Internet DRAFT - draft-ietf-sip-session-policy-framework
draft-ietf-sip-session-policy-framework
SIPPING Working Group V. Hilt
Internet-Draft Bell Labs/Alcatel-Lucent
Intended status: Standards Track G. Camarillo
Expires: August 23, 2011 Ericsson
J. Rosenberg
jdrosen.net
February 19, 2011
A Framework for Session Initiation Protocol (SIP) Session Policies
draft-ietf-sip-session-policy-framework-10
Abstract
Proxy servers play a central role as an intermediary in the Session
Initiation Protocol (SIP) as they define and impact policies on call
routing, rendezvous, and other call features. This document
specifies a framework for SIP session policies that provides a
standard mechanism by which a proxy can define or influence policies
on sessions, such as the codecs or media types to be used. It
defines a model, an overall architecture and new protocol mechanisms
for session policies.
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
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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."
This Internet-Draft will expire on August 23, 2011.
Copyright Notice
Copyright (c) 2011 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
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publication of this document. Please review these documents
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 6
3. Session-Independent Policies . . . . . . . . . . . . . . . . . 6
3.1. Architecture and Overview . . . . . . . . . . . . . . . . 6
3.2. Policy Subscription . . . . . . . . . . . . . . . . . . . 7
3.2.1. UAC Behavior . . . . . . . . . . . . . . . . . . . . . 7
3.2.2. UAS Behavior . . . . . . . . . . . . . . . . . . . . . 9
4. Session-Specific Policies . . . . . . . . . . . . . . . . . . 9
4.1. Architecture . . . . . . . . . . . . . . . . . . . . . . . 9
4.2. Overview . . . . . . . . . . . . . . . . . . . . . . . . . 10
4.3. Examples . . . . . . . . . . . . . . . . . . . . . . . . . 12
4.3.1. Offer in Request . . . . . . . . . . . . . . . . . . . 12
4.3.2. Offer in Response . . . . . . . . . . . . . . . . . . 14
4.4. UA/Policy Server Rendezvous . . . . . . . . . . . . . . . 16
4.4.1. UAC Behavior . . . . . . . . . . . . . . . . . . . . . 16
4.4.2. Proxy Behavior . . . . . . . . . . . . . . . . . . . . 18
4.4.3. UAS Behavior . . . . . . . . . . . . . . . . . . . . . 20
4.4.4. Caching the Local Policy Server URI . . . . . . . . . 21
4.4.5. Header Field Definition and Syntax . . . . . . . . . . 22
4.5. Policy Channel . . . . . . . . . . . . . . . . . . . . . . 24
4.5.1. Creation and Management . . . . . . . . . . . . . . . 24
4.5.2. Contacting the Policy Server . . . . . . . . . . . . . 25
4.5.3. Using Session Policies . . . . . . . . . . . . . . . . 27
5. Security Considerations . . . . . . . . . . . . . . . . . . . 28
6. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 29
6.1. Registration of the "Policy-Id" Header Field . . . . . . . 29
6.2. Registration of the "Policy-Contact" Header Field . . . . 30
6.3. Registration of the "non-cacheable" Policy-Contact
Header Field Parameter . . . . . . . . . . . . . . . . . . 30
6.4. Registration of the "policy" SIP Option-Tag . . . . . . . 30
7. References . . . . . . . . . . . . . . . . . . . . . . . . . . 31
7.1. Normative References . . . . . . . . . . . . . . . . . . . 31
7.2. Informative References . . . . . . . . . . . . . . . . . . 32
Appendix A. Acknowledgements . . . . . . . . . . . . . . . . . . 32
Appendix B. Session-Specific Policies - Call Flows . . . . . . . 33
B.1. Offer in Invite . . . . . . . . . . . . . . . . . . . . . 33
B.2. Offer in Response . . . . . . . . . . . . . . . . . . . . 35
B.3. Multiple Policy Servers for UAS . . . . . . . . . . . . . 36
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Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 37
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1. Introduction
The Session Initiation Protocol (SIP) [RFC3261] is a signaling
protocol for creating, modifying and terminating multimedia sessions.
A central element in SIP is the proxy server. Proxy servers are
intermediaries that are responsible for request routing, rendezvous,
authentication and authorization, mobility, and other signaling
services. However, proxies are divorced from the actual sessions -
audio, video, and session-mode messaging - that SIP establishes.
Details of the sessions are carried in the payload of SIP messages,
and are usually described with the Session Description Protocol (SDP)
[RFC4566].
Experience has shown that there is a need for SIP intermediaries to
impact aspects of a session. For example, SIP can be used in a
wireless network, which has limited resources for media traffic.
During periods of high activity, the wireless network provider could
want to restrict the amount of bandwidth available to each user.
With session policies, an intermediary in the wireless network can
inform the user agent about the bandwidth it has available. This
information enables the user agent to make an informed decision about
the number of streams, the media types, and the codecs it can
successfully use in a session. Similarly, a network provider can
have a service level agreement with a user that defines the set of
media types the user can use. With session policies, the network can
convey the current set of policies to user agents, enabling them to
set up sessions without inadvertently violating any of the network
policies.
In another example, a SIP user agent is using a network which is
connected to the public Internet through a firewall or a network
border device. The network provider would like to tell the user
agent that it needs to send its media streams to a specific IP
address and port on the firewall or border device to reach the public
Internet. Knowing this policy enables the user agent to set up
sessions across the firewall or the network border. In contrast to
other methods for inserting a media intermediary, the use of session
policies does not require the inspection or modification of SIP
message bodies.
Domains often have the need to enforce the session policies they have
in place. For example, a domain might have a policy that disallows
the use of video and can have an enforcement mechanism that drops all
packets containing a video encoding. Unfortunately, these
enforcement mechanisms usually do not inform the user about the
policies they are enforcing. Instead, they silently keep the user
from doing anything against them. This can lead to a malfunctioning
of devices that is incomprehensible to the user. With session
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policies, the user knows about the current network policies and can
set up policy-compliant sessions or simply connect to a domain with
less stringent policies. Thus, session policies provide an important
combination of consent coupled with enforcement. That is, the user
becomes aware of the policy and needs to act on it, but the provider
still retains the right to enforce the policy.
Two types of session policies exist: session-specific policies and
session-independent policies. Session-specific policies are policies
that are created for one particular session, based on the session
description of this session. They enable a network intermediary to
examine the session description a UA is proposing and to return a
policy specifically for this session description. For example, an
intermediary could open pinholes in a firewall/NAT for each media
stream in the proposed session description. It can then return a
policy for the session description that replaces the IP addresses and
ports of the UA with the ones opened in the firewall/NAT that are
reachable from external. Session-specific policies provide
information about a specific session to a domain, which can be used
to implement policies for opening pinholes on a firewall/NAT. Since
session-specific policies are tailored to a session, they only apply
to the session they are created for. Session-specific policies are
created on a session-by-session basis at the time the session is
established.
Session-independent policies on the other hand are policies that are
created independent of a session and generally apply to all SIP
sessions set up by a user agent. A session-independent policy can,
for example, be used to inform user agents about an existing
bandwidth limit or media type restrictions. Since these policies are
not based on a specific session description, they can be created
independent of an attempt to set up a session and only need to be
conveyed to the user agent when it initializes (e.g., at the time the
device is powered on) and when policies are changed.
This specification defines a framework for SIP session policies. It
specifies a model, the overall architecture and new protocol
mechanisms that are needed for session-independent and session-
specific policies. Since session-specific and session-independent
policies have different requirements, this specification defines two
different mechanisms to deliver them to user agents. These
mechanisms are independent of each other and, depending on whether
one or both types of session policies are needed, it is possible to
use the session-specific or the session-independent mechanism or both
to deliver policies to user agents.
It is RECOMMENDED that UAs and intermediaries use the mechanisms
defined in this specification for signaling session policies to
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endpoints. To ensure backwards compatibility with UAs that do not
support this specification, intermediaries may choose to resort to
existing mechanisms such as rejecting sessions that are not policy
compliant with a 488 response as a fallback solution if a UA does not
indicate support for session policies. UAs that do not support
session policies will receive the same user experience as they would
today. As these techniques are known to have many drawbacks it is
RECOMMENDED that UAs and intermediaries use explicit signaling of
policies using the mechanisms defined in this specification.
2. Terminology
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [RFC2119].
3. Session-Independent Policies
Session-independent policies are policies that are created
independent of a session and generally apply to all sessions a user
agent is setting up. They typically remain stable for a longer
period of time and apply to any session set up while they are valid.
However, it is possible for session-independent policies to change
over time. For example, a policy that defines a bandwidth limit for
a user can change during the day, defining a lower limit during peak
hours and allow more bandwidth off-peak. The policy server informs a
UA when session-independent policies change.
3.1. Architecture and Overview
+-------------+
/------| policy |
+----+ / | server 1 |
| |---/ +-------------+
| UA | ...
| |---\ +-------------+
+----+ \ | policy |
\------| server n |
+-------------+
Figure 1
A SIP UA can receive session-independent policies from one or more
policy servers. In a typical configuration, a UA receives session-
independent policies from a policy server in the local network domain
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(i.e., the domain from which the UA receives IP service) and possibly
the SIP service provider domain (i.e., the domain the UA registers
at). The local network can have policies that support the access
network infrastructure. For example, in a wireless network where
bandwidth is scarce, a provider can restrict the bandwidth available
to an individual user. The SIP service provider can have policies
that are needed to support services or policies that reflect the
service level agreement with the user. Thus, in most cases, a UA
will receive session-independent policies from one or two policy
servers.
Setting up session-independent policies involves the following steps:
1. A user agent discovers session-independent policy servers in the
local network and SIP service provider domain
2. A user agent requests session-independent policies from the
discovered policy servers. A user agent typically requests these
policies when it starts up or connects to a new network domain.
3. The policy server selects the policies that apply to this user
agent. The policy server can have general policies that apply to
all users or maintain separate policies for each individual user.
The selected policies are returned to the user agent.
4. The policy server can update the policies, for example, when
network conditions change.
3.2. Policy Subscription
3.2.1. UAC Behavior
A UA that supports session-independent policies compliant to this
specification MUST attempt to retrieve session-independent policies
from the local network and the SIP service provider domain, unless
the UA knows (e.g., through configuration) that a domain does not
provide session-independent policies (in which case the UA SHOULD NOT
retrieve session-independent policies from this specific domain).
A UA that supports session-independent policies compliant to this
specification MUST support the retrieval of session-independent
policies from the local network and the SIP service provider domain
using the "ua-profile" event package defined in the Framework for SIP
User Agent Profile Delivery [I-D.ietf-sipping-config-framework]. The
UA MAY support other methods of retrieving session-independent
policies from local network and SIP service provider domain.
The "ua-profile" event package [I-D.ietf-sipping-config-framework]
provides a mechanism to subscribe to session-independent policies. A
UA subscribes to the policy server in the local network domain using
the procedures defined for the "local-network" profile-type. The UA
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uses the procedures defined for the "user" profile type to subscribe
to the policy server in the SIP service provider domain.
A UA (re-)subscribes to session-independent policies when the
following events occur:
o The UA registers a new address-of-record (AoR) or removes a AoR
from the set of AoRs it has registered. In these cases, the UA
MUST establish subscriptions for each new AoR using the "user" and
the "local-network" profile-types. The UA MUST terminate all
subscriptions for AoRs it has removed.
o The UA changes the domain it is connected to. The UA MUST
terminate all existing subscriptions for the "local-network"
profile-type. The UA MUST then create a new subscription for each
AoR it maintains using the "local-network" profile-type. This
way, the UA stops receiving policies from the previous local
domain and starts to receive the policies of the new local domain.
The UA does not need to change the subscriptions for "user"
profiles.
If a UA is unable to establish a subscription, the UA SHOULD NOT
attempt to re-try this subscription, unless one of the above events
occurs again. This is to limit the number of SUBSCRIBE requests sent
within domains that do not support session-independent policies.
However, a UA SHOULD retry the subscription with a longer time
interval (e.g., once every 24 hours). This enables UAs to detect new
policies that are deployed in a network that previously did not have
policies.
A UA that supports session-independent policies compliant to this
specification MUST support the User Agent Profile Data Set for Media
Policy [I-D.ietf-sipping-media-policy-dataset]. To indicate that the
UA wants to receive session-independent policies, the UA includes the
MIME type "application/media-policy-dataset+xml" in the Accept header
field of a SUBSCRIBE request.
A UA MUST apply the session-independent policies it has received and
use these policies in the session descriptions it creates. If the UA
decides not to use the received policies, then the UA MUST NOT set up
a session unless it changes the domain that provided these policies.
A UA MAY try to connect to another local network and/or SIP service
provider domain with a different set of policies.
If a UA receives both session-independent and session-specific
policies, the UA MUST apply the session-independent policies to the
session description before the session description is sent to the
session-specific policy server (see Section 4). Thus, session-
independent policies are always applied before session-specific
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policies are retrieved.
3.2.2. UAS Behavior
A policy server MAY send a notification to the UA every time the
session-independent policies covered by the subscription change. The
definition of what causes a policy to change is at the discretion of
the administrator. A change in the policy can be triggered, for
example, by a change in the network status, by the change in the time
of day or by an update of the service level agreement with the
customer.
4. Session-Specific Policies
Session-specific policies are policies that are created specifically
for one particular session of a UA. Thus, session-specific policies
will typically be different for different sessions. The session-
specific policies for a session can change during the course of the
session. For example, a user can run out of credit during a session,
which will cause the network to disallow the transmission all media
streams from this point on.
4.1. Architecture
domain 1
+-----------+
/------| proxy |----...
+----+ / +-----------+
| |---/ +-----------+
| | | policy |
| UA |============| server |
| | +-----------+
| |**** +-----------+
+----+ * | policy |
*******|enforcement|****...
+-----------+
--- SIP Signaling
=== Policy Channel
*** Media
Figure 2
The following entities are needed for session-specific policies (see
Figure 2): a user agent (UA), a proxy, a policy server and possibly a
policy enforcement entity.
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The role of the proxy is to provide a rendezvous mechanism for UAs
and policy servers. It ensures that each UA has the URI [RFC3986] of
the policy server in its domain and knows where to retrieve policies
from. The proxy conveys the policy server URI to UAs in case they
have not yet received it (e.g., in a previous call or through
configuration). The proxy does not deliver the actual policies to
UAs.
The policy server is a separate logical entity that can be physically
co-located with the proxy. The role of the policy server is to
deliver session policies to UAs. The policy server receives session
information from the UA, uses this information to determine the
policies that apply to the session and returns these policies to the
UA. The mechanism for generating policies (i.e., making policy
decisions) is outside of the scope of this specification. A policy
server can, for example, query an external entity to get policies or
it can directly incorporate a policy decision point and generate
policies locally.
A UA receives the URI of a policy server from a proxy. It uses this
URI to contact the policy server. It provides information about the
current session to the policy server and receives session policies in
response. The UA can also receive policy updates from the policy
server during the course of a session.
A network can have a policy enforcement infrastructure in place.
However, this specification does not make any assumptions about the
enforcement of session policies and the mechanisms defined here are
orthogonal to a policy enforcement infrastructure.
In principle, each domain that is traversed by SIP signaling messages
can define session-specific policies for a session. Each domain
needs to run a policy server and a proxy that is able to rendezvous a
UA with the policy server (as shown in Figure 2). However, it is
expected that session-specific policies will often only be provided
by the local domain of the user agent.
4.2. Overview
The protocol defined in this specification clearly separates SIP
signaling and the exchange of policies. SIP signaling is only used
to rendezvous the UA with the policy server. From this point on, UA
and policy server communicate directly with each other over a
separate policy channel. This is opposed to a piggyback model, where
the exchange of policy information between endpoint and a policy
server in the network is piggybacked onto the SIP signaling messages
that are exchanged between endpoints.
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The main advantage of using a separate policy channel is that it
decouples signaling between endpoints from the policy exchange
between an endpoint and a policy server. This decoupling has a
number of desirable properties. It enables the use of separate
encryption mechanisms on the signaling path to secure the
communication between endpoints, and on the policy channel to secure
the communication between endpoint and policy server. Policies can
be submitted directly from the policy server to the endpoint and do
not travel along the signaling path, possibly crossing many domains.
Endpoints set up a separate policy channel to each policy server and
can disclose the information requested by the specific policy server
(e.g., offer or offer/answer). Finally, policy servers do not need
to rely on a SIP signaling message flowing by to send policies or
policy updates to an endpoint. A policy server can use the policy
channel at any time to update session policies as needed. A
disadvantage of the separate channel model is that it requires
additional messages for the exchange of policy information.
Following this model, signaling for session-specific policies
involves the following two fundamental tasks:
1. UA/policy server rendezvous: a UA setting up a session needs to
be able to discover the policy servers that are relevant to this
session.
2. Policy channel: once the UA has discovered the relevant policy
servers for a session, it needs to connect to these servers,
disclose session information and retrieve the policies that apply
to this session.
The communication between UA and policy server on the policy channel
involves the following steps:
1. A user agent submits information about the session it is trying
to establish to the policy server and asks whether a session
using these parameters is permissible.
2. The policy server generates a policy decision for this session
and returns the decision to the user agent. Possible policy
decisions are (1) to deny the session, (2) to propose changes to
the session parameters with which the session would be
acceptable, or (3) to accept the session as it was proposed.
3. The policy server can update the policy decision at a later time.
A policy decision update can, for example, propose additional
changes to the session (e.g., change the available bandwidth) or
deny a previously accepted session (i.e., disallow the
continuation of a session).
In many cases, the mechanism for session-specific policies will be
used to disclose session information and return session policies.
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However, some scenarios only involve the disclosure of session
information to a network intermediary. If an intermediary does not
intend to return a policy, it can simply accept the session as it was
proposed. Similarly, some session-specific policies only apply to
the offer (and therefore only require the disclosure of the offer)
whereas others apply to offer and answer. Both types of policies are
supported by session-specific policy mechanism.
4.3. Examples
This section provides two examples to illustrate the overall
operation of session-specific policies. The call flows depict the
rendezvous mechanism between UA and policy server and indicate the
points at which the UA exchanges policy information with the policy
server.
The example is based on the following scenario: there are two domains
(domain A and domain B), which both have session-specific policies
for the UAs in their domain. Both domains do not provide policies to
the UAs outside of their domain. The two domains have a proxy (P A
and P B) and a policy server (PS A and PS B). The policies in both
domains involve the session description offer and answer.
4.3.1. Offer in Request
The first call flow shown in Figure 3 depicts an INVITE transaction
with the offer in the request. It is assumed that this is the first
INVITE request the UAC creates in this domain and that it therefore
does not have previous knowledge about the policy server URIs in this
domain.
(1) UA A sends an INVITE request to proxy P A. P A knows that
policies apply to this session and (2) returns a 488 (Not Acceptable
Here) response to UA A. P A includes the URI of PS A in the 488 (Not
Acceptable Here) response. This step is needed since the UAC has no
prior knowledge about the URI of PS A. (3) UA A uses the URI to
contact PS A, discloses the session description offer to PS A and (4)
receives policies for the offer. (5) UA A reformulates the INVITE
request under consideration of the received policies and includes a
Policy-Id header field to indicate that it has already contacted PS
A. P A does not reject the INVITE request this time and removes the
Policy-Id header field when forwarding the INVITE request. P B adds
a Policy-Contact header field containing the URI of PS B. (6) UA B
uses this URI to contact PS B and disclose the offer and the answer
it is about to send. (7) UA B receives policies from PS B and applies
them to the offer and answer respectively. (8) UA B returns the
updated answer in the 200 (OK) response. (9) UA A contacts PS A again
with the current offer and answer and (10) retrieves the policies for
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both from PS A.
UA A P A P B UA B
| | | |
| INVITE offer | | |
|---------------->| | | (1)
| 488 | | |
| + Policy-Contact| | |
|<----------------| | | (2)
| ACK | | |
|---------------->| | |
| | PS A | |
| | | |
| PolicyChannel | | |
| + InfoOffer | | |
|------------------->| | | (3)
| PolicyChannel | | |
| + PolicyOffer | | |
|<-------------------| | | (4)
| | | |
| | | |
| INVITE offer' | INVITE offer' | INVITE offer' |
| + Policy-Id | | + Policy-Contact|
|---------------->|--------------->|---------------->| (5)
| | | |
| | PS B | |
| | | |
| | | PolicyChannel |
| | | + InfoOffer' |
| | | + InfoAnswer |
| | |<-------------------| (6)
| | | PolicyChannel |
| | | + PolicyOffer |
| | | + PolicyAnswer |
| | |------------------->| (7)
| | | |
| | | |
| OK answer' | OK answer' | OK answer' |
|<----------------|<---------------|<----------------| (8)
| ACK |
|--------------------------------------------------->|
| | | |
| | | |
| PolicyChannel | | |
| + InfoOffer' | | |
| + InfoAnswer' | | |
|------------------->| | | (9)
| PolicyChannel | | |
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| + PolicyOffer | | |
| + PolicyAnswer | | |
|<-------------------| | | (10)
| | | |
Figure 3
4.3.2. Offer in Response
The call flow shown in Figure 4 depicts an INVITE transaction with
the offer in the response.
(1) UA A sends an INVITE request without an offer to proxy P A and
(2) P A returns a 488 (Not Acceptable Here) response containing the
URI of PS A. (3),(4) UA A uses this policy server URI to set up the
policy channel. At this time, UA A does not disclose a session
description since it does not have the offer yet. (5) UA A re-sends
the INVITE request and includes a Policy-Id header field to indicate
that it has contacted PS A. P A does not reject the INVITE request
this time and removes the Policy-Id header field when forwarding the
INVITE request. P B adds a Policy-Contact header field containing
the URI of PS B. (6) UA B uses this URI to discloses the offer to PS
B. (7) UA B receives policies from PS B and applies them to the
offer. (8) UA B returns the updated offer the 200 (OK) response.
(9),(10) UA A contacts PS and discloses the offer and the answer it
is about to send. An important difference to the flow in the
previous example is that UA A performs steps (9) and (10) before
returning the answer in step (11). This enables UA A to return the
final answer in the ACK request, which includes all applicable
policies. However, it requires that PS A immediately returns a
policy to avoid a delay in the transmission of the ACK request.
(12),(13) UA B again sends the current offer and answer to PS B and
applies the policies it receives to both before using them.
UA A P A P B UA B
| | | |
| INVITE | | |
|---------------->| | | (1)
| 488 | | |
| + Policy-Contact| | |
|<----------------| | | (2)
| ACK | | |
|---------------->| | |
| | PS A | |
| | | |
| PolicyChannel | | |
|------------------->| | | (3)
| PolicyChannel | | |
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|<-------------------| | | (4)
| | | |
| | | |
| INVITE | INVITE | INVITE |
| + Policy-Id | | + Policy-Contact|
|---------------->|--------------->|---------------->| (5)
| | | |
| | PS B | |
| | | |
| | | PolicyChannel |
| | | + InfoOffer |
| | |<-------------------| (6)
| | | PolicyChannel |
| | | + PolicyOffer |
| | |------------------->| (7)
| | | |
| | | |
| OK offer' | OK offer' | OK offer' |
|<----------------|<---------------|<----------------| (8)
| | | |
| | | |
| PolicyChannel | | |
| + InfoOffer' | | |
| + InfoAnswer | | |
|------------------->| | | (9)
| PolicyChannel | | |
| + PolicyOffer | | |
| + PolicyAnswer | | |
|<-------------------| | | (10)
| | | |
| ACK answer' |
|--------------------------------------------------->| (11)
| | | |
| | | |
| | | PolicyChannel |
| | | + InfoOffer' |
| | | + InfoAnswer' |
| | |<-------------------| (12)
| | | PolicyChannel |
| | | + PolicyOffer |
| | | + PolicyAnswer |
| | |------------------->| (13)
| | | |
Figure 4
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4.4. UA/Policy Server Rendezvous
The first step in setting up session-specific policies is to
rendezvous the UAs with the relevant policy servers. This is
achieved by providing the URIs of all policy servers relevant for a
session to the UAs.
4.4.1. UAC Behavior
A UAC compliant to this specification MUST include a Supported header
field with the option tag "policy" into all requests that can
initiate an offer/answer exchange [RFC3264] (e.g., INVITE, UPDATE
[RFC3311] and PRACK [RFC3262] requests). The UAC MUST include the
"policy" option tag into these requests even if the particular
request does not contain an offer or answer (e.g., an INVITE request
without an offer). A UAC MAY include the "policy" option tag into
all requests.
A UAC can receive a 488 (Not Acceptable Here) response that contains
a Policy-Contact header field. The Policy-Contact header field is a
new header field defined in this specification. It contains one (or
multiple alternative) URIs for a policy server. A 488 (Not
Acceptable Here) response with this header field is generated by a
proxy to convey an URI of the local policy server to the UAC. After
receiving a 488 (Not Acceptable Here) response with a Policy-Contact
header field, a UAC compliant to this specification needs to decide
if it wants to continue with the session now knowing that there is a
policy server. If the UAC decides to continue, the UAC MUST use one
of the policy server URIs to contact the policy server using the
mechanism defined in Section 4.5.
The Policy-Contact header can contain multiple URIs each with a
different URI scheme and containing an "alt-uri" parameter with
identical values. These URIs represent alternative policy channel
mechanisms for obtaining the same policy. The UAC chooses one of the
alternative URIs to use to obtain the policy. The UAC MAY take as a
hint the order of the alternative URIs as indicating a preference as
to which URI to use. The topmost URI in the list might be more
preferred by the domain of the proxy for use to obtain the policy.
After receiving policies from the policy server, the UAC decides if
it wants to accept these policies or not. If the UAC accepts these
policies, the UAC MUST apply them to the current request and resend
the updated request. If no changes are required by policies or no
policies have been received, the request can be resent without any
policy-induced changes. If the UAC decides that the list of policy
servers or the received session policies are unacceptable, then the
UAC MUST NOT resend the request.
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To protect the integrity of the policy server URI in a Policy-Contact
header field, the UAC SHOULD use a secured transport protocol such as
Transport Layer Security (TLS) [RFC5246] between UAC and proxy.
The UAC MUST insert a Policy-Id header field into requests for which
it has contacted a policy server and accepted the policies received.
The Policy-Id header field is a new header field that is defined in
this specification. The UA MUST create a Policy-Id header field
value for each policy server it has contacted during the preparation
of the request. A Policy-Id header field value contains two pieces
of information: the policy server URI and an optional token. The
policy server URI is the URI the UA has used to contact the policy
server. The token is an opaque string the UAC can receive from the
policy server. A token can, for example, be contained in the policy
document [I-D.ietf-sipping-media-policy-dataset]. If the UAC has
received a token from the policy server the UAC MUST include the
token in the Policy-Id header field. The format of the Policy-Id
header field is defined in Section 4.4.5.
The main purpose of the Policy-Id header field is to enable a proxy
to determine if the UAC already knows an URI of the local policy
server. If the policy server URI is not yet known to the UAC, the
proxy can convey this URI to the UAC by rejecting the request with a
488 (Not Acceptable Here) response.
In some cases, a request can traverse multiple domains with a
session-policy server. Each of these domains can return a 488 (Not
Acceptable Here) response containing a policy server URI. A UAC
contacts a policy server after receiving a 488 (Not Acceptable Here)
response from a domain and before re-sending the request. This
creates an implicit order between the policy servers in multiple
domains. I.e., a UAC contacts the first policy server, re-sends the
modified request, contacts the second policy server, re-sends the
modified request and so on. This way, session policies are always
applied to a request in the order in which the request traverses
through the domains. The UAC MUST NOT change this implicit order
among policy servers.
A UAC frequently needs to contact the policy server in the local
domain before setting up a session. To avoid the retransmission of
the local policy server URI in a 488 (Not Acceptable Here) response
for each new request, a UA SHOULD maintain a cache that contains the
URI of the policy server in the local domain (see Section 4.4.4).
The UAC SHOULD use the cached policy server URI to contact the local
policy server before sending a request that initiates the offer/
answer exchange for a new session (e.g., an INVITE request). The UAC
SHOULD NOT cache a policy server URI that is in a different domain
than the UAC even if it is the first policy server URI returned. The
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first policy server URI returned can be from another domain if the
local domain does not have a policy server. Note that UACs perform
exact domain comparisons. That is, foo.example.com and example.com
are not considered equivalent.
UAs can re-negotiate the session description during a session by
initiating a subsequent offer/answer exchange, e.g., in an INVITE,
UPDATE or PRACK request. When creating such a mid-dialog request, a
UA SHOULD contact all policy servers to which it has established a
policy channel during the initial offer/answer exchange (see
Section 4.5) before sending the request. This avoids the
retransmission of all policy server URIs in 488 (Not Acceptable Here)
responses for mid-dialog requests.
4.4.2. Proxy Behavior
A proxy provides rendezvous functionalities for UAs and policy
server. This is achieved by conveying the URI of a policy server to
the UAC or the UAS (or both) when processing INVITE, UPDATE or PRACK
requests (or any other request that can initiate an offer/answer
exchange).
If an offer/answer exchange initiating request contains a Supported
header field with the option tag "policy", the proxy MAY reject the
request with a 488 (Not Acceptable Here) response to provide the
local policy server URI to the UAC. Before rejecting a request, the
proxy MUST verify that the request does not contain a Policy-Id
header field with the local policy server URI as a value. If the
request does not contain such a header field or a local policy server
URI is not present in this header field, then the proxy MAY reject
the request with a 488 (Not Acceptable Here) response. The proxy
MUST insert a Policy-Contact header field in the 488 (Not Acceptable
Here) response that contains one (or multiple) URIs of its associated
policy server. The proxy MAY add the header field parameter "non-
cacheable" to prevent the UAC from caching this policy server URI
(see Section 4.4.4).
More than one URI for the policy server using different URI schemes
MAY be provided by the proxy as alternative URIs to contact the
policy. If a proxy includes multiple URIs for the same policy, the
proxy MUST include an "alt-uri" parameter for all policy server URIs
that are alternatives for obtaining the same policy. The "alt-uri"
parameter MUST contain either the domain name of the domain for which
all the alternative policy server URIs relate to or a FQDN (e.g., the
hostname of a policy server). All URIs that are alternatives for the
same policy MUST have the same value for the "alt-uri" parameter.
The value used for the "alt-uri" parameter MUST be such that the same
value will not be included with other policy server URIs that a UA
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needs to contact by any other proxy within the same domain or another
domain. A method to create a new unique "alt-uri" parameter value is
to examine the value of existing "alt-uri" parameters and to make
sure that the new value differs. A proxy MAY hint to a UA at a
preference as to which URI to use by including the more preferred URI
higher in the list than the other alternative URIs. URIs with the
same "alt-uri" parameter MUST use different URI schemes. A SIP or
SIPS URI MUST be included even if other URI schemes are defined and
used in the future.
If a local policy server URI is present in a Policy-Id header field
value of a request, then the proxy MUST NOT reject the request as
described above (it can still reject the request for other reasons).
The proxy SHOULD remove the Policy-Id header field value of its
associated policy server from the Policy-Id header field before
forwarding the request. Not removing the Policy-Id header field
value will not cause harm, however, the value is not relevant to any
other proxy on the path and only increases message size. It also
would disclose the policy server URI to subsequent proxies.
The Policy-Id header field serves two main purposes: first and most
importantly, it enables the proxy to determine if a UAC already knows
the URI of the local policy server. The second purpose of the
Policy-Id header field is to enable a domain to route all requests
that belong to the same session (i.e., the initial request and
requests a UA retransmits after contacting the policy server) to the
same proxy and policy server. This is important if a domain has
multiple proxy/policy server combinations (e.g., in a proxy/policy
server farm that receives requests through a load balancer), which
create per-session state in the network. An example for such a
scenario is a policy server that is associated with a session border
device. The policy server configures the session border device after
receiving a session description from the UAC via the policy channel.
Retransmitted requests for such a session need to be routed to the
same proxy/policy server as the initial request since this proxy/
policy server combination has configured the associated border device
for the session.
Routing all requests that belong to the same session to the same
proxy can be achieved by using the Policy-Id header field token. It
requires that the policy server returns a token to the UAC that
uniquely identifies the specific proxy/policy server combination.
The UAC includes this token in the Policy-Id header field and it can
be used (together with the policy server URI) by the proxies in this
domain to route the request along the desired path. The format of
this token does not require standardization. The only requirement is
that the token provides sufficient information for proxies to route
the message inside a domain to the desired proxy/policy server. The
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token can, for example, be a numeric identifier or an IP address.
Note: it has been proposed to use the Policy-Id header field to
provide a hint for a proxy that the UAC has actually contacted the
policy server. This usage also requires the policy server to
return a token to the UA. In addition, the policy server needs to
share valid tokens with the proxy. After receiving a request with
a Policy-Id header field, the proxy can determine if the token in
the Policy-Id header field is valid. If it is valid, the proxy
knows that the UA has contacted the policy server for this
session. However, this token does not provide any proof that the
UA has actually used the policies it has received from the policy
server. A malicious UA can simply contact the policy server,
discard all policies it receives but still use the token in the
Policy-Id header field.
The proxy MAY insert a Policy-Contact header field into INVITE,
UPDATE or PRACK requests (or any other request that can initiate an
offer/answer exchange) in order to convey the policy server URI to
the UAS. If the request already contains a Policy-Contact header
field, the proxy MUST insert the URI after all existing values at the
end of the list. A proxy MUST NOT change the order of existing
Policy-Contact header field values.
A proxy MUST use the Record-Route mechanism [RFC3261] if its
associated policy server has session policies that apply to mid-
dialog requests. The Record-Route header field enables a proxy to
stay in the signaling path and re-submit the policy server URIs to
UAs during mid-dialog requests that initiate an offer/answer
exchange. Re-submitting the policy server URI to UAs ensures that
UAs keep contacting the policy server for mid-dialog requests.
A proxy can find out if the UAS supports this extension by examining
the Supported header field of responses. The proxy knows that the
UAS supports this extension if the Supported header field of a
response contains the option tag "policy". A proxy can use this
information to determine if the UAS has understood the Policy-Contact
header field it has inserted into the request.
To protect the integrity of the policy server URI in a Policy-Contact
header field, the proxy SHOULD use a secured transport protocol such
as TLS [RFC5246] between proxy and UAs.
4.4.3. UAS Behavior
A UAS can receive an INVITE, UPDATE or PRACK request (or another
request that can initiate offer/answer exchanges) that contains a
Policy-Contact header field with a list of policy server URIs. A UAS
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that receives such a request needs to decide if it wants to accept
the session knowing that there are policy servers involved. If the
Policy-Contact header contains multiple URIs each with a different
URI scheme and containing an "alt-uri" parameter with identical
values these URI schemes represent alternative policy channel
mechanisms for obtaining the same policy. If the UAS accepts the
session, the UAS MUST contact one URI out of each group of URIs with
identical "alt-uri" parameter values to obtain the policy. The UAS
MAY take as a hint the order of the alternative URIs as indicating a
preference as to which URI to use. The topmost URI in the list might
be more preferred by the domain of the proxy for use to obtain the
policy. The UAS MUST contact all policy server URIs in a Policy-
Contact header field that are not part of a group of alternative URIs
and MUST contact one URI in each group of alternative URIs. The UAS
MUST contact these policy server URIs in the order in which they were
contained in the Policy-Contact header field, starting with the
topmost value (i.e., the value that was inserted first).
If a UAS decides that it does not want to accept a session because
there are policy servers involved or because one of the session
policies received from a policy server is not acceptable, the UAS
MUST reject the request with a 488 (Not Acceptable Here) response.
The UAS MAY accept a request and continue with setting up a session
if it cannot setup a policy channel to the policy server, for
example, because the policy server is unreachable or returns an error
condition that cannot be resolved by the UAS (i.e., error conditions
other than, for example, a 401 (Unauthorized) response). This is to
avoid that the failure of a policy server prevents a UA from
communicating. Since this session might not be policy compliant
without the policy subscription, it can be blocked by policy
enforcement mechanisms if they are in place.
A UAS can receive a token from a policy server via the policy
channel. Since the UAS does not create a Policy-ID header field, it
can simply ignore this token.
A UAS compliant to this specification MUST include a Supported header
field with the option tag "policy" into responses to requests that
can initiate an offer/answer exchange. The UAS MAY include this
option tag in all responses. This way, a proxy that has inserted the
Policy-Contact header field can know that the header field was
understood by the UAS.
4.4.4. Caching the Local Policy Server URI
A UAC frequently needs to contact the policy server in the local
domain before setting up a session. To avoid the retransmission of
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the local policy server URI for each session, a UA SHOULD maintain a
cache that contains the URI of the local policy server.
A UA can receive this URI in a Policy-Contact header field of a
request or a 488 (Not Acceptable Here) response. The UA can also
receive the local policy server URI through configuration, for
example, via the configuration framework
[I-D.ietf-sipping-config-framework]. If a UA has received a local
policy server URI through configuration and receives another local
policy server URI in a Policy-Contact header field, the UA SHOULD
overwrite the configured URI with the most recent one received in a
Policy-Contact header field. A policy server URI received in a
Policy-Contact header field expires if it has not been refreshed
before it reaches the maximum cached URI validity. The default
maximum cached URI validity is 24 hours.
Domains can prevent a UA from caching the local policy server URI.
This is useful, for example, if the policy server does not need to be
involved in all sessions or the policy server URI changes from
session to session. A proxy can mark the URI of such a policy server
as "non-cacheable". A UA MUST NOT cache a non-cacheable policy
server URI. The UA SHOULD remove the current URI from the cache when
receiving a local policy server URI that is marked as "non-
cacheable". This is to avoid the use of policy server URIs that are
outdated.
The UA SHOULD NOT cache policy server URIs it has received from
proxies outside of the local domain. These policy servers need not
be relevant for subsequent sessions, which can go to a different
destination, traversing different domains.
The UA MUST NOT cache tokens it has received from a policy server. A
token is only valid for one request.
4.4.5. Header Field Definition and Syntax
4.4.5.1. Policy-Id Header Field
The Policy-Id header field is inserted by the UAC into INVITE, UPDATE
or PRACK requests (or any other request that can be used to initiate
an offer/answer exchange). The Policy-Id header field identifies all
policy servers the UAC has contacted for this request.
The value of a Policy-Id header field consists of a policy server URI
and an optional token parameter. The token parameter contains a
token the UA might have received from the policy server.
The syntax of the Policy-Id header field is described below in ABNF,
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according to RFC5234 [RFC5234], as an extension to the ABNF for SIP
in RFC3261 [RFC3261]:
Policy-Id = "Policy-Id" HCOLON policyURI
*(COMMA policyURI)
policyURI = ( SIP-URI / SIPS-URI / absoluteURI )
[ SEMI token-param ] *( SEMI generic-param )
token-param = "token=" token
4.4.5.2. Policy-Contact Header Field
The Policy-Contact header field can be inserted by a proxy into a 488
(Not Acceptable Here) response to INVITE, UPDATE or PRACK requests
(or other requests that initiate an offer/answer exchange). The
value of a Policy-Contact header field consists of a policy server
URI and an optional "non-cacheable" header field parameter. The
policy server URI identifies the policy server that needs to be
contacted by a UAC. The "non-cacheable" header field parameter
indicates that the policy server URI is not intended to be cached by
the UAC.
The Policy-Contact header field can also be inserted by a proxy into
INVITE, UPDATE and PRACK requests (or other requests that can be used
to initiate an offer/answer exchange). It contains an ordered list
of policy server URIs that need to be contacted by the UAS. The
topmost value of this list identifies the policy server that is
contacted first. New header field values are inserted at the end.
With this, the Policy-Contact header field effectively forms a fist-
in-first-out queue.
The syntax of the Policy-Contact header field is described below in
ABNF, according to RFC5234 [RFC5234], as an extension to the ABNF for
SIP in RFC3261 [RFC3261]:
Policy-Contact = "Policy-Contact" HCOLON
policyContact-info *(COMMA policyContact-info)
policyContact-info = LAQUOT policyContact-uri RAQUOT
*( SEMI policyContact-param )
policyContact-uri = ( SIP-URI / SIPS-URI / absoluteURI )
policyContact-param = ( "non-cacheable" / policyContact-alt-uri
/ generic-param )
policyContact-alt-uri = "alt-uri" EQUAL hostname
Tables 1 and 2 are extensions of Tables 2 and 3 in RFC 3261
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[RFC3261]. The column "INF" is for the INFO method [RFC2976], "PRA"
is for the PRACK method [RFC3262], "UPD" is for the UPDATE method
[RFC3311], "SUB" is for the SUBSCRIBE method [RFC3265], "NOT" is for
the NOTIFY method [RFC3265], "MSG" is for the MESSAGE method
[RFC3428], "REF" is for the REFER method [RFC3515], and "PUB" is for
the PUBLISH method [RFC3903].
Header field where proxy ACK BYE CAN INV OPT REG UPD
_______________________________________________________________
Policy-Id R rd - - - c - - c
Policy-Contact R a - - - c - - c
Policy-Contact 488 a - - - c - - c
Table 1: Policy-Id and Policy-Contact Header Fields
Header field where proxy PRA PUB SUB NOT INF MSG REF
_______________________________________________________________
Policy-Id R rd c - - - - - -
Policy-Contact R a c - - - - - -
Policy-Contact 488 a c - - - - - -
Table 1: Policy-Id and Policy-Contact Header Fields
4.5. Policy Channel
The main task of the policy channel is to enable a UA to submit
information about the session it is trying to establish (i.e., the
offer and the answer) to a policy server and to receive the resulting
session-specific policies and possible updates to these policies in
response.
The Event Package for Session-Specific Session Policies
[I-D.ietf-sipping-policy-package] defines a SUBSCRIBE/NOTIFY-based
[RFC3265] policy channel mechanism. A UA compliant to this
specification MUST support the Event Package for Session-Specific
Session Policies [I-D.ietf-sipping-policy-package]. The UA MUST use
this event package to contact a policy server if the policy server
URI is a SIP-URI or SIPS-URI. A UA MAY support other policy channel
mechanisms.
4.5.1. Creation and Management
A UA discovers the list of policy servers relevant for a session
during the initial offer/answer exchange (see Section 4.4). A UA
compliant to this specification MUST set up a policy channel to each
of the discovered policy server. If the UA does not want to set up a
policy channel to one of the policy servers provided, the UA MUST
cancel or reject a pending INVITE transaction for the session or
terminate the session if it is already in progress.
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A UA MUST maintain the policy channel to each discovered policy
server during the lifetime of a session, unless the policy channel is
closed by the policy server or the UA discovers that the policy
server is no longer relevant for the session as described below.
A UAC can receive a 488 (Not Acceptable Here) response with a Policy-
Contact header field containing a new policy server URI in response
to a mid-dialog request. This indicates that the set of policy
servers relevant for the current session has changed. If this
occurs, the UAC MUST retry sending the request as if it was the first
request in a dialog (i.e., without applying any policies except the
policies from the local policy server). This way, the UAC will re-
discover the list of policy servers for the current session. This is
necessary since the UAC has no other way of knowing when to contact
the newly discovered policy server relative to the existing policy
servers and if any of the existing policy servers does not need to be
contacted any more. The UAC MUST set up a policy channel to each new
policy server. The UAC SHOULD close policy channels to policy server
that are not listed any more. If the policy channel to these servers
is not closed, the UAC can receive policies that do not apply to the
session any more. The UAC MUST contact policy servers in the order
in which they were discovered in the most recent request.
If a UAS receives a mid-dialog request with a Policy-Contact header
field containing a list of policy server URIs that is different from
the list of policy servers to which the UAS has currently established
a policy channel, then the UAS MUST set up a policy channel to all
new policy servers and contact them. The UAS SHOULD close policy
channels to servers that are not listed any more. If the policy
channel to these servers is not closed, the UAS can receive policies
that do not apply to the session any more. The UAS MUST use policy
servers in the order in which they were contained in the most recent
Policy-Contact header field.
A UA MUST inform the policy server when a session is terminated
(e.g., when the UA has either sent or received a BYE) via the policy
channel, unless a policy server indicates via the policy channel that
it does not need to be contacted at the end of the session. This
enables a policy server to free all resources it has allocated for
this session.
4.5.2. Contacting the Policy Server
A UA MUST contact all policy servers to which it has established a
policy channel before sending or after receiving a mid-dialog
request. The UA MUST contact the policy servers in the order in
which they were discovered most recently.
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A UA that receives a SIP message containing an offer or answer SHOULD
completely process the message (e.g., according to RFC3261 [RFC3261])
before contacting the policy server. The SIP processing of the
message includes, for example, updating dialog state and timers as
well as creating ACK or PRACK requests as necessary. This ensures
that contacting a policy server does not interfere with SIP message
processing and timing (e.g., by inadvertently causing timers to
expire). This implies, for example, that a UAC which has received a
response to an INVITE request would normally finish the processing of
the response including transmitting the ACK request before it
contacts the policy server. An important exception to this rule is
discussed in the next paragraph.
In some cases, a UA needs to use the offer/answer it has received in
a SIP message to create an ACK or PRACK request for this message,
i.e., it needs to use the offer/answer before finishing the SIP
machinery for this message. For example, a UAC that has received an
offer in the response to an INVITE request needs to apply policies to
the offer and the answer before it can send the answer in an ACK
request. In these cases, a UA SHOULD contact the policy server even
if this is during the processing of a SIP message. This implies that
a UA, which has received an offer in the response of an INVITE
request, would normally contact the policy server and apply session
policies before sending the answer in the ACK request.
Note: this assumes that the policy server can always respond
immediately to a policy request and does not require manual
intervention to create a policy. This will be the case for most
policy servers. If, however, a policy server cannot respond with
a policy right away, it can return a policy that temporarily
denies the session and update this policy as the actual policy
decision becomes available. A delay in the response from the
policy server to the UA would delay the transmission of the ACK
request and could trigger retransmissions of the INVITE response
(also see the recommendations for Flow I in RFC3725 [RFC3725]).
The case of multiple policy servers providing policies to the same UA
requires additional considerations. A policy returned by one policy
server can contain information that needs to be shared with the other
policy servers. For example, two policy servers can have the policy
to insert a media intermediary by modifying the IP addresses and
ports of media streams. In order for media streams to pass through
both intermediaries, each intermediary needs to know the IP address
and port on which the other media intermediary is expecting the
stream to arrive. If media streams are flowing in both directions,
this means that each intermediary needs to know IP addresses and
ports of the other intermediary.
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UACs usually contact a policy server twice during an offer/answer
exchange (unless a policy server indicates that it only needs to be
contacted once). Therefore the case of multiple policy servers
providing policies to a single UAC does not require additional steps
in most cases. However, a UAS usually contacts each policy server
only once (see Figure 4). If a session policy returned by one of the
policy servers requires that information is shared between multiple
servers and the UAS receives policies from more than one policy
server, then the UAS MUST contact all policy servers a second time
after contacting all servers the first time. Whether or not a second
round is required is determined by the type of information returned
by the policy server. A data format for session policies (e.g.,
[I-D.ietf-sipping-media-policy-dataset]) needs to explicitly state if
a second round is needed for a particular data element. If a UA
receives such an element, it knows that is expected to contact policy
servers a second time. If such a data element is modified during a
mid-call offer/answer exchange and multiple policy servers are
providing policies to a UA then all UAs MUST contact policy servers
in a first and second round. An example call flow is shown in
Appendix B.3.
A UA that supports session-specific policies compliant to this
specification MUST support the User Agent Profile Data Set for Media
Policy [I-D.ietf-sipping-media-policy-dataset] as data format for
session policies.
4.5.3. Using Session Policies
A UA MUST disclose the session description(s) for the current session
to policy servers through the policy channel. The UA MUST apply
session policies it receives to the offer and, if one is received, to
the answer before using the offer/answer. If these policies are
unacceptable, the UA MUST NOT continue with the session. This means
that, the UA MUST cancel or reject a pending INVITE transaction for
the session or terminate the session if it is already in progress.
If the UA receives an unacceptable policy in an INVITE response, the
UA MUST complete the INVITE transaction and then terminate the
session.
When a UA receives a notification about a change in the current
policies, the UA MUST apply the updated policies to the current
session or the UA MUST terminate the session. If the policy update
causes a change in the session description of a session, then the UA
needs to re-negotiate the modified session description with its peer
UA, for example, using a re-INVITE or UPDATE request. For example,
if a policy update disallows the use of video and video is part of
the current session description, then the UA will need to create an
new session description offer without video. After receiving this
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offer, the peer UA knows that video can't be used any more and
responds with the corresponding answer.
5. Security Considerations
Policy enforcement mechanisms can prevent a UA from communicating
with another UA if the UAs are not aware of the policies that are
enforced. Policy enforcement mechanisms without policy signaling can
therefore create a denial of service condition for UAs. This
specification provides a mechanism for intermediaries to signal the
policies that are enforced to UAs. It enables UAs to establish
sessions that are conform and pass through policy enforcement.
Session policies can significantly change the behavior of a UA and
can be used by an attacker to compromise a UA. For example, session
policies can be used to prevent a UA from successfully establishing a
session (e.g., by setting the available bandwidth to zero). Such a
policy can be submitted to the UA during a session, which causes the
UA to terminate the session.
A UA transmits session information to a policy server for session-
specific policies. This session information can contain sensitive
data the user does not want an eavesdropper or an unauthorized policy
server to see. Vice versa, session policies can contain sensitive
information about the network or service level agreements the service
provider does not want to disclose to an eavesdropper or an
unauthorized UA.
It is important to secure the communication between the proxy and the
UA (for session-specific policies) as well as the UA and the policy
server. The following four discrete attributes need to be protected:
1. integrity of the policy server URI (for session-specific
policies),
2. authentication of the policy server and, if needed, the user
agent,
3. confidentiality of the messages exchanged between the user agent
and the policy server and
4. ensuring that private information is not exchanged between the
two parties, even over an confidentiality-assured and
authenticated session.
To protect the integrity of the policy server URI, a UA SHOULD use a
secured transport protocol such as TLS [RFC5246] between proxies and
the UA. Protecting the integrity of the policy server URI is
important since an attacker could intercept SIP messages between the
UA and the proxy and remove the policy header fields needed for
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session-specific policies. This would impede the rendezvous between
UA and policy server and, since the UA would not contact the policy
server, can prevent a UA from setting up a session.
Instead of removing a policy server URI, an attacker can also modify
the policy server URI and point the UA to a compromised policy
server. It is RECOMMENDED that a UA authenticates policy servers to
prevent such an attack from being effective.
It is RECOMMENDED that the UA only accepts session-independent
policies from trustworthy policy servers as these policies affect all
sessions of a UA. A list of trustworthy session-independent policy
servers can be provided to the UA through configuration. As SIP
messages can be affected by any proxy on a path and session-specific
policies only apply to a single session, a UA MAY choose to accept
session-specific policies from other policy servers as well.
Policy servers SHOULD authenticate UAs to protect the information
that is contained in a session policy. However, a policy server can
also frequently encounter UAs it cannot authenticate. In these
cases, the policy server MAY provide a generic policy that does not
reveal sensitive information to these UAs.
It is RECOMMENDED that administrators use SIPS URIs as policy server
URIs so that subscriptions to session policies are transmitted over
TLS.
The above security attributes are important to protect the
communication between the UA and policy server. This document does
not define the protocol used for the communication between UA and
policy server and merely refers to other specifications for this
purpose. The security considerations of these specifications need to
address the above security aspects.
6. IANA Considerations
6.1. Registration of the "Policy-Id" Header Field
Name of Header Field: Policy-Id
Short form: none
Normative description: Section 4.4.5 of this document
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6.2. Registration of the "Policy-Contact" Header Field
Name of Header Field: Policy-Contact
Short form: none
Normative description: Section 4.4.5 of this document
6.3. Registration of the "non-cacheable" Policy-Contact Header Field
Parameter
Registry Name: Header Field Parameters and Parameter Values
Reference: RFC3968 [RFC3968]
Registry:
Header Field Parameter Name Predefined Reference
Values
_____________________________________________________________________
Policy-Contact non-cacheable Yes this document
6.4. Registration of the "policy" SIP Option-Tag
This specification registers a new SIP option tag, as per the
guidelines in Section 27.1 of RFC3261 [RFC3261].
This document defines the SIP option tag "policy".
The following row has been added to the "Option Tags" section of the
SIP Parameter Registry:
+------------+------------------------------------------+-----------+
| Name | Description | Reference |
+------------+------------------------------------------+-----------+
| policy | This option tag is used to indicate that | this |
| | a UA can process policy server URIs for | document |
| | and subscribe to session-specific | |
| | policies. | |
+------------+------------------------------------------+-----------+
Name of option: policy
Description: Support for the Policy-Contact and Policy-Id header
fields.
SIP header fields defined: Policy-Contact, Policy-Id
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Normative description: This document
7. References
7.1. Normative References
[I-D.ietf-sipping-config-framework]
Channabasappa, S., "A Framework for Session Initiation
Protocol User Agent Profile Delivery",
draft-ietf-sipping-config-framework-18 (work in progress),
October 2010.
[I-D.ietf-sipping-media-policy-dataset]
Hilt, V., Worley, D., Camarillo, G., and J. Rosenberg, "A
User Agent Profile Data Set for Media Policy",
draft-ietf-sipping-media-policy-dataset-11 (work in
progress), February 2011.
[I-D.ietf-sipping-policy-package]
Hilt, V. and G. Camarillo, "A Session Initiation Protocol
(SIP) Event Package for Session-Specific Session
Policies.", draft-ietf-sipping-policy-package-08 (work in
progress), March 2010.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC3261] Rosenberg, J., Schulzrinne, H., Camarillo, G., Johnston,
A., Peterson, J., Sparks, R., Handley, M., and E.
Schooler, "SIP: Session Initiation Protocol", RFC 3261,
June 2002.
[RFC3262] Rosenberg, J. and H. Schulzrinne, "Reliability of
Provisional Responses in Session Initiation Protocol
(SIP)", RFC 3262, June 2002.
[RFC3264] Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model
with Session Description Protocol (SDP)", RFC 3264,
June 2002.
[RFC3265] Roach, A., "Session Initiation Protocol (SIP)-Specific
Event Notification", RFC 3265, June 2002.
[RFC3311] Rosenberg, J., "The Session Initiation Protocol (SIP)
UPDATE Method", RFC 3311, October 2002.
[RFC3968] Camarillo, G., "The Internet Assigned Number Authority
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(IANA) Header Field Parameter Registry for the Session
Initiation Protocol (SIP)", BCP 98, RFC 3968,
December 2004.
[RFC5234] Crocker, D. and P. Overell, "Augmented BNF for Syntax
Specifications: ABNF", STD 68, RFC 5234, January 2008.
7.2. Informative References
[RFC2976] Donovan, S., "The SIP INFO Method", RFC 2976,
October 2000.
[RFC3428] Campbell, B., Rosenberg, J., Schulzrinne, H., Huitema, C.,
and D. Gurle, "Session Initiation Protocol (SIP) Extension
for Instant Messaging", RFC 3428, December 2002.
[RFC3515] Sparks, R., "The Session Initiation Protocol (SIP) Refer
Method", RFC 3515, April 2003.
[RFC3725] Rosenberg, J., Peterson, J., Schulzrinne, H., and G.
Camarillo, "Best Current Practices for Third Party Call
Control (3pcc) in the Session Initiation Protocol (SIP)",
BCP 85, RFC 3725, April 2004.
[RFC3903] Niemi, A., "Session Initiation Protocol (SIP) Extension
for Event State Publication", RFC 3903, October 2004.
[RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform
Resource Identifier (URI): Generic Syntax", STD 66,
RFC 3986, January 2005.
[RFC4566] Handley, M., Jacobson, V., and C. Perkins, "SDP: Session
Description Protocol", RFC 4566, July 2006.
[RFC5246] Dierks, T. and E. Rescorla, "The Transport Layer Security
(TLS) Protocol Version 1.2", RFC 5246, August 2008.
Appendix A. Acknowledgements
Many thanks to Allison Mankin, Andrew Allen, Cullen Jennings and
Vijay Gurbani for their contributions to this draft. Many thanks to
Roni Even, Bob Penfield, Mary Barnes, Shida Schubert, Keith Drage,
Lisa Dusseault, Tim Polk and Pasi Eronen for their reviews and
suggestions.
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Appendix B. Session-Specific Policies - Call Flows
The following call flows illustrate the overall operation of session-
specific policies including the policy channel protocol as defined in
the SIP Event Package for Session-Specific Session Policies
[I-D.ietf-sipping-policy-package].
The following abbreviations are used:
o: offer
o': offer modified by a policy
po: offer policy
a: answer
a': answer modified by a policy
pa: answer policy
ps uri: policy server URI (in Policy-Contact header field)
ps id: policy server id (in Policy-Id header field)
B.1. Offer in Invite
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UA A P A PS A PS B P B UA B
| | | | | |
|(1) INV <o> | | | |
|-------->| | | | |
|(2) 488 <ps uri> | | | |
|<--------| | | | |
|(3) ACK | | | | |
|-------->| | | | |
|(4) SUBSCRIBE <o> | | | |
|------------------>| | | |
|(5) 200 OK | | | |
|<------------------| | | |
|(6) NOTIFY <po> | | | |
|<------------------| | | |
|(7) 200 OK | | | |
|------------------>| | | |
|(8) INV <ps id, o'>| | | |
|-------->| | | | |
| |(9) INV <o'> | | |
| |---------------------------->| |
| | | | |(10) INV <o', ps uri>
| | | | |-------->|
| | | |(11) SUBSCRIBE <o', a>
| | | |<------------------|
| | | |(12) 200 OK |
| | | |------------------>|
| | | |(13) NOTIFY <po, pa>
| | | |------------------>|
| | | |(14) 200 OK |
| | | |<------------------|
| | | | |(15) 200 OK <a'>
| | | | |<--------|
| |(16) 200 OK <a'> | | |
| |<----------------------------| |
|(17) 200 OK <a'> | | | |
|<--------| | | | |
|(18) ACK | | | | |
|------------------------------------------------>|
|(19) SUBSCRIBE <o', a'> | | |
|------------------>| | | |
|(20) 200 OK | | | |
|<------------------| | | |
|(21) NOTIFY <po, pa> | | |
|<------------------| | | |
|(22) 200 OK | | | |
|------------------>| | | |
| | | | | |
| | | | | |
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B.2. Offer in Response
UA A P A PS A PS B P B UA B
| | | | | |
|(1) INV | | | | |
|-------->| | | | |
|(2) 488 <ps uri> | | | |
|<--------| | | | |
|(3) ACK | | | | |
|-------->| | | | |
|(4) SUBSCRIBE | | | |
|------------------>| | | |
|(5) 200 OK | | | |
|<------------------| | | |
|(6) NOTIFY | | | |
|<------------------| | | |
|(7) 200 OK | | | |
|------------------>| | | |
|(8) INV <ps id> | | | |
|-------->| | | | |
| |(9) INV | | | |
| |---------------------------->| |
| | | | |(10) INV <ps uri>
| | | | |-------->|
| | | |(11) SUBSCRIBE <o> |
| | | |<------------------|
| | | |(12) 200 OK |
| | | |------------------>|
| | | |(13) NOTIFY <po> |
| | | |------------------>|
| | | |(14) 200 OK |
| | | |<------------------|
| | | | |(15) 200 OK <o'>
| | | | |<--------|
| |(16) 200 OK <o'> | | |
| |<----------------------------| |
|(17) 200 OK <o'> | | | |
|<--------| | | | |
|(18) SUBSCRIBE <o', a> | | |
|------------------>| | | |
|(19) 200 OK | | | |
|<------------------| | | |
|(20) NOTIFY <po, pa> | | |
|<------------------| | | |
|(21) 200 OK | | | |
|------------------>| | | |
|(22) ACK <a'> | | | |
|------------------------------------------------>|
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| | | |(23) SUBSCRIBE <o', a'>
| | | |<------------------|
| | | |(24) 200 OK |
| | | |------------------>|
| | | |(25) NOTIFY <po, pa>
| | | |------------------>|
| | | |(26) 200 OK |
| | | |<------------------|
| | | | | |
| | | | | |
B.3. Multiple Policy Servers for UAS
UA A P A PS A PS B P B UA B
| | | | | |
| | | | | |
| | | | | |
|(1) INV <o> | | | |
|-------->| | | | |
| |(2) INV <o, uri PSA> | |
| |---------------------------->| |
| | | | |(3) INV <o, uri PSA, uri PSB>
| | | | |-------->|
| | |(4) SUBSCRIBE <o, a> |
| | |<----------------------------|
| | |(5) 200 OK | |
| | |---------------------------->|
| | |(6) NOTIFY <po, pa>| |
| | |---------------------------->|
| | |(7) 200 OK | |
| | |<----------------------------|
| | | |(8) SUBSCRIBE <o', a'>
| | | |<------------------|
| | | |(9) 200 OK |
| | | |------------------>|
| | | |(10) NOTIFY <po, pa>
| | | |------------------>|
| | | |(11) 200 OK |
| | | |<------------------|
| | |(12) SUBSCRIBE <o", a"> |
| | |<----------------------------|
| | |(13) 200 OK | |
| | |---------------------------->|
| | |(14) NOTIFY <po, pa> |
| | |---------------------------->|
| | |(15) 200 OK | |
| | |<----------------------------|
| | | |(16) SUBSCRIBE <o", a">
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| | | |<------------------|
| | | |(17) 200 OK |
| | | |------------------>|
| | | |(18) NOTIFY <po, pa>
| | | |------------------>|
| | | |(19) 200 OK |
| | | |<------------------|
| | | | |(20) 200 OK <a">
| | | | |<--------|
| |(21) 200 OK <a"> | | |
| |<----------------------------| |
|(22) 200 OK <a"> | | | |
|<--------| | | | |
|(23) ACK | | | | |
|------------------------------------------------>|
| | | | | |
| | | | | |
Authors' Addresses
Volker Hilt
Bell Labs/Alcatel-Lucent
791 Holmdel-Keyport Rd
Holmdel, NJ 07733
USA
Email: volkerh@bell-labs.com
Gonzalo Camarillo
Ericsson
Hirsalantie 11
Jorvas 02420
Finland
Email: Gonzalo.Camarillo@ericsson.com
Jonathan Rosenberg
jdrosen.net
Monmouth, NJ
USA
Email: jdrosen@jdrosen.net
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