One document matched: draft-ietf-aaa-authorization-reqs-01.txt
Differences from draft-ietf-aaa-authorization-reqs-00.txt
AAA Working Group S. Farrell
INTERNET-DRAFT Baltimore Technologies
Expires in six months J. Vollbrecht
Merit Network, Inc.
P. Calhoun
Sun Microsystems, Inc.
L. Gommans
Cabletron Systems EMEA
G. Gross
Lucent Technologies
B. de Bruijn
Interpay Nederland B.V.
C. de Laat
Utrecht University
M. Holdrege
Lucent Technologies
D. Spence
Merit Network, Inc.
October 1999
AAA Authorization Requirements
<draft-ietf-aaa-authorization-reqs-01.txt>
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of [RFC2026].
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF), its areas, and its working groups. Note that
other groups may also distribute working documents as Internet-
Drafts. Internet-Drafts are draft documents valid for a maximum of
six months and may be updated, replaced, or obsoleted by other
documents at any time. It is inappropriate to use Internet- Drafts
as reference material or to cite them other than as "work in
progress."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt
The list of Internet-Draft Shadow Directories can be accessed at
http://www.ietf.org/shadow.html.
Abstract
This document specifies the requirements that AAA protocols must
meet in order to support authorization services in the Internet. The
requirements have been elicited from a study of a range of
applications including mobile-IP, roamops and others.
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Table Of Contents
Status of this Memo.............................................1
Abstract........................................................1
Table Of Contents...............................................2
1. Introduction.................................................2
2. Requirements.................................................3
2.1 Authorization Information..............................3
2.2 Security of authorization information..................6
2.3 Time...................................................8
2.4 Topology...............................................9
2.5 Application Proxying..................................11
2.6 Trust Model...........................................11
2.7 Not just transactions.................................13
2.8 Administration........................................14
2.9 Bytes on-the-wire.....................................15
2.10 Interfaces............................................16
2.11 Negotiation...........................................16
3. Security Considerations.....................................18
4. References..................................................18
Author's Addresses.............................................19
Full Copyright Statement.......................................20
1. Introduction
<<Comments are in angle-brackets like this. Where text was added
late in the editing process, requirements are marked "late
entrant".>>
The key words "MUST", "REQUIRED", "SHOULD", "RECOMMENDED", and "MAY"
in this document are to be interpreted as described in [RFC2119].
This document is one of a series of three documents prepared by the
AAA WG authorization subgroup dealing with the authorization
requirements for AAA protocols. The three documents are:
AAA Authorization Framework [FRMW]
AAA Authorization Requirements (this document)
AAA Authorization Application Examples [SAMP]
The process followed in producing this document was to analyze the
requirements from [SAMP] based on a common understanding of the AAA
authorization framework [FRMW]. This document assumes familiarity
with both the general issues involved in authorization and, in
particular, the reader will benefit from a reading of [FRMW] where,
for example, definitions of terms can be found.
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2. Requirements
Requirements are grouped under headings for convenience; this
grouping is not significant.
Definitions and explanations of some of the technical terms used in
this document may be found in [FRMW].
Each requirement is presented as a succinct (usually a sentence or
two) statement. Most are followed by a paragraph of explanatory
material, which sometimes contains an example. Fully described
examples may be found in [SAMP].
The requirements presented are not intended to be "orthogonal", that
is, some of them repeat, or overlap, with others.
2.1 Authorization Information
2.1.1 Authorization decisions MUST be able to be based on information
about the requestor, the service/method requested, and the
operating environment (authorization information). AAA protocols
are required to transport this information.
This simply states the requirement for a protocol and an access
decision function, which takes inputs, based on the requestor, the
resource requested and the environment.
2.1.2 It MUST be possible to represent authorization information as
sets of attributes. It MAY be possible to represent authorization
information as objects.
This states that authorization information must be decomposable into
sets of attributes. It is not intended to imply any particular
mechanism for representing attributes.
2.1.3 It MUST be possible to package authorization information so
that the authorization information for multiple services or
applications can be carried in a single message in a AAA or
application protocol.
This states that a protocol, which always required separate AAA
messages/transactions for each service/application, would not meet
the requirement. For example, it should be possible for a single AAA
message/transaction to be sufficient to allow both network and
application access.
2.1.4 Standard attributes types SHOULD be defined which are relevant
to many Internet applications/services (e.g. identity
information, group information, ...)
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There are many attributes that are used in lots of contexts, and
these should only be defined once, in order to promote
interoperability and prevent duplication of effort.
2.1.5 Authorization decisions MUST NOT be limited to being based on
identity information, i.e. AAA protocols MUST support the use of
non-identifying information, e.g. to support role based access
control (RBAC).
Authorization based on clearances, roles, groups or other
information is required to be supported. A AAA protocol that only
carried identity information would not meet the requirement.
2.1.6 Authorization data MAY include limits in addition to attributes
which are directly "owned" by end entities.
This states that some attributes do not simply represent attributes
of an entity, for example a spending limit of IRú1,000 is not an
intrinsic attribute of an entity. This also impacts on the access
decision function, in that the comparison to be made is not a simple
equality match.
2.1.7 It MUST be possible for other (non-AAA) protocols to define
their own attribute types, which can then be carried within an
authorization package in a AAA or application protocol.
This states that the attributes that are significant in an
authorization decision, may be application protocol dependent. For
example, many attribute types are defined by [RFC2138] and support
for the semantics of these attributes will be required. Of course,
only AAA entities that are aware of the added attribute types can
make use of them.
2.1.8 It SHOULD be possible for administrators of deployed systems to
define their own attribute types, which can then be carried within
an authorization package in a AAA or application protocol.
This states that the attributes that are significant in an
authorization decision, may be dependent on a closed environment.
For example, many organizations have a well-defined scheme of
seniority, which can be used to determine access levels. Of course,
only AAA entities that are aware of the added attribute types can
make use of them.
2.1.9 It SHOULD be possible to define new attribute types without
central administration and control of attribute name space.
A centralized or distributed registration scheme of some sort is
needed if collisions in attribute type allocations are to be
avoided. However a AAA protocol which always requires use of such a
centralized registration would not meet the requirement. Of course,
collisions should be avoided where possible.
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2.1.10 It MUST be possible to define attribute types so that an
instance of an attribute in a single AAA message can have multiple
values.
This states that a protocol which does not allow multiple instances
of an attribute in a message/transaction would not meet the
requirement. For example it should be possible to have a "group"
attribute which contains more than one groupname (or number or
whatever).
2.1.11 If MUST be possible to distinguish different instances of the
same authorization attribute type or value, on the basis of
"security domain" or "authority".
This recognizes that it is important to be able to distinguish
between attributes based not only on their value. For example, all
NT domains (which use the English language) have an Administrators
group, an access decision function has to be able to determine to
which of these groups the requestor belongs.
2.1.12 AAA protocols MUST specify mechanisms for updating the rules
which will be used to control authorization decisions.
This states that a AAA protocol that cannot provide a mechanism for
distributing authorization rules is not sufficient. For example,
this could be used to download ACLs to a PDP.
Note that this is not meant to mean that this AAA protocol mechanism
must always be used, simply that it must be available for use. In
particular, storing authorization rules in a trusted repository (in
many cases an LDAP server) will in many cases be used instead of
such a AAA protocol mechanism. Neither does this requirement call
for a standardized format for authorization rules, merely that there
be a mechanism for transporting these.
2.1.13 The AAA protocol MUST allow for chains of AAA entities to be
involved in an authorization decision.
This states that more than one AAA server may have to be involved in
a single authorization decision. This may occur either due to a
decision being spread across more than one "domain" or in order to
distribute authorization within a single "domain".
2.1.14 The AAA protocol MUST allow for intermediate AAA entities to
add their own local authorization information to a AAA request or
response.
This states that where more than one AAA entity is involved in an
authorization decision each of the AAA entities may manipulate the
AAA messages involved either by adding more information or by
processing parts of the information.
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2.1.15 AAA entities MAY be either be deployed independently or
integrated with application entities.
This states that the AAA entities may either be implemented as AAA
servers or integrated with application entities.
2.1.16 The AAA protocol MUST support the creation and encoding of
rules that are to be active inside one AAA server based on
attributes published by another AAA server. The level of
authorization of the requesting AAA Server MAY govern the view on
attributes.
This states that one AAA entity may have to distribute authorization
rules to another, and that the AAA entity that receives the rules
may only be seeing part of the story.
<<late entrant>>
2.1.17 AAA protocols MAY have to support the idea of critical and non-
critical attribute types.
This is analogous to the use of the criticality flag in public key
certificate extensions.
2.1.18 A AAA protocol MUST allow authorization rules to be expressed
in terms of combinations of other authorization rules which have
been evaluated.
For example, access may only be granted if the requestor is member
of the backup users group and not a member of the administrator's
group. Note that this requirement does not state which types of
combinations are to be supported.
2.1.19 It SHOULD be possible to make authorization decisions based on
the geographic location of a requestor, service or AAA entity.
This is just an example of an authorization attribute type, notable
because it requires different underlying implementation mechanisms.
2.1.20 It SHOULD be possible to make authorization decisions based on
the identity or the equipment used by a requestor, service or AAA
entity.
This is just an example of an authorization attribute type, notable
because it may require different underlying implementation
mechanisms (if IPSec isn't available).
<<late entrant>>
2.1.21 When there are multiple instances of a given attribute, there
must be an unambiguous mechanism by which a receiving peer can
determine the value of specified instance.
2.2 Security of authorization information
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2.2.1 It MUST be possible for authorization information to be
communicated securely in AAA and application protocols.
Mechanisms that preserve authenticity, integrity and privacy for
this information MUST be specified.
This states that there must be a well-defined method for securing
authorization information, not that such methods must always be
used. Whether support for these mechanisms is to be required for
conformance is left open. In particular, mechanisms must be provided
so that a service administrator in the middle of a chain cannot read
or change authorization information being sent between other AAA
entities.
2.2.2 AAA protocols MUST allow for use of an appropriate level of
security for authorization information. AAA protocols MUST be able
to support both highly secure and less secure mechanisms for data
integrity/confidentiality etc.
It is important that AAA protocols do not mandate too heavy a
security overhead, thus the security mechanisms specified donÆt
always need to be used (though not using them may affect the
authorization decision).
2.2.3 The security requirements MAY differ between different parts of
a package of authorization information.
Some parts may require confidentiality and integrity, some may only
require integrity. This effectively states that we require something
like selective field security mechanisms. For example, information
required to gain access to a network may have to be in clear, whilst
information required for access to an application within that
network may have to be encrypted in the AAA protocol.
2.2.4 AAA protocols MUST provide mechanisms that prevent intermediate
administrators breaching security.
This is a basic requirement to prevent man-in-the-middle attacks,
for example where an intermediate administrator changes AAA messages
on the fly.
2.2.5 AAA protocols MUST NOT open up replay attacks based on replay
of the authorization information.
For example, a AAA protocol should not allow flooding attacks where
the attacker replays AAA messages that require the recipient to use
a lot of CPU or communications before the replay is detected.
2.2.6 AAA protocols MUST be capable of leveraging any underlying peer
entity authentication mechanisms that may have been applied - this
MAY provide additional assurance that the owner of the
authorization information is the same as the authenticated entity.
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For example, if IPSec provides sufficient authentication, then it
must be possible to omit AAA protocol authentication.
2.2.7 End-to-end confidentiality, integrity, peer-entity-
authentication, or non-repudiation MAY be required for packages of
authorization information.
This states that confidentiality, (resp. the other security
services), may have to be provided for parts of a AAA message, even
where it is transmitted via other AAA entities. It does allow that
such a AAA message may also contain non-confidential, resp. the
other security services), parts. In addition, intermediate AAA
entities may themselves be considered end-points for end-to-end
security services applied to other parts of the AAA message.
2.2.8 AAA protocols MUST be usable even in environments where no peer
entity authentication is required (e.g. a network address on a
secure LAN may be enough to decide).
This requirement (in a sense the opposite of 2.2.6), indicates the
level of flexibility that is required in order to make the AAA
protocol useful across a broad range of applications/services.
2.2.9 AAA protocols MUST specify "secure" defaults for all protocol
options. Implementations of AAA entities MUST use these "secure"
defaults unless otherwise configured/administered.
This states that the out-of-the-box configuration must be "secure",
for example, authorization decisions should result in denial of
access until a AAA entity is configured. Note that the
interpretation of "secure" will vary on a case-by-case basis, though
the principle remains the same.
2.3 Time
2.3.1 Authorization information MUST be timely, which means that it
MUST expire and in some cases MAY be revoked before expiry.
This states that authorization information itself is never to be
considered valid for all time, every piece of authorization
information must have associated either an explicit or implicit
validity period or time-to-live.
2.3.2 AAA protocols MUST provide mechanisms for revoking
authorization information, in particular privileges.
Where the validity or time-to-live is long, it may be necessary to
revoke the authorization information, e.g. where someone leaves a
company. Note that this requirement does not mandate a particular
scheme for revocation, so that it is not a requirement for
blacklists or CRLs.
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2.3.3 A set of attributes MAY have an associated validity period -
such that that the set MUST only be used for authorization
decisions during that period. The validity period may be
relatively long, (e.g. months) or short (hours, minutes).
This states that explicit validity periods are, in some cases,
needed at the field level.
2.3.4 Authorization decisions MAY be time sensitive. Support for e.g.
"working hours" or equivalent MUST be possible.
This states that the AAA protocol must be able to support the
transmission of time control attributes, although it does not
mandate that AAA protocols must include a standard way of expressing
the "working hours" type constraint.
2.3.5 It MUST be possible to support authorization decisions that
produce time dependent results.
For example, an authorization result may be that service should be
provided for a certain period. In such cases a AAA protocol must be
able to transport this information, possibly as a specific result of
the authorization decision, or, as an additional "termination of
service" AAA message transmitted later.
2.3.6 It MUST be possible to support models where the authorization
information is issued in well in advance of an authorization
decision rather than near the time of the authorization decision.
This is required in order to support pre-paid (as opposed to
subscription) scenarios (e.g. for VoIP).
2.3.7 It SHOULD be possible to support models where the authorization
decision is made in advance of a service request.
This is for some applications such as backup, where actions are
scheduled for future dates. It also covers applications that require
reservation of resources.
2.3.8 A AAA mechanism must allow time stamp information to be carried
along with authorization information (e.g. for non-repudiation).
The PKIX WG is developing a time stamp protocol, which can be used
as part of a non-repudiation solution. In some environments it may
be necessary that certain AAA protocol messages are timestamped (by
a trusted authority) and that the timestamps are forwarded within
subsequent AAA messages.
2.4 Topology
2.4.1 AAA protocols MUST be able to support the use of the push, pull
and agent models.
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This states that a protocol that only supported one model, say pull,
would not meet the requirements of all the applications. The models
are defined in [FRMW].
2.4.2 In transactions/sessions, which involve more than one AAA
entity, each æhopÆ MAY use a different push/pull/agent model.
For example, in the mobile IP case, a "foreign" AAA server might
pull authorization information from a broker, whereas the broker
might push some authorization information to a "home" AAA server.
2.4.3 AAA Protocols MUST cater for applications and services where
the entities involved in the application or AAA protocols belong
to different (security) domains.
This states that it must be possible for any AAA protocol message to
cross security or administrative domain boundaries. Typically,
higher levels of security will be applied when crossing such
boundaries, and accounting mechanisms may also have to be more
stringent.
2.4.4 AAA protocols MUST support roaming.
Roaming here may also be thought of as "away-from-home" operation.
For example, this is a fundamental requirement for the mobile IP
case.
2.4.5 AAA protocols SHOULD support dynamic mobility
Dynamic mobility here means that a client moves from one domain to
another, without having to completely re-establish e.g. whatever AAA
session information is being maintained.
2.4.6 An authorization decision MAY have to be made before the
requestor has any other connection to a network.
For example, this means that the requestor canÆt go anywhere on the
network to fetch anything and must do requests via an
application/service or via an intermediate AAA entity. The AAA
protocol should not overexpose such a server to denial-of-service
attacks.
2.4.7 AAA protocols MUST support the use of intermediate AAA entities
which take part in authorization transactions but which donÆt
"own" any of the end entities or authorization data.
In some environments (e.g. roamops), these entities are termed
brokers (though these are not the same as bandwidth brokers in the
QoS environment).
2.4.8 AAA protocols MAY support cases where an intermediate AAA
entity returns a forwarding address to a requestor or AAA entity,
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in order that the requestor or originating AAA entity can contact
another AAA entity.
This requirement recognizes that there will be routing issues with
AAA servers, and that this requires that AAA protocols are able to
help with such routing. For example, in the mobile IP case, a broker
may be required, in part to allow the foreign and home AAA servers
to get in contact.
2.4.9 It MUST be possible for an access decision function to discover
the AAA server of a requestor. If the requestor provides
information used in this discovery process then the access
decision function MUST be able to verify this information in a
trusted manner.
This states that not only do AAA servers have to be able to find one
another, but that sometimes an application entity may have to find
an appropriate AAA server.
2.5 Application Proxying
2.5.1 AAA protocols MUST support cases where applications use
proxies, that is, an application entity (C), originates a service
request to a peer (I) and this intermediary (I) also initiates a
service request on behalf of the client (C) to a final target (T).
AAA protocols MUST be such that the authorization decision made at
T, MAY depend on the authorization information associated with C
and/or with I. This "application proxying" must not introduce new
security weaknesses in the AAA protocols. There MAY be chains of
application proxies of any length.
Note that this requirement addresses application layer proxying -
not chains of AAA servers. For example, a chain of HTTP proxies
might each want to restrict the content they serve to the "outside".
As the HTTP GET message goes from HTTP proxy to HTTP proxy, this
requirement states that it must be possible that the authorization
decisions made at each stage can depend on the user at the browser,
and not say, solely on the previous HTTP proxyÆs identity. Of course
there may only be a single AAA server involved, or there may be
many.
2.5.2 Where there is a chain of application proxies, the AAA protocol
flows at each stage MAY be independent, i.e. the first hop may use
the push model, the second pull, the third the agent model.
This simply restates a previous requirement (no. 2.4.7), to make it
clear that this also applies when application proxying is being
used.
2.6 Trust Model
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2.6.1 AAA entities MUST be able to make decisions about which other
AAA entities are trusted for which sorts of authorization
information.
This is analogous to a requirement in pubic key infrastructures:
Just because someone can produce a cryptographically correct public
key certificate doesnÆt mean that I should trust them for anything,
in particular, I might trust the issuer for some purposes, but not
for others.
2.6.2 AAA protocols MUST allow entities to be trusted for different
purposes, trust MUST NOT be an all-or-nothing issue.
This relates the packaging (no. 2.1.3) and trust (no. 2.6.1)
requirements. For example, a AAA entity may trust some parts of an
authorization package but not others.
2.6.3 A confirmation of authorization MAY be required in order to
initialize or resynchronize a AAA entity.
This states that a AAA entity may need to process some AAA protocol
messages in order to initialize itself. In particular, a AAA entity
may need to check that a previous AAA message remains "valid", e.g.
at boot-time.
2.6.4 A negation of static authorization MAY be required to shut down
certain services.
This is the converse of 2.6.5 above. It means that a AAA entity may
be "told" by another that a previous AAA message is no longer
"valid". See also 2.3.2 and 2.7.6.
2.6.5 It MUST be possible to configure sets of AAA entities that
belong to a local domain, so that they are mutually trusting, but
so that any external trust MUST be via some nominated subset of
AAA entities.
This states that for efficiency or organizational reasons, it must
be possible to set up some AAA servers through which all "external"
AAA services are handled. It also states that it must be possible to
do this without over-burdening the "internal-only" AAA servers with
onerous security mechanisms, just because some AAA servers do handle
external relations.
2.6.6 Intermediate AAA entities in a chain MUST be able to refuse a
connection approved by an earlier entity in the chain.
For example, in mobile IP the home network may authorize a
connection, but the foreign network may refuse to allow the
connection due to the settings chosen by the home network, say if
the home network will refuse to pay.
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2.6.7 It SHOULD be possible to modify authorization for resources
while a session is in progress without destroying other session
information.
For example, a "parent" AAA server should be able to modify the
authorization state of sessions managed by a "child" AAA server, say
by changing the maximum number of simultaneous sessions which are
allowed.
2.7 Not just transactions
2.7.1 Authorization decisions MAY be context sensitive, AAA protocols
MUST enable such decisions.
This states that AAA protocols need to support cases where the
authorization depends, (perhaps even only depends), on the current
state of the system, e.g. only seven sessions allowed, seventh
decision depends on existence of six current sessions. Since the
context might involve more than one service, the AAA protocol is
likely to have to offer some support.
2.7.2 AAA protocols SHOULD support both the authorization of
transactions and continuing authorization of sessions.
This states that AAA entities may have to maintain state and act
when the state indicates some condition has been met.
2.7.3 Within a single session or transaction, it MUST be possible to
interleave authentication, authorization and accounting AAA
messages.
This states, that e.g. a session may have to use initial
authentication, authorization and accounting AAA message(s), but
also have to include e.g. re-authentication every 30 minutes, or a
continuous "drip-drip" of accounting AAA messages.
2.7.4 Authorization decisions may result in a "not ready" answer.
This states that yes and no are not the only outcomes of an
authorization decision. In particular, if the AAA entity cannot yet
give a decision, it might have to return such a result. This is
analogous to how public key certification requests are sometimes
handled in PKI management protocols.
2.7.5 A AAA entity MAY re-direct a AAA request that it has received.
This states that if entity "a" asks "b", then "b" may say: "don't
ask me, ask 'c'". This is analogous to HTTP re-direction (status
code 307).
2.7.6 AAA protocols SHOULD allow a AAA entity to "take back" an
authorization.
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The expectation is that AAA protocols will support the ability of a
AAA entity to signal an application or other AAA entity that an
authorization (possibly previously granted by a third AAA entity) is
no longer valid.
2.8 Administration
2.8.1 It MUST be possible for authorization data to be administered
on behalf of the end entities and AAA entities.
This requirement indicates that administration of AAA has to be
considered as part of protocol design - a AAA protocol, which
required all AAA entities act independent of all other AAA entities,
would not meet the requirement.
2.8.2 Centralizable administration of all features SHOULD be
supported.
It should be possible (if it meets the domain requirements) to
centralize or distribute the administration of AAA.
2.8.3 AAA protocols SHOULD support cases where the user (as opposed
to an administrator) authorizes a transaction.
For example, a user might want to control anti-spam measures or
authorize things like a purchase. In such cases, the user is acting
somewhat like an administrator.
2.8.4 One AAA entity MAY create authorization rules for another AAA
entity.
This is required to properly support delegation of authority,
however when allowed, this must be able to be done in a secure
fashion.
2.8.5 AAA protocols SHOULD support failure recovery when one AAA
entity in a chain of AAA entities that maintain state about a
session fails.
For example, in a network access situation it may be required that a
AAA server which has crashed be able to determine how many sessions
are in progress, in order to make the "next" authorization decision.
2.8.6 It SHOULD be possible for a AAA entity to query the
authorization state of another AAA entity.
This may be required as part of a failure recovery procedure.
2.8.7 AAA protocols MUST be able to support "hot fail-over" for
server components without loss of state information.
This states that AAA protocols must be able to support cases where,
when a server is no longer operable, a secondary server can
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automatically be brought "live" without losing important state
information.
2.9 Bytes on-the-wire
2.9.1 Authorization separate from authentication SHOULD be allowed
when necessary, but the AAA protocols MUST also allow for a single
message to request both authentication and authorization.
AAA protocols have to allow a split between authentication and
authorization so that different mechanisms are used for each. This
states that sometimes both types of information need to be carried
in the same message.
2.9.2 In order to minimize resource usage (e.g. reduce roundtrips) it
MUST be possible to embed AAA PDUs into other protocols.
This states that the AAA protocol authorization packages must be
defined so that they can also be carried in other protocols. For
example, depending on AAA protocol header information in order to
reference an authorization package could cause a protocol to fail to
meet the requirement.
2.9.3 A AAA protocol MAY provide mechanisms for replication of state
information.
This can be required e.g. to support resiliency in cases where hot
fail-over is required. Note that AAA protocols are of course,
subject to normal protocol design requirements to do with
reliability, no single-point-of-failure etc even though these are
not all specified here.
2.9.4 A AAA protocol SHOULD allow the possibility for implementation
of a gateway function between the AAA protocol and other legacy
AAA related protocols.
For example, some form of support for [RFC2138] as a legacy protocol
is very likely to be required. Of course, the use of such a gateway
is almost certain to mean not meeting some other requirements, (e.g.
end-to-end security), for transactions routed through the gateway.
There is no implication that such gateway functionality needs to be
a separate server.
2.9.5 A AAA protocol MUST be able to support use of a wide range of
primitive data types, including RFC2277.
For example, various sized, signed and unsigned integers, possibly
including multi-precision integers will almost certainly need to be
transported. Floating point support according to ANSI IEEE 754-1985
may also be required.
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2.9.6 A AAA protocol transport SHOULD support being optimized for a
long-term exchange of small packets in a stream between a pair of
hosts.
NASes typically have a high number of transactions/second, so the
AAA protocol MUST allow the flow of requests to be controlled in
order for the server to make efficient use of it's receive buffers.
2.9.7 A AAA protocol MUST provide support for load balancing.
In the event that a peer's cannot receive any immediate requests,
the AAA protocol MUST allow for an implementation to balance the
load of requests among a set of peers.
2.10 Interfaces
2.10.1 It SHOULD be possible that authorization data can be used for
application purposes.
For example, in web access, if the authorization data includes a
group name, mechanisms to make this data available to the
application so that it can modify the URL originally requested are
desirable.
2.10.2 It SHOULD be possible that authorization data can be used to
mediate the response to a request.
For example, with web access the clearance attribute value may
affect the content of the HTTP response message.
2.10.3 AAA protocols SHOULD be able to operate in environments where
requestors are not pre-registered (at least for authorization
purposes, but possibly also for authentication purposes).
This is necessary to be able to scale a AAA solution where there are
many requestors.
2.10.4 AAA protocols MUST be able to support a linkage between
authorization and accounting mechanisms.
Motherhood and apple-pie.
2.10.5 AAA protocols MUST be able to support accountability (audit/
non-repudiation) mechanisms.
Sometimes, an authorization decision will be made where the
requestor has not authenticated. In such cases, it must be possible
that the authorization data used is linked to audit or other
accountability mechanisms. Note that this requirement does not call
for mandatory support for digital signatures, or other parts of a
non-repudiation solution.
2.11 Negotiation
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2.11.1 AAA protocols MUST support the ability to refer to sets of
authorization packages in order to allow peers negotiate a common
set.
Given that peers may support different combinations of authorization
attribute types and packages, the requirement states that protocol
support is required to ensure that the peers use packages supported
by both peers.
2.11.2 It MUST be possible to negotiate authorization packages between
AAA entities that are not in direct communication.
This states that where, e.g. a broker is involved, the end AAA
servers might still need to negotiate.
2.11.3 Where negotiation fails to produce an acceptable common
supported set then access MUST be denied.
For example, a server cannot grant access if it cannot understand
the attributes of the requestor.
2.11.4 Where negotiation fails to produce an acceptable common
supported set then it SHOULD be possible to generate an error
indication to be sent to another AAA entity.
If negotiation fails, then some administrator intervention is often
required, and protocol support for this should be provided.
2.11.5 It MUST be possible to pre-provision the result of a
negotiation, but in such cases, the AAA protocol MUST include a
confirmation of the "negotiation result".
Even if the supported packages of a peer are configured, this must
be confirmed before assuming both sides are similarly configured.
2.11.6 For each application making use of a AAA protocol, there MUST
be one inter-operable IETF standards-track specification of the
authorization package types that are "mandatory to implement".
This requirement assures that communicating peers can count on
finding at least one IETF specified inter-operable AAA protocol
dialect provided they are doing authorization for a common
application specific problem domain. This does not preclude the
negotiation of commonly understood but private AAA protocol
authorization package types (e.g. vendor specific).
2.11.7 It SHOULD also be possible to rank AAA negotiation options in
order of preference.
This states that, when negotiating, peers must be able to indicate
preferences as well as capabilities.
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2.11.8 The negotiation mechanisms used by AAA protocols SHOULD NOT be
vulnerable to a "bidding-down" attack.
A "bidding-down" attack is where an attacker forces the negotiating
parties to choose the "weakest" option available. This is analogous
to forcing 40-bit encryption on a link. The requirement highlights
that protocol support is needed to prevent such attacks, for example
by including the negotiation messages as part of a later MAC
calculation, if authentication has produced a shared secret.
<<late entrant>>
2.11.9 A peer MUST NOT send an attribute within an authorization
package or attribute that was not agreed to by a prior successful
negotiation. If this AAA protocol violation occurs, then it MUST
be possible to send an error indication to the misbehaving peer,
and generate an error indication to the network operator.
<<late entrant>>
2.11.10 A peer MUST declare all of the sets of the authorization
packages that it understands in its initial negotiation bid
message.
3. Security Considerations
This document includes specific security requirements.
This document does not state any detailed requirements for the
interplay with authentication, accounting or accountability (audit).
A AAA protocol, which meets all of the above requirements, may still
leave vulnerabilities due to such interactions. Such issues must be
considered as part of AAA protocol design.
4. References
[FRMW] Vollbrecht et al., "AAA Authorization Framework",
draft-ietf-aaa-authz-arch-00.txt, October 1999.
[RFC2026] Bradner, S., "The Internet Standards Process -- Revision
3", RFC 2026, BCP 9, October 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, March 1997.
[RFC2138] Rigney, C., et al., "Remote Authentication Dial In User
Service (RADIUS)", RFC2138, April 1997.
[RFC2277] Alvestrand, H., "IETF Policy on Character Sets and
Languages", RFC2277, January 1998.
[SAMP] Vollbrecht et al., "AAA Authorization Application
Examples", draft-ietf-aaa-authz-samp-00.txt, October
1999.
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Author's Addresses
Stephen Farrell John R. Vollbrecht
Baltimore Technologies Merit Network, Inc.
61/62 Fitzwilliam Lane 4251 Plymouth Rd., Suite 2000
Dublin 2, Ann Arbor, MI 48105
IRELAND USA
Phone: +353-1-647-7300 Phone: +1 734 763 1206
Fax: +353-1-647-7499 Fax: +1 734 647 3745
stephen.farrell@baltimore.ie EMail: jrv@merit.edu
Pat R. Calhoun Leon Gommans
Network and Security Research Cabletron Systems EMEA
Center, Sun Labs Kerkplein 24
Sun Microsystems, Inc. 2841 XM Moordrecht
15 Network Circle The Netherlands
Menlo Park, California, 94025 Phone: +31 182 379278
USA Email: gommans@cabletron.com
Phone: +1 650 786 7733
Fax: +1 650 786 6445
EMail: pcalhoun@eng.sun.com
George M. Gross Betty de Bruijn
Lucent Technologies Interpay Nederland B.V.
184 Liberty Corner Road, m.s. Eendrachtlaan 315
LC2N-D13 3526 LB Utrecht
Warren, NJ 07059 The Netherlands
USA Phone: +31 30 2835104
Phone: +1 908 580 4589 Email: betty@euronet.nl
Fax: +1 908 580 7430
Email: gmgross@lucent.com
Cees T.A.M. de Laat Matt Holdrege
Physics and Astronomy dept. Lucent Technologies
Utrecht University 1701 Harbor Bay Pkwy.
Pincetonplein 5, Alameda, CA 94502
3584CC Utrecht USA
Netherlands Phone: +1 510 747 2711
Phone: +31 30 2534585 Email: holdrege@lucent.com
Phone: +31 30 2537555
EMail: delaat@phys.uu.nl
David W. Spence
Merit Network, Inc.
4251 Plymouth Rd., Suite 2000
Ann Arbor, MI 48105
USA
Phone: +1 734 615 2630
Fax: +1 734 647 3745
EMail: dwspence@merit.edu
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Full Copyright Statement
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