Interworking between the Session Initiation Protocol (SIP) and the Extensible Messaging and Presence Protocol (XMPP): PresenceFilamentpeter@filament.comhttps://filament.com/
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Extensible Messaging and Presence ProtocolXMPPJabberSession Initiation ProtocolSIPSIMPLEpresenceavailabilityThis document defines a bidirectional protocol mapping for the exchange of presence information between the Session Initiation Protocol (SIP) and the Extensible Messaging and Presence Protocol (XMPP). This document obsoletes RFC 7248.Presence is information about the availability of an entity (such as network availability or availability for communication). Presence features in both SIP and XMPP involve several aspects:A long-lived authorization for a user to receive notifications about a contact's presence across presence and notification sessions; such an authorization is formally requested by the user, approved (or not) by the contact, and often associated with a record in an address list or "buddy list".An ephemeral presence session, during which the contact is online (i.e., available for interaction) and after which the contact is offline again.An ephemeral notification session, during which the user requests presence notifications from the contact (these are implicit in XMPP, but explicit in SIP where they are managed by means of notification dialogs).Notifications that are sent from the contact to the user for the life of either the contact's presence session or the user's notification session.Although specifications for both SIP and XMPP use the term "subscription", they do so in different ways. In SIP, a "subscription" is the specific mechanism whereby a subscriber (or an entity acting on the subscriber's behalf, such as a server) requests presence notifications from the contact over a relatively short period of time, renewed as necessary to keep receiving presence notifications during a presence session. By contrast, in XMPP a "subscription" is essentially shorthand for a long-lived presence authorization. To prevent confusion, this document uses the term "notification dialog" for a SIP subscription and the term "presence authorization" for an XMPP subscription.In order to help ensure interworking between presence systems that conform to the instant message / presence requirements , it is important to clearly define protocol mappings between such systems. Within the IETF, work has proceeded on two presence technologies:Various extensions to the Session Initiation Protocol () for presence, in particular The Extensible Messaging and Presence Protocol (XMPP), which consists of a formalization of the core XML streaming protocols developed originally by the Jabber open-source community; the relevant specifications are for the XML streaming layer and for basic presence and instant-messaging extensionsOne approach to helping ensure interworking between these protocols is to map each protocol to the abstract semantics described in ; however, apparently that approach has never been implemented. The approach taken in this document is to directly map semantics from one protocol to another (i.e., from SIP/SIMPLE (SIP for Instant Messaging and Presence Leveraging Extensions) to XMPP and vice versa), because that is how existing systems solve the interworking problem.The architectural assumptions underlying such direct mappings are provided in , including mapping of addresses and error conditions. The mappings specified in this document cover basic presence functionality. Mapping of more advanced functionality (e.g., so-called "rich presence") is out of scope for this document.This document obsoletes RFC 7248.The documents in this series are intended for use by software developers who have an existing system based on one of these technologies (e.g., SIP) and would like to enable communication from that existing system to systems based on the other technology (e.g., XMPP). We assume that readers are familiar with the core specifications for both SIP and XMPP , with the base document for this series , and with the following presence-related specifications:"A Presence Event Package for the Session Initiation Protocol" "Presence Information Data Format (PIDF)" "Extensible Messaging and Presence Protocol (XMPP): Instant Messaging and Presence" "SIP-Specific Event Notification" A number of terms used here (user, contact, notification, etc.) are explained in , , , , and . This document uses some, but not all, of the presence-related terms defined in the Model for Presence and Instant Messaging . In particular, the term "presence session" is used as described in to mean a delimited time period in which an endpoint is online and available for communications.In flow diagrams, SIP traffic is shown using arrows such as "***>", whereas XMPP traffic is shown using arrows such as "...>". As in , the terms "SIP to XMPP Gateway" and "XMPP to SIP Gateway" are abbreviated as "S2X GW" and "X2S GW", respectively.The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in .The fundamental architectural assumptions underlying SIP-XMPP interworking are described in .Note that, in SIP, there are two ways that presence services can be deployed on the server side:Under this model, described most fully in , a dedicated SIP Presence Server handles events related to the presence event package. Instead of forwarding a SUBSCRIBE message to the SIP user, the Presence Server would act on the basis of a policy set by the SIP User Agent using the 'presence.winfo' event package, for which the SIP user would receive events. The SIP User Agent would then authorize the subscribing contact through some interaction with the Presence Server (for instance using XCAP ). Therefore, presence updates from the SIP User Agent would not be sent as NOTIFY messages to the XMPP user but as PUBLISH messages to the Presence Server, which would then generate NOTIFY messages to all active subscribers.Under this model, a SIP Presence Server acts in proxy mode and merely passes through the SUBSCRIBE and NOTIFY messages to the SIP User Agent.Because the behavior of the XMPP-to-SIP gateway is not changed by the SIP architectural model that is used, the diagrams and protocol flows in this document cover both options by labeling the end entity a "SIP User Agent or Presence Server".Both XMPP and presence-aware SIP systems enable entities (often, but not necessarily, human users) to subscribe to the presence of other entities. XMPP presence is specified in . Presence using a SIP event package is specified in .As described in , XMPP presence authorizations are managed using XMPP <presence/> stanzas of type "subscribe", "subscribed", "unsubscribe", and "unsubscribed". The main states are:"none" (neither the user nor the contact is subscribed to the other's presence information)"from" (the contact will receive presence notifications from the user)"to" (the contact will send presence notifications to the user)"both" (both user and contact will receive each other's presence notifications)As described in , SIP presence authorizations are effectively implicit: when a SIP user receives an initial SIP SUBSCRIBE event from a contact, the recipient's SIP User Agent will prompt the user to approve or deny the request. This decision is recorded in the User Agent or in a Presence Server, so that in the future any notification dialogs from the contact are automatically approved. (Note that addresses for SIP users and contacts are most generally referenced by a Presence URI of the form <pres:user@domain> but might be referenced by a SIP or SIPS (Session Initiation Protocol Secure) URI of the form <sip:user@domain> or <sips:user@domain>; because in practice 'pres' URIs are rarely used, the examples in this document use 'sip' URIs.)In both SIP and XMPP, presence authorizations are long-lived (indeed permanent if not explicitly cancelled). In SIP, by default a notification session is typically short-lived unless explicitly extended (the default time-to-live of a SIP notification dialog is 3600 seconds, as specified in Section 6.4 of , so that a notification dialog needs to be explicitly refreshed in order for a user's notification session to last as long as the contact's presence session). In XMPP, a user's notification session with a contact is almost always automatically handled by the user's server based on the user's presence state (see for details).The following diagram illustrates the protocol flow necessary to establish an authorization for an XMPP user to a receive presence notifications from a SIP contact, as further explained in the text and examples after the diagram.An XMPP user (e.g., juliet@example.com) asks for a presence authorization by sending a request to a SIP contact (e.g., romeo@example.net), and the contact either accepts or declines the request. If the SIP contact accepts the request, the XMPP user will have a long-lived authorization to receive the SIP contact's presence information until (1) the XMPP user unsubscribes or (2) the SIP contact cancels the authorization. The request is encapsulated in a <presence/> stanza of type "subscribe":Upon receiving such a <presence/> stanza, the XMPP server to which Juliet has connected needs to determine the identity of the domainpart in the 'to' address, which it does by following the procedures explained in Section 5 of . If the domain is a SIP domain, the XMPP server will hand off the <presence/> stanza to an associated XMPP-to-SIP gateway or connection manager that natively communicates with presence-aware SIP proxies.The XMPP-to-SIP gateway is then responsible for translating the XMPP request into a SIP SUBSCRIBE request addressed from the XMPP user to the SIP contact:Once the SIP proxy has delivered the SIP SUBSCRIBE to the SIP User Agent or Presence Server (F3, no example shown), the SIP User Agent then would send a response indicating acceptance of the request:In accordance with Section 6.7 of , the XMPP-to-SIP gateway needs to consider the state to be "neutral" until it receives a NOTIFY message with a Subscription-State header whose value is "active". Therefore, the SIP User Agent or Presence Server SHOULD immediately send such a NOTIFY message (see below). In case the XMPP-to-SIP gateway initially receives one or more NOTIFY messages with Subscription-State header whose value is "pending" (F6), it MUST respond to them on the SIP side but not generate any presence stanzas towards the XMPP User.Upon receiving the first NOTIFY with a state of active, the XMPP-to-SIP gateway returns a 200 OK to the SIP User Agent or Presence Server (F12, no example shown).The XMPP-to-SIP gateway also generates a <presence/> stanza of type "subscribed":As described in , the XMPP-to-SIP gateway also generates a presence notification addressed to the XMPP user:It is the responsibility of the XMPP-to-SIP gateway to set the value of the Expires header and to periodically renew the notification dialog on the SIMPLE side of the gateway. For example, the XMPP-to-SIP gateway SHOULD send a new SUBSCRIBE request to the SIP contact whenever the XMPP user initiates a presence session with the XMPP server by sending initial presence to its XMPP server (this is functionally equivalent to sending an XMPP presence probe). The XMPP-to-SIP gateway also SHOULD send a new SUBSCRIBE request to the SIP contact sufficiently in advance of when the SIP notification dialog is scheduled to expire during the XMPP user's active presence session.The rules regarding SIP SUBSCRIBE requests for the purpose of establishing and refreshing a notification dialog are provided in . Those rules also apply to XMPP-to-SIP gateways. Furthermore, an XMPP-to-SIP gateway MUST consider the XMPP presence authorization to be permanently cancelled (and so inform the XMPP user) if it receives a SIP response of 403, 489, or 603. By contrast, it is appropriate to consider a SIP response of 423 or 481 to be a transient error and to honor the long-lived XMPP presence authorization. explains more detailed considerations about the handling of SIP responses in relation to notification dialogs and refreshes.Finally, see the security considerations section () of this document for important information and requirements regarding the security implications of notification refreshes.The following diagram illustrates the protocol flow by which an XMPP user cancels her outbound presence authorization to a SIP contact (i.e., indicates that she no longer wishes to be authorized to see the SIP contact's presence). As can be seen, because SIMPLE does not have a construct that enables a contact to cancel her presence authorization, this flow instead results in cancellation of the contact's notification dialog (with the implication on the XMPP side that the contact will not request a subsequent notification dialog). Additional details are explained in the text and examples after the diagram.At any time after subscribing, the XMPP user can indicate that she no longer wishes to be authorized to receive presence notifications from the contact. This is done by sending a <presence/> stanza of type "unsubscribe":The XMPP-to-SIP gateway is responsible for translating the XMPP unsubscribe command into a SIP SUBSCRIBE request with the Expires header set to a value of zero:Upon receiving the SIP 200 OK acknowleding the cancellation, the XMPP-to-SIP gateway SHOULD send a <presence/> stanza of type "unsubscribed" addressed to the XMPP user:In accordance with Section 4.4.1 of , the XMPP-to-SIP gateway is then responsible for sending a NOTIFY with a "Subscription-State" of "terminated" in order to formally end the XMPP user's outbound presence authorization and the associated SIP dialog.Note: When the XMPP user cancels her outbound presence authorization to the SIP user, any inbound authorization that she might have approved (thus enabling the SIP user to see her presence) remains unchanged.The following diagram illustrates the protocol flow for establishing an authorization for a SIP user to receive presence notifications from an XMPP contact, as further explained in the text and examples after the diagram.A SIP User Agent initiates a presence authorization to an XMPP contact's presence information by sending a SIP SUBSCRIBE request to the contact. The following is an example of such a request:Notice that the Expires header was not included in the SUBSCRIBE request; this means that the default value of 3600 (i.e., 3600 seconds = 1 hour) applies.Upon receiving the SUBSCRIBE, the SIP proxy needs to determine the identity of the domain portion of the Request-URI, which it does by following the procedures explained in Section 5 of . If the domain is an XMPP domain, the SIP proxy will hand off the SUBSCRIBE to an associated SIP-to-XMPP gateway or connection manager that natively communicates with XMPP servers.The SIP-to-XMPP gateway is then responsible for translating the SUBSCRIBE into an XMPP authorization request addressed from the SIP user to the XMPP contact:In accordance with , the XMPP user's server delivers the presence authorization request to the XMPP user (or, if an authorization already exists in the XMPP user's roster, the XMPP server SHOULD auto-reply with a <presence/> stanza of type 'subscribed').The "happy path" is for the XMPP user to approve the presence authorization request by generating a <presence/> stanza of type "subscribed" (F30). The XMPP server then stamps that presence stanza with the 'from' address of the XMPP contact and sends it to the SIP user (F31). Upon receiving the stanza, the SIP-to-XMPP gateway generates an empty SIP NOTIFY message with a Subscription-State header of "active", which serves to inform the SIP user that the presence authorization request has been approved (F32).As an alternative to the "happy path", the XMPP user could decline the presence authorization request by generating a <presence/> stanza of type "unsubscribed". The XMPP server would stamp that presence stanza with the 'from' address of the XMPP contact and would send it to the SIP user. The SIP-to-XMPP gateway then transforms that stanza into an empty SIP NOTIFY message with a Subscription-State header of "terminated" and a reason of "rejected":For as long as a SIP user is online and wishes to maintain a notification session (i.e., receive presence notifications from the XMPP contact), the user's SIP User Agent is responsible for periodically refreshing the notification dialog by sending an updated SUBSCRIBE request with an appropriate value for the Expires header. In response, the presence-aware SIP-to-XMPP gateway sends a SIP NOTIFY to the user agent (per ); if the SIP-to-XMPP gateway has meaningful information about the availability state of the XMPP user (e.g., obtained from the core presence session in the XMPP server or learned by sending a presence probe as described under ) then the NOTIFY communicates that information (e.g., by including a PIDF body with the relevant data), whereas if the SIP-to-XMPP gateway does not have meaningful information about the availability state of the XMPP user then the NOTIFY MUST be empty as allowed by .SIP does not directly have a construct for cancelling an outbound presence authorization. Instead, the SIP user would terminate his outbound notification dialog by sending a SUBSCRIBE message whose Expires header is set to a value of zero ("0"), and then never renew it:A presence-aware SIP-to-XMPP gateway is then responsible for sending a SIP NOTIFY request to the SIP User Agent containing a PIDF document specifying that the XMPP contact now has a basic status of "closed", including a Subscription-State header of "terminated" with a reason of "timeout"; and sending an XMPP <presence/> stanza of type "unavailable" to the XMPP contactNote: When the SIP user cancels his outbound presence authorization to the XMPP user, any inbound authorization that he might have approved (enabling the XMPP user to see his presence) remains unchanged.Both XMPP and presence-aware SIP systems enable entities (often, but not necessarily, human users) to send presence notifications to other entities. At its most basic, the term "presence" refers to information about an entity's "on/off" availability for communication on a network. Often, this basic concept is supplemented by information that further specifies the entity's context or status while available for communication; these availability states commonly include "away" and "do not disturb". Some systems and protocols extend the concepts of presence and availability even further and refer to any relatively ephemeral information about an entity as a kind of presence; categories of such "extended presence" include geographical location (e.g., GPS coordinates), user mood (e.g., grumpy), user activity (e.g., walking), and ambient environment (e.g., noisy). This document focuses on the "least common denominator" of network availability only, although future documents might address broader notions of presence, including availability states and extended presence. defines how XMPP <presence/> stanzas can indicate availability (via absence of a 'type' attribute) or lack of availability (via a 'type' attribute with a value of "unavailable"). SIP presence using a SIP event package for presence is specified in .As described in , XMPP presence information about an entity is communicated by means of an XML <presence/> stanza sent over an XML stream. This document assumes that such a <presence/> stanza is sent from an XMPP client to an XMPP server over an XML stream negotiated between the client and the server, and that the client is controlled by a human user. In general, XMPP presence is sent by the user to the user's server and then broadcast to all entities who are subscribed to the user's presence information.As described in , presence information about an entity is communicated by means of a SIP NOTIFY event sent from a SIP User Agent to an intended recipient who is most generally referenced by a Presence URI of the form <pres:user@domain> but who might be referenced by a SIP or SIPS URI of the form <sip:user@domain> or <sips:user@domain>.This document addresses basic presence or network availability only, not the various extensions to SIP and XMPP for "rich presence" such as , , and .When Juliet interacts with her XMPP client to modify her presence information (or when her client automatically updates her presence information, e.g., via an "auto-away" feature), her client generates an XMPP <presence/> stanza. The syntax of the <presence/> stanza, including required and optional elements and attributes, is defined in . The following is an example of such a stanza:Upon receiving such a stanza, the XMPP server to which Juliet has connected broadcasts it to all subscribers who are authorized to receive presence notifications from Juliet and who have indicated a current interest in receiving notifications (this is similar to the SIP NOTIFY method). For each subscriber, broadcasting the presence notification involves adding the 'to' address of the subscriber and then either delivering the notification to a local recipient (if the hostname in the subscriber's address matches one of the hostnames serviced by the XMPP server) or attempting to route it to the foreign domain that services the hostname in the subscriber's address. If the notification is bound for an address at a foreign domain, the XMPP server needs to determine the identity of the domainpart in the 'to' address, which it does by following the procedures discussed in . If the domain is a SIP domain, the XMPP server will hand off the <presence/> stanza to an associated XMPP-to-SIP gateway or connection manager that natively communicates with presence-aware SIP proxy (no example shown).The XMPP-to-SIP gateway is then responsible for translating the XMPP <presence/> stanza into a SIP NOTIFY request and included PIDF document from the XMPP user to the SIP contact.The mapping of XMPP syntax elements to SIP syntax elements MUST be as shown in the following table. (Mappings for elements not mentioned are undefined.)Note the following regarding these mappings:Only an XMPP <presence/> stanza that lacks a 'type' attribute or whose 'type' attribute has a value of "unavailable" MUST be mapped by an XMPP-to-SIP gateway to a SIP NOTIFY request, because those are the only <presence/> stanzas that represent notifications.The PIDF schema defines the tuple 'id' attribute as having a datatype of "xs:ID"; because this datatype is more restrictive than the "xs:string" datatype for XMPP resourceparts (in particular, a number is not allowed as the first character of an ID), it is RECOMMENDED to prepend the resourcepart with "ID-" or some other alphabetic string when mapping from XMPP to SIP.In practice, XMPP <presence/> stanzas often do not include the 'id' attribute.Because the lack of a 'type' attribute indicates that an XMPP entity is available for communications, the XMPP-to-SIP gateway MUST map that information to a PIDF basic status of "open". Because a 'type' attribute with a value of "unavailable" indicates that an XMPP entity is not available communications, the XMPP-to-SIP gateway MUST map that information to a PIDF <basic/> status of "closed".When the XMPP-to-SIP gateway receives XMPP presence of type "unavailable" from the XMPP contact, it sends a SIP NOTIFY request from the XMPP contact to the SIP User Agent containing a PIDF document specifying that the XMPP contact now has a basic status of "closed".The value of the XMPP <priority/> element is an integer between -128 and +127, whereas the value of the PIDF <contact/> element's 'priority' attribute is a decimal number from zero to one inclusive, with a maximum of three decimal places. If the value of the XMPP <priority/> element is negative, an XMPP-to-SIP gateway MUST NOT map the value. If an XMPP-to-SIP gateway maps positive values, it SHOULD treat XMPP priority 0 as PIDF priority 0 and XMPP priority 127 as PIDF priority 1, mapping intermediate values appropriately so that they are unique (e.g., XMPP priority 1 to PIDF priority 0.007, XMPP priority 2 to PIDF priority 0.015, and so on up through mapping XMPP priority 126 to PIDF priority 0.992; note that this is an example only and that the exact mapping is up to the implementation).Some implementations support custom extensions to encapsulate detailed information about availability; however, there is no need to standardize a PIDF extension for this purpose, because PIDF is already extensible and thus the <show/> element (qualified by the 'jabber:client' namespace) can be included directly in the PIDF XML. The examples in this document illustrate this usage, which is RECOMMENDED. The most useful values are likely "away" and "dnd", although note that the latter value merely means "busy" and does not imply that a server or client ought to block incoming traffic while the user is in that state. Naturally, an XMPP-to-SIP gateway can choose to translate a custom extension into an established value of the <show/> element or translate a <show/> element into a custom extension that the XMPP-to-SIP gateway knows is supported by the user agent of the intended recipient. Unfortunately, this behavior does not guarantee that information will not be lost; to help prevent information loss, an XMPP-to-SIP gateway ought to include both the <show/> element and the custom extension if it cannot suitably translate the custom value into a <show/> value. However, there is no guarantee that the SIP receiver will render a standard XMPP <show/> value or custom extension.In XMPP, a user can connect with multiple devices at the same time ; for presence notification purposes , each device is associated with a distinct resourcepart and a contact's user agent will receive a separate presence notification from each of the user's devices. Although the interpretation of multiple presence notifications from a single user is a matter of implementation by the contact's user agent, typically the user agent will show the "most available" status for the contact (e.g., if the user is online with three devices, one of which is away, one of which is in do not disturb mode, and one of which is available with no qualifications, then the status shown will simply be available. In SIP, it is reasonable for a user agent to model multiple presence notifications from an XMPP user in the same way that it would handle multiple tuples from a SIP user.When Romeo changes his presence, his SIP User Agent generates a SIP NOTIFY request for any contacts that have presence authorizations and notification sessions. The syntax of the NOTIFY request is defined in . The following is an example of such a request:Upon receiving the NOTIFY, the SIP proxy needs to determine the identity of the domain portion of the Request-URI, which it does by following the procedures discussed in . If the domain is an XMPP domain, the SIP proxy will hand off the NOTIFY to an associated SIP-to-XMPP gateway or connection manager that natively communicates with XMPP servers.The SIP-to-XMPP gateway is then responsible for translating the NOTIFY into an XMPP <presence/> stanza addressed from the SIP user to the XMPP contact:The mapping of SIP syntax elements to XMPP syntax elements MUST be as shown in the following table. (Mappings for elements not mentioned are undefined.)Note the following regarding these mappings:A PIDF basic status of "open" MUST be mapped to no 'type' attribute, and a PIDF basic status of "closed" MUST be mapped to a 'type' attribute whose value is "unavailable".See the notes following Table 1 of this document regarding mapping of presence priority.If a SIP implementation supports the <show/> element (qualified by the 'jabber:client' namespace) as a PIDF extension for availability status as described in the notes following Table 1 of this document, the SIP-to-XMPP gateway is responsible for including that element in the XMPP presence notification.Both SIP and XMPP provide methods for explicitly requesting one-time information about the current presence status of another entity. These are "polling" methods as opposed to the subscribing methods described in the rest of this document.In XMPP, an explicit request for information about current presence status is completed by sending a <presence/> stanza of type "probe":Note: As described in , presence probes are used by XMPP servers to request presence on behalf of XMPP users; XMPP clients are discouraged from sending presence probes, because retrieving presence is a service that servers provide automatically.A SIP-to-XMPP gateway would transform the presence probe into its SIP equivalent, which is a SUBSCRIBE request with an Expires header value of zero:As described in , this cancels any notification dialog but causes a NOTIFY to be sent to the subscriber, just as a presence probe does (the transformation rules for presence notifications have been previously described in of this document).In SIP, an explicit request for information about current presence status is effectively completed by sending a SUBSCRIBE with an Expires header value of zero:A presence-aware SIP-to-XMPP gateway translates such a SIP request into a <presence/> stanza of type "probe" if it does not already have presence information about the contact:This document makes no requests of IANA.Detailed privacy and security considerations for presence protocols are given in , for SIP-based presence in (see also ), and for XMPP-based presence in (see also ).There exists the possibility of an amplification attack launched from the XMPP network against a SIP presence server, because each long-lived XMPP presence authorization would typically result in multiple notification dialog refreshes on the SIP side of an XMPP-to-SIP gateway. Therefore, access to an XMPP-to-SIP gateway SHOULD be restricted in various ways; for example:Only an XMPP service that carefully controls account provisioning and provides effective methods for the administrators to control the behavior of registered users ought to host an XMPP-to-SIP gateway (e.g., not a service that offers open account registration).An XMPP-to-SIP gateway ought to be associated only with a single domain or trust realm. For example, an XMPP-to-SIP gateway hosted at simple.example.com ought to allow only users within the example.com domain to access the XMPP-to-SIP gateway, not users within example.org, example.net, or any other domain (unless they are part of the same multi-tenanted environment as example.com). This helps to prevent the gateway equivalent of open relays that are shared across XMPP domains from different trust realms.If a SIP presence server receives communications through an XMPP-to-SIP gateway from users who are not associated with a domain that is so related to the hostname of the XMPP-to-SIP gateway, it SHOULD (based on local service provisioning) refuse to service such users or refuse to receive traffic from the XMPP-to-SIP gateway. As a further check, whenever an XMPP-to-SIP gateway seeks to refresh an XMPP user's long-lived authorization to a SIP user's presence, it first sends an XMPP <presence/> stanza of type "probe" from the address of the XMPP-to-SIP gateway to the "bare JID" (user@domain.tld) of the XMPP user, to which the user's XMPP server responds in accordance with ; this puts an equal burden on the XMPP server and the SIP proxy.Presence notifications can contain sensitive information (e.g., about network availability). In addition, it is possible in both SIP and XMPP for an entity to send different presence notifications to different subscribers. Therefore, a gateway MUST honor data about the intended recipient of a presence notification (as represented by the 'to' address for XMPP and by the Request-URI for SIP) and it MUST NOT route or deliver a presence notification to any other entities, because it does not possess information about authorization to receive presence notifications for such entities - that information resides at the user's home service, not at the receiving gateway).Key words for use in RFCs to Indicate Requirement LevelsHarvard University1350 Mass. Ave.CambridgeMA 02138- +1 617 495 3864-
General
keywordIn many standards track documents several words are used to signify the requirements in the specification. These words are often capitalized. This document defines these words as they should be interpreted in IETF documents. Authors who follow these guidelines should incorporate this phrase near the beginning of their document:
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.Note that the force of these words is modified by the requirement level of the document in which they are used.SIP: Session Initiation ProtocolA Presence Event Package for the Session Initiation Protocol (SIP)A Watcher Information Event Template-Package for the Session Initiation Protocol (SIP)This document defines the watcher information template-package for the Session Initiation Protocol (SIP) event framework. Watcher information refers to the set of users subscribed to a particular resource within a particular event package. Watcher information changes dynamically as users subscribe, unsubscribe, are approved, or are rejected. A user can subscribe to this information, and therefore learn about changes to it. This event package is a template-package because it can be applied to any event package, including itself. [STANDARDS-TRACK]Presence Information Data Format (PIDF)This memo specifies the Common Profile for Presence (CPP) Presence Information Data Format (PIDF) as a common presence data format for CPP-compliant Presence protocols, and also defines a new media type "application/pidf+xml" to represent the XML MIME entity for PIDF. [STANDARDS-TRACK]Extensible Messaging and Presence Protocol (XMPP): CoreThe Extensible Messaging and Presence Protocol (XMPP) is an application profile of the Extensible Markup Language (XML) that enables the near-real-time exchange of structured yet extensible data between any two or more network entities. This document defines XMPP's core protocol methods: setup and teardown of XML streams, channel encryption, authentication, error handling, and communication primitives for messaging, network availability ("presence"), and request-response interactions. This document obsoletes RFC 3920. [STANDARDS-TRACK]Extensible Messaging and Presence Protocol (XMPP): Instant Messaging and PresenceThis document defines extensions to core features of the Extensible Messaging and Presence Protocol (XMPP) that provide basic instant messaging (IM) and presence functionality in conformance with the requirements in RFC 2779. This document obsoletes RFC 3921. [STANDARDS-TRACK]SIP-Specific Event NotificationThis document describes an extension to the Session Initiation Protocol (SIP) defined by RFC 3261. The purpose of this extension is to provide an extensible framework by which SIP nodes can request notification from remote nodes indicating that certain events have occurred.</t><t> Note that the event notification mechanisms defined herein are NOT intended to be a general-purpose infrastructure for all classes of event subscription and notification.</t><t> This document represents a backwards-compatible improvement on the original mechanism described by RFC 3265, taking into account several years of implementation experience. Accordingly, this document obsoletes RFC 3265. This document also updates RFC 4660 slightly to accommodate some small changes to the mechanism that were discussed in that document. [STANDARDS-TRACK]Interworking between the Session Initiation Protocol (SIP) and the Extensible Messaging and Presence Protocol (XMPP): Architecture, Addresses, and Error HandlingAs a foundation for the definition of bidirectional protocol mappings between the Session Initiation Protocol (SIP) and the Extensible Messaging and Presence Protocol (XMPP), this document specifies the architectural assumptions underlying such mappings as well as the mapping of addresses and error conditions.Extensible Messaging and Presence Protocol (XMPP): Address FormatThis document defines the address format for the Extensible Messaging and Presence Protocol (XMPP), including support for code points outside the ASCII range. This document obsoletes RFC 6122.A Model for Presence and Instant MessagingSightPath, Inc.135 Beaver StreetWalthamMA02452USmday@alum.mit.edudynamicsoft200 Executive DriveSuite 120West OrangeNJ07046USjdrosen@dynamicsoft.comFujitsu Laboratories Ltd.64 NishiwakiOhkubo-choAkashi674-8555JPsuga@flab.fujitsu.co.jpThis document defines an abstract model for a presence and instant messaging system. It defines the various entities involved, defines terminology, and outlines the services provided by the system. The goal is to provide a common vocabulary for further work on requirements for protocols and markup for presence and instant messaging.Instant Messaging / Presence Protocol RequirementsSightPath, Inc.135 Beaver StreetWalthamMA02452USmday@alum.mit.eduMicrosoft CorporationOne Microsoft WayRedmondWA98052USsonuag@microsoft.comInto Networks, Inc.150 Cambridgepark DriveCambridgeMA02140USjesse@intonet.comPresence and Instant Messaging have recently emerged as a new medium of communications over the Internet. Presence is a means for finding, retrieving, and subscribing to changes in the presence information (e.g. "online" or "offline") of other users. Instant messaging is a means for sending small, simple messages that are delivered immediately to online users.Applications of presence and instant messaging currently use independent, non-standard and non-interoperable protocols developed by various vendors. The goal of the Instant Messaging and Presence Protocol (IMPP) Working Group is to define a standard protocol so that independently developed applications of instant messaging and/or presence can interoperate across the Internet. This document defines a minimal set of requirements that IMPP must meet.Common Profile for Instant Messaging (CPIM)RPID: Rich Presence Extensions to the Presence Information Data Format (PIDF)The Presence Information Data Format (PIDF) defines a basic format for representing presence information for a presentity. This format defines a textual note, an indication of availability (open or closed) and a Uniform Resource Identifier (URI) for communication. The Rich Presence Information Data format (RPID) described here is an extension that adds optional elements to the Presence Information Data Format (PIDF). These extensions provide additional information about the presentity and its contacts. The information is designed so that much of it can be derived automatically, e.g., from calendar files or user activity.</t><t> This extension includes information about what the person is doing, a grouping identifier for a tuple, when a service or device was last used, the type of place a person is in, what media communications might remain private, the relationship of a service tuple to another presentity, the person's mood, the time zone it is located in, the type of service it offers, an icon reflecting the presentity's status, and the overall role of the presentity.</t><t> These extensions include presence information for persons, services (tuples), and devices. [STANDARDS-TRACK]The Extensible Markup Language (XML) Configuration Access Protocol (XCAP)This specification defines the Extensible Markup Language (XML) Configuration Access Protocol (XCAP). XCAP allows a client to read, write, and modify application configuration data stored in XML format on a server. XCAP maps XML document sub-trees and element attributes to HTTP URIs, so that these components can be directly accessed by HTTP. [STANDARDS-TRACK]User Moodstpeter@jabber.orgralphm@ik.nuUser Activityralphm@ik.nustpeter@jabber.orgThanks to the authors, contributors, and other individuals acknowledged in RFC 7248. Thanks to Saul Ibarra Corretge and Markus Isomaki for their reviews during working group consideration.Special thanks to Ben Campbell for identifying the underlying discrepancy that resulted in the need to obsolete RFC 7248.Thanks also to Markus Isomaki and Yana Stamcheva as the working group chairs and Alissa Cooper as the sponsoring Area Director.