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INTERNET-DRAFT D. Yon
Document: draft-ietf-mmusic-sdp-tcpmedia-00.txt Dialout.Net
Expires April 2001 October 2000
TCP-Based Media Transport in SDP
<draft-ietf-mmusic-sdp-tcpmedia-00.txt>
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of RFC2026.
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Copyright (C) The Internet Society (2000). All Rights Reserved.
Abstract
This document describes how to express TCP-based media transport
using the Session Description Protocol (SDP). It defines two new
protocol identifiers: TCP and RTP/AVP-TCP. It also defines the
syntax and semantics for an SDP "direction" attribute that describes
the TCP connection setup procedure.
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Introduction
The Session Description Protocol [SDP] provides a general-purpose
format for describing multimedia sessions in announcements or
invitations. SDP uses an entirely textual data format (the US-ASCII
subset of [UTF-8]) to maximize portability among transports. SDP
does not define a protocol, but only the syntax to describe a
multimedia session with sufficient information to discover and
participate in that session. Session descriptions may be sent using
any number of existing application protocols for transport (e.g.,
SAP, SIP, RTSP, email, HTTP, etc.).
Motivation
[SDP] describes two protocol identifiers: RTP/AVP and UDP, both of
which are unreliable, connectionless protocols, an appropriate
choice for multimedia streams. There are, however, applications for
which the connection-oriented TCP transport is more appropriate, but
[SDP] provides no way to describe a session that uses the TCP
protocol.
The connection-oriented nature of TCP introduces a new factor when
describing a session: not only must it be possible to express that a
protocol will be based on TCP, but it must also describe the
connection setup procedure.
1 Protocol Identifiers
1.1 RTP/AVP-TCP
[SDP] already specifies the RTP/AVP protocol identifier as a way to
describe media that uses the Real Time Protocol and the associated
Audio-Video Profiles. The assumption in [SDP] is that the
underlying network transport is UDP. RTP is transport-neutral, so
it is possible to transport RTP/RTCP packets using TCP rather than
UDP. To describe a media session that uses RTP/AVP over TCP, the
protocol identifier RTP/AVP-TCP must be specified in the m= line.
1.2 TCP
The TCP protocol identifier is similar to the UDP protocol
identifier in that it only describes the transport protocol without
any connotation as to the upper-layer protocol. An m= line that
specifies TCP must further qualify the protocol using a fmt
identifier (see [SDP] Appendix B).
2 Direction Attribute
An important attribute of a TCP connection is the setup procedure.
One endpoint needs to initiate the connection and the other endpoint
needs to accept the connection. The direction attribute is used to
describe these roles, and the syntax is as follows:
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a=direction:<role> <source-port>
The <role> is one of the following:
passive: The endpoint will accept an incoming TCP connection.
active: The endpoint will initiate an outgoing TCP connection.
both: The endpoint will both accept an incoming TCP connection
and will initiate an outgoing TCP connection.
The <source-port> is an optional value that may only be specified in
the context of direction:active or direction:both.
2.1 Semantics of direction:passive
By specifying direction:passive, the endpoint indicates that the
port number specified in the m= line is available to accept a TCP
connection from the other endpoint.
2.2 Semantics of direction:active
By specifying direction:active, the endpoint indicates that it will
initiate a TCP connection to the port number on the m= line of the
other endpoint. The port number on its own m= line is irrelevant
and is to be ignored by the other endpoint. Nevertheless, since the
m= line must contain a valid port number, the endpoint specifying
direction:active should specify a port number of 9 (the discard
port) on its m= line. The endpoint must not specify a port number
of zero, as that carries other semantics in [SDP].
The endpoint may optionally specify the port number from which it
will initiate the TCP connection in the <source-port> position on
the a= line.
2.3 Semantics of direction:both
By specifying direction:both, the endpoint indicates that it will
both accept a TCP connection on the port number of its own m= line,
and that it will also initiate a TCP connection to the port number
on the m= line of the other endpoint. As with direction:active, the
endpoint may optionally specify the port number from which it will
initiate the TCP connection in the <source-port> position on the a=
line.
Since this attribute describes behavior that is similar to
connectionless media descriptions in [SDP], it is the default value
for the direction attribute and is therefore optional.
Endpoints may choose to specify direction:both for one or more of
the following reasons:
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1) The endpoint has no preference as to whether it accepts or
initiates the TCP connection, and therefore is offering the
remote endpoint a choice of connection setup procedures.
2) The endpoints intend to use a single TCP connection to
transport the media, but it is not known whether firewall
issues will prevent either endpoint from initiating or
accepting the TCP connection. Therefore both endpoints will
attempt to initiate a TCP connection in hopes that at least
one will succeed.
3) The endpoints intend to use two TCP connections to transport
the media, and one must be initiated by the remote endpoint
and the other must be initiated by the local endpoint.
If one endpoint specifies either direction:active or
direction:passive and the other specifies direction:both, both
endpoints must behave as if the latter had specified the inverse
direction of the former. For example, specifying direction:both
when the other endpoint specifies direction:active should cause both
endpoints to behave as if the former had specified
direction:passive. Conversely, specifying direction:both when the
other endpoint specifies direction:passive should cause both
endpoints to behave as if the former had specified direction:active.
If both endpoints specify direction:both then each endpoint must
initiate a TCP connection to the port number specified on the m=
line of the opposite endpoint. If only one connection succeeds,
then that connection will be used to carry the media. If both
connections succeed but only one was needed (case #2 above), the
following rules shall apply:
a) Each endpoint MUST accept data from either TCP connection.
b) Once an endpoint has transmitted data to one of the TCP
connections, it MUST use that TCP connection exclusively for
transmission.
c) Once an endpoint has transmitted AND received data, if one of
the TCP connections is determined to be idle, the endpoint MAY
close the idle TCP connection.
3 Source-Port Considerations
In the cases where the endpoint is initiating the TCP connection, a
source port number may optionally be specified on the a= line by
that endpoint. In most environments, the source port number can be
determined by binding the socket before initiating the connect, as
shown in the sample C code below:
{
SOCKET s_id
SOCKADDR_IN cli_sin;
int namelen;
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// Create the socket
s_id = socket(AF_INET,SOCK_STREAM,IPPROTO_TCP);
// Bind the socket to any IP address and port
bzero((char *)&cli_sin,sizeof(cli_sin));
cli_sin.sin_family = AF_INET;
cli_sin.sin_addr.s_addr = htonl(INADDR_ANY);
cli_sin.sin_port = 0;
bind(s_id,(SOCKADDR *)&cli_sin,sizeof(cli_sin));
// Find the port number that was bound
namelen = sizeof(cli_sin);
getsockname(s_id,(SOCKADDR *)&cli_sin,&namelen);
// Print the port number
printf("Source Port = %d\n",ntohs(cli_sin.sin_port));
}
The motivation for specifying the source port is to allow topologies
where one or more endpoints use a single, fixed TCP port for
incoming connections. Non-RTP protocols transported over TCP
commonly use this technique. By specifying the source port, an
endpoint avoids a potential ambiguity when more than one session is
set up between two endpoints.
For example, consider two endpoints with IP addresses of 10.1.1.1
and 10.1.1.2. The endpoint at 10.1.1.1 signals the availability of
a session on TCP port 2393 (passive). Before the endpoint at
10.1.1.2 has a chance to initiate the connection, events transpire
that cause the endpoint at 10.1.1.1 to signal the availability of a
separate session that is also found at TCP port 2393 (passive).
Shortly thereafter, both entities at 10.1.1.2 initiate connections
to 10.1.1.1 on port 2393.
The problem is this: how does the endpoint at 10.1.1.1 differentiate
the two connections? To which entity at 10.1.1.2 does each
connection correspond? By specifying the source port prior to
connecting, the entities at 10.1.1.2 can avoid this ambiguity,
because now the endpoint at 10.1.1.1 can simply inspect the port
number from which the connection originated to determine which
entity has initiated the connection.
Caution must be exercised when designing systems that rely on this
feature, as not all environments are able to determine the source
port prior to initiating the connection.
4 Examples
What follows are a number of examples that show the most common
usage of the direction attribute combined with TCP-based media
descriptions. For the purpose of brevity, the main portion of the
session description is omitted in the examples and is assumed to be
the following:
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v=0
o=Me <me@ietf.org>
s=Call me using TCP
t=0 0
4.1 Example: simple passive/active
An endpoint at 10.1.1.2 signals the availability of an audio session
at port 54111:
c=IN IP4 10.1.1.2/127
m=audio 54111 RTP/AVP-TCP 0
a=direction:passive
An endpoint at 10.1.1.1 receiving this description responds with the
following:
c=IN IP4 10.1.1.1/127
m=audio 9 RTP/AVP-TCP 0
a=direction:active
The endpoint at 10.1.1.1 then initiates the TCP connection to port
54111 at 10.1.1.2. Note that the TCP connection may originate from
any port. The endpoint at 10.1.1.1 could have optionally committed
to a source port with a simple modification:
c=IN IP4 10.1.1.1/127
m=audio 9 RTP/AVP-TCP 0
a=direction:active 1892
By adding the "1892" to the a= line, the endpoint at 10.1.1.1 must
now use a source port of 1892 when initiating the TCP connection to
port 54111 at 10.1.1.2.
4.2 Example: agnostic both
An endpoint at 10.1.1.2 signals the availability of an audio session
at TCP port 54111, but is also willing to set up the media stream by
initiating the TCP connection:
c=IN IP4 10.1.1.2/127
m=audio 54111 RTP/AVP-TCP 0
a=direction:both
The endpoint at 10.1.1.1 has three choices:
1) It can respond with either of the two direction:active
descriptions listed in the previous example. In this case the
endpoint at 10.1.1.1 must initiate a connection to port 54111
at 10.1.1.2.
2) It can respond with a description similar to the following:
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c=IN IP4 10.1.1.1/127
m=audio 54321 RTP/AVP-TCP 0
a=direction:passive
In this case the endpoint at 10.1.1.2 must initiate a
connection to port 54321 at 10.1.1.1.
3) It can respond with a description that specifies
direction:both, which is covered in the next example.
4.3 Example: redundant both
An endpoint at 10.1.1.2 uses the same description as the previous
example:
c=IN IP4 10.1.1.2/127
m=audio 54111 RTP/AVP-TCP 0
a=direction:both
Unlike the previous example, the endpoint at 10.1.1.1 responds with
the following description:
c=IN IP4 10.1.1.1/127
m=audio 54321 RTP/AVP-TCP 0
a=direction:both
This will cause the endpoint at 10.1.1.2 to initiate a connection to
port 54321 at 10.1.1.1, and the endpoint at 10.1.1.1 to initiate a
connection to port 54111 at 10.1.1.2. Whichever TCP connection
succeeds will be used. If both succeed, one of the connections may
be closed as an optimization, using the rules in section 2.3.
5 Security Considerations
See [SDP] for security and other considerations specific to the
Session Description Protocol in general. There are no new security
considerations introduced by these protocol identifiers and
attributes.
6 IANA Considerations
As recommended by [SDP] Appendix B, the direction attribute
described in this document should be registered with IANA, as should
the TCP and RTP/AVP-TCP protocol identifiers.
Acknowledgements
The author would like to thank Jonathan Rosenberg, Anders
Kristensen, and Robert Fairlie-Cuninghame for their valuable
insights.
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Appendix A: Direction Attribute Syntax
This appendix provides an Augmented BNF [ABNF] grammar for
expressing the direction attribute for TCP connection setup. It is
intended as an extension to the grammar for the Session Description
Protocol, as defined in [SDP]. Specifically, it describes the
syntax for the new "connection-setup" attribute field, which MAY be
either a session-level or media-level attribute.
connection-setup = "direction" ":" direction-spec
direction-spec = "passive" | qualified-direction
qualified-direction = direction-ident | direction-ident port
direction-ident = "both" | "active"
References
[ABNF] D. Crocker, P. Overell, "Augmented BNF for Syntax
Specifications: ABNF," RFC 2234, November 1997
[SDP] M. Handley, V. Jacobson, "SDP: Session Description
Protocol," RFC 2327, April 1998
[UTF-8] F. Yergeau, "UTF-8, a transformation format of Unicode
and ISO 10646," RFC 2044, October 1996
Author's Address
David Yon
Dialout.Net, Inc.
402 Amherst St
Nashua, NH 03063
Phone: (603) 577-8708
EMail: yon@dialout.net
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