Network Working Group D. Wallner
Request for Comments: 2627 E. Harder
Category: Informational R. Agee
National Security Agency
June 1999
Key Management for Multicast: Issues and Architectures
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (1999). All Rights Reserved.
Abstract
This report contains a discussion of the difficult problem of key
management for multicast communication sessions. It focuses on two
main areas of concern with respect to key management, which are,
initializing the multicast group with a common net key and rekeying
the multicast group. A rekey may be necessary upon the compromise of
a user or for other reasons (e.g., periodic rekey). In particular,
this report identifies a technique which allows for secure compromise
recovery, while also being robust against collusion of excluded
users. This is one important feature of multicast key management
which has not been addressed in detail by most other multicast key
management proposals [1,2,4]. The benefits of this proposed
technique are that it minimizes the number of transmissions required
to rekey the multicast group and it imposes minimal storage
requirements on the multicast group.
It is recognized that future networks will have requirements that
will strain the capabilities of current key management architectures.
One of these requirements will be the secure multicast requirement.
The need for high bandwidth, very dynamic secure multicast
communications is increasingly evident in a wide variety of
commercial, government, and Internet communities. Specifically, the
secure multicast requirement is the necessity for multiple users who
share the same security attributes and communication requirements to
securely communicate with every other member of the multicast group
using a common multicast group net key. The largest benefit of the
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multicast communication being that multiple receivers simultaneously
get the same transmission. Thus the problem is enabling each user to
determine/obtain the same net key without permitting unauthorized
parties to do likewise (initializing the multicast group) and
securely rekeying the users of the multicast group when necessary.
At first glance, this may not appear to be any different than current
key management scenarios. This paper will show, however, that future
multicast scenarios will have very divergent and dynamically changing
requirements which will make it very challenging from a key
management perspective to address.
The networks of the future will be able to support gigabit bandwidths
for individual users, to large groups of users. These users will
possess various quality of service options and multimedia
applications that include video, voice, and data, all on the same
network backbone. The desire to create small groups of users all
interconnected and capable of communicating with each other, but who
are securely isolated from all other users on the network is being
expressed strongly by users in a variety of communities.
The key management infrastructure must support bandwidths ranging
from kilobits/second to gigabits/second, handle a range of multicast
group sizes, and be flexible enough for example to handle such
communications environments as wireless and mobile technologies. In
addition to these performance and communications requirements, the
security requirements of different scenarios are also wide ranging.
It is required that users can be added and removed securely and
efficiently, both individually and in bulk. The system must be
resistant to compromise, insofar as users who have been dropped
should not be able to read any subsequent traffic, even if they share
their secret information. The costs we seek to minimize are time
required for setup, storage space for each end user, and total number
of transmissions required for setup, rekey and maintenance. It is
also envisioned that any proposed multicast security mechanisms will
be implemented no lower than any layer with the characteristics of
the network layer of the protocol stack. Bandwidth efficiency for
any key management system must also be considered. The trade-off
between security and performance of the entire multicast session
establishment will be discussed in further detail later in this
document.
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The following section will explain several potential scenarios where
multicast capabilities may be needed, and quantify their requirements
from both a performance and security perspective. It will be
followed in Section 4.0 by a list of factors one must consider when
designing a potential solution. While there are several security
services that will be covered at some point in this document, much of
the focus of this document has been on the generation and
distribution of multicast group net keys. It is assumed that all
potential multicast participants either through some manual or
automated, centralized or decentralized mechanism have received
initialization keying material (e.g. certificates). This document
does not address the initialization key distribution issue. Section
5 will then detail several potential multicast key management
architectures, manual (symmetric) and public key based (asymmetric),
and highlight their relative advantages and disadvantages (Note:The
list of advantages and disadvantages is by no means all inclusive.).
In particular, this section emphasizes our technique which allows for
secure compromise recovery.
There are a variety of potential scenarios that may stress the key
management infrastructure. These scenarios include, but are not
limited to, wargaming, law enforcement, teleconferencing, command and
control conferencing, disaster relief, and distributed computing.
Potential performance and security requirements, particularly in
terms of multicast groups that may be formed by these users for each
scenario, consists of the potential multicast group sizes,
initialization requirements (how fast do users need to be brought
on-line), add/drop requirements (how fast a user needs to be added or
deleted from the multicast group subsequent to initialization), size
dynamics (the relative number of people joining/leaving these groups
per given unit of time), top level security requirements, and
miscellaneous special issues for each scenario. While some scenarios
describe future secure multicast requirements, others have immediate
security needs.
As examples, let us consider two scenarios, distributed gaming and
teleconferencing.
Distributed gaming deals with the government's need to simulate a
conflict scenario for the purposes of training and evaluation. In
addition to actual communications equipment being used, this concept
would include a massive interconnection of computer simulations
containing, for example, video conferencing and image processing.
Distributed gaming could be more demanding from a key management
perspective than an actual scenario for several reasons. First, the
nodes of the simulation net may be dispersed throughout the country.
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Second, very large bandwidth communications, which enable the
possibility for real time simulation capabilities, will drive the
need to drop users in and out of the simulation quickly. This is
potentially the most demanding scenario of any considered.
This scenario may involve group sizes of potentially 1000 or more
participants, some of which may be collected in smaller subgroups.
These groups must be initialized very rapidly, for example, in a ten
second total initialization time. This scenario is also very
demanding in that users may be required to be added or dropped from
the group within one second. From a size dynamics perspective, we
estimate that approximately ten percent of the group members may
change over a one minute time period. Data rate requirements are
broad, ranging from kilobits per second (simulating tactical users)
to gigabits per second (multicast video). The distributed gaming
scenario has a fairly thorough set of security requirements covering
access control, user to user authentication, data confidentiality,
and data integrity. It also must be "robust" which implies the need
to handle noisy operating environments that are typical for some
tactical devices. Finally, the notion of availability is applied to
this scenario which implies that the communications network supplying
the multicast capability must be up and functioning a specified
percentage of the time.
The teleconference scenario may involve group sizes of potentially
1000 or more participants. These groups may take up to minutes to be
initialized. This scenario is less demanding in that users may be
required to be added or dropped from the group within seconds. From
a size dynamics perspective, we estimate that approximately ten
percent of the group members may change over a period of minutes.
Data rate requirements are broad, ranging from kilobits per second to
100's of Mb per second. The teleconference scenario also has a
fairly thorough set of security requirements covering access control,
user to user authentication, data confidentiality, data integrity,
and non-repudiation. The notion of availability is also applicable
to this scenario. The time frame for when this scenario must be
provided is now.
There are many factors that must be taken into account when
developing the desired key management architecture. Important issues
for key management architectures include level (strength) of
security, cost, initializing the system, policy concerns, access
control procedures, performance requirements and support mechanisms.
In addition, issues particular to multicast groups include:
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1. What are the security requirements of the group members? Most
likely there will be some group controller, or controllers. Do
the other members possess the same security requirements as the
controller(s)?
2. Interdomain issues - When crossing from one "group domain" to
another domain with a potentially different security policy,
which policy is enforced? An example would be two users
wishing to communicate, but having different cryptoperiods
and/or key length policies.
3. How does the formation of the multicast group occur? Will the
group controller initiate the user joining process, or will the
users initiate when they join the formation of the multicast
group?
4. How does one handle the case where certain group members have
inferior processing capabilities which could delay the
formation of the net key? Do these users delay the formation
of the whole multicast group, or do they come on-line later
enabling the remaining participants to be brought up more
quickly?
5. One must minimize the number of bits required for multicast
group net key distribution. This greatly impacts bandwidth
limited equipments.
All of these and other issues need to be taken into account, along
with the communication protocols that will be used which support the
desired multicast capability. The next section addresses some of
these issues and presents some candidate architectures that could be
used to tackle the key management problem for multicasting.
There are several basic functions that must be performed in order for
a secure multicast session to occur. The order in which these
functions will be performed, and the efficiency of the overall
solution results from making trade-offs of the various factors listed
above. Before looking at specific architectures, these basic
functions will be outlined, along with some definition of terms that
will be used in the representative architectures. These definitions
and functions are as follows:
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1. Someone determines the need for a multicast session, sets the
security attributes for that particular session (e.g.,
classification levels of traffic, algorithms to be used, key
variable bit lengths, etc.), and creates the group access
control list which we will call the initial multicast group
participant list. The entity which performs these functions
will be called the INITIATOR. At this point, the multicast
group participant list is strictly a list of users who the
initiator wants to be in the multicast group.
2. The initiator determines who will control the multicast group.
This controller will be called the ROOT (or equivalently the
SERVER). Often, the initiator will become the root, but the
possibility exists where this control may be passed off to
someone other than the initiator. (Some key management
architectures employ multiple roots, see [4].) The root's job
is to perform the addition and deletion of group participants,
perform user access control against the security attributes of
that session, and distribute the traffic encryption key for the
session which we will call the multicast group NET KEY. After
initialization, the entity with the authority to accept or
reject the addition of future group participants, or delete
current group participants is called the LIST CONTROLLER.
This may or may not be the initiator. The list controller has
been distinguished from the root for reasons which will become
clear later. In short, it may be desirable for someone to have
the authority to accept or reject new members, while another
party (the root) would actually perform the function.
3. Every participant in the multicast session will be referred to
as a GROUP PARTICIPANT. Specific group participants other than
the root or list controller will be referred to as LEAVES.
4. After the root checks the security attributes of the
participants listed on the multicast group participant list to
make sure that they all support the required security
attributes, the root will then pass the multicast group list to
all other participants and create and distribute the Net Key.
If a participant on the multicast group list did not meet the
required security attributes, the leaf must be deleted from the
list.
Multiple issues can be raised with the distribution of the
multicast group list and Net Key.
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a. An issue exists with the time ordering of these functions.
The multicast group list could be distributed before or
after the link is secured (i.e. the Net Key is
distributed).
b. An issue exists when a leaf refuses to join the session.
If a leaf refuses to join a session, we can send out a
modified list before sending out the Net Key, however
sending out modified lists, potentially multiple times,
would be inefficient. Instead, the root could continue
on, and would not send the Net Key to those participants
on the list who rejected the session.
For the scenario architectures which follow, we assume the
multicast group list will be distributed to the group
participants once before the Net Key is distributed. Unlike
the scheme described in [4], we recommend that the multicast
group participant list be provided to all leaves. By
distributing this list to the leaves, it allows them to
determine upfront whether they desire to participate in the
multicast group or not, thus saving potentially unnecessary
key exchanges.
Four potential key management architectures to distribute keying
material for multicast sessions are presented. Recall that the
features that are highly desirable for the architecture to possess
include the time required to setup the multicast group should be
minimized, the number of transmissions should be minimized, and
memory/storage requirements should be minimized. As will be seen, the
first three proposals each fall short in a different aspect of these
desired qualities, whereas the fourth proposal appears to strike a
balance in the features desired. Thus, the fourth proposal is the
one recommended for general implementation and use.
Please note that these approaches also address securely eliminating
users from the multicast group, but don't specifically address adding
new users to the multicast group following initial setup because this
is viewed as evident as to how it would be performed.
Through manual key distribution, symmetric key is delivered without
the use of public key exchanges. To set up a multicast group Net Key
utilizing manual key distribution would require a sequence of events
where Net Key and spare Net Keys would be ordered by the root of the
multicast session group. Alternate (supersession) Net Keys are
ordered (by the root) to be used in case of a compromise of a group
participant(s). The Net Keys would be distributed to each individual
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group participant, often through some centralized physical
intermediate location. At some predetermined time, all group
participants would switch to the new Net Key. Group participants use
this Net Key until a predetermined time when they need another new
Net Key. If the Net Key is compromised during this time, the
alternate Net Key is used. Group participants switch to the alternate
Net Key as soon as they receive it, or upon notification from the
root that everyone has the new Net Key and thus the switch over
should take place. This procedure is repeated for each cryptoperiod.
A scheme like this may be attractive because the methods exist today
and are understood by users. Unfortunately, this type of scheme can
be time consuming to set up the multicast group based on time
necessary to order keying material and having it delivered. For most
real time scenarios, this method is much too slow.
This approach is a brute force method to provide a common multicast
group Net Key to the group participants. In this scheme, the
initiator sets the security attributes for a particular session,
generates a list of desired group participants and transmits the list
to all group participants. The leaves then respond with an initial
acceptance or rejection of participation. By sending the list up
front, time can be saved by not performing key exchanges with people
who rejected participation in the session. The root (who for this
and future examples is assumed to be the initiator) generates a
pairwise key with one of the participants (leaves) in the multicast
group using some standard public key exchange technique (e.g., a
Diffie-Hellman public key exchange.) The root will then provide the
security association parameters of the multicast (which may be
different from the parameters of the initial pairwise key) to this
first leaf. Parameters may include items such as classification and
policy. Some negotiation (through the use of a Security Association
Management Protocol, or SAMP) of the parameters may be necessary.
The possibility exists for the leaf to reject the connection to the
multicast group based on the above parameters and multicast group
list. If the leaf rejects this session, the root will repeat this
process with another leaf.
Once a leaf accepts participation in the multicast session, these two
then choose a Net Key to be used by the multicast group. The Net Key
could be generated through another public key exchange between the
two entities, or simply chosen by the root, depending upon the policy
which is in place for the multicast group ( i.e. this policy decision
will not be a real time choice). The issue here is the level of
trust that the leaf has in the root. If the initial pairwise key
exchange provides some level of user authentication, then it seems
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adequate to just have the root select the Net Key at this stage.
Another issue is the level of trust in the strength of the security
of the generated key. Through a cooperative process, both entities
(leaf and root) will be providing information to be used in the
formation of the Net Key.
The root then performs a pairwise key exchange with another leaf and
optionally performs the negotiation discussed earlier. Upon
acceptance by the leaf to join the multicast group, the root sends
the leaf the Net Key.
This pairwise key exchange and Net Key distribution continues for all
N users of the multicast group.
Root/leaves cache pairwise keys for future use. These keys serve as
Key Encryption Keys (KEKs) used for rekeying leaves in the net at a
later time. Only the root will cache all of the leaves' pairwise
keys. Each individual leaf will cache only its own unique pairwise
Key Encryption Key.
There are two cases to consider when caching the KEKs. The first
case is when the Net key and KEK are per session keys. In this case,
if one wants to exclude a group participant from the multicast
session (and rekey the remaining participants with a new Net Key),
the root would distribute a new Net key encrypted with each
individual KEK to every legitimate remaining participant. These KEKs
are deleted once the multicast session is completed.
The second case to consider is when the KEKs are valid for more than
one session. In this case, the Net Key may also be valid for
multiple sessions, or the Net Key may still only be valid for one
session as in the above case. Whether the Net Key is valid for one
session or more than one session, the KEK will be cached. If the Net
Key is only valid per session, the KEKs will be used to encrypt new
Net Keys for subsequent multicast sessions. The deleting of group
participants occurs as in the previous case described above,
regardless of whether the Net Key is per session or to be used for
multiple sessions.
A scheme like this may be attractive to a user because it is a
straightforward extension of certifiable public key exchange
techniques. It may also be attractive because it does not involve
third parties. Only the participants who are part of the multicast
session participate in the keying mechanism. What makes this scheme
so undesirable is that it will be transmission intensive as we scale
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up in numbers, even for the most computationally efficient
participants, not to mention those with less capable hardware
(tactical, wireless, etc.). Every time the need arises to drop an
"unauthorized" participant, a new Net Key must be distributed.
This distribution requires a transmission from the Root to each
remaining participant, whereby the new Net Key will be encrypted
under the cover of each participant's unique pairwise Key Encryption
Key (KEK).
Note: This approach is essentially the same as one proposal to the
Internet Engineering Task Force (IETF) Security Subworking Group [Ref
1,2].
Also note that there exist multiple twists to an approach like this.
For example, instead of having the root do all N key exchanges, the
root could pass some of this functionality (and control) to a number
of leaves beneath him. For example, the multicast group list could
be split in half and the root tells one leaf to take half of the
users and perform a key exchange with them (and then distribute the
Net key) while the root will take care of the other half of the list.
(The chosen leaves are thus functioning as a root and we can call
them "subroots." These subroots will have leaves beneath them, and
the subroots will maintain the KEK of each leaf beneath it.) This
scales better than original approach as N becomes large.
Specifically, it will require less time to set up (or rekey) the
multicast net because the singular responsibility of performing
pairwise key exchanges and distributing Net Key will be shared among
multiple group participants and can be performed in parallel, as
opposed to the root only distributing the Net Key to all of the
participants.
This scheme is not without its own security concerns. This scheme
pushes trust down to each subgroup controller - the root assumes that
these "subroot" controllers are acting in a trustworthy way. Every
control element (root and subroots) must remain in the system
throughout the multicast. This effectively makes removing someone
from the net (especially the subroots) harder and slower due to the
distributed control. When removing a participant from the multicast
group which has functioned on behalf of the root, as a subroot, to
distribute Net Key, additional steps will be necessary. A new
subroot must be delegated by the root to replace the removed subroot.
A key exchange (to generate a new pairwise KEK) must occur between
the new subroot and each leaf the removed subroot was responsible
for. A new Net Key will now be distributed from the root, to the
subroots, and to the leaves. Note that this last step would have
been the only step required if the removed party was a leaf with no
controlling responsibilities.
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Let us suppose we have N leaves. The Root performs a public key
exchange with each leaf i (i= 1,2, ..., N). The Root will cache each
pairwise KEK. Each leaf stores their own KEK. The root would provide
the multicast group list of participants and attributes to all users.
Participants would accept or reject participation in the multicast
session as described in previous sections. The root encrypts the Net
Key for the Multicast group to each leaf, using their own unique
KEK(i). (The Root either generated this Net Key himself, or
cooperatively generated with one of the leaves as was discussed
earlier). In addition to the encrypted Net Key, the root will also
encrypt something called complementary variables and send them to the
leaves.
A leaf will NOT receive his own complementary variable, but he will
receive the other N-1 leaf complementary variables. The root sends
the Net Key and complementary variables j, where j=1,2,...,N and j
not equal to i, encrypted by KEK(i) to each leaf. Thus, every leaf
receives and stores N variables which are the Net key, and N-1
complementary variables.
Thus to cut a user from the multicast group and get the remaining
participants back up again on a new Net Key would involve the
following. Basically, to cut leaf number 20 out of the net, one
message is sent out that says "cut leaf 20 from the net." All of the
other leaves (and Root) generate a new Net Key based on the current
Net Key and Complementary variable 20. [Thus some type of
deterministic key variable generation process will be necessary for
all participants of the multicast group]. This newly generated
variable will be used as the new Net Key by all remaining
participants of the multicast group. Everyone except leaf 20 is able
to generate the new Net Key, because they have complementary variable
20, but leaf 20 does not.
A scheme like this seems very desirable from the viewpoint of
transmission savings since a rekey message encrypted with each
individual KEK to every leaf does not have to be sent to delete
someone from the net. In other words, there will be one plaintext
message to the multicast group versus N encrypted rekey messages.
There exists two major drawbacks with this scheme. First are the
storage requirements necessary for the (N-1) complementary variables.
Secondly, when deleting multiple users from the multicast group,
collusion will be a concern. What this means is that these deleted
users could work together and share their individual complementary
variables to regain access to the multicast session.
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The Hierarchical Tree Approach is our recommended approach to address
the multicast key management problem. This approach provides for the
following requisite features:
1. Provides for the secure removal of a compromised user from the
multicast group
2. Provides for transmission efficiency
3. Provides for storage efficiency
This approach balances the costs of time, storage and number of
required message transmissions, using a hierarchical system of
auxiliary keys to facilitate distribution of new Net Key. The result
is that the storage requirement for each user and the transmissions
required for key replacement are both logarithmic in the number of
users, with no background transmissions required. This approach is
robust against collusion of excluded users. Moreover, while the
scheme is hierarchical in nature, no infrastructure is needed beyond
a server (e.g., a root), though the presence of such elements could
be used to advantage (See Figure 1).
--------------------------
| |
| S E R V E R |
| |
--------------------------
| | |
| | . . . . |
- - -
|1| |2| |n|
- - -
Figure 1: Assumed Communication Architecture
The scheme, advantages and disadvantages are enumerated in more
detail below. Consider Figure 2 below. This figure illustrates the
logical key distribution architecture, where keys exist only at the
server and at the users. Thus, the server in this architecture would
hold Keys A through O, and the KEKs of each user. User 11 in this
architecture would hold its own unique KEK, and Keys F, K, N, and O.
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RFC 2627 Key Management for Multicast June 1999
net key Key O
-------------------------------------
intermediate | |
keys | |
Key M Key N
----------------- --------------------
| | | |
| | | |
Key I Key J Key K Key L
-------- -------- --------- ----------
| | | | | | | |
| | | | | | | |
Key A Key B Key C Key D Key E Key F Key G Key H
--- --- --- --- --- ---- ---- ----
| | | | | | | | | | | | | | | |
- - - - - - - - - -- -- -- -- -- -- --
|1| |2| |3| |4| |5| |6| |7| |8| |9| |10| |11| |12| |13| |14| |15| |16|
- - - - - - - - - -- -- -- -- -- -- --
users
Figure 2: Logical Key Distribution Architecture
We now describe the organization of the key hierarchy and the setup
process. It will be clear from the description how to add users
after the hierarchy is in place; we will also describe the removal of
a user. Note: The passing of the multicast group list and any
negotiation protocols is not included in this discussion for
simplicity purposes.
We construct a rooted tree (from the bottom up) with one leaf
corresponding to each user, as in Figure 2. (Though we have drawn a
balanced binary tree for convenience, there is no need for the tree
to be either balanced or binary - some preliminary analysis on tree
shaping has been performed.) Each user establishes a unique pairwise
key with the server. For users with transmission capability, this can
be done using the public key exchange protocol. The situation is more
complicated for receive-only users; it is easiest to assume these
users have pre-placed key.
Once each user has a pairwise key known to the server, the server
generates (according to the security policy in place for that
session) a key for each remaining node in the tree. The keys
themselves should be generated by a robust process. We will also
assume users have no information about keys they don't need. (Note:
There are no users at these remaining nodes, (i.e., they are logical
nodes) and the key for each node need only be generated by the server
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via secure means.) Starting with those nodes all of whose children
are leaves and proceeding towards the root, the server transmits the
key for each node, encrypted using the keys for each of that node's
children. At the end of the process, each user can determine the
keys corresponding to those nodes above her leaf. In particular, all
users hold the root key, which serves as the common Net Key for the
group. The storage requirement for a user at depth d is d+1 keys
(Thus for the example in Figure 2, a user at depth d=4 would hold
five keys. That is, the unique Key Encryption Key generated as a
result of the pairwise key exchange, three intermediate node keys -
each separately encrypted and transmitted, and the common Net Key for
the multicast group which is also separately encrypted.)
It is also possible to transmit all of the intermediate node keys and
root node key in one message, where the node keys would all be
encrypted with the unique pairwise key of the individual leaf. In
this manner, only one transmission (of a larger message) is required
per user to receive all of the node keys (as compared to d
transmissions). It is noted for this method, that the leaf would
require some means to determine which key corresponds to which node
level.
It is important to note that this approach requires additional
processing capabilities at the server where other alternative
approaches may not. In the worst case, a server will be responsible
for generating the intermediate keys required in the architecture.
Suppose that User 11 (marked on Figure 2 in black) needs to be
deleted from the multicast group. Then all of the keys held by User
11 (bolded Keys F, K, N, O) must be changed and distributed to the
users who need them, without permitting User 11 or anyone else from
obtaining them. To do this, we must replace the bolded keys held by
User 11, proceeding from the bottom up. The server chooses a new key
for the lowest node, then transmits it encrypted with the appropriate
daughter keys (These transmissions are represented by the dotted
lines). Thus for this example, the first key replaced is Key F, and
this new key will be sent encrypted with User 12's unique pairwise
key.
Since we are proceeding from the bottom up, each of the replacement
keys will have been replaced before it is used to encrypt another
key. (Thus, for the replacement of Key K, this new key will be sent
encrypted in the newly replaced Key F (for User 12) and will also be
sent as one multicast transmission encrypted in the node key shared
by Users 9 and 10 (Key E). For the replacement of Key N, this new key
will be sent encrypted in the newly replaced Key K (for Users 9, 10,
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and 12) and will also be encrypted in the node key shared by Users
13, 14, 15, and 16 (Key L). For the replacement of Key O, this new
key will be sent encrypted in the newly replaced Key N (for Users 9,
10, 12, 13, 14, 15, and 16) and will also be encrypted in the node
key shared by Users 1, 2 , 3, 4, 5, 6, 7, and 8 (Key M).) The number
of transmissions required is the sum of the degrees of the replaced
nodes. In a k-ary tree in which a sits at depth d, this comes to at
most kd-1 transmissions. Thus in this example, seven transmissions
will be required to exclude User 11 from the multicast group and to
get the other 15 users back onto a new multicast group Net Key that
User 11 does not have access to. It is easy to see that the system
is robust against collusion, in that no set of users together can
read any message unless one of them could have read it individually.
If the same strategy is taken as in the previous section to send
multiple keys in one message, the number of transmissions required
can be reduced even further to four transmissions. Note once again
that the messages will be larger in the number of bits being
transmitted. Additionally, there must exist a means for each leaf to
determine which key in the message corresponds to which node of the
hierarchy. Thus, in this example, for the replacement of keys F, K,
N, and O to User 12, the four keys will be encrypted in one message
under User 12's unique pairwise key. To replace keys K, N, and O for
Users 9 and 10, the three keys will be encrypted in one message under
the node key shared by Users 9 and 10 (Key E). To replace keys N and
O for Users 13, 14, 15, 16, the two keys will be encrypted in one
message under the node key shared by Users 13, 14, 15, and 16 (Key
L). Finally, to replace key O for Users 1, 2 , 3, 4, 5, 6, 7, and 8,
key O will be encrypted under the node key shared by Users 1, 2 , 3,
4, 5, 6, 7, and 8 (Key M). Thus the number of transmission required
is at most (k-1)d.
The following table demonstrates the removal of a user, and how the
storage and transmission requirements grow with the number of users.
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Table 1: Storage and Transmission Costs
Number Degree Storage per user Transmissions to Transmissions
of users (k) (d+1) rekey remaining to rekey
participants of remaining
multicast group- participants of
one key per message multicast
(kd-1) group -
multiple keys
per message
(k-1)d
8 2 4 5 3
9 3 3 5 4
16 2 5 7 4
2048 2 12 21 11
2187 3 8 20 14
131072 2 18 33 17
177147 3 12 32 22
The benefits of a scheme such as this are:
1. The costs of user storage and rekey transmissions are balanced
and scalable as the number of users increases. This is not the
case for [1], [2], or [4].
2. The auxiliary keys can be used to transmit not only other keys,
but also messages. Thus the hierarchy can be designed to place
subgroups that wish to communicate securely (i.e. without
transmitting to the rest of the large multicast group) under
particular nodes, eliminating the need for maintenance of
separate Net Keys for these subgroups. This works best if the
users operate in a hierarchy to begin with (e.g., military
operations), which can be reflected by the key hierarchy.
3. The hierarchy can be designed to reflect network architecture,
increasing efficiency (each user receives fewer irrelevant
messages). Also, server responsibilities can be divided up
among subroots (all of which must be secure).
4. The security risk associated with receive-only users can be
minimized by collecting such users in a particular area of the
tree.
5. This approach is resistant to collusion among arbitrarily many
users.
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As noted earlier, in the rekeying process after one user is
compromised, in the case of one key per message, each replaced key
must be decrypted successfully before the next key can be replaced
(unless users can cache the rekey messages). This bottleneck could
be a problem on a noisy or slow network. (If multiple users are being
removed, this can be parallelized, so the expected time to rekey is
roughly independent of the number of users removed.)
By increasing the valences and decreasing the depth of the tree, one
can reduce the storage requirements for users at the price of
increased transmissions. For example, in the one key per message
case, if n users are arranged in a k-ary tree, each user will need
storage. Rekeying after one user is removed now requires
transmissions. As k approaches n, this approaches the pairwise key
scheme described earlier in the paper.
The Hierarchical Tree Approach outlined in this section could be
distributed as indicated in Section 5.2 to more closely resemble the
proposal put forth in [4]. Subroots could exist at each of the nodes
to handle any joining or rekeying that is necessary for any of the
subordinate users. This could be particularly attractive to users
which do not have a direct connection back to the Root. Recall as
indicated in Section 5.2, that the trust placed in these subroots to
act with the authority and security of a Root, is a potentially
dangerous proposition. This thought is also echoed in [4].
Some practical recommendations that might be made for these subroots
include the following. The subroots should not be allowed to change
the multicast group participant list that has been provided to them
from the Root. One method to accomplish this, would be for the Root
to sign the list before providing it to the subroots. Authorized
subroots could though be allowed to set up new multicast groups for
users below them in the hierarchy.
It is important to note that although this distribution may appear to
provide some benefits with respect to the time required to initialize
the multicast group (as compared to the time required to initialize
the group as described in Section 5.4) and for periodic rekeying, it
does not appear to provide any benefit in rekeying the multicast
group when a user has been compromised.
It is also noted that whatever the key management scheme is
(hierarchical tree, distributed hierarchical tree, core based tree,
GKMP, etc.), there will be a "hit" incurred to initialize the
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multicast group with the first multicast group net key. Thus, the
hierarchical tree approach does not suffer from additional complexity
with comparison to the other schemes with respect to initialization.
Although this paper has presented the formation of the multicast
group as being Root initiated, the hierarchical approach is
consistent with user initiated joining. User initiated joining is
the method of multicast group formation presented in [4]. User
initiated joining may be desirable when some core subset of users in
the multicast group need to be brought up on-line and communicating
more quickly. Other participants in the multicast group can then be
brought in when they wish. In this type of approach though, there
does not exist a finite period of time by when it can be ensured all
participants will be a part of the multicast group.
For example, in the case of a single root, the hierarchy is set up
once, in the beginnning, by the initiator (also usually the root) who
also generates the group participant list. The group of keys for each
participant can then be individually requested (pulled) as soon as,
but not until, each participant wishes to join the session.
In the multicast environment, the possibility exists that
participants of the group at times may want to uniquely identify
which participant is the sender of a multicast group message. In the
multicast key distribution system described by Ballardie [4], the
notion of "sender specific keys" is presented.
Another option to allow participants of a multicast group to uniquely
determine the sender of a message is through the use of a signature
process. When a member of the multicast group signs a message with
their own private signature key, the recipients of that signed
message in the multicast group can use the sender's public
verification key to determine if indeed the message is from who it is
claimed to be from.
Another related idea to this is the case when two users of a
multicast group want to communicate strictly with each other, and
want no one else to listen in on the communication. If this
communication relationship is known when the multicast group is
originally set up, then these two participants could simply be placed
adjacent to one another at the lowest level of the hierarchy (below a
binary node). Thus, they would naturally share a secret pairwise
key. Otherwise, a simple way to accomplish this is to perform a
public key based pairwise key exchange between the two users to
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generate a traffic encryption key for their private unicast
communications. Through this process, not only will the encrypted
transmissions between them be readable only by them, but unique
sender authentication can be accomplished via the public key based
pairwise exchange.
Encryption Keys
Reference [4] makes use of a Group Key Encryption Key that can be
shared by the multicast group for use in periodic rekeys of the
multicast group. Aside from the potential security drawbacks of
implementing a shared key for encrypting future keys, the use of a
Group Key Encryption Key is of no benefit to a multicast group if a
rekey is necessary due to the known compromise of one of the members.
The strategy for rekeying the multicast group presented in Section
5.4.1 specifically addresses this critical problem and offers a means
to accomplish this task with minimal message transmissions and
storage requirements.
The question though can now be asked as to whether the rekey of a
multicast group will be necessary in a non-compromise scenario. For
example, if a user decides they do not want to participate in the
group any longer, and requests the list controller to remove them
from the multicast group participant list, will a rekey of the
multicast group be necessary? If the security policy of the
multicast group mandates that deleted users can no longer receive
transmissions, than a rekey of a new net key will be required. If
the multicast group security policy does not care that the deleted
person can still decrypt any transmissions (encrypted in the group
net key that they might still hold), but does care that they can not
encrypt and transmit messages, a rekey will once again be necessary.
The only alternative to rekeying the multicast group under this
scenario would require a recipient to check every received message
sender, against the group participant list. Thus rejecting any
message sent by a user not on the list. This is not a practical
option. Thus it is recommended to always rekey the multicast group
when someone is deleted, whether it is because of compromise reasons
or not.
As indicated in Section 2, the need may arise to remove users in
bulk. If the users are setup as discussed in Section 5.4.1 into
subgroups that wish to communicate securely all being under the same
node, bulk user removal can be done quite simply if the whole node is
to be removed. The same technique as described in Section 5.4.1 is
performed to rekey any shared node key that the remaining
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participants hold in common with the removed node.
The problem of bulk removal becomes more difficult when the
participants to be removed are dispersed throughout the tree.
Depending on how many participants are to be removed, and where they
are located within the hierarchy, the number of transmissions
required to rekey the multicast group could be equivalent to brute
force rekeying of the remaining participants. Also the question can
be raised as to at what point the remaining users are restructured
into a new hierarchical tree, or should a new multicast group be
formed. Restructuring of the hierarchical tree would most likely be
the preferred option, because it would not necessitate the need to
perform pairwise key exchanges again to form the new user unique
KEKs.
Thus far this document has had a major focus on the architectural
trade-offs involved in the generation, distribution, and maintenance
of traffic encryption keys (Net Keys) for multicast groups. There
are other elements involved in the establishment of a secure
connection among the multicast participants that have not been
discussed in any detail. For example, the concept of being able to
"pick and choose" and negotiating the capabilities of the key
exchange mechanism and various other elements is a very important and
necessary aspect.
The NSA proposal to the Internet Engineering Task Force (IETF)
Security Subworking Group [Ref. 3] entitled "Internet Security
Association and Key Management Protocol (ISAKMP)" has attempted to
identify the various functional elements required for the
establishment of a secure connection for the largest current network,
the Internet. While the proposal has currently focused on the
problem of point to point connections, the functional elements should
be the same for multicast connections, with appropriate changes to
the techniques chosen to implement the individual functional
elements. Thus the implementation of ISAKMP is compatible with the
use of the hierarchical tree approach.
As discussed in this report, there are two main areas of concern when
addressing solutions for the multicast key management problem. They
are the secure initialization and rekeying of the multicast group
with a common net key. At the present time, there are multiple
papers which address the initialization of a multicast group, but
they do not adequately address how to efficiently and securely remove
a compromised user from the multicast group.
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This paper proposed a hierarchical tree approach to meet this
difficult problem. It is robust against collusion, while at the same
time, balancing the number of transmissions required and storage
required to rekey the multicast group in a time of compromise.
It is also important to note that the proposal recommended in this
paper is consistent with other multicast key management solutions
[4], and allows for multiple options for its implementation.
1. Harney, H., Muckenhirn, C. and T. Rivers, "Group Key Management
Protocol Architecture", RFC 2094, September 1994.
2. Harney, H., Muckenhirn, C. and T. Rivers, "Group Key Management
Protocol Specification", RFC 2093, September 1994.
3. Maughan, D., Schertler, M. Schneider, M. and J.Turner, "Internet
Security Association and Key Management Protocol, Version 7",
February 1997.
4. Ballardie, T., "Scalable Multicast Key Distribution", RFC 1949,
May 1996.
5. Wong, C., Gouda, M. and S. Lam, "Secure Group Communications Using
Key Graphs", Technical Report TR 97-23, Department of Computer
Sciences, The University of Texas at Austin, July 1997.
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Authors' Addresses
Debby M. Wallner
National Security Agency
Attn: R2
9800 Savage Road STE 6451
Ft. Meade, MD. 20755-6451
Phone: 301-688-0331
EMail: dmwalln@orion.ncsc.mil
Eric J. Harder
National Security Agency
Attn: R2
9800 Savage Road STE 6451
Ft. Meade, MD. 20755-6451
Phone: 301-688-0850
EMail: ejh@tycho.ncsc.mil
Ryan C. Agee
National Security Agency
Attn: R2
9800 Savage Road STE 6451
Ft. Meade, MD. 20755-6451
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RFC 2627 Key Management for Multicast June 1999
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