Network Working Group J. Rosenberg
Request for Comments: 4596 P. Kyzivat
Category: Informational Cisco Systems
July 2006
Guidelines for Usage of the Session Initiation Protocol (SIP)
Caller Preferences Extension
Status of This Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2006).
Abstract
This document contains guidelines for usage of the Caller Preferences
Extension to the Session Initiation Protocol (SIP). It demonstrates
the benefits of caller preferences with specific example
applications, provides use cases to show proper operation, provides
guidance on the applicability of the registered feature tags, and
describes a straightforward implementation of the preference and
capability matching algorithm specified in Section 7.2 of RFC 3841.
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Table of Contents
1. Introduction ....................................................4
2. Motivations for Caller Preferences ..............................5
2.1. One-Number .................................................7
2.2. Direct-to-Voicemail ........................................7
3. Caller Preference Use Cases .....................................8
3.1. Routing of INVITE and MESSAGE to Different UA ..............8
3.1.1. Desired Behavior ....................................8
3.1.2. Solution ............................................9
3.2. Single Contact Not Matching Implicit Preferences ..........10
3.2.1. Desired Behavior ...................................10
3.2.2. Solution ...........................................10
3.3. Package-Based Routing .....................................11
3.3.1. Desired Behavior ...................................11
3.3.2. Solution ...........................................11
3.4. Package Routing II ........................................12
3.4.1. Desired Behavior ...................................12
3.4.2. Solution ...........................................13
3.5. Audio/Video vs. Audio Only ................................13
3.5.1. Desired Behavior ...................................13
3.5.2. Solution ...........................................14
3.6. Forcing Audio/Video .......................................15
3.6.1. Desired Behavior ...................................15
3.6.2. Solution ...........................................15
3.7. Third-Party Call Control: Forcing Media ...................16
3.7.1. Desired Behavior ...................................16
3.7.2. Solution ...........................................16
3.8. Maximizing Media Overlaps .................................17
3.8.1. Desired Behavior ...................................17
3.8.2. Solution ...........................................17
3.9. Multilingual Lines ........................................18
3.9.1. Desired Behavior ...................................18
3.9.2. Solution ...........................................19
3.10. I Hate Voicemail! ........................................20
3.10.1. Desired Behavior ..................................20
3.10.2. Solution ..........................................20
3.11. I Hate People! ...........................................21
3.11.1. Desired Behavior ..................................21
3.11.2. Solution ..........................................21
3.12. Prefer Voicemail .........................................22
3.12.1. Desired Behavior ..................................22
3.12.2. Solution ..........................................22
3.13. Routing to an Executive ..................................22
3.13.1. Desired Behavior ..................................22
3.13.2. Solution ..........................................22
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3.14. Speak to the Executive ...................................23
3.14.1. Desired Behavior ..................................23
3.14.2. Solution ..........................................24
3.15. Mobile Phone Only ........................................24
3.15.1. Desired Behavior ..................................24
3.15.2. Solution ..........................................24
3.16. Simultaneous Languages ...................................25
3.16.1. Desired Behavior ..................................25
3.16.2. Solution ..........................................25
3.17. The Number You Have Called... ............................26
3.17.1. Desired Behavior ..................................26
3.17.2. Solution ..........................................26
3.18. The Number You Have Called, Take Two .....................27
3.18.1. Desired Behavior ..................................27
3.18.2. Solution ..........................................27
3.19. Forwarding to a Colleague ................................28
3.19.1. Desired Behavior ..................................28
3.19.2. Solution ..........................................28
4. Capability Use Cases ...........................................30
4.1. Web Redirect ..............................................30
4.2. Voicemail Icon ............................................30
5. Usage of the Feature Tags ......................................31
5.1. Traditional Cell Phone ....................................31
5.2. Traditional Work Phone ....................................32
5.3. PC Messaging Application ..................................32
5.4. Standalone Videophone .....................................33
6. Example of Implementation of Preference and Capability
Matching .......................................................33
6.1. Extracting a Feature Set from a Header ....................34
6.2. Extracting Values from a Feature Parameter ................35
6.3. Comparing Two Value-Ranges ................................36
6.4. Feature Set to Feature Set Matching .......................36
6.5. Selecting and Ordering Contacts Based on Caller
Preferences ...............................................37
6.5.1. Reject-Contact Processing ..........................37
6.5.2. Accept-Contact Processing ..........................37
7. Security Considerations ........................................38
8. Acknowledgements ...............................................38
9. Informative References .........................................38
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1. Introduction
The Session Initiation Protocol (SIP) [1] extension for Callee
Capabilities [2] describes mechanisms that allow a UA (User Agent) to
register its capabilities in a REGISTER request. A caller can
express preferences, either explicitly or implicitly, about how that
request is to be handled. This is accomplished with the Accept-
Contact and Reject-Contact header fields described in Caller
Preferences for the Session Initiation Protocol[3].
The caller preferences extension can serve as a useful tool for
supporting many applications. However, its generality makes it
difficult to use correctly and effectively in any one situation. To
remedy that, this document serves as a compendium of examples of the
usage of the caller preferences extension.
NOTE: This document is intended to assist the reader in
understanding RFCs 3840 and 3841. It is not intended to serve as
a substitute for reading those documents. The examples presented
in this document cannot be fully understood without awareness of
the mechanisms defined in RFCs 3840 and 3841.
First, Section 2 demonstrates the benefits of using caller
preferences by describing several concrete applications that are
enabled by the extension. Section 3 describes a set of detailed use
cases for expressing caller preferences. Each use case presents a
situation, describes how caller preferences can be used to handle the
requirements for the situation, and verifies that the desired
behavior occurs by showing the results of the matching operation.
These use cases validate that the caller preferences specification is
complete and capable of meeting a specific set of requirements.
Since the caller preferences specification predates the SIP change
process [4], no requirements document was ever published for it. To
some degree, this document "backfills" requirements. However, this
is not an academic exercise only, since the use cases described here
did result in changes in the caller preferences document as it
evolved. These use cases also help implementors figure out how to
use caller preferences in their own applications.
Section 4 discusses applications for the callee capabilities
specification. Section 5 discusses the example registrations of the
feature tags described in [2]. Proper usage of the caller
preferences extension depends on proper interpretation of the
semantics of these tags. More detail is provided on the tags, and
example registrations are included that show typical usage.
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Section 6 outlines an implementation approach to the matching
algorithm that doesn't require RFC 2533 [6] to be implemented in all
its generality.
2. Motivations for Caller Preferences
At its core, SIP is a protocol that facilitates rendezvous of users.
The caller and callee need to meet up in order to exchange session
information, so that they may communicate. The rendezvous process is
complicated by the fact that a user has multiple points of attachment
to the network. A called user (callee) can have a cell phone, a PDA,
a work phone, a home phone, and one of several PC-based
communications applications. When someone calls that user, to which
of these devices is the call routed?
Certainly, the call can be routed to all of them at the same time, a
process known as parallel forking. However, that is not always the
desired behavior. Users may prefer that their registered devices be
tried in a particular order. As an example, a user might prefer that
his cell phone ring first, and if no one answers, that his work phone
ring next. Another user might prefer that her cell phone ring first,
and then her home and work phones ring at the same time, and then, if
no one answers either of those, that the call be forwarded to
voicemail. These variations are all referred to as find-me/
follow-me features.
SIP supports find-me/follow-me features in many ways. The most basic
is through the SIP registration process. Each device at which a user
can be contacted registers to the network. This registration
associates the device with the canonical name of the user, called the
address-of-record (AOR), which is a SIP URI. Each registration can
include a preference value, indicating the relative preference for
receiving calls at that device, compared to other devices. When
someone makes a call to the AOR, proxies compliant to RFC 3261 will
try the registered devices in order of preference, unless
administrative policy overrides user preferences.
Preference values in SIP registrations can only provide basic find-
me/follow-me features. To support more complex features, the Call
Processing Language (CPL) [5] has been specified. It is an XML
script that provides specific call routing instructions. Users can
upload these scripts to the network, instructing the servers how
calls should be routed. As an example, a CPL script can instruct a
proxy to route a call to the work phone during work hours (9 am -
5 pm) and then to the cell phone after hours, unless the call is from
a family member, in which case it always goes to the cell phone.
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It is important to note that both CPL scripts and preference values
in registrations describe operation of a service from the perspective
of the called party. That is, they describe how a call made to the
called party should be routed by the network. However, the called
party is not the only one with preferences. A caller will also have
preferences for how they want their call to be routed. As an
example, a caller will often want to reach a user on their cell
phone. In the current telephone network, this is accomplished by
requiring a user to have a separate number for each device. This
way, when a caller wishes to reach the cell phone, they dial the
number for the cell phone. This requires users to maintain lists of
potential reach numbers for a user, and then select the appropriate
one. A far better approach is for a user to maintain a single
address-of-record. When someone wishes to reach them on their cell
phone, they call the AOR, but indicate a preference for the call to
be routed to the cell phone.
A caller may actually have a wide variety of preferences for how a
call should be routed. They may prefer to go right to voicemail.
They may prefer never to reach voicemail. The may prefer to reach
the user on a device that supports video (because a video-conference
is desired). They may wish to reach a device that has an attendant
who can answer if the user is not there.
The SIP caller preferences extension allows a caller to express these
preferences for the way in which their calls are handled. These
preferences are expressed in terms of properties of the desired
device. These properties are name-value pairs that convey some kind
of information about a device. One example is the property
"mobility", which can have the values "mobile" or "fixed". When a
caller wishes to reach a cell phone, they include information in
their call setup request (the INVITE method) which indicates that the
call should be routed to a device that has the property "mobility"
set to "mobile". When devices register to the network, they include
their properties (also known as callee capabilities) as part of the
registration. In this way, a proxy can match the caller's
preferences against the capabilities of the various devices
registered to the user and route the call appropriately.
While this document addresses the preferences of a caller, it does so
from the perspective of a SIP User Agent representing the caller.
Caller preferences are herein represented via syntactic elements
placed in a SIP request. This document does not attempt to address
how preferences might be conveyed by a human user to the User Agent.
Thus this document is likely to be of most value to the developer of
a User Agent.
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The caller preferences extension can support a wide variety of call
routing applications and features. Two particularly important
examples are "one-number" and "direct-to-voicemail".
2.1. One-Number
In today's circuit-switched telephony networks, users have multiple
devices, and each device is associated with its own phone number. A
user will typically list all of these numbers on a business card:
cell phone, work phone, home office phone, and so on. Other users
need to store and manage all of these numbers. It is difficult to
keep these numbers complete and up-to-date. Worse, when you want to
call someone, you need to pick a number to try. Sometimes, you want
a specific device (the cell phone); and other times, you just want to
reach them wherever they are. In the latter case, a user is forced
to try each number, one at a time. This is inefficient, and
difficult to do while driving, for example.
As an alternative, a user can have a single address. This is the one
and only address they give out to other users on their business
cards. If a caller wishes to reach that user on their cell phone,
they select that one address, and then access a pull-down menu of
device types. This menu would include home phone, work phone, and
cell phone. The caller can select cell-phone, and then the call is
placed to the cell phone. There is no need to manage or maintain
more than one number for the user -- a single number will suffice.
If, on the other hand, the caller wishes to reach the user wherever
they are, they make a call to that one number without a selection of
a preferred device. The network will ring all devices at the same
time, and therefore reach the user as fast as possible.
This one-number service makes use of caller preferences. To express
a preference for the cell phone, the caller's device would include a
header in the SIP INVITE request, indicating a desire to reach a
device with "mobility" equal to "mobile".
2.2. Direct-to-Voicemail
Frequently, a busy executive on the road wants to quickly pass a
message to a colleague by voice. As an example, a boss might want to
instruct an employee to call a specific customer and resolve a
pending issue. In such a case, the user doesn't actually want to
talk to the person; they just want to leave a voice message. Having
a phone conversation may require too much time, whereas a voice
message can be quick and to the point. The voice message can also
serve as a record of exactly what is desired, whereas a fleeting
voice conversation can be forgotten or misremembered.
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In today's circuit-switched telephone networks, there is often no way
to go directly to someone's voicemail and leave a message.
Sometimes, you can dial the main number for the voicemail system,
enter in the extension of the desired party, and leave a message by
entering a specific prompt. This is time consuming, and requires the
caller to know the main voicemail number.
Instead, an address book in a cell phone can have an option called
"leave voice message", available for each entry in the address book.
When this option is selected, a call is made directly to the
voicemail for that user, which immediately picks up and prompts for a
message. In fact, a rapid greeting is played, so that the caller can
go directly to the recording procedure.
This saves time for the caller, making it very easy to quickly leave
recorded messages for a large number of people.
This feature is possible using the caller preferences extension.
When the user selects the "leave voice message" option, the phone
sends a SIP INVITE request, and includes a caller preferences header
field that indicates a preference for devices whose "msgserver"
attribute has a value of "true". This will cause the proxy to route
the call directly to a registered voicemail service. Furthermore,
the voicemail server will see that the caller asked to go directly to
voicemail, and can therefore play an abbreviated greeting explicitly
designed for this case.
3. Caller Preference Use Cases
Each use case is described as a situation along with a desired
behavior. Then, it demonstrates how the various caller preferences
headers and the proxy processing logic would result in the
appropriate decision.
3.1. Routing of INVITE and MESSAGE to Different UA
3.1.1. Desired Behavior
Address of Record (AOR) Y has two contacts, Y1 and Y2. Y1 is a phone
and supports the standard operations INVITE, ACK, OPTIONS, BYE, and
CANCEL but does not support MESSAGE, whereas Y2 is a pager and
supports only OPTIONS and MESSAGE. Caller X wants to send pages to
Y. There is a lot of traffic in the network of both calls and pages,
so there is a goal not to unnecessarily fork messages to devices that
can't support them. So, this is done by ensuring that INVITEs of Y
are delivered only to Y1, while MESSAGEs to Y are delivered only to
Y2.
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3.1.2. Solution
Y1 will create a registration that looks like, in part:
When a UAC (User Agent Client) sends an INVITE, it will arrive at the
proxy for example.com. There are no caller preferences in the
request. However, per Section 7.2.2 of [3], the proxy will construct
an implicit require-flagged Accept-Contact preference that looks
like:
(& (sip.methods="INVITE"))
Applying the matching algorithm of RFC 2533 [6] to this feature set
and those registered by Y1 and Y2, the feature set of Y1 alone
matches. Because the Accept-Contact predicate has its require flag
set, Y2 is discarded, and the INVITE is routed to Y1.
If the request was MESSAGE, the proxy constructs an implicit Accept-
Contact preference with its require flag set (require-flagged) that
looks like:
(& (sip.methods="MESSAGE"))
which matches the feature set of Y2, but not Y1. Thus, Y1 is
discarded, and the request is routed to Y2.
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3.2. Single Contact Not Matching Implicit Preferences
3.2.1. Desired Behavior
AOR Y has a single contact, Y1. It's a phone, and therefore supports
the standard operations INVITE, ACK, OPTIONS, BYE, and CANCEL but
does not support MESSAGE. A caller X sends a MESSAGE request. The
desired behavior is that the request is still routed to the solitary
contact so that it can generate a 405 response.
3.2.2. Solution
The single contact Y1 will generate a registration that looks like,
in part:
X sends a MESSAGE request. There are no explicit caller preferences.
This results in an implicit require-flagged Accept-Contact
preference:
(& (sip.methods="MESSAGE"))
Since Y1 doesn't match and the Accept-Contact predicate is require-
flagged, it is discarded. However, according to section 7.2.4 of RFC
3841, if there are no matching targets, the original target set is
used. Thus, the request is sent to the one original target, Y1, as
desired. Y1 then responds with a 405.
If there were multiple contacts, and none of them matched the Accept-
Contact predicate, then the original target set including all of the
contacts would be restored. Then all the contacts would be processed
according to Section 16.6 of RFC 3261.
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3.3. Package-Based Routing
3.3.1. Desired Behavior
AOR Y has a number of contacts, Y1, Y2, ..., Yn, that can each
support the standard operations INVITE, ACK, OPTIONS, BYE, and CANCEL
and can also support SUBSCRIBE for the "dialog" event package [7]. Y
also has another contact, Yp, that is a presence agent (PA) [8]: it
can accept only SUBSCRIBE requests for the "presence" event package.
The goal is for SUBSCRIBE requests for presence to be routed to Yp
while INVITEs and SUBSCRIBEs for the dialog package are forked to
Y1...Yn.
3.3.2. Solution
Y1..Yn will generate REGISTER requests that look like, in part:
A SUBSCRIBE request for presence will arrive at the proxy for
example.com. Since there are no explicit preferences, it constructs
an implicit require-flagged Accept-Contact preference from the
request:
Following Section 7.2.4 of RFC 3841, this feature set only matches
the one registered by Yp. Because the require flag is set, the
contacts which do not match are removed from the target set.
Therefore, Y1..Yn are discarded. The request is sent to the
remaining contact, Yp, representing the PA.
An INVITE request without explicit preferences results in an implicit
require-flagged Accept-Contact preference:
(& (sip.methods="INVITE"))
The implicit Accept-Contact feature set matches Y1..Yn, but does not
match Yp. Using the scoring algorithm from Section 7.2.4 of RFC
3841, the score for Y1..Yn against this predicate is 1.0. As a
result, the caller preference Qa for each contact is 1.0. The
registrations did not contain q-values, so the default q-value of 1.0
is applied to each Contact URI. Since the caller and callee
preferences are the same and all equal to 1.0, there is no reordering
of contacts. The result is that the proxy will consider Y1..Yn each
as equally good targets for the request and possibly fork the request
to each.
A SUBSCRIBE request for the dialog event package without explicit
preferences will result in an implicit require-flagged Accept-Contact
preference:
This only matches Y1..Yn, so Yp is discarded, and the request is
routed to the remaining contacts just as the INVITE was.
3.4. Package Routing II
3.4.1. Desired Behavior
This case is nearly identical to that of Section 3.3. However,
Y1..Yn omit the "events" feature tag from their registration. Yp
registers as in Section 3.3. A SUBSCRIBE for the presence event
package should still preferentially route to Yp.
This predicate matches Y1..Yn and Yp. However, the score for Y1..Yn
against this predicate is 0.5, and the score of Yp is 1.0. The
result is a caller preference Qa of 0.5 for Y1..Yn, and a caller
preference Qa of 1.0 for Yp. Since the callee provided no q-values,
the proxy will assume a default of 1.0. Thus, all contacts are in
the same equivalence class. They are then sorted by Qa, so that Yp
is first, followed by Y1 through Yn. It will therefore route the
request first to Yp, and if that should fail, to Y1..Yn.
3.5. Audio/Video vs. Audio Only
3.5.1. Desired Behavior
X sends an invitation to Y to initiate an audio/video call, including
both m=audio and m=video lines in the SDP. AOR Y has two contacts,
Y1 and Y2. Y1 represents a normal audio phone, where Y prefers to
receive their calls. It will answer an audio/video call, refusing
the video. Y2 represents an audio/video phone that should only used
when needed. The caller really wants the call answered by a device
that supports video, but will accept an audio-only call as a second
choice.
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3.5.2. Solution
Y1 will generate a registration that looks like, in part:
The proxy will convert this to a feature set. This feature set
matches Y2 and Y1. However, the score for Y2 is 1.0, and 0.5 for Y1.
The two contacts are then ordered by q-value and broken into
equivalence classes. There are two equivalence classes, each with
one contact. As a result, the caller preference values have no
impact on the ordering. The call will first try the higher priority
Y1, which will answer the call and reject the video stream. Thus,
the desired behavior is not achieved.
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The desired behavior could be achieved by adding the "explicit" and
"require" tags to the Accept-Contact header field in the INVITE, as
is done in Section 3.6. However, doing so may result in calls
failing when they could occur, but without video. As discussed in
[3], both the "require" and "explicit" tags are generally used only
when the request cannot be serviced in any way unless the preferences
are met. That is not the case here.
3.6. Forcing Audio/Video
3.6.1. Desired Behavior
This case is similar to that of Section 3.5. However, X requires an
audio/video call and would like the call to fail if this is not
possible, rather than succeed with audio only.
3.6.2. Solution
The solution is similar to that of Section 3.5; however, the Accept-
Contact header field now includes the "explicit" and "require" tags,
guaranteeing that the call is never established to any UA that had
not explicitly indicated support for video:
This arrives at the example.com proxy. This explicit feature set
matches the feature set for Y2 and Y1. However, the match for Y1 did
not have a score of 1. Since the "explicit" and "require" tags are
present, the contact is discarded. That leaves Y2 only. The call
will therefore get routed to the videophone, and if the user is not
there, the audio phone will never ring.
Because both the "require" and "explicit" flags are present, a
contact will also be discarded if it does not include a feature tag
indicating support for video. Thus, a UA that can do video, but
neglected to indicate it, would not be reached in this case. This is
why it is important for a UA to indicate all of its capabilities.
Note that this is only true for a contact that indicated some
capabilities but not the video capability. Contacts that don't
indicate any capabilities are "immune" from caller preferences
filtering and would not be discarded.
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3.7. Third-Party Call Control: Forcing Media
3.7.1. Desired Behavior
Z is a third-party call control controller (3pcc) [9] trying to
establish an audio/video call from X to Y. X has contacts X1 and X2,
and Y has contacts Y1 and Y2. X1 and X2 have capabilities identical
to Y1 and Y2, respectively. Z needs to send an offerless invite to X
and use the offer proposed by X to send an invite to Y. When sending
the offerless invite to X, the 3pcc controller must ensure that an
audio/video contact (X2) is chosen over an audio only contact (X1).
3.7.2. Solution
X1 will generate a registration that looks like, in part:
This caller preference matches both X1 and X2. However, it matches
X1 with a score of .5 and X2 with a score of 1. Because of the
"require" and "explicit" tags, X1 is discarded despite X's preference
for it. Thus, the call is routed to X2.
The same caveats apply here as do in Section 3.6. Generally, it is
not advisable to mandate support for features (such as video) that
are not strictly necessary for the request to proceed.
3.8. Maximizing Media Overlaps
3.8.1. Desired Behavior
AOR Y has two contacts: Y1, which is a regular audio phone, and Y2,
which is a PC capable of supporting both audio and session-oriented
IM [10]. X is a PC with capability to support audio, video, and
session-oriented IM. X calls Y for the purpose of establishing a
voice call. However, X wishes to connect to the device that has the
maximal overlap with its media capabilities, in order to maximize the
functionality available to the caller.
3.8.2. Solution
Y1 will generate a registration that looks like, in part:
The solution requires the caller to support caller preferences. The
caller would include, in their INVITE, an Accept-Contact header field
that lists all the media types they support. In this case:
Both Y1 and Y2 match the predicate. Y1 matches with a score of 0.33,
and Y2 matches with a score of 0.66. Since there is only one Accept-
Contact predicate, the Qa for each contact is equal to the score.
The registered contacts are then sorted by q-value and broken into
equivalence classes. There is a single equivalence class with
q-value of 1.0. The two contacts in that class are then re-ordered
based on the values of Qa. Y2 has a higher Qa, so it is used first,
followed by Y1. The result is that the call is routed to the device
with the maximum overlap in media capabilities, as desired.
Note that neither "require" nor "explicit" tags are used because
there is no intent to exclude contacts, only to order them.
3.9. Multilingual Lines
3.9.1. Desired Behavior
AOR Y represents a shared line in an office. Several employees in
the office have phones registered for Y. Some of the employees speak
only English, some speak Spanish fluently and have some limited
capability for English, and some speak both English and Spanish
fluently. Calls from callers that speak only English should be
parallel forked to all office workers that speak fluent English. If
the call isn't picked up, then the phones of workers that speak
English marginally should be rung. Calls from callers that speak
only Spanish should be forked only to workers that speak Spanish.
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3.9.2. Solution
A user at phone Y1 that speaks English only would generate a REGISTER
that looks like, in part:
Y2 has registered two contacts. Both of them route to the same
device (pc2.example.com), but they differ in their language support
and relative q-values. Multiple contacts are needed whenever a UA
wishes to express differing preferences for being reached for
different feature collections.
A user at phone Y3 that speaks English and Spanish fluently would
generate a REGISTER that looks like, in part:
This matches the one contact for Y1, the second contact registered
for Y2, and the one contact for Y3, all with a score of 1.0. The
first contact registered by Y2 does not match, and because of the
"require" flag, is discarded. The remaining contacts are sorted by
q-value and divided into equivalence classes. There are two
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equivalence classes. The first contains Y1 and Y3 with a q-value of
1.0, and the second contains Y2-en with a q-value of 0.2. The
contacts in the first class are ordered by Qa. However, since all
contacts have the same value of Qa (1.0), there is no change in
ordering. Thus, Y1 and Y3 are tried first, followed by Y2-en. This
is the desired behavior.
An "explicit" tag is not used because that would cause the exclusion
of a contact that does not mention language.
A caller that speaks Spanish only would specify their preference
thusly:
This matches the first contact of Y2 phones, and Y3 phones, all with
a score of 1.0. The English contact of Y2, Y2-en, doesn't match and
is discarded because of the "require" flag. The remaining contacts
are sorted by q-values (Y3, Y2-es) and broken into a single
equivalence class containing both contacts. Since the Qa for both
contacts is the same (1.0) there is no reordering. The result is
that the call is routed to either Y3 or Y2-es.
3.10. I Hate Voicemail!
3.10.1. Desired Behavior
AOR Y has two contacts, a phone Y1 and a voicemail service Y2. X
wishes to call Y and talk in person. X does not want to be sent to
voicemail under any circumstances.
3.10.2. Solution
The phone would register with a Contact that looks like, in part:
The voicemail server registers with a lower q-value so that it is
used only after the phone itself is rung. Note that the voicemail
server need not actually register. There can be a configured contact
and feature set defined for it instead.
A caller that wishes to avoid voicemail can include an explicit
preference to avoid it. A caller would do this with the Reject-
Contact header field:
Since this feature set contains a feature tag that is not contained
in the registration for Y1, the feature set is discarded when
examining Y1. However, the registration for Y2 contains all feature
tags listed in the feature set, and so the rule is considered. There
is a match, and therefore, Y2 is discarded. The result is that the
user is never routed to voicemail.
3.11. I Hate People!
3.11.1. Desired Behavior
The situation is similar to Section 3.10, except the caller wishes
only to leave a message, not actually speak to the person.
3.11.2. Solution
The caller would send an INVITE that looks like, in part:
This caller preference matches both Y1 and Y2. Y1 matches, but with
a score of zero. Y2 matches with a score of 1. Since both the
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"require" and "explicit" flags are set, Y1 is discarded. Therefore,
the call is routed to Y2, the voicemail server, as desired.
Because of the presence of the "require" and "explicit" tags, if
these preferences are used with a user that doesn't have voicemail or
that fails to indicate it with a msgserver capability, the call will
fail completely with a 480 Temporarily Unavailable error, rather than
connect to the user.
3.12. Prefer Voicemail
3.12.1. Desired Behavior
The situation is similar to that of Section 3.10. However, the
caller prefers to leave a message. If voicemail is not available,
they are willing to talk to a person.
3.12.2. Solution
It had been hoped that RFC 3841 could provide a solution for this
case, but it does not, because doing so would require a re-ordering
of the callee contacts, which is not done. The caller may achieve
the intended effect by making two call attempts:
o First, make an attempt requiring voicemail, as described in
Section 3.11.
o If that fails with a 480 error, send an invitation with no Accept-
Contact or Reject-Contact headers.
3.13. Routing to an Executive
3.13.1. Desired Behavior
Y is the AOR of an executive. It has three contacts. Y1 is the
phone on the executive's desk. Y2 is the phone on the desk of the
executive's assistant. Y3 is the address of an auto-attendant system
that can answer general questions, route calls to other parties, etc.
By default, calls to Y should be directed to Y2, and if that fails,
to Y3. If Y3 doesn't answer, then Y1 should ring.
3.13.2. Solution
This is primarily a called party feature and is best accomplished
with a CPL (Call Processing Language) script [5]. However, it can be
accomplished with caller preferences alone by properly setting the
q-values across the three devices. Assuming this coordination is
possible, here are the settings that would be made:
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Y1 would generate a REGISTER that looks like, in part:
Note that, in reality, the automated attendant would probably not use
REGISTER. Since the attendant would be used for every employee in
the company, a static contact would probably be added
administratively for each user in the enterprise. However, the
information in that static contact would be identical to the
information in the registration above.
When X makes a call to the executive, Y, and expresses no preference,
the proxy computes an implicit preference to support INVITE. All
three contacts match such a preference, even though they have not
indicated explicit support for INVITE. Thus, no contacts are
discarded. Since each contact has a different q-value, the caller
preferences do not cause any reordering. The result is that the call
is first routed to Y2, then Y3, then Y1, all as a result of the
proper setting of the q-values.
3.14. Speak to the Executive
3.14.1. Desired Behavior
This case is similar to that of Section 3.13, but this time the
caller, X, has a preference. X calls Y, but wants to speak directly
to the executive. X doesn't want the call to ring either the
assistant or the auto attendant (automaton).
Note that the caller uses two separate Reject-Contact header field
values, rather than a single one with two separate feature
parameters. The distinction is important. If X had to use a single
value with two parameters, a matching UA would need to declare that
it was BOTH an attendant and an automaton. If it only declared that
it was one of these, based on the matching rules in the caller
preferences specification, it would not be rejected.
The above request would result in the elimination of both Y2 and Y3
as contacts. The call would then be routed to Y1, as desired.
This case indicates why a CPL script, or some other programmed
version of the feature, is preferable. With caller preferences, a
caller can override the desired ring sequence and disturb the
executive without any kind of authorization. A proper version of
this service would simply not permit caller preferences to force the
call to go directly to the executive.
3.15. Mobile Phone Only
3.15.1. Desired Behavior
The situation is similar to that in Section 3.13. However, the
executive also has a mobile phone that they have registered. Caller
X knows that the owner of Y is traveling, and that an assistant is
covering the office phone. X wants to call Y and ring only the
mobile phone.
3.15.2. Solution
The mobile phone would generate a registration that looks like, in
part:
All four contacts match. However, Y1 through Y3 match with a score
of zero. Y4 matches with a score of 1. Because of the "require" and
"explicit" tags, Y1 through Y3 are discarded, and only Y4 is used, as
desired.
Note that this only works if the mobile phone specifies the mobility
feature in its registration.
3.16. Simultaneous Languages
3.16.1. Desired Behavior
AOR Y is as in Section 3.9. Caller X, fluent in both English and
Spanish, has discovered that the company's Spanish language
documentation is inconsistent with the English language documentation
and wants to discuss the differences between the two. So X wants to
speak with one of the workers that is fluent in both English and
Spanish.
3.16.2. Solution
The caller would generate an INVITE that looks like, in part:
It would have connected them to a UA that speaks either English or
Spanish, which is not what is desired here.
An "explicit" option is not used, because it would bypass contacts
that do not include a language tag.
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3.17. The Number You Have Called...
3.17.1. Desired Behavior
Consider once more the case of the executive, where the caller wishes
to reach only their mobile phone (Section 3.15). However, there is a
twist. The callee Y has moved to new address YY, and all the
configuration described for the callee now applies to YY. The old
address Y remains with a pair of statically assigned contacts. One
contact is YY. The other is M, referencing an automaton that
generates a voice message reporting that the number has been changed.
The caller is unaware of the move and calls Y, requesting to reach
the mobile phone in exactly the same way they did in Section 3.15.
The call should connect to the mobile.
3.17.2. Solution
There would be four registrations against YY:
YY1, the executive, would generate a REGISTER that looks like, in
part:
This reaches the example.com proxy, which finds two registrations.
Only one of these (the automaton) is associated with feature
parameters. The other has no feature parameters and is therefore
immune to caller preferences processing. The caller preferences are
applied to the automaton's contact. The feature sets match, but have
a score of zero. Since the "require" and "explicit" tags are
present, the contact for the automaton is dropped. The other
contact, [email protected], is then added back in as the sole contact.
The proxy therefore sends the call to sip:[email protected]. There,
there are four registrations, all of which are associated with
feature parameters. The caller preferences are applied. Only YY4
matches explicitly, however. Because of the presence of the
"require" and "explicit" flags, all other contacts are dropped. As
such, the call is forwarded to YY4, and the mobile phone rings.
3.18. The Number You Have Called, Take Two
3.18.1. Desired Behavior
This use case is nearly identical to that of Section 3.17. However,
this time, the caller wishes to contact the personal phone of Y.
They don't feel strongly about it, and will accept other devices.
3.18.2. Solution
The INVITE generated by the caller in this case will look like:
This reaches the example.com proxy. Once more, the first
registration (which forwards to the address-of-record for YY) is
unaffected by the caller preferences computation. The other contact,
for the automaton, is a match, but its score is zero. Its caller
preference Qa equals zero. The other contact is added back in with a
Qa of 1.0. The contacts are sorted based on q-value, resulting in YY
(q=1.0) followed by machine (q=0.5). These are broken into
equivalence classes. There are two classes, one for each contact.
As a result, the caller's preferences have no impact on the ordering,
and the call is routed to YY.
When the request for [email protected] is processed, all four contacts
match. However, the score for all of them is zero (none are the
personal phone). As such, the contacts are ordered based on q-value.
Each contact has a different q-value, so no reordering based on
caller preference is possible (not that the caller preference would
cause a reordering; all contacts have a Qa of 0.0). Thus, the
highest q-value contact is tried, which is the executive assistant.
3.19. Forwarding to a Colleague
3.19.1. Desired Behavior
Alice wants to forward her phone to Bob, but doesn't want folks
calling her to get Bob's voicemail if he doesn't answer. She wants
her callers to get her voicemail.
3.19.2. Solution
Alice would create three registrations. The first, Y1, represents
Alice's phone. The second is Bob's AOR. The third is a voicemail
server. The three contacts have decreasing q-values. The
registration for Bob's AOR contains an embedded Reject-Contact header
field, which rejects message servers.
Carol calls Alice and doesn't include any caller preference
parameters. As such, the example.com proxy constructs an implicit
preference for INVITE. This preference matches all three registered
contacts, with a score of zero. Because each contact has a different
q-value, there is no reordering of contacts. So, the proxy tries the
highest q-value Contact, Alice's desk phone (Y1). The proxy cancels
after a few seconds (no answer). The proxy then tries the next
Contact, which is Bob's AOR. When constructing the request for this
Contact, the proxy includes the embedded Reject-Contact header field
in the INVITE. This INVITE undergoes caller preferences processing
based on Bob's registered Contacts.
Bob has two registered Contacts. The second is a message server, and
it matches the Reject-Contact in the INVITE. Thus, this contact is
discarded. The other remaining Contact, Bob's phone, is tried. Bob
is not around, so his phone rings for a while. Upon timeout, the
proxy determines it is unable to reach Bob's AOR. So, the proxy
handling Alice tries the final remaining contact, which is Alice's
message server.
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4. Capability Use Cases
The callee capabilities spec [2] allows the Contact header field in
OPTIONS responses and dialog initiating messages to contain
capabilities of the UA. These capabilities can be very useful for
developing new applications. In the subsections below, several
usages are outlined.
4.1. Web Redirect
A caller sends an INVITE to the called party. However, the called
party is not present. The proxy server representing the called party
would like to redirect the caller to a web page, where they can find
out more information on how to reach the called party. However, the
proxy needs to know whether or not the caller supports redirects to
web pages. If it doesn't, the proxy would connect the user to an
interactive voice response (IVR) device, which would execute an
answering machine application.
The proxy could make such a determination if the caller included the
"schemes" feature tag in the Contact header field of its INVITE:
This tells the proxy that the UAC can be redirected to an http URI.
The INVITE from a normal "black phone" that lacked this capability
would look like:
This indicates that it needs to be connected to the IVR.
4.2. Voicemail Icon
On the circuit network, when a user makes a call, and an answering
machine picks up, the caller usually requires several seconds to
determine that they are speaking to an answering machine. It would
be helpful if a phone could display an icon immediately on call
completion that indicated that an answering machine was reached.
This indication can be provided by the "msgserver" feature parameter.
When the answering machine picks up, its 200 OK looks like, in part:
SIP/2.0 200 OK
Contact: <sip:server33.example.com>;msgserver;automata;attendant
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This tells the caller that it's an answering machine.
5. Usage of the Feature Tags
The caller preferences extension briefly enumerates a list of media
feature tags that can be registered by a device and included in the
Accept-Contact and Reject-Contact header fields in a request. Proper
operation of caller preferences depends strongly on consistent
interpretation of these feature tags by the caller and the callee.
In this section, we provide some guidelines on the usage of these
feature tags.
Generally speaking, the more information a device provides when it
registers, the more effective the caller preferences extension is.
This is why the callee capabilities extension recommends that a
device register as much information as it can. This point cannot be
overstated.
If devices explicitly registered features that they don't support,
such as 'video="false"', the operation of RFC 3841 would be improved.
However, given the open-ended nature of capabilities, it will never
be possible to ensure the registration of negative values for all
capabilities of interest to a caller. Furthermore, attempting to do
so would significantly bloat registrations. Instead, it is
recommended that all "unusual" capabilities be explicitly registered.
The subsections below show example registrations from typical
devices.
5.1. Traditional Cell Phone
A VoIP cell phone capable of making voice calls would generate a
registration that looks like, in part:
6. Example of Implementation of Preference and Capability Matching
RFC 3841 [3] utilizes the definitions and feature matching algorithm
defined in RFC 2533 [6]. This provides a precise normative
specification of the algorithm. However, that specification isn't
ideal as a guideline for implementation because it is more complex
than is required for the restricted use employed by RFC 3841. (The
simplification is primarily because a particular feature tag may only
appear once in each Contact, Accept-Contact, or Reject-Contact
header.)
This section provides a sample approach to implementing the matching
of caller preferences to callee capabilities; it does not require the
use of the notation and techniques of RFC 2533. It is not normative,
but is believed to be consistent with that definition. It may be
considered an alternative for that portion of RFC 3841 beginning with
Section 7.2.3 and extending to the end of page 13 in the middle of
Section 7.2.4.
In this section, there are frequent references to syntactic elements
defined by ABNF in RFC 3840, Section 9, and RFC 3841, Section 10.
Here, ABNF elements are enclosed to single quotes -- for example,
'feature-param'. Such a reference identifies a sequence of octets
within a SIP request that match the corresponding ABNF element when
the sip request is parsed according to RFCs 3261, 3840, and 3841.
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6.1. Extracting a Feature Set from a Header
Contact header fields, Accept-Contact header fields, and Reject-
Contact header fields each contain zero or more 'feature-param's,
each in turn may contain one or more 'tag-value's, or a 'string-
value'. The first step is to extract from each header field a more
useful representation as a feature set, herein called an FS. (This
FS representation of a feature set representation differs from that
in RFC 2533.) This process is the same for each type of header.
An FS consists of a set of one or more feature params denoted by FP.
Each FP has a name, denoted FP.NAME, and a set of one or more value
ranges denoted by VR. Each VR consists of:
o A type (VR.TYPE): either token (TOKEN-TYPE), string (STRING-TYPE),
or number-range (RANGE-TYPE)
o A negation flag (VR.NEGATION): either NEGATED, or NON-NEGATED
o The actual value, differing by type:
* For TOKEN-TYPE and STRING-TYPE, a sequence of octets
(VR.OCTETS)
* For RANGE-TYPE, a pair of signed real numbers (VR.LB and VR.UB)
representing the lower and upper bounds on the range,
inclusive.
A single FS is created to represent the features of one header.
(Contact, Accept-Contact, Reject-Contact.) Within the FS, an FP is
created for each 'feature-param' in the header. To create an FP, a
'feature-param' is examined as follows:
o If the 'feature-param' contains an instance of 'other-tags', then
FP.NAME is the value matched by 'ftag-name'.
o Otherwise, the 'feature-param' contains an instance of 'base-
tags'. If the value matched by 'base-tags' is "language" or
"type", then FP.NAME is just the value matched by 'base-tags'. If
not, then FP.NAME is the value matched by 'base-tags' and prefixed
with "sip.".
o The value of the 'feature-param', if any, is processed (according
to the rules in the next section) to extract a set of one or more
VRs that are associated with the FP.
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6.2. Extracting Values from a Feature Parameter
The value of a 'feature-param' is an encoded representation (as
specified in RFC 3840) of one or more value ranges of the
corresponding feature. There are several data types that these
values may take on: boolean, token, string, number, or numeric range.
The type is determined by the encoded form of the value. (These
types and their representations are specific to this implementation.)
(Note: numeric values can explicitly represent a range of values.
The other types only represent single value: a degenerate range. The
term value range is used to encompass all of these.)
The value of the 'feature-param' ('string-value', 'tag-value-list',
or none) is converted to VR form as follows:
o If there is no value, then a single new VR is created with VR.TYPE
= TOKEN-TYPE, VR.NEGATION = NON-NEGATED, and VR.OCTETS set to
"true".
o If the 'feature-param' contains a 'string-value', then a single
new VR is created with VR.TYPE = STRING-TYPE, VR.NEGATION =
NON-NEGATED, and VR.OCTETS is set to the octets matching 'qdtext'.
o Otherwise the 'feature-param' contains a 'tag-value-list', and a
new VR is created for each 'tag-value' in the 'tag-value-list', as
follows:
o If the 'tag-value' begins with "!", VR.NEGATION = NEGATED;
otherwise, VR.NEGATION = NON-NEGATED.
o If the 'tag-value' contains a 'boolean' or 'token-nobang', then
VR.TYPE = TOKEN-TYPE, and VR.OCTETS is set to the octets matched
by 'boolean' or 'token-nobang'.
o If the 'tag-value' contains a 'numeric', VR.TYPE = RANGE-TYPE and:
* If 'numeric-relation' is "<=", VR.UB is set to the numeric
value matching 'number'. VR.LB is set to MIN-REAL (a negative
number with the largest expressible magnitude.)
* If 'numeric-relation' is "=", both VR.LB and VR.UB are set to
the numeric value matching 'number'.
* If 'numeric-relation' is ">=", VR.LB is set to the numeric
value matching 'number' plus a small epsilon. VR.UB is set to
MAX-REAL (a positive number with the largest expressible
magnitude).
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* Else the 'numeric-relation' consists of two 'number's separated
by a colon. In this case, VR.LB is set to the numeric value of
the smaller of the two numbers, and VR.UB is set to the numeric
value of the larger of the two numbers.
6.3. Comparing Two Value-Ranges
Two VRs match if their ranges overlap. The comparison is done
according to type, and only comparisons between like types are
defined. When two VRs of differing types are compared, they are
considered not to overlap. Either or both of the VRs may be NEGATED.
Comparison proceeds as follows:
o If the VRs are of different types, the match is false.
o Otherwise:
* Two VRs with VR.TYPE = RANGE-TYPE match if max(VR1.LB, VR2.LB)
<= min(VR1.UB, VR2.UB).
* Two VRs with VR.TYPE = TOKEN-TYPE match if their respective
VR.OCTETS values compare equal by case-insensitive comparison.
* Two VRs with VR.TYPE = STRING-TYPE match if their respective
VR.OCTETS values compare equal by case-sensitive comparison.
o The result (true/false) is then negated if VR1.NEGATION = NEGATED,
and negated again if VR2.NEGATION = NEGATED.
6.4. Feature Set to Feature Set Matching
In RFC 2533, the matching of two feature sets is commutative, but as
applied to caller preferences matching it is not. In this
application, one feature set comes from an Accept-Contact or Reject-
Contact header, and the other comes from a Contact header. For
purposes of this description, these will be termed the preferred-
features (FSp) and the capability-features (FSc), respectively.
Non-commutativity arises from explicit tests for the presence among
capability-params of feature param names used in preferred-features.
A preferred-features feature set FSp may be matched to one
capability-features feature set FSc, and this yields the following
metrics:
o NPF - The number of preferred-features.
o NCF - The number of preferred-features for which there is a
capability-feature of the same name.
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o NVM - The number of value matches between corresponding features
of the two feature sets.
For a particular pair of FPp and FPc, these metrics are computed as
follows:
o All the metrics are set to zero.
o The following steps are applied for each feature param (FPp) of
the FSp:
* NPF is incremented.
* A corresponding FP with the same name is sought (using case-
insensitive comparison) in the FSc.
* If a corresponding feature param (FPc) is found:
+ NCF is incremented.
+ Every VR of FPp is matched to every VR of FPc.
+ If any of those matches succeed, NVM is incremented.
6.5. Selecting and Ordering Contacts Based on Caller Preferences
6.5.1. Reject-Contact Processing
The reject processing specified in Section 7.4.2 of RFC 3841 may be
performed as follows:
o For each candidate Contact in the target set, match the feature
set of each Reject-Contact to it.
o If (NVM == NPF) & (NCF == NPF), remove the contact URI from the
target set.
6.5.2. Accept-Contact Processing
The matching of an Accept-Contact against a Contact and subsequent
scoring of the match specified in Section 7.4.2 of RFC 3841 may be
performed as follows:
o Match the feature set of the Accept-Contact to that of the Contact
as specified in Section 6.4.
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o If (NVM < NCF), then the match failed. If the Accept-Contact had
its "require" flag set, then discard the corresponding contact URI
from the target set.
o Compute the score as NVM/NPF.
o Apply the "require" and "explicit" flags as specified in the text
and Figure 7 of RFC 3841.
7. Security Considerations
This document provides explanation and examples of the use and
implementation of RFCs 3840 and 3841. The security considerations
sections of those documents apply to the material presented here.
8. Acknowledgements
The authors would like to thank Rohan Mahy for his input in this
specification.
9. Informative References
[1] 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.
[2] Rosenberg, J., Schulzrinne, H., and P. Kyzivat, "Indicating
User Agent Capabilities in the Session Initiation Protocol
(SIP)", RFC 3840, August 2004.
[3] Rosenberg, J., Schulzrinne, H., and P. Kyzivat, "Caller
Preferences for the Session Initiation Protocol (SIP)",
RFC 3841, August 2004.
[4] Mankin, A., Bradner, S., Mahy, R., Willis, D., Ott, J., and B.
Rosen, "Change Process for the Session Initiation Protocol
(SIP)", BCP 67, RFC 3427, December 2002.
[5] Lennox, J. and H. Schulzrinne, "Call Processing Language
Framework and Requirements", RFC 2824, May 2000.
[6] Klyne, G., "A Syntax for Describing Media Feature Sets",
RFC 2533, March 1999.
[7] Rosenberg, J., Schulzrinne, H., and R. Mahy, "An INVITE-
Initiated Dialog Event Package for the Session Initiation
Protocol (SIP)", RFC 4235, November 2005.
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[8] Rosenberg, J., "A Presence Event Package for the Session
Initiation Protocol (SIP)", RFC 3856, August 2004.
[9] Rosenberg, J., Peterson, J., Schulzrinne, H., and G. Camarillo,
"Best Current Practices for Third Party Call Control (3pcc) in
the Session Initiation Protocol (SIP)", BCP 85, RFC 3725,
April 2004.
[10] Campbell, B., "The Message Session Relay Protocol", Work in
Progress, July 2006.
Authors' Addresses
Jonathan Rosenberg
Cisco Systems
600 Lanidex Plaza
Parsippany, NJ 07054
US
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