Network Working Group J. Rosenberg Request for Comments: 5629 Cisco Systems Category: Standards Track October 2009
A Framework for Application Interaction in the Session Initiation Protocol (SIP)
Abstract
This document describes a framework for the interaction between users and Session Initiation Protocol (SIP) based applications. By interacting with applications, users can guide the way in which they operate. The focus of this framework is stimulus signaling, which allows a user agent (UA) to interact with an application without knowledge of the semantics of that application. Stimulus signaling can occur to a user interface running locally with the client, or to a remote user interface, through media streams. Stimulus signaling encompasses a wide range of mechanisms, ranging from clicking on hyperlinks, to pressing buttons, to traditional Dual-Tone Multi- Frequency (DTMF) input. In all cases, stimulus signaling is supported through the use of markup languages, which play a key role in this framework.
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) 2009 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 publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Simplified BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the BSD License.
Rosenberg Standards Track [Page 1]
RFC 5629 App Interaction Framework October 2009
This document may contain material from IETF Documents or IETF Contributions published or made publicly available before November 10, 2008. The person(s) controlling the copyright in some of this material may not have granted the IETF Trust the right to allow
modifications of such material outside the IETF Standards Process. Without obtaining an adequate license from the person(s) controlling the copyright in such materials, this document may not be modified outside the IETF Standards Process, and derivative works of it may not be created outside the IETF Standards Process, except to format it for publication as an RFC or to translate it into languages other than English.
The Session Initiation Protocol (SIP) [2] provides the ability for users to initiate, manage, and terminate communications sessions. Frequently, these sessions will involve a SIP application. A SIP application is defined as a program running on a SIP-based element (such as a proxy or user agent) that provides some value-added function to a user or system administrator. Examples of SIP applications include prepaid calling card calls, conferencing, and presence-based [12] call routing.
In order for most applications to properly function, they need input from the user to guide their operation. As an example, a prepaid calling card application requires the user to input their calling card number, their PIN code, and the destination number they wish to reach. The process by which a user provides input to an application is called "application interaction".
Application interaction can be either functional or stimulus. Functional interaction requires the user device to understand the semantics of the application, whereas stimulus interaction does not. Stimulus signaling allows for applications to be built without requiring modifications to the user device. Stimulus interaction is the subject of this framework. The framework provides a model for how users interact with applications through user interfaces, and how user interfaces and applications can be distributed throughout a network. This model is then used to describe how applications can instantiate and manage user interfaces.
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 [1]
SIP Application: A SIP application is defined as a program running on a SIP-based element (such as a proxy or user agent) that provides some value-added function to a user or system administrator. Examples of SIP applications include prepaid calling card calls, conferencing, and presence-based [12] call routing.
Application Interaction: The process by which a user provides input to an application.
Rosenberg Standards Track [Page 4]
RFC 5629 App Interaction Framework October 2009
Real-Time Application Interaction: Application interaction that takes place while an application instance is executing. For example, when a user enters their PIN number into a prepaid calling card application, this is real-time application interaction.
Non-Real-Time Application Interaction: Application interaction that takes place asynchronously with the execution of the application. Generally, non-real-time application interaction is accomplished through provisioning.
Functional Application Interaction: Application interaction is functional when the user device has an understanding of the semantics of the interaction with the application.
Stimulus Application Interaction: Application interaction is stimulus when the user device has no understanding of the semantics of the interaction with the application.
User Interface (UI): The user interface provides the user with context to make decisions about what they want. The user interacts with the device, which conveys the user input to the user interface. The user interface interprets the information and passes it to the application.
User Interface Component: A piece of user interface that operates independently of other pieces of the user interface. For example, a user might have two separate web interfaces to a prepaid calling card application: one for hanging up and making another call, and another for entering the username and PIN.
User Device: The software or hardware system that the user directly interacts with to communicate with the application. An example of a user device is a telephone. Another example is a PC with a web browser.
User Device Proxy: A software or hardware system that a user indirectly interacts through to communicate with the application. This indirection can be through a network. An example is a gateway from IP to the Public Switched Telephone Network (PSTN). It acts as a user device proxy, acting on behalf of the user on the circuit network.
User Input: The "raw" information passed from a user to a user interface. Examples of user input include a spoken word or a click on a hyperlink.
Rosenberg Standards Track [Page 5]
RFC 5629 App Interaction Framework October 2009
Client-Local User Interface: A user interface that is co-resident with the user device.
Client-Remote User Interface: A user interface that executes remotely from the user device. In this case, a standardized interface is needed between the user device and the user interface. Typically, this is done through media sessions: audio, video, or application sharing.
Markup Language: A markup language describes a logical flow of presentation of information to the user, collection of information from the user, and transmission of that information to an application.
Media Interaction: A means of separating a user and a user interface by connecting them with media streams.
Interactive Voice Response (IVR): An IVR is a type of user interface that allows users to speak commands to the application, and hear responses to those commands prompting for more information.
Prompt-and-Collect: The basic primitive of an IVR user interface. The user is presented with a voice option, and the user speaks their choice.
Barge-In: The act of entering information into an IVR user interface prior to the completion of a prompt requesting that information.
Focus: A user interface component has focus when user input is provided to it, as opposed to any other user interface components. This is not to be confused with the term "focus" within the SIP conferencing framework, which refers to the center user agent in a conference [14].
Focus Determination: The process by which the user device determines which user interface component will receive the user input.
Focusless Device: A user device that has no ability to perform focus determination. An example of a focusless device is a telephone with a keypad.
Presentation-Capable UI: A user interface that can prompt the user with input, collect results, and then prompt the user with new information based on those results.
Rosenberg Standards Track [Page 6]
RFC 5629 App Interaction Framework October 2009
Presentation-Free UI: A user interface that cannot prompt the user with information.
Feature Interaction: A class of problems that result when multiple applications or application components are trying to provide services to a user at the same time.
Inter-Application Feature Interaction: Feature interactions that occur between applications.
DTMF: Dual-Tone Multi-Frequency. DTMF refers to a class of tones generated by circuit-switched telephony devices when the user presses a key on the keypad. As a result, DTMF and keypad input are often used synonymously, when in fact one of them (DTMF) is merely a means of conveying the other (the keypad input) to a client-remote user interface (the switch, for example).
Application Instance: A single execution path of a SIP application.
Originating Application: A SIP application that acts as a User Agent Client (UAC), making a call on behalf of the user.
Terminating Application: A SIP application that acts as a User Agent Server (UAS), answering a call generated by a user. IVR applications are terminating applications.
Intermediary Application: A SIP application that is neither the caller or callee, but rather a third party involved in a call.
+---+ +---+ +---+ +---+ | | | | | | | | | | | U | | U | | A | | | Input | s | Input | s | Results | p | | | ---------> | e | ---------> | e | ----------> | p | | U | | r | | r | | l | | s | | | | | | i | | e | | D | | I | | c | | r | Output | e | Output | f | Update | a | | | <--------- | v | <--------- | a | <.......... | t | | | | i | | c | | i | | | | c | | e | | o | | | | e | | | | n | | | | | | | | | +---+ +---+ +---+ +---+
Figure 1: Model for Real-Time Interactions
Rosenberg Standards Track [Page 7]
RFC 5629 App Interaction Framework October 2009
Figure 1 presents a general model for how users interact with applications. Generally, users interact with a user interface through a user device. A user device can be a telephone, or it can be a PC with a web browser. Its role is to pass the user input from the user to the user interface. The user interface provides the user with context in order to make decisions about what they want. The user interacts with the device, causing information to be passed from the device to the user interface. The user interface interprets the information, and passes it as a user interface event to the application. The application may be able to modify the user interface based on this event. Whether or not this is possible depends on the type of user interface.
User interfaces are fundamentally about rendering and interpretation. Rendering refers to the way in which the user is provided context. This can be through hyperlinks, images, sounds, videos, text, and so on. Interpretation refers to the way in which the user interface takes the "raw" data provided by the user, and returns the result to the application as a meaningful event, abstracted from the particulars of the user interface. As an example, consider a prepaid calling card application. The user interface worries about details such as what prompt the user is provided, whether the voice is male or female, and so on. It is concerned with recognizing the speech that the user provides, in order to obtain the desired information. In this case, the desired information is the calling card number, the PIN code, and the destination number. The application needs that data, and it doesn't matter to the application whether it was collected using a male prompt or a female one.
User interfaces generally have real-time requirements towards the user. That is, when a user interacts with the user interface, the user interface needs to react quickly, and that change needs to be propagated to the user right away. However, the interface between the user interface and the application need not be that fast. Faster is better, but the user interface itself can frequently compensate for long latencies between the user interface and the application. In the case of a prepaid calling card application, when the user is prompted to enter their PIN, the prompt should generally stop immediately once the first digit of the PIN is entered. This is referred to as "barge-in". After the user interface collects the rest of the PIN, it can tell the user to "please wait while processing". The PIN can then be gradually transmitted to the application. In this example, the user interface has compensated for a slow UI to application interface by asking the user to wait.
The separation between user interface and application is absolutely fundamental to the entire framework provided in this document. Its importance cannot be overstated.
Rosenberg Standards Track [Page 8]
RFC 5629 App Interaction Framework October 2009
With this basic model, we can begin to taxonomize the types of systems that can be built.
The first way to taxonomize the system is to consider the interface between the UI and the application. There are two fundamentally different models for this interface. In a functional interface, the user interface has detailed knowledge about the application and is, in fact, specific to the application. The interface between the two components is through a functional protocol, capable of representing the semantics that can be exposed through the user interface. Because the user interface has knowledge of the application, it can be optimally designed for that application. As a result, functional user interfaces are almost always the most user friendly, the fastest, and the most responsive. However, in order to allow interoperability between user devices and applications, the details of the functional protocols need to be specified in standards. This slows down innovation and limits the scope of applications that can be built.
An alternative is a stimulus interface. In a stimulus interface, the user interface is generic -- that is, totally ignorant of the details of the application. Indeed, the application may pass instructions to the user interface describing how it should operate. The user interface translates user input into "stimulus", which are data understood only by the application, and not by the user interface. Because they are generic, and because they require communications with the application in order to change the way in which they render information to the user, stimulus user interfaces are usually slower, less user friendly, and less responsive than a functional counterpart. However, they allow for substantial innovation in applications, since no standardization activity is needed to build a new application, as long as it can interact with the user within the confines of the user interface mechanism. The web is an example of a stimulus user interface to applications.
In SIP systems, functional interfaces are provided by extending the SIP protocol to provide the needed functionality. For example, the SIP caller preferences specification [15] provides a functional interface that allows a user to request applications to route the call to specific types of user agents. Functional interfaces are important, but are not the subject of this framework. The primary goal of this framework is to address the role of stimulus interfaces to SIP applications.
Application interaction systems can also be real-time or non-real- time. Non-real-time interaction allows the user to enter information about application operation asynchronously with its invocation. Frequently, this is done through provisioning systems. As an example, a user can set up the forwarding number for a call-forward on no-answer application using a web page. Real-time interaction requires the user to interact with the application at the time of its invocation.
Another axis in the taxonomization is whether the user interface is co-resident with the user device (which we refer to as a client-local user interface), or the user interface runs in a host separated from the client (which we refer to as a client-remote user interface). In a client-remote user interface, there exists some kind of protocol between the client device and the UI that allows the client to interact with the user interface over a network.
The most important way to separate the UI and the client device is through media interaction. In media interaction, the interface between the user and the user interface is through media: audio, video, messaging, and so on. This is the classic mode of operation for VoiceXML [5], where the user interface (also referred to as the voice browser) runs on a platform in the network. Users communicate with the voice browser through the telephone network (or using a SIP session). The voice browser interacts with the application using HTTP to convey the information collected from the user.
In the case of a client-local user interface, the user interface runs co-located with the user device. The interface between them is through the software that interprets the user's input and passes it to the user interface. The classic example of this is the Web. In the Web, the user interface is a web browser, and the interface is defined by the HTML document that it's rendering. The user interacts directly with the user interface running in the browser. The results of that user interface are sent to the application (running on the web server) using HTTP.
It is important to note that whether or not the user interface is local or remote (in the case of media interaction) is not a property of the modality of the interface, but rather a property of the system. As an example, it is possible for a Web-based user interface to be provided with a client-remote user interface. In such a scenario, video- and application-sharing media sessions can be used between the user and the user interface. The user interface, still
Rosenberg Standards Track [Page 10]
RFC 5629 App Interaction Framework October 2009
guided by HTML, now runs "in the network", remote from the client. Similarly, a VoiceXML document can be interpreted locally by a client device, with no media streams at all. Indeed, the VoiceXML document can be rendered using text, rather than media, with no impact on the interface between the user interface and the application.
It is also important to note that systems can be hybrid. In a hybrid user interface, some aspects of it (usually those associated with a particular modality) run locally, and others run remotely.
A user interface can be capable of presenting information to the user (a presentation-capable UI), or it can be capable only of collecting user input (a presentation-free UI). These are very different types of user interfaces. A presentation-capable UI can provide the user with feedback after every input, providing the context for collecting the next input. As a result, presentation-capable user interfaces require an update to the information provided to the user after each input. The Web is a classic example of this. After every input (i.e., a click), the browser provides the input to the application and fetches the next page to render. In a presentation-free user interface, this is not the case. Since the user is not provided with feedback, these user interfaces tend to merely collect information as it's entered, and pass it to the application.
Another difference is that a presentation-free user interface cannot easily support the concept of a focus. Selection of a focus usually requires a means for informing the user of the available applications, allowing the user to choose, and then informing them about which one they have chosen. Without the first and third steps (which a presentation-free UI cannot provide), focus selection is very difficult. Without a selected focus, the input provided to applications through presentation-free user interfaces is more of a broadcast or notification operation.
In this section, we apply the model of Section 4 to telephones.
In a traditional telephone, the user interface consists of a 12-key keypad, a speaker, and a microphone. Indeed, from here forward, the term "telephone" is used to represent any device that meets, at a minimum, the characteristics described in the previous sentence. Circuit-switched telephony applications are almost universally client-remote user interfaces. In the Public Switched Telephone Network (PSTN), there is usually a circuit interface between the user and the user interface. The user input from the keypad is conveyed
Rosenberg Standards Track [Page 11]
RFC 5629 App Interaction Framework October 2009
using Dual-Tone Multi-Frequency (DTMF), and the microphone input as Pulse Code Modulated (PCM) encoded voice.
In an IP-based system, there is more variability in how the system can be instantiated. Both client-remote and client-local user interfaces to a telephone can be provided.
In this framework, a PSTN gateway can be considered a User Device Proxy. It is a proxy for the user because it can provide, to a user interface on an IP network, input taken from a user on a circuit- switched telephone. The gateway may be able to run a client-local user interface, just as an IP telephone might.
The most obvious instantiation is the "classic" circuit-switched telephony model. In that model, the user interface runs remotely from the client. The interface between the user and the user interface is through media, which is set up by SIP and carried over the Real Time Transport Protocol (RTP) [18]. The microphone input can be carried using any suitable voice-encoding algorithm. The keypad input can be conveyed in one of two ways. The first is to convert the keypad input to DTMF, and then convey that DTMF using a suitable encoding algorithm (such as PCMU). An alternative, and generally the preferred approach, is to transmit the keypad input using RFC 4733 [19], which provides an encoding mechanism for carrying keypad input within RTP.
In this classic model, the user interface would run on a server in the IP network. It would perform speech recognition and DTMF recognition to derive the user intent, feed them through the user interface, and provide the result to an application.
An alternative model is for the entire user interface to reside on the telephone. The user interface can be a VoiceXML browser, running speech recognition on the microphone input, and feeding the keypad input directly into the script. As discussed above, the VoiceXML script could be rendered using text instead of voice, if the telephone has a textual display.
For simpler phones without a display, the user interface can be described by a Keypad Markup Language request document [8]. As the user enters digits in the keypad, they are passed to the user interface, which generates user interface events that can be transported to the application.
A middle-ground approach is to flip back and forth between a client- local and client-remote user interface. Many voice applications are of the type that listen to the media stream and wait for some specific trigger that kicks off a more complex user interaction. The long pound in a prepaid calling card application is one example. Another example is a conference recording application, where the user can press a key at some point in the call to begin recording. When the key is pressed, the user hears a whisper to inform them that recording has started.
The ideal way to support such an application is to install a client- local user interface component that waits for the trigger to kick off the real interaction. Once the trigger is received, the application connects the user to a client-remote user interface that can play announcements, collect more information, and so on.
The benefit of flip-flopping between a client-local and client-remote user interface is cost. The client-local user interface will eliminate the need to send media streams into the network just to wait for the user to press the pound key on the keypad.
The Keypad Markup Language (KPML) was designed to support exactly this kind of need [8]. It models the keypad on a phone and allows an application to be informed when any sequence of keys has been pressed. However, KPML has no presentation component. Since user interfaces generally require a response to user input, the presentation will need to be done using a client-remote user interface that gets instantiated as a result of the trigger.
It is tempting to use a hybrid model, where a prompt-and-collect application is implemented by using a client-remote user interface that plays the prompts, and a client-local user interface, described by KPML, that collects digits. However, this only complicates the application. Firstly, the keypad input will be sent to both the media stream and the KPML user interface. This requires the application to sort out which user inputs are duplicates, a process that is very complicated. Secondly, the primary benefit of KPML is to avoid having a media stream towards a user interface. However, there is already a media stream for the prompting, so there is no real savings.
In this framework, we use the term "SIP application" to refer to a broad set of functionality. A SIP application is a program running on a SIP-based element (such as a proxy or user agent) that provides
Rosenberg Standards Track [Page 13]
RFC 5629 App Interaction Framework October 2009
some value-added function to a user or system administrator. SIP applications can execute on behalf of a caller, a called party, or a multitude of users at once.
Each application has a number of instances that are executing at any given time. An instance represents a single execution path for an application. It is established as a result of some event. That event can be a SIP event, such as the reception of a SIP INVITE request, or it can be a non-SIP event, such as a web form post or even a timer. Application instances also have an end time. Some instances have a lifetime that is coupled with a SIP transaction or dialog. For example, a proxy application might begin when an INVITE arrives, and terminate when the call is answered. Other applications have a lifetime that spans multiple dialogs or transactions. For example, a conferencing application instance may exist so long as there are dialogs connected to it. When the last dialog terminates, the application instance terminates. Other applications have a lifetime that is completely decoupled from SIP events.
It is fundamental to the framework described here that multiple application instances may interact with a user during a single SIP transaction or dialog. Each instance may be for the same application, or different applications. Each of the applications may be completely independent, in that each may be owned by a different provider, and may not be aware of each other's existence. Similarly, there may be application instances interacting with the caller, and instances interacting with the callee, both within the same transaction or dialog.
The first step in the interaction with the user is to instantiate one or more user interface components for the application instance. A user interface component is a single piece of the user interface that is defined by a logical flow that is not synchronously coupled with any other component. In other words, each component runs independently.
A user interface component can be instantiated in one of the user agents in a dialog (for a client-local user interface), or within a network element (for a client-remote user interface). If a client- local user interface is to be used, the application needs to determine whether or not the user agent is capable of supporting a client-local user interface, and in what format. In this framework, all client-local user interface components are described by a markup language. A markup language describes a logical flow of presentation of information to the user, a collection of information from the user, and a transmission of that information to an application. Examples of markup languages include HTML, Wireless Markup Language (WML), VoiceXML, and the Keypad Markup Language (KPML) [8].
Rosenberg Standards Track [Page 14]
RFC 5629 App Interaction Framework October 2009
Unlike an application instance, which has a very flexible lifetime, a user interface component has a very fixed lifetime. A user interface component is always associated with a dialog. The user interface component can be created at any point after the dialog (or early dialog) is created. However, the user interface component terminates when the dialog terminates. The user interface component can be terminated earlier by the user agent, and possibly by the application, but its lifetime never exceeds that of its associated dialog.
There are two ways to create a client-local interface component. For interface components that are presentation capable, the application sends a REFER [7] request to the user agent. The Refer-To header field contains an HTTP URI that points to the markup for the user interface, and the REFER contains a Target-Dialog header field [10] which identifies the dialog associated with the user interface component. For user interface components that are presentation free (such as those defined by KPML), the application sends a SUBSCRIBE request to the user agent. The body of the SUBSCRIBE request contains a filter, which, in this case, is the markup that defines when information is to be sent to the application in a NOTIFY. The SUBSCRIBE does not contain the Target-Dialog header field, since equivalent information is conveyed in the Event header field.
If a user interface component is to be instantiated in the network, there is no need to determine the capabilities of the device on which the user interface is instantiated. Presumably, it is on a device on which the application knows a UI can be created. However, the application does need to connect the user device to the user interface. This will require manipulation of media streams in order to establish that connection.
The interface between the user interface component and the application depends on the type of user interface. For presentation- capable user interfaces, such as those described by HTML and VoiceXML, HTTP form POST operations are used. For presentation-free user interfaces, a SIP NOTIFY is used. The differing needs and capabilities of these two user interfaces, as described in Section 4.4, are what drives the different choices for the interactions. Since presentation-capable user interfaces require an update to the presentation every time user data is entered, they are a good match for HTTP. Since presentation-free user interfaces merely transmit user input to the application, a NOTIFY is more appropriate.
Indeed, for presentation-free user interfaces, there are two different modalities of operation. The first is called "one shot". In the one-shot role, the markup waits for a user to enter some
Rosenberg Standards Track [Page 15]
RFC 5629 App Interaction Framework October 2009
information and, when they do, reports this event to the application. The application then does something, and the markup is no longer used. In the other modality, called "monitor", the markup stays permanently resident, and reports information back to an application until termination of the associated dialog.
In this topology, the application that is interested in interacting with the users exists outside of the SIP dialog between the user agents. In that case, the application learns about the initiation and termination of the dialog, along with the dialog identifiers, through some out-of-band means. One such possibility is the dialog event package [16]. Dialog information is only revealed to trusted parties, so the application would need to be trusted by one of the users in order to obtain this information.
At any point during the dialog, the application can instantiate user interface components on the user device of the caller or callee. It can do this using either SUBSCRIBE or REFER, depending on the type of user interface (presentation capable or presentation free).
In this deployment topology, the application is co-resident with one of the user agents (the one on the right in the picture above). This application can install client-local user interface components on the other user agent, which is acting as the user device. These components can be installed using either SUBSCRIBE, for presentation- free user interfaces, or REFER, for presentation-capable ones. This situation typically arises when the application wishes to install UI components on a presentation-capable user interface. If the only user input is via keypad input, the framework is not needed per se, because the UA/application will receive the input via RFC 4733 in the RTP stream.
If the application resides in the called party, it is called a "terminating application". If it resides in the calling party, it is called an "originating application".
This kind of topology is common in protocol converter and gateway applications.
Rosenberg Standards Track [Page 17]
RFC 5629 App Interaction Framework October 2009
7.3. Third-Party Application and User Device Proxy
In this deployment topology, there is a third-party application as in Section 7.1. However, instead of installing a user interface component on the end user device, the component is installed in an intermediate device, known as a User Device Proxy. From the perspective of the actual user device (on the left), the User Device Proxy is a client remote user interface. As such, media, typically transported using RTP (including RFC 4733 for carrying user input), is sent from the user device to the client remote user interface on the User Device Proxy. As far as the application is concerned, it is installing what it thinks is a client-local user interface on the user device, but it happens to be on a user device proxy that looks like the user device to the application.
The user device proxy will need to terminate and re-originate both signaling (SIP) and media traffic towards the actual peer in the conversation. The User Device Proxy is a media relay in the terminology of RFC 3550 [18]. The User Device Proxy will need to monitor the media streams associated with each dialog, in order to convert user input received in the media stream to events reported to the user interface. This can pose a challenge in multi-media systems, where it may be unclear on which media stream the user input is being sent. As discussed in RFC 3264 [20], if a user agent has a single media source and is supporting multiple streams, it is supposed to send that source to all streams. In cases where there are multiple sources, the mapping is a matter of local policy. In
Rosenberg Standards Track [Page 18]
RFC 5629 App Interaction Framework October 2009
the absence of a way to explicitly identify or request which sources map to which streams, the user device proxy will need to do the best job it can. This specification RECOMMENDS that the User Device Proxy monitor the first stream (defined in terms of ordering of media sessions within a session description). As such, user agents SHOULD send their user input on the first stream, absent a policy to direct it otherwise.
In this topology, the application is co-resident with a transaction stateful, record-routing proxy server on the call path between two user devices. The application uses SUBSCRIBE or REFER to install user interface components on one or both user devices.
This topology is common in routing applications, such as a web- assisted call-routing application.
A client-local user interface can only be instantiated on a user agent if the user agent supports that type of user interface component. Support for client-local user interface components is declared by both the UAC and UAS in their Allow, Accept, Supported, and Allow-Event header fields of dialog-initiating requests and responses. If the Allow header field indicates support for the SIP SUBSCRIBE method, and the Allow-Event header field indicates support for the KPML package [8], and the Supported header field indicates support for the Globally Routable UA URI (GRUU) [9] specification (which, in turn, means that the Contact header field contains a GRUU), it means that the UA can instantiate presentation-free user interface components. In this case, the application can push presentation-free user interface components according to the rules of Section 8.1.2. The specific markup languages that can be supported are indicated in the Accept header field.
If the Allow header field indicates support for the SIP REFER method, and the Supported header field indicates support for the Target- Dialog header field [10], and the Contact header field contains UA capabilities [6] that indicate support for the HTTP URI scheme, it means that the UA supports presentation-capable user interface components. In this case, the application can push presentation- capable user interface components to the client according to the rules of Section 8.1.2. The specific markups that are supported are indicated in the Accept header field.
A third-party application that is not present on the call path will not be privy to these header fields in the dialog-initiating requests that pass by. As such, it will need to obtain this capability information in other ways. One way is through the registration event package [21], which can contain user agent capability information provided in REGISTER requests [6].
Generally, we anticipate that interface components will need to be created at various different points in a SIP session. Clearly, they will need to be pushed during session setup, or after the session is established. A user interface component is always associated with a specific dialog, however.
Rosenberg Standards Track [Page 20]
RFC 5629 App Interaction Framework October 2009
An application MUST NOT attempt to push a user interface component to a user agent until it has determined that the user agent has the necessary capabilities and a dialog has been created. In the case of a UAC, this means that an application MUST NOT push a user interface component for an INVITE-initiated dialog until the application has seen a request confirming the receipt of a dialog-creating response. This could be an ACK for a 200 OK, or a PRACK for a provisional response [3]. For SUBSCRIBE-initiated dialogs, the application MUST NOT push a user interface component until the application has seen a 200 OK to the NOTIFY request. For a user interface component on a UAS, the application MUST NOT push a user interface component for an INVITE-initiated dialog until it has seen a dialog-creating response from the UAS. For a SUBSCRIBE-initiated dialog, it MUST NOT push a user interface component until it has seen a NOTIFY request from the notifier.
To create a presentation-capable UI component on the UA, the application sends a REFER request to the UA. This REFER MUST be sent to the GRUU [9] advertised by that UA in the Contact header field of the dialog-initiating request or response sent by that UA. Note that this REFER request creates a separate dialog between the application and the UA. The Refer-To header field of the REFER request MUST contain an HTTP URI that references the markup document to be fetched.
Furthermore, it is essential for the REFER request to be correlated with the dialog to which the user interface component will be associated. This is necessary for authorization and for terminating the user interface components when the dialog terminates. To provide this context, the REFER request MUST contain a Target-Dialog header field identifying the dialog with which the user interface component is associated. As discussed in [10], this request will also contain a Require header field with the tdialog option tag.
To create a presentation-free user interface component, the application sends a SUBSCRIBE request to the UA. The SUBSCRIBE MUST be sent to the GRUU advertised by the UA. This SUBSCRIBE request creates a separate dialog. The SUBSCRIBE request MUST use the KPML [8] event package. The body of the SUBSCRIBE request contains the markup document that defines the conditions under which the application wishes to be notified of user input.
In both cases, the REFER or SUBSCRIBE request SHOULD include a display name in the From header field that identifies the name of the application. For example, a prepaid calling card might include a From header field that looks like:
Once a user interface component has been created on a client, it can be updated. The means for updating it depends on the type of UI component.
Presentation-capable UI components are updated using techniques already in place for those markups. In particular, user input will cause an HTTP POST operation to push the user input to the application. The result of the POST operation is a new markup that the UI is supposed to use. This allows the UI to be updated in response to user action. Some markups, such as HTML, provide the ability to force a refresh after a certain period of time, so that the UI can be updated without user input. Those mechanisms can be used here as well. However, there is no support for an asynchronous push of an updated UI component from the application to the user agent. A new REFER request to the same GRUU would create a new UI component rather than update any components already in place.
For presentation-free UI, the story is different. The application MAY update the filter at any time by generating a SUBSCRIBE refresh with the new filter. The UA will immediately begin using this new filter.
User interface components have a well-defined lifetime. They are created when the component is first pushed to the client. User interface components are always associated with the SIP dialog on which they were pushed. As such, their lifetime is bound by the lifetime of the dialog. When the dialog ends, so does the interface component.
However, there are some cases where the application would like to terminate the user interface component before its natural termination point. For presentation-capable user interfaces, this is not possible. For presentation-free user interfaces, the application MAY terminate the component by sending a SUBSCRIBE with Expires equal to zero. This terminates the subscription, which removes the UI component.
A client can remove a UI component at any time. For presentation- capable UI, this is analogous to the user dismissing the web form
Rosenberg Standards Track [Page 22]
RFC 5629 App Interaction Framework October 2009
window. There is no mechanism provided for reporting this kind of event to the application. The application MUST be prepared to time out and never receive input from a user. The duration of this timeout is application dependent. For presentation-free user interfaces, the UA can explicitly terminate the subscription. This will result in the generation of a NOTIFY with a Subscription-State header field equal to "terminated".
As an alternative to, or in conjunction with client-local user interfaces, an application can make use of client-remote user interfaces. These user interfaces can execute co-resident with the application itself (in which case no standardized interfaces between the UI and the application need to be used), or they can run separately. This framework assumes that the user interface runs on a host that has a sufficient trust relationship with the application. As such, the means for instantiating the user interface is not considered here.
The primary issue is to connect the user device to the remote user interface. Doing so requires the manipulation of media streams between the client and the user interface. Such manipulation can only be done by user agents. There are two types of user agent applications within this framework: originating/terminating applications, and intermediary applications.
Originating and terminating applications are applications that are themselves the originator or the final recipient of a SIP invitation. They are "pure" user agent applications, not back-to-back user agents. The classic example of such an application is an interactive voice response (IVR) application, which is typically a terminating application. It is a terminating application because the user explicitly calls it; i.e., it is the actual called party. An example of an originating application is a wakeup call application, which calls a user at a specified time in order to wake them up.
Because originating and terminating applications are a natural termination point of the dialog, manipulation of the media session by the application is trivial. Traditional SIP techniques for adding and removing media streams, modifying codecs, and changing the address of the recipient of the media streams can be applied.
Intermediary applications are, at the same time, more common than originating/terminating applications and more complex. Intermediary applications are applications that are neither the actual caller nor the called party. Rather, they represent a "third party" that wishes to interact with the user. The classic example is the ubiquitous prepaid calling card application.
In order for the intermediary application to add a client-remote user interface, it needs to manipulate the media streams of the user agent to terminate on that user interface. This also introduces a fundamental feature interaction issue. Since the intermediary application is not an actual participant in the call, the user will need to interact with both the intermediary application and its peer in the dialog. Doing both at the same time is complicated and is discussed in more detail in Section 10.
In order to participate in applications that make use of stimulus interfaces, a user agent needs to advertise its interaction capabilities.
If a user agent supports presentation-capable user interfaces, it MUST support the REFER method. It MUST include, in all dialog- initiating requests and responses, an Allow header field that includes the REFER method. The user agent MUST support the target dialog specification [10], and MUST include the "tdialog" option tag in the Supported header field of dialog-forming requests and responses. Furthermore, the UA MUST support the SIP user agent capabilities specification [6]. The UA MUST be capable of being REFERed to an HTTP URI. It MUST include, in the Contact header field of its dialog-initiating requests and responses, a "schemes" Contact header field parameter that includes the HTTP URI scheme. The UA MUST include, in all dialog-initiating requests and responses, an Accept header field listing all of those markups supported by the UA. It is RECOMMENDED that all user agents that support presentation- capable user interfaces support HTML.
If a user agent supports presentation-free user interfaces, it MUST support the SUBSCRIBE [4] method. It MUST support the KPML [8] event package. It MUST include, in all dialog-initiating requests and responses, an Allow header field that includes the SUBSCRIBE method. It MUST include, in all dialog-initiating requests and responses, an Allow-Events header field that lists the KPML event package. The UA
Rosenberg Standards Track [Page 24]
RFC 5629 App Interaction Framework October 2009
MUST include, in all dialog-initiating requests and responses, an Accept header field listing those event filters it supports. At a minimum, a UA MUST support the "application/kpml-request+xml" MIME type.
For either presentation-free or presentation-capable user interfaces, the user agent MUST support the GRUU [9] specification. The Contact header field in all dialog-initiating requests and responses MUST contain a GRUU. The UA MUST include a Supported header field that contains the "gruu" option tag and the "tdialog" option tag.
Because these headers are examined by proxies that may be executing applications, a UA that wishes to support client-local user interfaces should not encrypt them.
Once the UA has created a dialog (in either the early or confirmed states), it MUST be prepared to receive a SUBSCRIBE or REFER request against its GRUU. If the UA receives such a request prior to the establishment of a dialog, the UA MUST reject the request.
A user agent SHOULD attempt to authenticate the sender of the request. The sender will generally be an application; therefore, the user agent is unlikely to ever have a shared secret with it, making digest authentication useless. However, authenticated identities can be obtained through other means, such as the Identity mechanism [11].
A user agent MAY have pre-defined authorization policies that permit applications which have authenticated themselves with a particular identity to push user interface components. If such a set of policies is present, it is checked first. If the application is authorized, processing proceeds.
If the application has authenticated itself but is not explicitly authorized or blocked, this specification RECOMMENDS that the application be automatically authorized if it can prove that it was either on the call path, or is trusted by one of the elements on the call path. An application proves this to the user agent by demonstrating that it knows the dialog identifiers. That occurs by including them in a Target-Dialog header field for REFER requests, or in the Event header field parameters of the KPML SUBSCRIBE request.
Because the dialog identifiers serve as a tool for authorization, a user agent compliant to this framework SHOULD use dialog identifiers that are cryptographically random, with at least 128 bits of randomness. It is recommended that this randomness be split between the Call-ID and From header field tags in the case of a UAC.
Rosenberg Standards Track [Page 25]
RFC 5629 App Interaction Framework October 2009
Furthermore, to ensure that only applications resident in or trusted by on-path elements can instantiate a user interface component, a user agent compliant to this specification SHOULD use the Session Initiation Protocol Secure (SIPS) URI scheme for all dialogs it initiates. This will guarantee secure links between all the elements on the signaling path.
If the dialog was not established with a SIPS URI, or the user agent did not choose cryptographically random dialog identifiers, then the application MUST NOT automatically be authorized, even if it presented valid dialog identifiers. A user agent MAY apply any other policies in addition to (but not instead of) the ones specified here in order to authorize the creation of the user interface component. One such mechanism would be to prompt the user, informing them of the identity of the application and the dialog it is associated with. If an authorization policy requires user interaction, the user agent SHOULD respond to the SUBSCRIBE or REFER request with a 202. In the case of SUBSCRIBE, if authorization is not granted, the user agent SHOULD generate a NOTIFY to terminate the subscription. In the case of REFER, the user agent MUST NOT act upon the URI in the Refer-To header field until user authorization is obtained.
If an application does not present a valid dialog identifier in its REFER or SUBSCRIBE request, the user agent MUST reject the request with a 403 response.
If a REFER request to an HTTP URI is authorized, the UA executes the URI and fetches the content to be rendered to the user. This instantiates a presentation-capable user interface component. If a SUBSCRIBE was authorized, a presentation-free user interface component is instantiated.
9.3. Mapping User Input to User Interface Components
Once the user interface components are instantiated, the user agent must direct user input to the appropriate component. In the case of presentation-capable user interfaces, this process is known as focus selection. It is done by means that are specific to the user interface on the device. In the case of a PC, for example, the window manager would allow the user to select the appropriate user interface component to which their input is directed.
For presentation-free user interfaces, the situation is more complicated. In some cases, the device may support a mechanism that allows the user to select a "line", and thus the associated dialog. Any user input on the keypad while this line is selected are fed to the user interface components associated with that dialog.
Rosenberg Standards Track [Page 26]
RFC 5629 App Interaction Framework October 2009
Otherwise, for client-local user interfaces, the user input is assumed to be associated with all user interface components. For client-remote user interfaces, the user device converts the user input to media, typically conveyed using RFC 4733, and sends this to the client-remote user interface. This user interface then needs to map user input from potentially many media streams into user interface events. The process for doing this is described in Section 7.3.
9.4. Receiving Updates to User Interface Components
For presentation-capable user interfaces, updates to the user interface occur in ways specific to that user interface component. In the case of HTML, for example, the document can tell the client to fetch a new document periodically. However, this framework does not provide any additional machinery to asynchronously push a new user interface component to the client.
For presentation-free user interfaces, an application can push an update to a component by sending a SUBSCRIBE refresh with a new filter. The user agent will process these according to the rules of the event package.
Termination of a presentation-capable user interface component is a trivial procedure. The user agent merely dismisses the window (or its equivalent). The fact that the component is dismissed is not communicated to the application. As such, it is purely a local matter.
In the case of a presentation-free user interface, the user might wish to cease interacting with the application. However, most presentation-free user interfaces will not have a way for the user to signal this through the device. If such a mechanism did exist, the UA SHOULD generate a NOTIFY request with a Subscription-State header field equal to "terminated" and a reason of "rejected". This tells the application that the component has been removed and that it should not attempt to re-subscribe.
The inter-application feature interaction problem is inherent to stimulus signaling. Whenever there are multiple applications, there are multiple user interfaces. The system has to determine to which user interface any particular input is destined. That question is the essence of the inter-application feature interaction problem.
Rosenberg Standards Track [Page 27]
RFC 5629 App Interaction Framework October 2009
Inter-application feature interaction is not an easy problem to resolve. For now, we consider separately the issues for client-local and client-remote user interface components.
When the user interface itself resides locally on the client device, the feature interaction problem is actually much simpler. The end device knows explicitly about each application, and therefore can present the user with each one separately. When the user provides input, the client device can determine to which user interface the input is destined. The user interface to which input is destined is referred to as the "application in focus", and the means by which the focused application is selected is called "focus determination".
Generally speaking, focus determination is purely a local operation. In the PC universe, focus determination is provided by window managers. Each application does not know about focus; it merely receives the user input that has been targeted to it when it's in focus. This basic concept applies to SIP-based applications as well.
Focus determination will frequently be trivial, depending on the user interface type. Consider a user that makes a call from a PC. The call passes through a prepaid calling card application and a call- recording application. Both of these wish to interact with the user. Both push an HTML-based user interface to the user. On the PC, each user interface would appear as a separate window. The user interacts with the call-recording application by selecting its window, and with the prepaid calling card application by selecting its window. Focus determination is literally provided by the PC window manager. It is clear to which application the user input is targeted.
As another example, consider the same two applications, but on a "smart phone" that has a set of buttons, and next to each button, there is an LCD display that can provide the user with an option. This user interface can be represented using the Wireless Markup Language (WML), for example.
The phone would allocate some number of buttons to each application. The prepaid calling card would get one button for its "hangup" command, and the recording application would get one for its "start/ stop" command. The user can easily determine which application to interact with by pressing the appropriate button. Pressing a button determines focus and provides user input, both at the same time.
Unfortunately, not all devices will have these advanced displays. A PSTN gateway, or a basic IP telephone, may only have a 12-key keypad. The user interfaces for these devices are provided through the Keypad
Rosenberg Standards Track [Page 28]
RFC 5629 App Interaction Framework October 2009
Markup Language (KPML). Considering once again the feature interaction case above, the prepaid calling card application and the call-recording application would both pass a KPML document to the device. When the user presses a button on the keypad, to which document does the input apply? The device does not allow the user to select. A device where the user cannot provide focus is called a "focusless device". This is quite a hard problem to solve. This framework does not make any explicit normative recommendation, but it concludes that the best option is to send the input to both user interfaces unless the markup in one interface has indicated that it should be suppressed from others. This is a sensible choice by analogy -- it's exactly what the existing circuit-switched telephone network will do. It is an explicit non-goal to provide a better mechanism for feature interaction resolution than the PSTN on devices that have the same user interface as they do on the PSTN. Devices with better displays, such as PCs or screen phones, can benefit from the capabilities of this framework, allowing the user to determine which application they are interacting with.
Indeed, when a user provides input on a focusless device, the input must be passed to all client-local user interfaces AND all client- remote user interfaces, unless the markup tells the UI to suppress the media. In the case of KPML, key events are passed to remote user interfaces by encoding them as described in RFC 4733 [19]. Of course, since a client cannot determine whether or not a media stream terminates in a remote user interface, these key events are passed in all audio media streams unless the KPML request document is used to suppress them.
When the user interfaces run remotely, the determination of focus can be much, much harder. There are many architectures that can be deployed to handle the interaction. None are ideal. However, all are beyond the scope of this specification.
An application can instantiate a multiplicity of user interface components. For example, a single application can instantiate two separate HTML components and one WML component. Furthermore, an application can instantiate both client-local and client-remote user interfaces.
The feature interaction issues between these components within the same application are less severe. If an application has multiple client user interface components, their interaction is resolved identically to the inter-application case -- through focus
Rosenberg Standards Track [Page 29]
RFC 5629 App Interaction Framework October 2009
determination. However, the problems in focusless user devices (such as a keypad on a telephone) generally won't exist, since the application can generate user interfaces that do not overlap in their usage of an input.
The real issue is that the optimal user experience frequently requires some kind of coupling between the differing user interface components. This is a classic problem in multi-modal user interfaces, such as those described by Speech Application Language Tags (SALT). As an example, consider a user interface where a user can either press a labeled button to make a selection, or listen to a prompt, and speak the desired selection. Ideally, when the user presses the button, the prompt should cease immediately, since both of them were targeted at collecting the same information in parallel. Such interactions are best handled by markups that natively support such interactions, such as SALT, and thus require no explicit support from this framework.
This section shows the operation of a call-recording application. This application allows a user to record the media in their call by clicking on a button in a web form. The application uses a presentation-capable user interface component that is pushed to the caller. The conventions of [17] are used to describe representation of long message lines.
Rosenberg Standards Track [Page 30]
RFC 5629 App Interaction Framework October 2009
A Recording App B |(1) INVITE | | |----------------------->| | | |(2) INVITE | | |----------------------->| | |(3) 200 OK | | |<-----------------------| |(4) 200 OK | | |<-----------------------| | |(5) ACK | | |----------------------->| | | |(6) ACK | | |----------------------->| |(7) REFER | | |<-----------------------| | |(8) 200 OK | | |----------------------->| | |(9) NOTIFY | | |----------------------->| | |(10) 200 OK | | |<-----------------------| | |(11) HTTP GET | | |----------------------->| | |(12) 200 OK | | |<-----------------------| | |(13) NOTIFY | | |----------------------->| | |(14) 200 OK | | |<-----------------------| | |(15) HTTP POST | | |----------------------->| | |(16) 200 OK | | |<-----------------------| |
Figure 6
First, the caller, A, sends an INVITE to set up a call (message 1). Since the caller supports the framework and can handle presentation- capable user interface components, it includes the Supported header field indicating that the GRUU extension and the Target-Dialog header field are understood, the Allow header field indicating that REFER is understood, and the Contact header field that includes the "schemes" header field parameter.
The proxy acts as a recording server, and forwards the INVITE to the called party (message 2). It strips the Record-Route it would normally insert due to the presence of the GRUU in the INVITE:
Since the recording application is the same as the authoritative proxy for the domain, it resolves the Request URI to the registered contact of A, and then sent there. The REFER is answered by a 200 OK (message 8).
And the recording server responds with a 200 OK (message 10).
SIP/2.0 200 OK Via: SIP/2.0/TLS host.example.com;branch=z9hG4bK9320394238995 To: Recorder Application <sip:app.example.com>;tag=jhgf From: Caller <sip:A@example.com>;tag=pqoew Call-ID: 66676776767@app.example.com CSeq: 1 NOTIFY
The REFER request contained a Target-Dialog header field parameter with a valid dialog identifier. Furthermore, all of the signaling was over TLS and the dialog identifiers contain sufficient randomness. As such, the caller, A, automatically authorizes the application. It then acts on the Refer-To URI, fetching the script from app.example.com (message 11). The response, message 12, contains a web application that the user can click on to enable recording. Because the client executed the URL in the Refer-To, it generates another NOTIFY to the application, informing it of the successful response (message 13). This is answered with a 200 OK (message 14). When the user clicks on the link (message 15), the results are posted to the server, and an updated display is provided (message 16).
There are many security considerations associated with this framework. It allows applications in the network to instantiate user interface components on a client device. Such instantiations need to be from authenticated applications, and also need to be authorized to place a UI into the client. Indeed, the stronger requirement is authorization. It is not as important to know the name of the provider of the application, as it is to know that the provider is authorized to instantiate components.
This specification defines specific authorization techniques and requirements. Automatic authorization is granted if the application can prove that it is on the call path, or is trusted by an element on the call path. As documented above, this can be accomplished by the use of cryptographically random dialog identifiers and the usage of SIPS for message confidentiality. It is RECOMMENDED that SIPS be implemented by user agents compliant to this specification. This does not represent a change from the requirements in RFC 3261.
This document was produced as a result of discussions amongst the application interaction design team. All members of this team contributed significantly to the ideas embodied in this document. The members of this team were:
Eric Burger Cullen Jennings Robert Fairlie-Cuninghame
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997.
[2] 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.
Rosenberg Standards Track [Page 36]
RFC 5629 App Interaction Framework October 2009
[3] Rosenberg, J. and H. Schulzrinne, "Reliability of Provisional Responses in Session Initiation Protocol (SIP)", RFC 3262, June 2002.
[4] Roach, A., "Session Initiation Protocol (SIP)-Specific Event Notification", RFC 3265, June 2002.
[5] McGlashan, S., Lucas, B., Porter, B., Rehor, K., Burnett, D., Carter, J., Ferrans, J., and A. Hunt, "Voice Extensible Markup Language (VoiceXML) Version 2.0", W3C CR CR-voicexml20- 20030220, February 2003.
[6] Rosenberg, J., Schulzrinne, H., and P. Kyzivat, "Indicating User Agent Capabilities in the Session Initiation Protocol (SIP)", RFC 3840, August 2004.
[7] Sparks, R., "The Session Initiation Protocol (SIP) Refer Method", RFC 3515, April 2003.
[8] Burger, E. and M. Dolly, "A Session Initiation Protocol (SIP) Event Package for Key Press Stimulus (KPML)", RFC 4730, November 2006.
[9] Rosenberg, J., "Obtaining and Using Globally Routable User Agent URIs (GRUUs) in the Session Initiation Protocol (SIP)", RFC 5627, October 2009.
[10] Rosenberg, J., "Request Authorization through Dialog Identification in the Session Initiation Protocol (SIP)", RFC 4538, June 2006.
[11] Peterson, J. and C. Jennings, "Enhancements for Authenticated Identity Management in the Session Initiation Protocol (SIP)", RFC 4474, August 2006.
[12] Day, M., Rosenberg, J., and H. Sugano, "A Model for Presence and Instant Messaging", RFC 2778, February 2000.
[13] Jennings, C., Peterson, J., and M. Watson, "Private Extensions to the Session Initiation Protocol (SIP) for Asserted Identity within Trusted Networks", RFC 3325, November 2002.
[14] Rosenberg, J., "A Framework for Conferencing with the Session Initiation Protocol (SIP)", RFC 4353, February 2006.
Rosenberg Standards Track [Page 37]
RFC 5629 App Interaction Framework October 2009
[15] Rosenberg, J., Schulzrinne, H., and P. Kyzivat, "Caller Preferences for the Session Initiation Protocol (SIP)", RFC 3841, August 2004.
[16] Rosenberg, J., Schulzrinne, H., and R. Mahy, "An INVITE- Initiated Dialog Event Package for the Session Initiation Protocol (SIP)", RFC 4235, November 2005.
[17] Sparks, R., Hawrylyshen, A., Johnston, A., Rosenberg, J., and H. Schulzrinne, "Session Initiation Protocol (SIP) Torture Test Messages", RFC 4475, May 2006.
[18] Schulzrinne, H., Casner, S., Frederick, R., and V. Jacobson, "RTP: A Transport Protocol for Real-Time Applications", STD 64, RFC 3550, July 2003.
[19] Schulzrinne, H. and T. Taylor, "RTP Payload for DTMF Digits, Telephony Tones, and Telephony Signals", RFC 4733, December 2006.
[20] Rosenberg, J. and H. Schulzrinne, "An Offer/Answer Model with Session Description Protocol (SDP)", RFC 3264, June 2002.
[21] Rosenberg, J., "A Session Initiation Protocol (SIP) Event Package for Registrations", RFC 3680, March 2004.
Author's Address
Jonathan Rosenberg Cisco Systems 600 Lanidex Plaza Parsippany, NJ 07054 US