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IETF RFC 7835
Last modified on Saturday, April 30th, 2016
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Internet Engineering Task Force (IETF) D. Saucez
Request for Comments: 7835 INRIA
Category: Informational L. Iannone
ISSN: 2070-1721 Telecom ParisTech
O. Bonaventure
Universite catholique de Louvain
April 2016
Locator/ID Separation Protocol (LISP) Threat Analysis
Abstract
This document provides a threat analysis of the Locator/ID Separation
Protocol (LISP).
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for informational purposes.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Not all documents
approved by the IESG are a candidate for any level of Internet
Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/RFC 7835.
Copyright Notice
Copyright (c) 2016 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
publication of this document. Please review these documents
carefully, as they describe your rights and restrictions with respect
to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Saucez, et al. Informational PAGE 1
RFC 7835 LISP Threats April 2016
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
2. Threat Model . . . . . . . . . . . . . . . . . . . . . . . . 3
2.1. Operation Modes of Attackers . . . . . . . . . . . . . . 4
2.1.1. On-Path vs. Off-Path Attackers . . . . . . . . . . . 4
2.1.2. Internal vs. External Attackers . . . . . . . . . . . 4
2.1.3. Live vs. Time-Shifted Attackers . . . . . . . . . . . 5
2.1.4. Control-Plane vs. Data-Plane Attackers . . . . . . . 5
2.1.5. Cross-Mode Attackers . . . . . . . . . . . . . . . . 5
2.2. Threat Categories . . . . . . . . . . . . . . . . . . . . 5
2.2.1. Replay Attack . . . . . . . . . . . . . . . . . . . . 5
2.2.2. Packet Manipulation . . . . . . . . . . . . . . . . . 6
2.2.3. Packet Interception and Suppression . . . . . . . . . 6
2.2.4. Spoofing . . . . . . . . . . . . . . . . . . . . . . 6
2.2.5. Rogue Attack . . . . . . . . . . . . . . . . . . . . 7
2.2.6. Denial-of-Service (DoS) Attack . . . . . . . . . . . 7
2.2.7. Performance Attack . . . . . . . . . . . . . . . . . 7
2.2.8. Intrusion Attack . . . . . . . . . . . . . . . . . . 7
2.2.9. Amplification Attack . . . . . . . . . . . . . . . . 7
2.2.10. Passive Monitoring Attacks . . . . . . . . . . . . . 7
2.2.11. Multi-category Attacks . . . . . . . . . . . . . . . 8
3. Attack Vectors . . . . . . . . . . . . . . . . . . . . . . . 8
3.1. Gleaning . . . . . . . . . . . . . . . . . . . . . . . . 8
3.2. Locator Status Bits . . . . . . . . . . . . . . . . . . . 9
3.3. Map-Version . . . . . . . . . . . . . . . . . . . . . . . 10
3.4. Routing Locator Reachability . . . . . . . . . . . . . . 11
3.5. Instance ID . . . . . . . . . . . . . . . . . . . . . . . 12
3.6. Interworking . . . . . . . . . . . . . . . . . . . . . . 12
3.7. Map-Request Messages . . . . . . . . . . . . . . . . . . 12
3.8. Map-Reply Messages . . . . . . . . . . . . . . . . . . . 13
3.9. Map-Register Messages . . . . . . . . . . . . . . . . . . 15
3.10. Map-Notify Messages . . . . . . . . . . . . . . . . . . . 15
4. Note on Privacy . . . . . . . . . . . . . . . . . . . . . . . 15
5. Threat Mitigation . . . . . . . . . . . . . . . . . . . . . . 16
6. Security Considerations . . . . . . . . . . . . . . . . . . . 16
7. References . . . . . . . . . . . . . . . . . . . . . . . . . 17
7.1. Normative References . . . . . . . . . . . . . . . . . . 17
7.2. Informative References . . . . . . . . . . . . . . . . . 17
Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . . . 18
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 19
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1. Introduction
The Locator/ID Separation Protocol (LISP) is specified in [RFC 6830].
This document provides an assessment of the potential security
threats for the current LISP specifications if LISP is deployed in
the Internet (i.e., a public non-trustable environment).
The document is composed of three main parts. The first part defines
a general threat model that attackers use to mount attacks. The
second part, using this threat model, describes the techniques based
on LISP and its architecture that attackers may use to construct
attacks. The third part discusses mitigation techniques and general
solutions to protect LISP and its architecture from attacks.
This document does not consider all the possible uses of LISP as
discussed in [RFC 6830] and [RFC 7215] and does not cover threats due
to specific implementations. The document focuses on LISP unicast,
including as well LISP Interworking [RFC 6832], LISP Map-Server
[RFC 6833], and LISP Map-Versioning [RFC 6834]. Additional threats may
be discovered in the future while deployment continues. The reader
is assumed to be familiar with these documents for understanding the
present document.
This document assumes a generic IP service and does not discuss the
difference, from a security viewpoint, between using IPv4 or IPv6.
2. Threat Model
This document assumes that attackers can be located anywhere in the
Internet (either in LISP sites or outside LISP sites) and that
attacks can be mounted either by a single attacker or by the
collusion of several attackers.
An attacker is a malicious entity that performs the action of
attacking a target in a network where LISP is (partially) deployed by
leveraging LISP and/or its architecture.
An attack is the action of performing an illegitimate action on a
target in a network where LISP is (partially) deployed.
The target of an attack is the entity (i.e., a device connected to
the network or a network) that is aimed to undergo the consequences
of an attack. Other entities can potentially undergo side effects of
an attack, even though they are not directly targeted by the attack.
The target of an attack can be selected specifically, i.e., a
particular entity, or arbitrarily, i.e., any entity. Finally, an
attacker can aim to attack one or several targets with a single
attack.
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Section 2.1 specifies the different modes of operation that attackers
can follow to mount attacks, and Section 2.2 specifies the different
categories of attacks that attackers can build.
2.1. Operation Modes of Attackers
In this document, attackers are classified according to their modes
of operation, i.e., the temporal and spacial diversity of the
attacker. These modes are not mutually exclusive; they can be used
by attackers in any combination, and other modes may be discovered in
the future. Further, attackers are not at all bound by our
classification scheme, so implementers and those deploying will
always need to do additional risk analysis for themselves.
2.1.1. On-Path vs. Off-Path Attackers
On-path attackers, also known as Men-in-the-Middle, are able to
intercept and modify packets between legitimate communicating
entities. On-path attackers are located either directly on the
normal communication path (either by gaining access to a node on the
path or by placing themselves directly on the path) or outside the
location path but manage to deviate (or gain a copy of) packets sent
between the communication entities. On-path attackers hence mount
their attacks by modifying packets initially sent legitimately
between communication entities.
An attacker is called an off-path attacker if it does not have access
to packets exchanged during the communication or if there is no
communication. In order for their attacks to succeed, off-path
attackers must hence generate packets and inject them in the network.
2.1.2. Internal vs. External Attackers
An internal attacker launches its attack from a node located within a
legitimate LISP site. Such an attacker is either a legitimate node
of the site or it exploits a vulnerability to gain access to a
legitimate node in the site. Because of their location, internal
attackers are trusted by the site they are in.
On the contrary, an external attacker launches its attacks from the
outside of a legitimate LISP site.
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2.1.3. Live vs. Time-Shifted Attackers
A live attacker mounts attacks for which it must remain connected as
long as the attack is mounted. In other words, the attacker must
remain active for the whole duration of the attack. Consequently,
the attack ends as soon as the attacker (or the used attack vector)
is neutralized.
On the contrary, a time-shifted attacker mounts attacks that remain
active after it disconnects from the Internet.
2.1.4. Control-Plane vs. Data-Plane Attackers
A control-plane attacker mounts its attack by using control-plane
functionalities, typically the mapping system.
A data-plane attacker mounts its attack by using data-plane
functionalities.
As there is no complete isolation between the control plane and the
data plane, an attacker can operate in the control plane (or data
plane) to mount attacks targeting the data plane (or control plane)
or keep the attacked and targeted planes at the same layer (i.e.,
from control plane to control plane or from data plane to data
plane).
2.1.5. Cross-Mode Attackers
The modes of operation used by attackers are not mutually exclusive;
hence, attackers can combine them to mount attacks.
For example, an attacker can launch an attack using the control plane
directly from within a LISP site to which it is able to get temporary
access (i.e., internal + control-plane attacker) to create a
vulnerability on its target and later on (i.e., time-shifted +
external attacker) mount an attack on the data plane (i.e., data-
plane attacker) that leverages the vulnerability.
2.2. Threat Categories
Attacks can be classified according to the eleven following
categories. These categories are not mutually exclusive and can be
used by attackers in any combination.
2.2.1. Replay Attack
A replay attack happens when an attacker retransmits a packet (or a
sequence of packets) without modifying it.
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2.2.2. Packet Manipulation
A packet manipulation attack happens when an attacker receives a
packet, modifies the packet (i.e., changes some information contained
in the packet), and finally transmits the packet to its final
destination, which can be the initial destination of the packet or a
different one.
2.2.3. Packet Interception and Suppression
In a packet interception and suppression attack, the attacker
captures the packet and drops it before it can reach its final
destination.
2.2.4. Spoofing
With a spoofing attack, the attacker injects packets in the network
pretending to be another node. Spoofing attacks are made by forging
source addresses in packets.
It should be noted that with LISP, packet spoofing is similar to
spoofing with any other existing tunneling technology currently
deployed in the Internet. Generally, the term "spoofed packet"
indicates a packet containing a source IP address that is not the
actual originator of the packet. Hence, since LISP uses
encapsulation, the spoofed address could be in the outer header as
well as in the inner header; this translates to two types of
spoofing.
Inner address spoofing: The attacker uses encapsulation and uses a
spoofed source address in the inner packet. In case of data-plane
LISP encapsulation, that corresponds to spoofing the source
Endpoint Identifier (EID) address of the encapsulated packet.
Outer address spoofing: The attacker does not use encapsulation and
spoofs the source address of the packet. In case of data-plane
LISP encapsulation, that corresponds to spoofing the source
Routing Locator (RLOC) address of the encapsulated packet.
Note that the two types of spoofing are not mutually exclusive;
rather, all combinations are possible and could be used to perform
different kinds of attacks. For example, an attacker outside a LISP
site can generate a packet with a forged source IP address (i.e.,
outer address spoofing) and forward it to a LISP destination. The
packet is then eventually encapsulated by a Proxy Ingress Tunnel
Router (PITR) so that once encapsulated, the attack corresponds to an
inner address spoofing. One can also imagine an attacker forging a
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packet with encapsulation where both inner and outer source addresses
are spoofed.
It is important to note that the combination of inner and outer
spoofing makes the identification of the attacker complex as the
packet may not contain information that allows detection of the
origin of the attack.
2.2.5. Rogue Attack
In a rogue attack, the attacker manages to appear as a legitimate
source of information, without faking its identity (as opposed to a
spoofing attacker).
2.2.6. Denial-of-Service (DoS) Attack
A DoS attack aims to disrupt a specific targeted service to make it
unable to operate properly.
2.2.7. Performance Attack
A performance attack aims to exploit computational resources (e.g.,
memory, processor) of a targeted node so as to make it unable to
operate properly.
2.2.8. Intrusion Attack
In an intrusion attack, the attacker gains remote access to a
resource (e.g., a host, a router, or a network) or information that
it legitimately should not have accessed. Intrusion attacks can lead
to privacy leakages.
2.2.9. Amplification Attack
In an amplification attack, the traffic generated by the target of
the attack in response to the attack is larger than the traffic that
the attacker must generate.
In some cases, the data plane can be several orders of magnitude
faster than the control plane at processing packets. This difference
can be exploited to overload the control plane via the data plane
without overloading the data plane.
2.2.10. Passive Monitoring Attacks
An attacker can use pervasive monitoring, which is a technical attack
[RFC 7258] that targets information about LISP traffic that may or may
not be used to mount other types of attacks.
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2.2.11. Multi-category Attacks
Attack categories are not mutually exclusive, and any combination can
be used to perform specific attacks.
For example, one can mount a rogue attack to perform a performance
attack starving the memory of an Ingress Tunnel Router (ITR)
resulting in a DoS on the ITR.
3. Attack Vectors
This section presents attack techniques that may be used by attackers
when leveraging LISP and/or its architecture.
3.1. Gleaning
To reduce the time required to obtain a mapping, the optional
gleaning mechanism defined for LISP allows an xTR (Ingress and/or
Egress Tunnel Router) to directly learn a mapping from the LISP-
encapsulated data packets and the Map-Request packets that it
receives. LISP-encapsulated data packets contain a source RLOC,
destination RLOC, source EID, and destination EID. When an xTR
receives an encapsulated data packet coming from a source EID for
which it does not already know a mapping, it may insert the mapping
between the source RLOC and the source EID in its EID-to-RLOC cache.
The same technique can be used when an xTR receives a Map-Request as
the Map-Request also contains a source EID address and a source RLOC.
Once a gleaned entry has been added to the EID-to-RLOC cache, the xTR
sends a Map-Request to retrieve the actual mapping for the gleaned
EID from the mapping system.
If a packet injected by an off-path attacker and with a spoofed inner
address is gleaned by an xTR, then the attacker may divert the
traffic meant to be delivered to the spoofed EID as long as the
gleaned entry is used by the xTR. This attack can be used as part of
replay, packet manipulation, packet interception and suppression, or
DoS attacks as the packets are sent to the attacker.
If the packet sent by the attacker contains a spoofed outer address
instead of a spoofed inner address, then it can achieve a DoS or a
performance attack as the traffic normally destined to the attacker
will be redirected to the spoofed source RLOC. Such traffic may
overload the owner of the spoofed source RLOC, preventing it from
operating properly.
If the packet injected uses both inner and outer spoofing, the
attacker can achieve a spoofing, a performance, or an amplification
attack as traffic normally destined to the spoofed EID address will
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RFC 7835 LISP Threats April 2016
be sent to the spoofed RLOC address. If the attacked LISP site also
generates traffic to the spoofed EID address, such traffic may have a
positive amplification factor.
A gleaning attack does not only impact the data plane but can also
have repercussions on the control plane as a Map-Request is sent
after the creation of a gleaned entry. The attacker can then achieve
DoS and performance attacks on the control plane. For example, if an
attacker sends a packet for each address of a prefix not yet cached
in the EID-to-RLOC cache of an xTR, the xTR will potentially send a
Map-Request for each such packet until the mapping is installed,
which leads to an over-utilization of the control plane as each
packet generates a control-plane event. In order for this attack to
succeed, the attacker may not need to use spoofing. This issue can
occur even if gleaning is turned off since whether or not gleaning is
used, the ITR may need to send a Map-Request in response to incoming
packets whose EID is not currently in the cache.
Gleaning attacks fundamentally involve a time-shifted mode of
operation as the attack may last as long as the gleaned entry is kept
by the targeted xTR. [RFC 6830] recommends storing the gleaned
entries for only a few seconds, which limits the duration of the
attack.
Gleaning attacks always involve external data-plane attackers but
result in attacks on either the control plane or data plane.
Note that the outer spoofed address does not need to be the RLOC of a
LISP site; it may be any address.
3.2. Locator Status Bits
When the L bit in the LISP header is set to 1, it indicates that the
second 32-bit longword of the LISP header contains the Locator-
Status-Bits (LSBs). In this field, each bit position reflects the
status of one of the RLOCs mapped to the source EID found in the
encapsulated packet. The reaction of a LISP xTR that receives such a
packet is left as an operational choice in [RFC 6830].
When an attacker sends a LISP-encapsulated packet with an
illegitimately crafted LSB to an xTR, it can influence the xTR's
choice of the locators for the prefix associated with the source EID.
In case of an off-path attacker, the attacker must inject a forged
packet in the network with a spoofed inner address. An on-path
attacker can manipulate the LSB of legitimate packets passing through
it and hence does not need to use spoofing. Instead of manipulating
the LSB field, an on-path attacker can also obtain the same result of
injecting packets with invalid LSB values by replaying packets.
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The LSB field can be leveraged to mount a DoS attack by either
declaring all RLOCs as unreachable (all LSBs set to 0), concentrating
all the traffic to one RLOC (e.g., all but one LSB set to 0), and
hence overloading the RLOC concentrating all the traffic from the
xTR, or by forcing packets to be sent to RLOCs that are actually not
reachable (e.g., invert LSB values).
The LSB field can also be used to mount a replay, a packet
manipulation, or a packet interception and suppression attack.
Indeed, if the attacker manages to be on the path between the xTR and
one of the RLOCs specified in the mapping, forcing packets to go via
that RLOC implies that the attacker will gain access to the packets.
Attacks using the LSB fundamentally involve a time-shifted mode of
operation as the attack may last as long as the reachability
information gathered from the LSB is used by the xTR to decide the
RLOCs to be used.
3.3. Map-Version
When the Map-Version bit of the LISP header is set to 1, it indicates
that the low-order 24 bits of the first 32-bit longword of the LISP
header contain a Source and Destination Map-Version. When a LISP xTR
receives a LISP-encapsulated packet with the Map-Version bit set to
1, the following actions are taken:
o It compares the Destination Map-Version found in the header with
the current version of its own configured EID-to-RLOC mapping for
the destination EID found in the encapsulated packet. If the
received Destination Map-Version is smaller (i.e., older) than the
current version, the Egress Tunnel Router (ETR) should apply the
Solicit-Map-Request (SMR) procedure described in [RFC 6830] and
send a Map-Request with the SMR bit set.
o If a mapping exists in the EID-to-RLOC cache for the source EID,
then it compares the Map-Version of that entry with the Source
Map-Version found in the header of the packet. If the stored
mapping is older (i.e., the Map-Version is smaller), than the
source version of the LISP-encapsulated packet, the xTR, should
send a Map-Request for the source EID.
A cross-mode attacker can use the Map-Version bit to mount a DoS
attack, an amplification attack, or a spoofing attack. For instance,
if the mapping cached at the xTR is outdated, the xTR will send a
Map-Request to retrieve the new mapping, which can yield to a DoS
attack (by excess of signaling traffic) or an amplification attack if
the data-plane packet sent by the attacker is smaller, or otherwise
uses fewer resources, than the control-plane packets sent in response
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to the attacker's packet. With a spoofing attack, and if the xTR
considers that the spoofed ITR has an outdated mapping, it will send
an SMR to the spoofed ITR, which can result in a performance,
amplification, or DoS attack as well.
Map-Version attackers are inherently cross-mode as the Map-Version is
a method to put control information in the data plane. Moreover,
this vector involves live attackers. Nevertheless, on-path attackers
do not have a specific advantage over off-path attackers.
3.4. Routing Locator Reachability
The Nonce-Present and Echo-Nonce bits in the LISP header are used to
verify the reachability of an xTR. A testing xTR sets the Echo-Nonce
and the Nonce-Present bits in LISP-encapsulated data packets and
includes a random nonce in the LISP header of the packets. Upon
reception of these packets, the tested xTR stores the nonce and
echoes it whenever it returns a LISP-encapsulated data packet to the
testing xTR. The reception of the echoed nonce confirms that the
tested xTR is reachable.
An attacker can interfere with the reachability test by sending two
different types of packets:
1. LISP-encapsulated data packets with the Nonce-Present bit set and
a random nonce. Such packets are normally used in response to a
reachability test.
2. LISP-encapsulated data packets with the Nonce-Present and the
Echo-Nonce bits both set. These packets will force the receiving
ETR to store the received nonce and echo it in the LISP-
encapsulated packets that it sends. These packets are normally
used as a trigger for a reachability test.
The first type of packets are used to make xTRs think that another
xTR is reachable when it is not. It is hence a way to mount a DoS
attack (i.e., the ITR will send its packet to a non-reachable ETR
when it should use another one).
The second type of packets could be exploited to attack the nonce-
based reachability test. If the attacker sends a continuous flow of
packets that each have a different random nonce, the ETR that
receives such packets will continuously change the nonce that it
returns to the remote ITR, which can yield to a performance attack.
If the remote ITR tries a nonce reachability test, this test may fail
because the ETR may echo an invalid nonce. This hence yields to a
DoS attack.
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In the case of an on-path attacker, a packet manipulation attack is
necessary to mount the attack. To mount such an attack, an off-path
attacker must mount an outer address spoofing attack.
If an xTR chooses to periodically check with active probes the
liveness of entries in its EID-to-RLOC cache (as described in
Section 6.3 of [RFC 6830]), then this may amplify the attack that
caused the insertion of entries being checked.
3.5. Instance ID
LISP allows a 24-bit value called Instance ID to be carried in its
header; it's used on the ITR to indicate which local Instance ID has
been used for encapsulation, while on the ETR, the Instance ID
decides which forwarding table to use to forward the decapsulated
packet in the LISP site.
An attacker (either a control-plane or data-plane attacker) can use
the Instance ID functionality to mount an intrusion attack.
3.6. Interworking
[RFC 6832] defines Proxy-ITR and Proxy-ETR network elements to allow
LISP and non-LISP sites to communicate. The Proxy-ITR has
functionality similar to the ITR; however, its main purpose is to
encapsulate packets arriving from the Default-Free Zone (DFZ) in
order to reach LISP sites. A Proxy Egress Tunnel Router (PETR) has
functionality similar to the ETR; however, its main purpose is to
inject de-encapsulated packets in the DFZ in order to reach non-LISP
sites from LISP sites. As a PITR (or PETR) is a particular case of
ITR (or ETR), it is subject to similar attacks as ITRs (or ETRs).
As any other system relying on proxies, LISP interworking can be used
by attackers to hide their exact origin in the network.
3.7. Map-Request Messages
A control-plane off-path attacker can exploit Map-Request messages to
mount DoS, performance, or amplification attacks. By sending Map-
Request messages at a high rate, the attacker can overload nodes
involved in the mapping system. For instance, sending Map-Requests
at a high rate can considerably increase the state maintained in a
Map-Resolver or consume CPU cycles on ETRs that have to process the
Map-Request packets they receive in their slow path (i.e.,
performance or DoS attack). When the Map-Reply packet is larger than
the Map-Request sent by the attacker, that yields to an amplification
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attack. The attacker can combine the attack with a spoofing attack
to overload the node to which the spoofed address is actually
attached.
Note that if the attacker sets the P bit (Probe Bit) in the Map-
Request, the Map-Request will be legitimately sent directly to the
ETR instead of passing through the mapping system.
The SMR bit can be used to mount a variant of these attacks.
For efficiency reasons, Map-Records can be appended to Map-Request
messages. When an xTR receives a Map-Request with appended Map-
Records, it does the same operations as for the other Map-Request
messages and so is subject to the same attacks. However, it also
installs in its EID-to-RLOC cache the Map-Records contained in the
Map-Request. An attacker can then use this vector to force the
installation of mappings in its target xTR. Consequently, the EID-
to-RLOC cache of the xTR is polluted by potentially forged mappings
allowing the attacker to mount any of the attacks categorized in
Section 2.2 (see Section 3.8 for more details). Note that the
attacker does not need to forge the mappings present in the Map-
Request to achieve a performance or DoS attack. Indeed, if the
attacker owns a large enough EID prefix, it can de-aggregate it in
many small prefixes, each corresponding to another mapping, and it
installs them in the xTR cache by means of the Map-Request.
Moreover, attackers can use Map Resolver and/or Map Server network
elements to relay its attacks and hide the origin of the attack.
Indeed, on the one hand, a Map Resolver is used to dispatch Map-
Request to the mapping system, and on the other hand, a Map Server is
used to dispatch Map-Requests coming from the mapping system to ETRs
that are authoritative for the EID in the Map-Request.
3.8. Map-Reply Messages
Most of the security risks associated with Map-Reply messages will
depend on the 64-bit nonce that is included in a Map-Request and
returned in the Map-Reply. Given the size of the nonce (64 bits), if
a best current practice is used [RFC 4086] and if an ETR does not
accept Map-Reply messages with an invalid nonce, the risk of an off-
path attack is limited. Nevertheless, the nonce only confirms that
the Map-Reply received was sent in response to a Map-Request sent; it
does not validate the contents of that Map-Reply.
If an attacker manages to send a valid (i.e., in response to a Map-
Request and with the correct nonce) Map-Reply to an ITR, then it can
perform any of the attacks categorized in Section 2.2 as it can
inject forged mappings directly in the ITR EID-to-RLOC cache. For
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instance, if the mapping injected to the ITR points to the address of
a node controlled by the attacker, it can mount replay, packet
manipulation, packet interception and suppression, or DoS attacks, as
it will receive every packet destined to a destination lying in the
EID prefix of the injected mapping. In addition, the attacker can
inject a plethora of mappings in the ITR to mount a performance
attack by filling up the EID-to-RLOC cache of the ITR. The attacker
can also mount an amplification attack if the ITR at that time is
sending a large number of packets to the EIDs matching the injected
mapping. In this case, the RLOC address associated with the mapping
is the address of the real target of the attacker, so all the traffic
of the ITR will be sent to the target, which means that with one
single packet the attacker may generate very high traffic towards its
final target.
If the attacker is a valid ETR in the system, it can mount a rogue
attack if it uses prefix overclaiming. In such a scenario, the
attacker ETR replies to a legitimate Map-Request message that it
received with a Map-Reply message that contains an EID prefix that is
larger than the prefix owned by the attacker. For example, if the
owned prefix is 192.0.2.0/25 but the Map-Reply contains a mapping for
192.0.2.0/24, then the mapping will influence packets destined to
EIDs other than the one the attacker has authority on. With such
technique, the attacker can mount the attacks presented above as it
can (partially) control the mappings installed on its target ITR. To
force its target ITR to send a Map-Request, nothing prevents the
attacker to initiate some communication with the ITR. This method
can be used by internal attackers that want to control the mappings
installed in their site. To that aim, they simply have to collude
with an external attacker ready to overclaim prefixes on behalf of
the internal attacker.
Note that when the Map-Reply is in response to a Map-Request sent via
the mapping system (i.e., not sent directly from the ITR to an ETR),
the attacker does not need to use a spoofing attack to achieve its
attack as by design the source IP address of a Map-Reply is not known
in advance by the ITR.
Map-Request and Map-Reply messages are exposed to any type of
attackers, on-path or off-path but also external or internal
attackers. Also, even though they are control messages, they can be
leveraged by data-plane attackers. As the decision of removing
mappings is based on the TTL indicated in the mapping, time-shifted
attackers can take advantage of injecting forged mappings as well.
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3.9. Map-Register Messages
Map-Register messages are sent by ETRs to Map Servers to indicate to
the mapping system the EID prefixes associated with them. The Map-
Register message provides an EID prefix and the list of ETRs that are
able to provide Map-Replies for the EID covered by the EID prefix.
As Map-Register messages are protected by an authentication
mechanism, only a compromised ETR can register itself to its
allocated Map Server.
A compromised ETR can overclaim the prefix it owns in order to
influence the route followed by Map-Requests for EIDs outside the
scope of its legitimate EID prefix (see Section 3.8 for the list of
overclaiming attacks).
A compromised ETR can also de-aggregate its EID prefix in order to
register more EID prefixes than necessary to its Map Servers (see
Section 3.7 for the impact of de-aggregation of prefixes by an
attacker).
Similarly, a compromised Map Server can accept an invalid
registration or advertise an invalid EID prefix to the mapping
system.
3.10. Map-Notify Messages
Map-Notify messages are sent by a Map Server to an ETR to acknowledge
the reception and processing of a Map-Register message.
Similarly, to the pair Map-Request/Map-Reply, the pair Map-Register/
Map-Notify is protected by a nonce making it difficult for an
attacker to inject a falsified notification to an ETR to make this
ETR believe that the registration succeeded when it has not.
4. Note on Privacy
As reviewed in [RFC 6973], universal privacy considerations are
difficult to establish as the privacy definitions may vary for
different scenarios. As a consequence, this document does not aim to
identify privacy issues related to the LISP protocol, but the
security threats identified in this document could play a role in
privacy threats as defined in Section 5 of [RFC 6973].
Similar to public deployments of any other control-plane protocol, in
an Internet deployment, LISP mappings are public and hence provide
information about the infrastructure and reachability of LISP sites
(i.e., the addresses of the edge routers). Depending upon deployment
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RFC 7835 LISP Threats April 2016
details, LISP map replies might or might not provide finer-grained
and more detailed information than is available with currently
deployed routing and control protocols.
5. Threat Mitigation
Most of the above threats can be mitigated with careful deployment
and configuration (e.g., filter) and also by applying the general
rules of security, e.g., only activating features that are necessary
for the deployment and verifying the validity of the information
obtained from third parties.
The control plane is the most critical part of LISP from a security
viewpoint, and it is worth noticing that the LISP specifications
already offer an authentication mechanism for mappings registration
[RFC 6833]. This mechanism, combined with LISP-SEC [LISP-SEC],
strongly mitigates threats in non-trustable environments such as the
Internet. Moreover, an authentication data field for Map-Request
messages and Encapsulated Control messages was allocated [RFC 6830].
This field provides a general authentication mechanism technique for
the LISP control plane that future specifications may use while
staying backward compatible. The exact technique still has to be
designed and defined. To maximally mitigate the threats on the
mapping system, authentication must be used, whenever possible, for
both Map-Request and Map-Reply messages and for messages exchanged
internally among elements of the mapping system, such as specified in
[LISP-SEC] and [LISP-DDT].
Systematically applying filters and rate limitation, as proposed in
[RFC 6830], will mitigate most of the threats presented in this
document. In order to minimize the risk of overloading the control
plane with actions triggered from data-plane events, such actions
should be rate limited.
Moreover, all information opportunistically learned (e.g., with LSB
or gleaning) should be used with care until they are verified. For
example, a reachability change learned with LSB should not be used
directly to decide the destination RLOC but instead should trigger a
rate-limited reachability test. Similarly, a gleaned entry should be
used only for the flow that triggered the gleaning procedure until
the gleaned entry has been verified [Trilogy].
6. Security Considerations
This document provides a threat analysis and proposes mitigation
techniques for the Locator/ID Separation Protocol.
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RFC 7835 LISP Threats April 2016
7. References
7.1. Normative References
[RFC 6830] Farinacci, D., Fuller, V., Meyer, D., and D. Lewis, "The
Locator/ID Separation Protocol (LISP)", RFC 6830,
DOI 10.17487/RFC 6830, January 2013,
<http://www.rfc-editor.org/info/RFC 6830>.
[RFC 6832] Lewis, D., Meyer, D., Farinacci, D., and V. Fuller,
"Interworking between Locator/ID Separation Protocol
(LISP) and Non-LISP Sites", RFC 6832,
DOI 10.17487/RFC 6832, January 2013,
<http://www.rfc-editor.org/info/RFC 6832>.
[RFC 6833] Fuller, V. and D. Farinacci, "Locator/ID Separation
Protocol (LISP) Map-Server Interface", RFC 6833,
DOI 10.17487/RFC 6833, January 2013,
<http://www.rfc-editor.org/info/RFC 6833>.
[RFC 6834] Iannone, L., Saucez, D., and O. Bonaventure, "Locator/ID
Separation Protocol (LISP) Map-Versioning", RFC 6834,
DOI 10.17487/RFC 6834, January 2013,
<http://www.rfc-editor.org/info/RFC 6834>.
[RFC 6973] Cooper, A., Tschofenig, H., Aboba, B., Peterson, J.,
Morris, J., Hansen, M., and R. Smith, "Privacy
Considerations for Internet Protocols", RFC 6973,
DOI 10.17487/RFC 6973, July 2013,
<http://www.rfc-editor.org/info/RFC 6973>.
7.2. Informative References
[LISP-DDT] Fuller, V., Lewis, D., Ermagan, V., and A. Jain, "LISP
Delegated Database Tree", Work in Progress,
draft-ietf-lisp-ddt-03, April 2015.
[LISP-SEC] Maino, F., Ermagan, V., Cabellos-Aparicio, A., and D.
Saucez, "LISP-Security (LISP-SEC)", Work in Progress,
draft-ietf-lisp-sec-10, October 2015.
[PRELIM-LISP-THREAT]
Bagnulo, M., "Preliminary LISP Threat Analysis", Work in
Progress, draft-bagnulo-lisp-threat-01, July 2007.
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RFC 7835 LISP Threats April 2016
[RFC 4086] Eastlake 3rd, D., Schiller, J., and S. Crocker,
"Randomness Requirements for Security", BCP 106, RFC 4086,
DOI 10.17487/RFC 4086, June 2005,
<http://www.rfc-editor.org/info/RFC 4086>.
[RFC 7215] Jakab, L., Cabellos-Aparicio, A., Coras, F., Domingo-
Pascual, J., and D. Lewis, "Locator/Identifier Separation
Protocol (LISP) Network Element Deployment
Considerations", RFC 7215, DOI 10.17487/RFC 7215, April
2014, <http://www.rfc-editor.org/info/RFC 7215>.
[RFC 7258] Farrell, S. and H. Tschofenig, "Pervasive Monitoring Is an
Attack", BCP 188, RFC 7258, DOI 10.17487/RFC 7258, May
2014, <http://www.rfc-editor.org/info/RFC 7258>.
[Trilogy] Saucez, D. and L. Iannone, "How to mitigate the effect of
scans on mapping systems", Trilogy Future Internet Summer
School, 2009.
Acknowledgments
This document builds upon the document by Marcelo Bagnulo
[PRELIM-LISP-THREAT], where the flooding attack and the reference
environment was first described.
The authors would like to thank Ronald Bonica, Deborah Brungard,
Albert Cabellos, Ross Callon, Noel Chiappa, Florin Coras, Vina
Ermagan, Dino Farinacci, Stephen Farrell, Joel Halpern, Emily
Hiltzik, Darrel Lewis, Edward Lopez, Fabio Maino, Terry Manderson,
and Jeff Wheeler for their comments.
This work has been partially supported by the INFSO-ICT-216372
TRILOGY Project <http://www.trilogy-project.org>.
The work of Luigi Iannone has been partially supported by the
ANR-13-INFR-0009 LISP-Lab Project <http://www.lisp-lab.org> and the
EIT KIC ICT-Labs SOFNETS Project.
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Authors' Addresses
Damien Saucez
INRIA
2004 route des Lucioles BP 93
06902 Sophia Antipolis Cedex
France
Email: damien.saucez@inria.fr
Luigi Iannone
Telecom ParisTech
23, Avenue d'Italie, CS 51327
75214 Paris Cedex 13
France
Email: ggx@gigix.net
Olivier Bonaventure
Universite catholique de Louvain
Place St. Barbe 2
Louvain la Neuve
Belgium
Email: olivier.bonaventure@uclouvain.be
Saucez, et al. Informational PAGE 19
RFC TOTAL SIZE: 45107 bytes
PUBLICATION DATE: Saturday, April 30th, 2016
LEGAL RIGHTS: The IETF Trust (see BCP 78)
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