Network Working Group M. Isomaki Request for Comments: 4827 E. Leppanen Category: Standards Track Nokia May 2007
An Extensible Markup Language (XML) Configuration Access Protocol (XCAP) Usage for Manipulating Presence Document Contents
Status of This Memo
This document specifies an Internet standards track protocol for the Internet community, and requests discussion and suggestions for improvements. Please refer to the current edition of the "Internet Official Protocol Standards" (STD 1) for the standardization state and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The IETF Trust (2007).
Abstract
This document describes a usage of the Extensible Markup Language (XML) Configuration Access Protocol (XCAP) for manipulating the contents of Presence Information Data Format (PIDF) based presence documents. It is intended to be used in Session Initiation Protocol (SIP) based presence systems, where the Event State Compositor can use the XCAP-manipulated presence document as one of the inputs on which it builds the overall presence state for the presentity.
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RFC 4827 XCAP for Manipulating Presence Document May 2007
The Session Initiation Protocol (SIP) for Instant Messaging and Presence (SIMPLE) specifications allow a user, called a watcher, to subscribe to another user, called a presentity, in order to learn its presence information [7]. The presence data model has been specified in [10]. The data model makes a clean separation between person-, service-, and device-related information.
A SIP-based mechanism, SIP PUBLISH method, has been defined for publishing presence state [4]. Using SIP PUBLISH, a Presence User Agent (PUA) can publish its view of the presence state, independently of and without the need to learn about the states set by other PUAs. However, SIP PUBLISH has a limited scope and does not address all the requirements for setting presence state. The main issue is that SIP PUBLISH creates a soft state that expires after the negotiated lifetime unless it is refreshed. This makes it unsuitable for cases where the state should prevail without active devices capable of refreshing the state.
There are three main use cases where setting of permanent presence state that is independent of activeness of any particular device is useful. The first case concerns setting person-related state. The presentity would often like to set its presence state even for periods when it has no active devices capable of publishing available. Good examples are traveling, vacations, and so on. The second case is about setting state for services that are open for communication, even if the presentity does not have a device running that service online. Examples of these kinds of services include e-mail, Multimedia Messaging Service (MMS), and Short Message Service (SMS). In these services, the presentity is provisioned with a server that makes the service persistently available, at least in certain forms, and it would be good to be able to advertise this to the watchers. Since it is not realistic to assume that all e-mail, MMS, or SMS servers can publish presence state on their own (and even if this were possible, such state would almost never change), this has to be done by some other device. And since the availability of the service is not dependent on that device, it would be impractical to require that device to be constantly active just to publish such availability. The third case concerns setting the default state of any person, service, or device in the absence of any device capable of actively publishing such state. For instance, the presentity might want to advertise that his or her voice service is currently closed, just to let the watchers know that such service might be open at some point. Again, this type of default state is independent of any particular device and can be considered rather persistent.
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Even though SIP PUBLISH remains the main way of publishing presence state in SIMPLE-based presence systems and is especially well-suited for publishing dynamic state (which presence mainly is), it needs to be complemented by the mechanism described in this document to address the use cases presented above.
XML Configuration Access Protocol (XCAP) [2] allows a client to read, write, and modify application configuration data stored in XML format on a server. The data has no expiration time, so it must be explicitly inserted and deleted. The protocol allows multiple clients to manipulate the data, provided that they are authorized to do so. XCAP is already used in SIMPLE-based presence systems for manipulation of presence lists and presence authorization policies. This makes XCAP an ideal choice for doing device-independent presence document manipulation.
This document defines an XML Configuration Access Protocol (XCAP) application usage for manipulating the contents of presence document. Presence Information Document Format (PIDF) [3] is used as the presence document format, since the event state compositor already has to support it, as it is used in SIP PUBLISH.
Section 3 describes in detail how the presence document manipulated with XCAP is related to soft state publishing done with SIP PUBLISH.
XCAP requires application usages to standardize several pieces of information, including a unique application usage ID (AUID) and an XML schema for the manipulated data. These are specified starting from Section 4.
In this document, the key words 'MUST', 'MUST NOT', 'REQUIRED', 'SHALL', 'SHALL NOT', 'SHOULD', 'SHOULD NOT', 'RECOMMENDED', 'MAY', and 'OPTIONAL' are to be interpreted as described in RFC 2119 [1] and indicate requirement levels for compliant implementations.
Comprehensive terminology of presence and event state publishing is provided in "Session Initiation Protocol (SIP) Extension for Event State Publication" [4].
3. Relationship with Presence State Published Using SIP PUBLISH
The framework for publishing presence state is described in Figure 1. A central part of the framework is the event state compositor element, whose function is to compose presence information received from several sources into a single coherent presence document.
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RFC 4827 XCAP for Manipulating Presence Document May 2007
The presence state manipulated with XCAP can be seen as one of the information sources for the compositor to be combined with the soft state information published using SIP PUBLISH. This is illustrated in Figure 1. It is expected that, in the normal case, there can be several PUAs publishing their separate views with SIP PUBLISH, but only a single XCAP manipulated presence document. As shown in the figure, multiple XCAP clients (for instance, in different physical devices) can manipulate the same document on the XCAP server, but this still creates only one input to the event state compositor. The XCAP server stores the XCAP manipulated presence document under the "users" tree in the XCAP document hierarchy. See Section 9 for details and Section 11 for an example.
As individual inputs, the presence states set by XCAP and SIP PUBLISH are completely separated, and it is not possible to directly manipulate the state set by one mechanism with the other. How the compositor treats XCAP-based inputs with respect to SIP PUBLISH-based inputs is a matter of compositor policy, which is beyond the scope of this specification. Since the SIP PUBLISH specification already mandates the compositor to be able to construct the overall presence state from multiple inputs, which may contain non-orthogonal (or in some ways even conflicting) information, this XCAP usage does not impose any new requirements on the compositor functionality.
XCAP requires application usages to define a unique application usage ID (AUID) in either the IETF tree or a vendor tree. This specification defines the 'pidf-manipulation' AUID within the IETF tree, via the IANA registration in Section 13.
The XML Schema of the presence information is defined in the Presence Information Data Format (PIDF) [3]. The PIDF also defines a mechanism for extending presence information. See [8], [9], [11], and [12] for currently defined PIDF extensions and their XML Schemas.
The namespace URI for PIDF is 'urn:ietf:params:xml:ns:pidf' which is also the XCAP default document namespace.
There are no resource interdependencies beyond the possible interdependencies defined in PIDF [3] and XCAP [2] that need to be defined for this application usage.
The XCAP server MUST store only a single XCAP manipulated presence document for each user. The presence document MUST be located under the "users" tree, using filename "index". See an example in Section 11.
This application usage does not modify the default XCAP authorization policy, which allows only a user (owner) to read, write, or modify their own documents. A server can allow privileged users to modify documents that they do not own, but the establishment and indication of such policies is outside the scope of this document.
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RFC 4827 XCAP for Manipulating Presence Document May 2007
The section provides an example of a presence document provided by an XCAP Client to an XCAP Server. The presence document illustrates the situation where a (human) presentity has left for vacation, and before that, has set his presence information so that he is only available via e-mail. In the absence of any published soft state information, this would be the sole input to the compositor forming the presence document. The example document contains PIDF extensions specified in "RPID: Rich Presence Extensions to the Presence Information Data Format (PIDF)" [8] and "CIPID: Contact Information in Presence Information Data Format" [9].
It is assumed that the presentity is a SIP user with Address-of- Record (AOR) sip:someone@example.com. The XCAP root URI for example.com is assumed to be http://xcap.example.com. The XCAP User Identifier (XUI) is assumed to be identical to the SIP AOR, according to XCAP recommendations. In this case, the presence document would be located at http://xcap.example.com/pidf-manipulation/users/ sip:someone@example.com/index.
The presence document is created with the following XCAP operation:
PUT /pidf-manipulation/users/sip:someone@example.com/index HTTP/1.1 Host: xcap.example.com Content-Type: application/pidf+xml ...
<tuple id="x8eg92m"> <status> <basic>closed</basic> </status> <rp:user-input>idle</rp:user-input> <rp:class>auth-1</rp:class> <contact priority="0.5">sip:user@example.com</contact> <note>I'm available only by e-mail.</note> <timestamp>2004-02-06T16:49:29Z</timestamp> </tuple>
<tuple id="x8eg92n"> <status>
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RFC 4827 XCAP for Manipulating Presence Document May 2007
<basic>open</basic> </status> <rp:class>auth-1</rp:class> <contact priority="1.0">mailto:someone@example.com</contact> <note>I'm reading mail a couple of times a week</note> </tuple>
A presence document may contain information that is highly sensitive. Its delivery to watchers needs to happen strictly according to the relevant authorization policies. It is also important that only authorized clients are able to manipulate the presence information.
The XCAP base specification mandates that all XCAP servers MUST implement HTTP Digest authentication specified in RFC 2617 [5]. Furthermore, XCAP servers MUST implement HTTP over TLS [6]. It is recommended that administrators of XCAP servers use an HTTPS URI as the XCAP root services' URI, so that the digest client authentication occurs over TLS. By using these means, XCAP client and server can ensure the confidentiality and integrity of the XCAP presence document manipulation operations, and that only authorized clients are allowed to perform them.
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RFC 4827 XCAP for Manipulating Presence Document May 2007
The authors would like to thank Jari Urpalainen, Jonathan Rosenberg, Hisham Khartabil, Aki Niemi, Mikko Lonnfors, Oliver Biot, Alex Audu, Krisztian Kiss, Jose Costa-Requena, George Foti, and Paul Kyzivat for their comments.
[7] Rosenberg, J., "A Presence Event Package for the Session Initiation Protocol (SIP)", RFC 3856, August 2004.
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RFC 4827 XCAP for Manipulating Presence Document May 2007
[8] Schulzrinne, H., Gurbani, V., Kyzivat, P., and J. Rosenberg, "RPID: Rich Presence Extensions to the Presence Information Data Format (PIDF)", RFC 4480, July 2006.
[9] Schulzrinne, H., "CIPID: Contact Information for the Presence Information Data Format", RFC 4482, July 2006.
[10] Rosenberg, J., "A Data Model for Presence", RFC 4479, July 2006.
[11] Lonnfors, M. and K. Kiss, "Session Initiation Protocol (SIP) User Agent Capability Extension to Presence Information Data Format (PIDF)", Work in Progress, July 2006.
[12] Schulzrinne, H., "Timed Presence Extensions to the Presence Information Data Format (PIDF) to Indicate Status Information for Past and Future Time Intervals", RFC 4481, July 2006.
Authors' Addresses
Markus Isomaki Nokia P.O. BOX 100 00045 NOKIA GROUP Finland
EMail: markus.isomaki@nokia.com
Eva Leppanen Nokia P.O. BOX 785 33101 Tampere Finland
EMail: eva-maria.leppanen@nokia.com
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RFC 4827 XCAP for Manipulating Presence Document May 2007
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