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Internet Engineering Task Force                     Gonzalo Camarillo
Internet draft                                             Jan Holler
                                                    Goran AP Eriksson
                                                             Ericsson
                                                        November 2000
                                                    Expires June 2001
                                     <draft-camarillo-sip-sdp-01.txt>


                       SDP media alignment in SIP


Status of this Memo

   This document is an Internet-Draft and is in full conformance with
      all provisions of Section 10 of RFC2026.

   Internet-Drafts are working documents of the Internet Engineering
   Task Force (IETF), its areas, and its working groups. Note that
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Abstract

   This document defines an SDP media attribute. This attribute is
   intended to be used in conjunction with SIP in order to align
   different media streams belonging to a session. The use of this
   attribute allows sending media from a single flow (several media
   streams), encoded in different formats during the session, to
   different ports and host interfaces.

1. Introduction

   SIP [1] is an application layer protocol for establishing,
   terminating and modifying multimedia sessions. SIP carries session
   descriptions in the bodies of the SIP messages but is independent
   from the protocol used for describing sessions. SDP [2] is one of
   the protocols that can be used for this purpose.

   Appendix B of [1] describes the usage of SDP in relation to SIP. It
   states: "The caller and callee align their media description so that
   the nth media stream ("m=" line) in the caller³s session description
   corresponds to the nth media stream in the callee³s description."


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                      SDP media alignment in SIP


   This way of performing the media alignment is not efficient when a
   single flow comprises several media streams. This is a common
   situation when AP (Application Sever) components [3] are employed.
   It is also common for systems that handle different codecs on
   different port numbers (or on different interfaces).

2. Media flow definition

   The RTSP RFC [4] defines a media stream as "a single media instance,
   e.g., an audio stream or a video stream as well as a single
   whiteboard or shared application group. When using RTP, a stream
   consists of all RTP and RTCP packets created by a source within an
   RTP session".

   This definition assumes that a single audio (or video) stream maps
   into an RTP session. The RTP RFC [5] defines an RTP session as
   follows: "For each participant, the session is defined by a
   particular pair of destination transport addresses (one network
   address plus a port pair for RTP and RTCP)".

   However, there are situations where a single media instance, e.g.,
   an audio stream or a video stream is sent using more than one RTP
   session. Two examples (among many others) of this kind of situation
   are cellular systems using SIP and systems receiving DTMF tones on a
   different host than the voice. Both examples are described in later
   sections.

   We introduce the definition of media flow:

   Media flow consists of a single media instance, e.g., an audio
   stream or a video stream as well as a single whiteboard or shared
   application group. When using RTP, a media flow comprises one or
   more RTP sessions.

   For instance, in a two party call where the voice exchanged can be
   encoded using GSM or PCM, the receiver wants to receive GSM on a
   port number and PCM on a different port number. Two RTP sessions
   will be established, one carrying GSM and the other carrying PCM.

   At any particular moment just one codec is in use. Therefore, at any
   moment one of the RTP sessions will not transport any voice. Here
   the systems are dealing with a single flow (one audio stream) and
   two RTP sessions.

2.1 SIP and cellular access

   Systems using a cellular access (such as UMTS or EDGE) and SIP as a
   signalling protocol need to receive media over the air. During a
   session the media can be encoded using different codecs. The encoded
   media has to traverse the radio interface. The radio interface is
   generally characterized by being bit error prone and associated with
   relatively high packet transfer delays. In addition, radio interface
   resources in a cellular environment are scarce and thus expensive,

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                      SDP media alignment in SIP


   which calls for special measures in providing a highly efficient
   transport [6]. In order to get an appropriate speech quality in
   combination with an efficient transport, precise knowledge of codec
   properties are required so that a proper radio bearer for the RTP
   session can be configured before transferring the media. These radio
   bearers are dedicated bearers per media type, i.e. codec.

   In UMTS, for instance, when the RTP packets shall be delivered over
   the air interface, a packet filtering function routes the packets to
   the proper radio bearer towards the UMTS/SIP terminal. The packet
   filtering function operates using a Traffic Flow Template (TFT) [7],
   which is established when configuring the radio bearer. The TFT
   hence specifies the profile of the data that should be carried by
   the radio bearer. A TFT can contain the following data:

   -Source Address and Subnet Mask.
   -Protocol Number (IPv4) / Next Header (IPv6).
   -Destination Port Range.
   -Source Port Range.
   -IPSec Security Parameter Index (SPI).
   -Type of Service (TOS) (IPv4) / Traffic class (IPv6) and Mask.
   -Flow Label (IPv6).

   It is worth noticing that just certain combinations of these
   parameters are allowed.

   The media has to have different destination port numbers for the
   different possible codecs in order to be filtered and routed
   properly to the correct radio bearer. Therefore, several RTP
   sessions are used for a single media flow.

2.2 DTMF tones

   Some voice sessions include DTMF tones. Sometimes the voice handling
   is performed by a different host than the DTMF handling (e.g.
   section 5.4, figures 3 and 4 of [3]). In this situations it is
   necessary to establish two RTP sessions: one for the voice and the
   other for the DTMF tones. Both RTP sessions are logically part of
   the same media flow.

3. Flow identification attribute

   A new "flow identification" media attribute is defined. It is used
   for identifying media flows within a session. It provides a means
   for aligning a number of flows (rather than a number of media
   streams) within a session between members participating in the
   session. Its formatting in SDP is described by the following BNF:

         fid-attribute      = "a=fid:" identification-tag
         identification-tag = token

   The identification tag is unique within the SDP session description.
   The following examples illustrate its usage.

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                      SDP media alignment in SIP





4. Examples of flow identification attribute

4.1 UMTS/SIP terminal

   In the following example John uses a traditional access such as an
   ethernet while Laura has a UMTS/SIP terminal. The caller John sends
   an INVITE with the following session description to the callee
   Laura.

         v=0
         o=John 289085535 289085535 IN IP4 first.example.com
         t=0 0
         c=IN IP4 111.111.111.111
         m=audio 20000 RTP/AVP 0 8
         a=fid:1

   The callee Laura is on a UMTS/SIP terminal. She configures the
   necessary radio bearers and implements the TFTs:

   All the incoming IP packets with destination port UDP 30000 will be
   carried by the radio access bearer configured for G-711 u-law
   (payload type 0).

   All the incoming IP packets with destination port UDP 30002 will be
   carried by the radio access bearer configured for G-711 A-law
   (payload type 8).

   Accordingly, the following SDP is returned to the caller in a 200 OK
   response:

         v=0
         o=Laura 289083124 289083124 IN IP4 second.example.com
         t=0 0
         c=IN IP4 222.222.222.222
         m=audio 30000 RTP/AVP 0
         a=fid:1
         m=audio 30002 RTP/AVP 8
         a=fid:1

   With the current way of performing SDP media alignment in SIP the
   callee would have accepted the call and immediately after re-INVITEd
   the caller with the new SDP. The fid attribute saves many RTTs.

   Besides saving bandwidth and RTTs the fid attribute provides a means
   for describing a logical relationship between media streams that
   belong to the same flow.

4.2 Application Server Components



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                      SDP media alignment in SIP


   In section 5.4 of "An Application Server Architecture for SIP" [3]
   contains two examples (figures 3 and 4) where DTMF tones are
   received by a different host than the voice stream. In both
   situations using the fid attribute to perform media alignment would
   save a tremendous amount of messages exchanged and reduce the golbal
   session establishment time.

   Let us take figure 4. A UAC sends an INVITE with just a voice
   stream. There are two ASs in the path that want to receive DTMF
   tones.

   Three steps are needed in order to set the session up:
   1) A session is established between the UAC and the callee. This
      involves three messages from the callerÆs point of view (INVITE-
      200 OK-ACK).
   2) The session is modified by A (one of the ASs that wants to
      receive DTMF tones). It adds an "m" line to the session
      description indicating that it wants to receive DTMF tones. This
      involves three more messages from the callerÆs point of view
      (INVITE-200 OK-ACK)
   3) The session is modified once more by B (the other AS that also
      wants to receive DTMF tones). It adds another "m" line indicating
      that it wants to receive DTMF tones. This involves three more
      messages from the callerÆs point of view (INVITE-200 OK-ACK).

          Caller            A                B              Callee
            |               |                |                 |
            |(1) SIP INV    |                |                 |
            |-------------->|(2) SIP INV     |                 |
            |               |--------------->|(3) SIP INV      |
            |               |                |---------------->|
            |               |                |(4) 200 OK       |
            |               |(5) 200 OK      |<----------------|
            |(6) 200 OK     |<---------------|                 |
            |<--------------|                |                 |
            |(7) SIP ACK    |                |                 |
            |-------------->|(8) SIP ACK     |                 |
            |               |--------------->|(9) SIP ACK      |
            |               |                |---------------->|
            |(10) SIP INV   |                |                 |
            |<--------------|                |                 |
            |(11) 200 OK    |                |                 |
            |-------------->|                |                 |
            |(12) SIP ACK   |                |                 |
            |<--------------|                |                 |
            |               |                |                 |
            |               |(13) SIP INV    |                 |
            |(14) SIP INV   |<---------------|                 |
            |<--------------|                |                 |
            |(15) 200 OK    |                |                 |
            |-------------->|(16) 200 OK     |                 |
            |               |--------------->|                 |
            |               |(17) SIP ACK    |                 |

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                      SDP media alignment in SIP


            |(18) SIP ACK   |<---------------|                 |
            |<--------------|                |                 |
            |               |                |                 |

           Figure 4 of "An AS Component Architecture for SIP" [3]

   The whole session is not correctly set up until the end of this
   sequence of messages. If the caller is using a low-rate access this
   can take a long time.

   The use of the fid attribute would reduce these nine messages that
   the caller sees to just three (INVITE-200 OK-ACK). B would add an
   "m" line to the 200 OK from the callee with the same fid value as
   the voice stream. Then A would add another "m" line, again with the
   same fid value than the two previous "m" lines.

   As a result, the caller receives a 200 OK indicating that just one
   flow is established, but also that all the DTMF tones should be sent
   to A and B. For a low-rate access the establishment time has been
   reduced a lot.

5. Media-level versus session-level attribute

   Syntactically fid is a media-level attribute. It provides
   information about a media stream defined by an "m" line.
   Semantically fid would be defined as a session-level attribute since
   it provides flow hierarchy inside a session description.

6. Backward compatibility

   A system that understands the fid attribute MUST add it to any SDP
   session description that it generates.

   If a response to a request that included the fid attribute also
   includes it media alignment is performed based on the fid attribute
   rather than on matching of nth lines.

6.1 Caller does not support fid

   This situation does not represent a problem. The SDP in the INVITE
   will not contain any fid attribute and the callee will use the "nth-
   line" method to perform media alignment.

   The callee will need a re-INVITE in order to receive the proper
   media encoding on the proper interface.

6.2 Callee does not support fid

   The callee will ignore the fid attribute. It will consider that the
   session comprises several media streams.

   Different implementations would behave in different ways.


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                      SDP media alignment in SIP


   In the case of audio and different "m" lines for different codecs an
   implementation might decide to act as a mixer with the different
   incoming RTP sessions, which is the correct behavior.

   If an implementation decides to refuse the request (e.g. 488 Not
   acceptable here or 606 Not Acceptable) the caller should re-try the
   request without the fid attribute and only one "m" line per flow.
   Note that even re-INVITEs without the fid attribute adding new "m"
   lines would probably fail in this situation because the callee does
   not support multiple "m" lines. Therefore, this problem is related
   to UAs that do not handle multiple "m" lines rather than to the fid
   attribute.

7. Acronyms

   AP       Application Server
   BNF      Backus-Naur Form
   DTMF     Dual Tone Multi Frequency
   EDGE     Enhanced Data rates for GSM and TDMA/136 Evolution
   GSM      Global System for Mobile communication
   IP       Internet Protocol
   PCM      Pulse Code Modulation
   RFC      Request For Comments
   RTCP     RTP Control Protocol
   RTP      Real-time Transport Protocol
   RTSP     Real-Time Streaming Protocol
   RTT      Round Trip Time
   SDP      Session Description Protocol
   SIP      Session Initiation Protocol
   TFT      Traffic Flow Template
   UA       User Agent
   UAC      User Agent Client
   UMTS     Universal Mobile Telecommunication System
   WLAN     Wireless Local Area Network

8. Acknowledgments

   The authors would like to thank Adam Roach for his feedback on this
   document.

9. References

   [1] M. Handley/H. Schulzrinne/E. Schooler/J. Rosenberg, "SIP:
   Session Initiation Protocol", RFC 2543, IETF; Mach 1999.

   [2] M. Handley/V. Jacobson, "SDP: Session Description Protocol", RFC
   2327, IETF; April 1998.

   [3] J. Rosemberg/P.Mataga/H.Schulzrinne, "An Applcation Server
   Component Architecture for SIP", draft-rosenberg-sip-app-components-
   00.txt, IETF; November 2000.



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                      SDP media alignment in SIP


   [4] H. Schulzrinne/A. Rao/R. Lanphier, "Real Time Streaming Protocol
   (RTSP)", RFC 2326, IETF; April 1998.

   [5] H. Schulzrinne/S. Casner/R. Frederick/V. Jacobson, "RTP: A
   Transport Protocol for Real-Time Applications", RFC 1889, IETF;
   January 1996.

   [6] L. Westberg/M. Lindqvist, "Realtime Traffic over Cellular Access
   Networks", draft-westberg-realtime-cellular-02.txt, IETF; May 2000.
   Work in progress.

   [7] 3G TS 23.060 v3.2.1 General Packet Radio Service Description.

10. Authors³ Addresses

   Gonzalo Camarillo
   Ericsson
   Advanced Signalling Research Lab.
   FIN-02420 Jorvas
   Finland
   Phone: +358 9 299 3371
   Fax: +358 9 299 3052
   Email: Gonzalo.Camarillo@ericsson.com

   Jan Holler
   Ericsson Research
   S-16480 Stockholm
   Sweden
   Phone: +46 8 58532845
   Fax: +46 8 4047020
   Email: Jan.Holler@era.ericsson.se

   Goran AP Eriksson
   Ericsson Research
   S-16480 Stockholm
   Sweden
   Phone: +46 8 58531762
   Fax: +46 8 4047020
   Email: Goran.AP.Eriksson@era.ericsson.se















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