary to other distance-vector
protocols, EIGRP is capable of sending event-
driven partial bounded updates;
It has neighbor discovery and recovery
mechanism to determine route reachibility via
particular adjacent node;
EIGRP contains protocol-dependent modules
that allow operation over different network
protocols (including IPv4 and IPv6);
The EIGRP was introduced in 1993 as a cojoint
effort of Cisco and SRI International (Albrightson,
et al., May 1994). Initial and later measurements
revealed that it outperforms other routing protocols
(i.e., speed of convergece, network bandwidth
utilization, queing delay) (Xu & Trajkovic, 2011).
Despite its beneficial aspects (or maybe because of
them) it had been protected as one of the major
Cisco intellectual properties by a bunch of patents
for nearly twenty years. In the beginning of 2013,
basic EIGRP design and functionality were
submitted as a publicly available IETF informational
draft (Savage, et al., 2013).
The project ANSA (Automated Network
Simulation and Analysis) running at the Faculty of
Information Technology is dedicated to develop the
variety of software tools that can create simulation
models based on real networks and subsequently to
allow formal analysis and verification of network
configurations. This paper outlines a new simulation
module, which is a part of the ANSA project and
which extends functionality of the INET framework
(OMNeTpp/INET, 2014) in OMNeT++ (OMNeTpp,
2014).
This paper has the following structure. The next
section covers a quick overview of existing EIGRP
implementations (either real or simulation ones).
Section 3 deals with our contribution, mainly
necessary theory, proposed design and subsequent
implementation. Section 4 presents validation
scenarios proving corectness of the implementation.
The paper is summarized in Section 5 together with
unveiling our future plans.
2 STATE OF THE ART
Currently none of vendors other than Cisco supports
EIGRP in its active network devices. Despite
positive campaign targeting wider EIGRP
acceptance, many manufacturers and customers
remain skeptical and rely on a long-time proven
open solutions like OSPF or IS-IS. The one of the
first publicly available open-source EIGRP routing
demon is being developed at the University of Žilina
(GitHub/janovic, 2013) within the scope of Quagga
project (nonGNU, 2013).
A freely available demonstration tool called
Easy-EIGRP (SourceForge, 2013) exists rather for
educational purposes.
OPNET simulator has contained EIGRP
simulation modules even before its public IETF
release. However, its functionality is limited and it
lacks IPv6 support for EIGRP. Nevertheless,
OPNET and its simulation models were used to
conduct several measurement studies comparing
different routing protocols including EIGRP (Wu,
2011).
Previously described state of EIGRP deployment
affirmed our decision to offer academic and
enterprise community with a full-fledged EIGRP
implementation with all usually employed features.
The current status of unicast routing support in
OMNeT 4.4.1 and INET 2.2 framework is according
to our best knowledge as follows. The IPv4 (named
networkLayer) and IPv6 (pragmatically called
networkLayer6) layers are already parts of INET
framework. The framework contains OSPFv2 as the
only available dynamic routing protocol.
During ANSA project development we have
extended original simple router module to be dual-
stack and enhanced it with a variety of dynamic
routing protocols (RIP, RIPng, IS-IS, OSPFv3,
EnhancedInteriorGatewayRoutingProtocolforOMNeT++
51
PIM), thus creating ANSARouter as the compound
simulation module based on the standard behavior of
Cisco routers.
The basic goal behind our effort is to support
EIGRP dynamic routing protocol. Hence, we have
decided to add missing functionality in form of
simulation module directly connected to
networkLayer and networkLayer6 as
depicted on
Figure 1.
Figure 1: ANSARouter structure with highlighted
contribution.
OMNeT++ state of the art prior to this paper is
the result of ongoing research covered in our other
articles.
3 CONTRIBUTION
We have implemented OMNeT++ compound
simulation module supporting EIGRP behavior and
functionality. This section provides a short
theoretical background, overview of design and
some implementation notes.
3.1 Theory of Operation
An EIGRP process computes a successor for every
destination. A successor represents the next-hop
router where the route to the destination via
successor is loop-less and with the shortest distance.
Feasible successor (FS) or so called backup next-
hop is the router that provides loop-less route but
with higher distance. To determine whether
particular router is a feasible successor, the router is
working with two parameters – a feasible and a
reported distance. Feasible distance () is the best
known distance from a destination network to a
given EIGRP router (historical minimum).
Reported distance () is distance from
destination network advertised by a given EIGRP
router neighbor. The router is using and to
decide whether the feasible condition is satisfied or
not. Feasible condition assumes that any route with
is without any doubts loop-less. The
passive state is the state of the destination network
when the successor is known and the route is
converged and usable. Active state is in contrast to
the previous definition when the destination network
does neither have a successor nor FS and the router
is actively searching and computing a new
successor.
The EIGRP employs composite metric which
takes into account multiple route attributes. The
basic composite metric consists of following four
parameters: a) bandwidth (abbr. is minimal
bandwidth enroute); b) delay (abbr. is
accumulative sum of delays enroute), c) load (abbr.
is maximal traffic load in range from 1 to 255 on
the links towards destination where lower is
considered better), d) reliability (abbr. is minimal
reliability in range from 1 to 255 on the links
towards destination where higher is considered
better). Parameters a) and b) are static, parameters c)
and d) are dynamically recomputed every 5 minutes
on certain EIGRP versions. Parameters are
accompanied with K-values called weights which
are unsigned byte long values where
.
Usually Cisco routers are using default composite
formula for metric computation without dynamic
parameters:
.
.
Complete composite formula including all
parameters looks like this:
.
.
256
.∙
The new revision of EIGRP establishes two new
parameters: a) jitter (abbr. is accumulative delay
SIMULTECH2014-4thInternationalConferenceonSimulationandModelingMethodologies,Technologiesand
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variation enroute measured in microseconds where
lower is preferred); b) energy (abbr. is
accumulative energy consumption in watts per
transferred kilobit where lower is preferred). Both
parameters are accompanied with
weight. A new
wide metric is 64 bit long in opposite to older 32 bit
long standard metric and it also solves problem of
standard metric when taking into account delay on
links faster than 1 Gbps. Wide metric composite
formula is then:
.
.
256
.
.
∙
When employing multicast for communication
on local segment, EIGRP has either reserved address
224.0.0.10 for IPv4 or FF02::A for IPv6. EIGRP
routers exchange following messages during
operation:
EIGRP Hello – Detects EIGRP neighbors with
their settings (K-values, autonomous system
number, timers and authentication) and checks
their aliveness. Sent periodically every
5 seconds by default. Hold timer (period after
which neighbor is considered dead) is 3×
longer, and by default it is 15 seconds.
Neighbor announces its own hello and hold
intervals which will obey during its operation;
EIGRP Update – Carries routing information
that might cause receivers to start DUAL. Sent
either as unicast or multicast;
EIGRP Ack – Used for acknowledging EIGRP
Update, Query and Reply messages. It is reused
EIGRP Hello message with empty structure;
EIGRP Query – If network transits to active
state and router starts to search for a new
successor then router starts DUAL and sends
EIGRP Queries to neighbors usually as
multicast;
EIGRP Reply – This message contains the
routing answer to previous EIGRP Query.
3.2 Design and Implementation
The EIGRP implementation works with three tables:
Neighbor table (NT) – Stores information
(e.g., IP address, router-id, uptime, hold-time,
query count, etc.) relevant to all adjacent
EIGRP routers;
Topology table (TT) – The main routing
information base from point of view of a given
router. It contains each known network and
relevant routes, their states and next-hop
addresses together with their and ;
Routing table (RT) – A routing table is the
gathering place of best routes from different
routing sources, thus the best EIGRP routes are
installed here from topology table.
The compound EIGRP simulation module is
divided into components depicted in Figure 2.
Figure 2: EIGRP simulation module structure.
A brief description of components is provided in
Table 1:
Table 1: Description of EIGRP submodules.
Name Description
pdmv4
The protocol-dependent
module (PDMs) sends and
receives EIGRP messages that
contain IPv4 routing
information. It mediates control
exchange between routing table
and topology table.
rtp
EIGRP uses Cisco Reliable
Transport Protocol (RTP) to
ensure reliable transfer of
EIGRP messages. It uses
sequence number and positive
acknowledgement scheme to
detect any gaps in transfers.
eigrpIpv4
NeighborTable
This module is emanation of
neighbor table. It maintains
state of all EIGRP adjacencies
(i.e., neighbor IP address, state,
hold timer, RTP sequence
number)
eigrpIpv4
TopologyTable
EIGRP RIB which includes all
learned routes, their state,
and computed successors.
eigrp
InterfaceTable
Simulation module keeps
settings relevant to any
interface on which EIGRP is
enabled (i.e., separate hello and
hold timers, query count).
EnhancedInteriorGatewayRoutingProtocolforOMNeT++
53
4 TESTING
In this section, we provide information on testing
and validation of our implementation. Only two
scenarios are described here really thoroughly
because of limited space. Nevertheless a rich set of
test scenarios is accompanied with the published
source codes.
We compared results with the behavior of the
referential EIGRP implementation running at Cisco
routers. For this reason, we built exactly the same
topology and observed (using Switched Port
Analyzer and Wireshark) relevant message
exchanges between real devices (Cisco 7204 as
routers with IOS version c7200-adventerprisek9-
mz.152-4.M2 and host stations with Windows 7
OS).
Figure 3: EIGRP testing topology.
Testing topology (see above Figure 3) consists of
four EIGRPRouters (marked R1, R2, R3 and R4)
and four ANSAStandardHosts (LAN1, LAN2,
LAN3 and LAN4) which substitutes whole separate
LAN segment with dedicated IP networks.
In the first scenario, we would like to show how
metric changes are being propagated. In the second
scenario, we focus on topology changes.
4.1 Scenario 1: Metric Change
A typical message exchange of freshly booted
routers is following:
#1) Routers establish neighborship by sending
and receiving EIGRP Hello messages.
Whenever a new neighbor is discovered, all
relevant information is recorded and stored in
NT. This fact is depicted on Figure 4 where
we can observe
eigrpIpv4NeighborTable content on
router R2 just few seconds after beginning of
scenario (no later than 4 seconds after the
start);
#2) Whenever neighborship is established,
routers exchange EIGRP Updates containing
routing information to build their TTs and
determine best routes towards known
destinations. Reception and processing of any
update is confirmed by EIGRP Ack.
Figure 5
shows converged state of topology from the
router R2’s eigrpIpv4TopologyTable
point of view. Routes have known ,
successors and are in passive states.
Figure 4: R2's Neighbor Table prior to Scenario 1 events.
Figure 5: R2's Topology Table prior to Scenario 1 events.
We scheduled bandwidth alternation R3’s eth2
interface facing LAN3 changes its attribute from
100 to 10 000 in order to show how the change of
metric influences topology (for instance content or
R2’s RT is depicted on Figure 6). In simulator, we
uses scenarioManager to accomplish this goal,
in case of real-network, we change interface
configuration.
#3) R3 initiates DUAL, which discovers that only
10.0.3.0/24 is reachable via eth2 and
propagates metric change to its neighbors R2
and R1 by sending EIGRP Update for
network 10.0.3.0/24;
#4) R2 acknowledges update with EIGRP Ack.
R2’s DUAL is unable to find FS, hence route
transits to active state and router sends
ordinary EIGRP Query to R1 and R4 and
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Figure 6: R2's Routing Table prior to Scenario 1 events.
poison reverse EIGRP Query with maximal
metric towards R3. Same previous steps
apply also for R1 where situation is similar –
acknowledgment towards R3, DUAL marks
network as active, query to R2 and poison
reverse query to R3;
#5) R1 receives EIGRP Query from R2 and it
acknowledges it with EIGRP Ack. Following
next, R1 responds with EIGRP Reply with a
new metric via successor R3. Same situation
repeats on R2 when replying to R1 query;
#6) R3 receives queries from R1 and R2 and it
acknowledges them. Following next, R3 finds
out FS (itself) and responds with EIGRP
Replies to R2 and R1;
#7) R4 receives EIGRP Query from R2 and
confirms it with EIGRP Ack. DUAL is unable
to determine FS, thus route transits to active
state. Because of split-horizon rule, there is
no neighbor to query. Hence, R2 is marked as
a successor due to infinity . The network
transits back to passive state with a changed
metric via new and old successor R2. R4
sends poison reverse EIGRP Reply back to
R2;
#8) R1 and R2 receive and acknowledge EIGRP
Replies which they exchanged and store a
new metric in TT;
#9) R1 and R2 receive EIGRP Reply from R3 and
store a new metric in TT. Because all
neighbors of R1 and R2 responded to their
queries, DUAL stops. Next, they both R1 and
R2 update records in RTs to reflect changed
metric situation of network 10.0.3.0/24.
Topology is converged and state of R2’s
routing table is depicted on
Figure 7.
Figure 7: R2's Routing Table after Scenario 1 events.
4.2 Scenario 2: Topology Change
Scenario begins exactly same as the previous one
with phase #1, when neighbors are discovered, and
phase #2, when topology converges by initial
routing information exchange (same content of R2’s
NT, TT and RT as on Figure 4, 5 and 6).
We scheduled link failure (R2’s eth1) of
interconnection between routers R2 and R3 for this
scenario. Goal is to show how topology change is
propagated from the source to other routers. Once
again we accomplish this with the help of
scenarioManager in simulator. In case of real
network, we just shut down the interface. In both
cases, R3’s eth1 remains operational.
We have decided to omit all acknowledgement
in subsequent text in order to make it clearer and
easier to read. Nevertheless, all routers correctly
confirm reception of EIGRP Update, Query and
Reply messages by sending EIGRP Ack. Scenario
continues in following manner:
#3) Eth1 comes down on R2. EIGRP process
goes through TT and transits all networks
reachable via successor (10.0.23.0/30 and
10.0.3.0/24) on eth1 interface to active
state. R2 sends EIGRP Queries to
neighbors R1 and R4. Load balancing is
enabled, thus 10.0.13.0/30 is reachable via
two routes in the RT – the one that leads
through R3 is removed and neighbors are
notified by EIGRP Update messages;
EnhancedInteriorGatewayRoutingProtocolforOMNeT++
55
#4) R4 receives EIGRP Query from R2. DUAL
cannot find FS for routes and because of
split-horizon rule there is no other neighbor
to ask. Hence, R4 sends EIGRP Reply
stating that 10.0.23.0/30 and 10.0.3.0/24 are
unreachable from its perspective;
#5) R1 receives EIGRP Query. Dual finds out
FS and responds back with EIGRP Reply.
Moreover, the route to 10.0.23.0/30 via R2
is removed from RT and EIGRP Update
about this is sent to neighbors R3 and R2.
Routes on this router remain in passive
state;
#6) Integrated optimization prevents
information from particular updates to be
passed to DUAL. Namely previously sent
EIGRP Update from R1 to R3, from R2 to
R1, from R1 to R2 and from R2 to R4;
#7) R2 receives EIGRP Reply from R4 and
from R1. All replies has been received, thus
routes to 10.0.23.0/24 and 10.0.3.0/30 has a
new successor in R2’s TT and that is R1.
Those routes are propagated to R2’s RT and
information about change is sent to
neighbors as EIGRP Update;
#8) R4 receives EIGRP Update from R2 and
inserts R2 as a new successor to its RT.
Because of RT change, poison reverse
EIGRP Update is sent back to R2;
#9) Same optimization as in case of phase #6.
EIRGP Updates from R2 to R1 and from
R4 to R2 are omitted from DUAL
processing. Content of R2’s NT, TT and RT
does not change for the rest of scenario and
it shown on Figures 8, 9 and 10);
Figure 8: R2's Routing table after Scenario 2 events.
Figure 9: R2's Neighbor table after Scenario 2 events.
Figure 10: R2's Topology Table after Scenario 2 events.
#10) Hold timer expires on R3, thus
neighborship is terminated and R2 is
removed from R3’s NT. Also R3 sends
goodbye EIGRP Hello as a preventive
notification. All affected networks
reachable via R2 (10.0.24.0/30, 10.0.2.0/24,
10.0.4.0/24) transit to active state and
EIGRP Query is sent to remaining neighbor
R1. Only exception is 10.0.12.0/30 that has
another FS due to load balancing. However,
its second route is removed from R3’s RT
and EIGRP Update is sent to R1;
#11) R1 receives EIGRP Query and Update from
R3. DUAL finds FS for all queried routes in
R1’s TT and thus no network transits to
active state. EIGRP Reply is sent to R3 as
response;
#12) R3’s DUAL collects all (single) EIGRP
Replies (from R1). R3’s TT is updated with
a new successor and affected networks
transit back to passive state. The best routes
are introduced to R3’s RT and EIGRP
Update is sent to R1;
#13) Processing of update is optimized just as in
case of phase #6 and #9 on R1. Topology is
converged.
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4.3 Test Summary
Comparison for Scenario 1 can be observed in Table
2. Similarly description for Scenario 2 is in Table 3.
Column marked with header “
S → R” contains
sender and receiver of a given message. In
comparisons, we have focused on messages
processed mostly by router R2. Nevertheless,
messages that are not shown and were processed by
other routers are also in correct order and without
any significant deviations between simulation and
real time.
The correlation of messages between simulation
and real network suggests correctness of our EIGRP
implementation.
Table 2: Timestamp comparison for Scenario 1.
Phase Message
S →R
Simul. [s] Real [s]
#3 Update
R3→R2
0.000 0.000
#4 Query
R2→R1
0.001 0.036
#5 Reply
R1→R2
0.002 0.068
#9 Reply
R4→R2
0.003 0.088
Table 3: Timestamp comparison for Scenario 2.
Phase Message
S →R
Simul. [s] Real [s]
#3 Query
R2→R1
0.000 0.040
#4 Reply
R4→R2
0.001 0.076
#5 Reply
R1→R2
0.001 0.096
#7 Update
R2→R1
0.002 0.116
#8 Update
R4→R2
0.003 0.180
#10
Hello
R3→R2
10.659 10.736
Query
R3→R1
10.660 10.764
#11 Reply
R1→R3
10.661 10.812
Validation testing against the real-life topology
shows just reasonable time variations (around ±200
milliseconds). This variation observable on Cisco
devices is caused by three factors: a) control-plane
processing delay and internal EIGRP optimizations;
b) packet pacing that guarantees constant bandwidth
consumption by EIGRP process and avoids potential
race conditions between EIGRP instances;
and c) inaccuracy in timing of certain event in real-
life network. Nevertheless, the routing outcomes of
simulated and real network are exactly same when
taking into account accuracy in order of seconds.
5 CONCLUSIONS
We presented an overview of the theory behind
EIGRP routing protocol. The main contribution of
work is a new OMNeT++ simulation module that
mimics Cisco’s EIGRP protocol implementation
based on the available specification and from a
reverse-engineering observations. We introduce a
simulation scenario and relevant results to
demonstrate its compliance with the reference Cisco
IOS implementation.
EIGRP is beneficial namely for large enterprise
networks because it generally consumes less
resources than link-state IGPs. It is the one of the
best distance-vector IGPs available and with its
public release we can expect that more companies
will tend to use it. For such entities, we offer
polished simulation models for a reliable
comparison on their network functionality which
now includes also EIGRP.
We plan to carry on work towards: 1) wrap up
IPv6 protocol dependent module for our EIGRP
simulation module; 2) extend functionality with stub
functionality, stuck-in-active support and further
tune EIGRP simulation model. Additional plan is to
conduct comparative evaluation of our models
against those in OPNET simulator.
More information about the ANSA project is
available on homepage (Brno University of
Technology, 2014). All source codes including
EIGRP implementation could be downloaded from
GitHub repository (GitHub/kvetak, 2013).
ACKNOWLEDGEMENTS
This work was supported by the Brno University of
Technology organization and by the research grants:
FIT-S-14-2299 supported by Brno University
of Technology;
VG20102015022 supported by Ministry of the
Interior of the Czech Republic;
IT4Innovation ED1.1.00/02.0070 supported by
Czech Ministry of Education Youth and Sports.
REFERENCES
Albrightson, R., Garcia-Luna-Aceves, J. J. & Boyle, J.,
May 1994. EIGRP a fast routing protocol based on
distance vectors. Proceedings Networld/Interop,
Volume Vol. XCIV, pp. 136-147.
Brno University of Technology, 2014. [Online] Available
at: http://nes.fit.vutbr.cz/ansa/pmwiki.php.
Coltun, R., Ferguson, D., Moy, J. & Lindem, A., 2008.
RFC 5340: OSPF for IPv6. [Online] Available at:
http://tools.ietf.org/html/rfc5340.
Garcia-Lunes-Aceves, J., 1993. Loop-Free Routing Using
Diffusing Computations. IEEE/ACM Transactions on
Networking, Vol. I(No. 1), pp. 130-141.
EnhancedInteriorGatewayRoutingProtocolforOMNeT++
57
GitHub/janovic, 2013. janovic/Quagga-EIGRP. [Online]
Available at: https://github.com/janovic/Quagga-
EIGRP [Accessed April 2014].
GitHub/kvetak, 2013. [Online] Available at:
https://github.com/kvetak/ANSA [Accessed January
2014].
Chroboczek, J., 2011. RFC 6126: The Babel Routing
Protocol. [Online] Available at: http://
tools.ietf.org/html/rfc6126.
Malkin, G., 1998. RFC 2453: RIP Version 2. [Online]
Available at: https://tools.ietf.org/html/rfc2453.
Malkin, G. & Minnear, R., 1997. RFC 2080: RIPng for
IPv6. [Online] Available at: https://
tools.ietf.org/html/rfc2080.
Moy, J., 1998. RFC 2328: OSPF Version 2. [Online]
Available at: http://tools.ietf.org/html/rfc2328.
nonGNU, 2013. Quagga Software Routing Suite. [Online]
Available at: http://www.nongnu.org/quagga/
[Accessed April 2014].
OMNeTpp/INET, 2014. INET Framework | Main /
Welcome to the INET Framework. [Online] Available
at: http://inet.omnetpp.org/ [Accessed April 2014].
OMNeTpp, 2014. OMNeT++ Network Simulation
Framework. [Online] Available at: http://
www.omnetpp.org/ [Accessed April 2014].
Oran, D., 1990. RFC 1142: OSI IS-IS Intra-domain
Routing Protocol. [Online] Available at:
http://tools.ietf.org/html/rfc1142.
Rekhter, Y. & Hares, S., 2006. RFC 4271: A Border
Gateway Protocol 4 (BGP-4). [Online] Available at:
http://tools.ietf.org/html/rfc4271.
Savage, D. et al., 2013. Enhanced Interior Gateway
Routing Protocol. [Online] Available at:
https://tools.ietf.org/html/draft-savage-eigrp-01.
SourceForge, 2013. Easy-EIGRP | Free software
downloads at SourceForge.net. [Online] Available at:
http://sourceforge.net/projects/easy-eigrp/
Wu, B., 2011. Simulation Based Performance Analyses on
RIPv2, EIGRP, and OSPF Using OPNET. [Online]
Available at: http://digitalcommons.uncfsu.edu/
macsc_wp/11.
Xu, D. & Trajkovic, T., 2011. Performance Analysis of
RIP, EIGRP, and OSPF Using OPNET. [Online]
Available at: http://summit.sfu.ca/item/10841.
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