Internet Engineering Task Force (IETF) L. Stout, Ed.
Request for Comments: 7395 &yet
Category: Standards Track J. Moffitt
ISSN: 2070-1721 Mozilla
E. Cestari
cstar industries
October 2014
An Extensible Messaging and Presence Protocol (XMPP) Subprotocol for
WebSocket
Abstract
This document defines a binding for the Extensible Messaging and
Presence Protocol (XMPP) over a WebSocket transport layer. A
WebSocket binding for XMPP provides higher performance than the
current HTTP binding for XMPP.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc7395.
Copyright Notice
Copyright (c) 2014 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 Simplified BSD License.
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Table of Contents
1. Introduction ....................................................2
2. Terminology .....................................................3
3. XMPP Subprotocol ................................................3
3.1. Handshake ..................................................3
3.2. WebSocket Messages .........................................4
3.3. XMPP Framing ...............................................5
3.3.1. Framed XML Stream ...................................5
3.3.2. Framed Stream Namespace .............................5
3.3.3. Stream Frames .......................................5
3.4. Stream Initiation ..........................................6
3.5. Stream Errors ..............................................7
3.6. Closing the Connection .....................................7
3.6.1. see-other-uri .......................................8
3.7. Stream Restarts ............................................9
3.8. Pings and Keepalives .......................................9
3.9. Use of TLS .................................................9
3.10. Stream Management ........................................10
4. Discovering the WebSocket Connection Method ....................10
5. IANA Considerations ............................................11
5.1. WebSocket Subprotocol Name ................................11
5.2. URN Sub-namespace .........................................11
6. Security Considerations ........................................12
7. References .....................................................14
7.1. Normative References ......................................14
7.2. Informative References ....................................14
Appendix A. XML Schema ............................................16
Acknowledgements ..................................................17
Authors' Addresses ................................................18
1. Introduction
To date, applications using the Extensible Messaging and Presence
Protocol (XMPP) (see [RFC6120] and [RFC6121]) on the Web have made
use of Bidirectional-streams Over Synchronous HTTP (BOSH) (see
[XEP-0124] and [XEP-0206]), an XMPP binding to HTTP. BOSH is based
on the HTTP "long polling" technique, and it suffers from high
transport overhead compared to XMPP's native binding to TCP. In
addition, there are a number of other known issues with long polling
[RFC6202] that have an impact on BOSH-based systems.
In most circumstances, it would be much better to avoid tunneling
XMPP over HTTP long-polled connections and instead use XMPP directly.
However, the APIs and sandbox that browsers have provided do not
allow this. The WebSocket protocol [RFC6455] exists to solve these
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kinds of problems and is a bidirectional protocol that provides a
simple message-based framing layer, allowing for more robust and
efficient communication in web applications.
The WebSocket protocol enables two-way communication between a client
and a server, effectively emulating TCP at the application layer and,
therefore, overcoming many of the problems with existing long-polling
techniques for bidirectional HTTP. This document defines a WebSocket
subprotocol for XMPP.
The WebSocket binding for XMPP is designed for use by browser-based
applications (e.g., XMPP clients written in JavaScript). Typically,
these applications are used to access the same information and
communication opportunities (e.g., the same XMPP "roster" of
contacts) as clients that connect to an XMPP server over the TCP
binding defined in [RFC6120]. Although the only essential difference
is the underlying transport binding, relevant implications (e.g.,
framing methods and discovery processes) are highlighted in this
specification.
2. Terminology
The basic unit of framing in the WebSocket protocol is called a
"message". In XMPP, the basic unit is the stanza, which is a subset
of the first-level children of each document in an XMPP stream (see
Section 9 of [RFC6120]). XMPP also has a concept of messages, which
are stanzas with a top-level element of . In this
document, the word "message" will mean a WebSocket message, not an
XMPP message stanza (unless otherwise noted).
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
"OPTIONAL" in this document are to be interpreted as described in
[RFC2119].
3. XMPP Subprotocol
3.1. Handshake
The XMPP subprotocol is used to transport XMPP over a WebSocket
connection. The client and server agree to this protocol during the
WebSocket handshake (see Section 1.3 of [RFC6455]).
During the WebSocket handshake, the client MUST include the value
'xmpp' in the list of protocols for the 'Sec-WebSocket-Protocol'
header. The reply from the server MUST also contain 'xmpp' in its
own 'Sec-WebSocket-Protocol' header in order for an XMPP subprotocol
connection to be established.
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If a client receives a handshake response that does not include
'xmpp' in the 'Sec-WebSocket-Protocol' header, then an XMPP
subprotocol WebSocket connection was not established and the client
MUST close the WebSocket connection.
Once the handshake has successfully completed, WebSocket messages
sent or received MUST conform to the protocol defined in the rest of
this document.
The following is an example of a WebSocket handshake, followed by
opening an XMPP stream:
C: GET /xmpp-websocket HTTP/1.1
Host: example.com
Upgrade: websocket
Connection: Upgrade
Sec-WebSocket-Key: dGhlIHNhbXBsZSBub25jZQ==
Origin: http://example.com
...
Sec-WebSocket-Protocol: xmpp
Sec-WebSocket-Version: 13
S: HTTP/1.1 101 Switching Protocols
Upgrade: websocket
Connection: Upgrade
...
Sec-WebSocket-Accept: s3pPLMBiTxaQ9kYGzzhZRbK+xOo=
Sec-WebSocket-Protocol: xmpp
[WebSocket connection established]
C:
S:
3.2. WebSocket Messages
Data frame messages in the XMPP subprotocol MUST be of the text type
and contain UTF-8 encoded data.
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3.3. XMPP Framing
The framing method for the binding of XMPP to WebSocket differs from
the framing method for the TCP binding as defined in [RFC6120]; in
particular, the WebSocket binding adopts the message framing provided
by WebSocket to delineate the stream open and close headers, stanzas,
and other top-level stream elements.
3.3.1. Framed XML Stream
The start of a framed XML stream is marked by the use of an opening
"stream header", which is an element with the appropriate
attributes and namespace declarations (see Section 3.3.2). The
attributes of the element are the same as those of the
element defined for the 'http://etherx.jabber.org/streams'
namespace [RFC6120] and with the same semantics and restrictions.
The end of a framed XML stream is denoted by the closing "stream
header", which is a element with its associated attributes
and namespace declarations (see Section 3.3.2).
The introduction of the and elements is motivated by
the parsable XML document framing restriction in Section 3.3.3. As a
consequence, note that a framed XML stream does not provide a
wrapping [RFC6120] element encompassing the entirety
of the XML stream.
3.3.2. Framed Stream Namespace
The XML stream headers (the and elements) MUST be
qualified by the namespace 'urn:ietf:params:xml:ns:xmpp-framing' (the
"framed stream namespace"). If this rule is violated, the entity
that receives the offending stream header MUST close the stream with
an error, which MUST be (see Section 4.9.3.10 of
[RFC6120]).
3.3.3. Stream Frames
The individual frames of a framed XML stream have a one-to-one
correspondence with WebSocket messages and MUST be parsable as
standalone XML documents, complete with all relevant namespace and
language declarations. The inclusion of XML declarations, however,
is NOT RECOMMENDED, as WebSocket messages are already mandated to be
UTF-8 encoded. Including declarations in each message would only
increase the framing overhead of each message.
The first character of each frame MUST be a '<' character.
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Every XMPP stanza or other XML element (including the stream open and
close headers) sent directly over the XML stream MUST be sent in its
own frame.
Example of a WebSocket message that contains an independently
parsable XML document:
Every WebSocket message is parsable by itself.
Note that for stream features and errors, there is no parent context
element providing the "stream" namespace prefix as in [RFC6120], and
thus the stream prefix MUST be declared or use an unprefixed form:
-- OR --
3.4. Stream Initiation
The first message sent after the WebSocket opening handshake MUST be
from the initiating entity and MUST be an element qualified
by the 'urn:ietf:params:xml:ns:xmpp-framing' namespace and with the
same attributes mandated for the opening tag as described in
Section 4.7 of [RFC6120].
The receiving entity MUST respond with either an element
(whose attributes match those described in Section 4.7 of [RFC6120])
or a element (see Section 3.6.1).
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An example of a successful stream initiation exchange:
C:
S:
Clients MUST NOT multiplex XMPP streams over the same WebSocket.
3.5. Stream Errors
Stream-level errors in XMPP are fatal. Should such an error occur,
the server MUST send the stream error as a complete element in a
message to the client.
If the error occurs during the opening of a stream, the server MUST
send the initial open element response, followed by the stream-level
error in a second WebSocket message frame. The server MUST then
close the connection as specified in Section 3.6.
3.6. Closing the Connection
The closing process for the XMPP subprotocol mirrors that of the XMPP
TCP binding as defined in Section 4.4 of [RFC6120], except that a
element is used instead of the ending tag.
Either the server or the client may close the connection at any time.
Before closing the connection, the closing party is expected to first
close the XMPP stream (if one has been opened) by sending a message
with the element, qualified by the
"urn:ietf:params:xml:ns:xmpp-framing" namespace. The stream is
considered closed when a corresponding element is received
from the other party, and the XMPP session is ended.
To then close the WebSocket connection, the closing party MUST
initiate the WebSocket closing handshake (see Section 7.1.2 of
[RFC6455]).
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An example of ending an XMPP-over-WebSocket session by first closing
the XMPP stream layer and then the WebSocket connection layer:
Client (XMPP WSS) Server
| | | |
| | | |
| |------------------------------------------------------------>| |
| | | |
| |<------------------------------------------------------------| |
| | | |
| | (XMPP Stream Closed) | |
| +-------------------------------------------------------------+ |
| |
| WS CLOSE FRAME |
|------------------------------------------------------------------>|
| WS CLOSE FRAME |
|<------------------------------------------------------------------|
| |
| (Connection Closed) |
+-------------------------------------------------------------------+
If the WebSocket connection is closed or broken without the XMPP
stream having been closed first, then the XMPP stream is considered
implicitly closed and the XMPP session ended; however, if the use of
stream management resumption was negotiated (see [XEP-0198]), the
server SHOULD consider the XMPP session still alive for a period of
time based on server policy as specified in [XEP-0198].
3.6.1. see-other-uri
At any point, if the server wishes to instruct the client to move to
a different WebSocket endpoint (e.g., for load-balancing purposes),
then a element is sent with the 'see-other-uri' attribute
set to the URI of the new connection endpoint (which MAY be for a
different transport method, such as BOSH (see [XEP-0124] and
[XEP-0206])).
Clients MUST NOT accept suggested endpoints with a lower security
context (e.g., moving from a 'wss://' endpoint to a 'ws://' or
'http://' endpoint).
An example of the server closing a stream and instructing the client
to connect at a different WebSocket endpoint:
S:
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3.7. Stream Restarts
Whenever a stream restart is mandated (see Section 4.3.3 of
[RFC6120]), both the server and client streams are implicitly closed
and new streams MUST be opened, using the same process as in
Section 3.4.
The client MUST send a new stream element and MUST NOT send a
closing element.
An example of restarting the stream after successful Simple
Authentication and Security Layer (SASL) negotiation:
S:
[Streams implicitly closed]
C:
3.8. Pings and Keepalives
Traditionally, XMPP servers and clients often send "whitespace
keepalives" (see Section 4.6.1 of [RFC6120]) between stanzas to
maintain an XML stream. However, for the XMPP subprotocol each
message is required to start with a '<' character, and, as such,
whitespace keepalives MUST NOT be used.
As alternatives, the XMPP Ping extension [XEP-0199] and the XMPP
Stream Management extension [XEP-0198] provide pinging mechanisms.
Either of these extensions (or both) MAY be used to determine the
state of the connection.
Clients and servers MAY also use WebSocket ping control frames for
this purpose, but note that some environments, such as browsers, do
not provide access for generating or monitoring ping control frames.
3.9. Use of TLS
Transport Layer Security (TLS) cannot be used at the XMPP subprotocol
layer because the subprotocol does not allow for raw binary data to
be sent. Instead, when TLS is used, it MUST be enabled at the
WebSocket layer using secure WebSocket connections via the 'wss' URI
scheme. (See Section 10.6 of [RFC6455].)
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Because TLS is to be provided outside of the XMPP subprotocol layer,
a server MUST NOT advertise TLS as a stream feature (see Section 4.6
of [RFC6120]) when using the XMPP subprotocol. Likewise, a client
MUST ignore any advertised TLS stream feature when using the XMPP
subprotocol.
3.10. Stream Management
In order to alleviate the problems of temporary disconnections, the
client MAY use the XMPP Stream Management extension [XEP-0198] to
confirm when stanzas have been received by the server.
In particular, the client MAY use session resumption as described in
[XEP-0198] to recreate the same stream session state after a
temporary network unavailability or after navigating to a new URL in
a browser.
4. Discovering the WebSocket Connection Method
Section 3 of [RFC6120] defines a procedure for connecting to an XMPP
server, including ways to discover the TCP/IP address and port of the
server using Domain Name System service (DNS SRV) records [RFC2782].
When using the WebSocket binding as specified in this document
(instead of the TCP binding as specified in [RFC6120]), a client
needs an alternative way to discover information about the server's
connection methods, since web browsers and other WebSocket-capable
software applications typically cannot obtain such information from
the DNS.
The alternative lookup process uses Web-host Metadata [RFC6415] and
Web Linking [RFC5988], where the link relation type is
"urn:xmpp:alt-connections:websocket" as described in "Discovering
Alternative XMPP Connection Methods" [XEP-0156]. Conceptually, the
host-meta lookup process used for the WebSocket binding is analogous
to the DNS SRV lookup process used for the TCP binding. The process
is as follows.
1. Send a request over secure HTTP to the path
"/.well-known/host-meta" at an HTTP origin [RFC6454] that matches
the XMPP service domain (e.g., a URL of
"https://im.example.org/.well-known/host-meta" if the XMPP
service domain is "im.example.org").
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2. Retrieve a host-meta document specifying a link relation type of
"urn:xmpp:alt-connections:websocket", such as:
Servers MAY expose discovery information using host-meta documents,
and clients MAY use such information to determine the WebSocket
endpoint for a server.
In cases where the XMPP service domain does not match the discovered
web origin of the WebSocket endpoint, the Web-host Metadata SHOULD be
used to establish trust between the XMPP server domain and the
WebSocket endpoint as long as the host-meta request and response
occurred over secure HTTP; this is especially relevant in multi-
tenant situations where the same WebSocket endpoint is serving
multiple XMPP domains (e.g., the XMPP service domains for both
"example.com" and "im.example.org" might be serviced by the same
WebSocket endpoint at "hosting.example.net"). See Section 6 for
related discussion.
5. IANA Considerations
5.1. WebSocket Subprotocol Name
IANA has registered the WebSocket XMPP subprotocol in the "WebSocket
Subprotocol Name Registry", with the following data:
Subprotocol Identifier: xmpp
Subprotocol Common Name: WebSocket Transport for the Extensible
Messaging and Presence Protocol (XMPP)
Subprotocol Definition: this document
5.2. URN Sub-namespace
A URN sub-namespace for framing of Extensible Messaging and Presence
Protocol (XMPP) streams is defined as follows.
URI: urn:ietf:params:xml:ns:xmpp-framing
Specification: this document
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Description: This is the XML namespace name for framing of
Extensible Messaging and Presence Protocol (XMPP) streams as
defined by RFC 7395.
Registrant Contact: IESG
6. Security Considerations
The WebSocket binding for XMPP differs in several respects from the
TCP binding defined in [RFC6120]:
1. As described in Section 4 of this document, the method for
discovering a connection endpoint does not use DNS SRV records as
in the TCP binding but instead uses Web-host Metadata files
retrieved via HTTPS from a URL at the XMPP service domain. From
a security standpoint, this is functionally equivalent to
resolution via DNS SRV records (and still relies on the DNS for
resolution of the XMPP source domain).
2. The method for authenticating a connection endpoint uses TLS
(typically with PKIX certificates) as in the TCP binding, but the
identity to be authenticated is the connection endpoint address
instead of the XMPP service domain; delegation from the XMPP
service domain to the connection endpoint address (if any) is
accomplished via the discovery method described in Section 4.
Thus, the connection endpoint is still authenticated, and the
delegation is secure as long as the Web-host Metadata file is
retrieved via HTTPS. However, note that, in practice, this
option might not be employed when user agents are configured or
deployed for a particular delegated domain.
3. The framing method described in Section 3.3 follows the WebSocket
pattern by sending one top-level XML element per WebSocket
message, instead of using streaming XML as in the TCP binding.
However, the framing method has no impact on the security
properties of an XMPP session (e.g., end-to-end encryption of XML
stanzas can be accomplished just as easily with WebSocket framing
as with streaming XML).
4. In all other respects (e.g., user authentication via SASL,
allowable characters in XMPP addresses, and reuse of various
technologies such as Base 64, SASL mechanisms, UTF-8, and XML),
the WebSocket binding does not differ from the TCP binding and,
thus, does not modify the security properties of the protocol.
In all these respects, the security considerations of [RFC6120]
apply directly to the WebSocket binding.
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In order to ensure that communications over the WebSocket binding are
as secure as communications over the TCP binding, an operator needs
to (1) serve the Web-host Metadata file for the XMPP service domain
over secure HTTP ('https' URIs) only, (2) configure the WebSocket
connection endpoint to use TLS ('wss' URIs) only, and (3) deploy
certificates that properly identify the XMPP service domain and
WebSocket connection endpoint for usages (1) and (2), respectively.
Since application-level TLS cannot be used (see Section 3.9),
applications need to protect the privacy of XMPP traffic at the
WebSocket or other appropriate layer.
Browser-based applications are not able to inspect and verify, at the
application layer, the certificate used for the WebSocket connection
to ensure that it corresponds to the domain specified as the 'to'
address of the XMPP stream. There are two cases:
1. If the XMPP service domain matches the origin for the WebSocket
connection, the relevant check is already performed by the
browser. For example, the XMPP service domain might be
"foo.example", and the WebSocket endpoint discovered for the link
relation type of "urn:xmpp:alt-connections:websocket" might be
"wss://foo.example/websocket". As long as the certificate
provided over WebSocket or HTTPS is verified according to the
rules defined for secure HTTP [RFC2818], then the browser will
report the successful establishment of a secure connection to the
application. (However, as noted, the application is still not
able to independently inspect and verify the certificate, and
needs to trust the browser; this is a limitation of existing
browser technologies and thus cannot be worked around by
WebSocket applications.)
2. In situations where the user agent has to deal with delegation
and the domain of the XMPP server does not match the web origin
of the WebSocket endpoint (such as multi-tenant hosting
situations), the host-meta process described in Section 4 SHOULD
be used to delegate trust from the XMPP server domain to the
WebSocket origin, as long as the host-meta request and response
occurred over secure HTTP (with appropriate certificate
verification as defined in [RFC2818]).
When presented with a new WebSocket endpoint via the 'see-other-uri'
attribute of a element, clients MUST NOT accept the
suggestion if the security context of the new endpoint is lower than
the current one in order to prevent downgrade attacks from a 'wss://'
endpoint to 'ws://'.
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The security considerations for both WebSocket (see Section 10 of
[RFC6455]) and XMPP (see Section 13 of [RFC6120]) apply to the
WebSocket XMPP subprotocol.
7. References
7.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997,
.
[RFC2818] Rescorla, E., "HTTP Over TLS", RFC 2818, May 2000,
.
[RFC5988] Nottingham, M., "Web Linking", RFC 5988, October 2010,
.
[RFC6120] Saint-Andre, P., "Extensible Messaging and Presence
Protocol (XMPP): Core", RFC 6120, March 2011,
.
[RFC6415] Hammer-Lahav, E. and B. Cook, "Web Host Metadata", RFC
6415, October 2011,
.
[RFC6455] Fette, I. and A. Melnikov, "The WebSocket Protocol", RFC
6455, December 2011,
.
7.2. Informative References
[RFC2782] Gulbrandsen, A., Vixie, P., and L. Esibov, "A DNS RR for
specifying the location of services (DNS SRV)", RFC 2782,
February 2000, .
[RFC6121] Saint-Andre, P., "Extensible Messaging and Presence
Protocol (XMPP): Instant Messaging and Presence", RFC
6121, March 2011,
.
[RFC6202] Loreto, S., Saint-Andre, P., Salsano, S., and G. Wilkins,
"Known Issues and Best Practices for the Use of Long
Polling and Streaming in Bidirectional HTTP", RFC 6202,
April 2011, .
[RFC6454] Barth, A., "The Web Origin Concept", RFC 6454,
December 2011, .
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[XEP-0124] Paterson, I., Smith, D., Saint-Andre, P., Moffitt, J.,
Stout, L., and W. Tilanus, "Bidirectional-streams Over
Synchronous HTTP (BOSH)", XSF XEP 0124, April 2014.
[XEP-0156] Hildebrand, J., Saint-Andre, P., and L. Stout,
"Discovering Alternative XMPP Connection Methods",
XSF XEP 0156, January 2014.
[XEP-0198] Karneges, J., Saint-Andre, P., Hildebrand, J., Forno, F.,
Cridland, D., and M. Wild, "Stream Management",
XSF XEP 0198, June 2011.
[XEP-0199] Saint-Andre, P., "XMPP Ping", XSF XEP 0199, June 2009.
[XEP-0206] Paterson, I., Saint-Andre, P., Stout, L., and W. Tilanus,
"XMPP Over BOSH", XSF XEP 0206, April 2014.
[XML-SCHEMA]
Thompson, H., Beech, D., Maloney, M., and N. Mendelsohn,
"XML Schema Part 1: Structures Second Edition", World Wide
Web Consortium Recommendation REC-xmlschema-1-20041028,
October 2004,
.
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Appendix A. XML Schema
The following schema formally defines the
'urn:ietf:params:xml:ns:xmpp-framing' namespace used in this
document, in conformance with W3C XML Schema [XML-SCHEMA]. Because
validation of XML streams and stanzas is optional, this schema is not
normative and is provided for descriptive purposes only.
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Acknowledgements
The authors wish to thank the following individuals for their
feedback: Andreas Guth, Bjoern Hoerhmann, Dave Cridland, Florian
Zeitz, Kurt Zeilenga, Matt Miller, Matthew Wild, Paul Aurich, Sergey
Dobrov, and Waqas Hussain.
Dan Romascanu reviewed the document on behalf of the General Area
Review Team.
During IESG review, Barry Leiba, Benoit Claise, Dan Romascanu, Jari
Arkko, Juergen Schoenwaelder, Spencer Dawkins, Stephen Farrell, Ted
Lemon, Kathleen Moriarty, and Pete Resnick caught several issues that
needed to be addressed.
The authors gratefully acknowledge the assistance of Peter Saint-
Andre as document shepherd, Ben Campbell and Joe Hildebrand as the
working group chairs, and Richard Barnes as the sponsoring Area
Director.
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Authors' Addresses
Lance Stout (editor)
&yet
EMail: lance@andyet.net
Jack Moffitt
Mozilla
EMail: jack@metajack.im
Eric Cestari
cstar industries
EMail: eric@cstar.io
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