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<?xml version='1.0' encoding='UTF-8'?>
<!DOCTYPE xep SYSTEM 'xep.dtd' [
<!ENTITY % ents SYSTEM 'xep.ent'>
%ents;
]>
<?xml-stylesheet type='text/xsl' href='xep.xsl'?>
<xep>
<header>
<title>Jabber HTTP Polling</title>
<abstract>This document defines an XMPP protocol extension that enables access to a Jabber server from behind firewalls which do not allow outgoing sockets on port 5222, via HTTP requests.</abstract>
&LEGALNOTICE;
<number>0025</number>
<status>Obsolete</status>
<type>Historical</type>
<sig>Standards</sig>
<dependencies>
<spec>XMPP Core</spec>
</dependencies>
<supersedes/>
<supersededby>
<spec>XEP-0124</spec>
</supersededby>
<shortname>httppoll</shortname>
&hildjj;
<author>
<firstname>Craig</firstname>
<surname>Kaes</surname>
<email>ckaes@jabber.com</email>
<jid>ckaes@corp.jabber.com</jid>
</author>
<author>
<firstname>David</firstname>
<surname>Waite</surname>
<email>mass@akuma.org</email>
<jid>mass@akuma.org</jid>
</author>
<revision>
<version>1.2</version>
<date>2009-06-03</date>
<initials>psa</initials>
<remark><p>Per a vote of the XMPP Council, changed status to Obsolete.</p></remark>
</revision>
<revision>
<version>1.1</version>
<date>2006-07-26</date>
<initials>psa</initials>
<remark><p>Per a vote of the Jabber Council, changed status to Deprecated.</p></remark>
</revision>
<revision>
<version>1.0</version>
<date>2002-10-11</date>
<initials>psa</initials>
<remark><p>Per a vote of the Jabber Council, advanced status to Active.</p></remark>
</revision>
<revision>
<version>0.2</version>
<date>2002-09-23</date>
<initials>dew</initials>
<remark><p>Changed format to allow socket-equivalent security.</p></remark>
</revision>
<revision>
<version>0.1</version>
<date>2002-03-14</date>
<initials>jjh</initials>
<remark><p>Initial version.</p></remark>
</revision>
</header>
<section1 topic="Introduction">
<p><em>Note Well: This protocol specified in this document has been superseded by the protocol specified in &xep0124;.</em></p>
<p>
This specification documents a method to allow Jabber clients to access Jabber
servers from behind existing firewalls. Although several similar methods
have been proposed, this approach should work through all known firewall
configurations which allow outbound HTTP access.
</p>
</section1>
<section1 topic="Background">
<p>
In general, a firewall is a box that protects a network from outsiders,
by controlling the IP connections that are allowed to pass through the
box. Often, a firewall will also allow access outside only by proxy,
either explicit proxy support or implicit through Network Address
Translation (NAT).
</p>
<p>
In the interest of security, many firewall administrators do not allow
outbound connections to unknown and unused ports. Until Jabber becomes
more widely deployed, port 5222/tcp (for Jabber client connections) will
often be blocked.
</p>
<p>
The best solution for sites that are concerned about security is to run
their own Jabber server, either inside the firewall, or in a DMZ
<note>
DMZ definition at
<link
url="http://searchwebmanagement.techtarget.com/sDefinition/0,,sid27_gci213891,00.html">
searchwebmanagement.com
</link>
</note>
network. However, there are network configuration where an external
Jabber server must still be used and port 5222/tcp outbound cannot be
allowed. In these situations, different methods for connecting to a
Jabber server are required. Several methods exist today for doing this
traversal. Most rely on the fact that a most firewalls are configured to
allow access through port 80/tcp. Although some less-complicated
firewalls will allow any protocol to traverse this port, many will proxy,
filter, and verify requests on this port as HTTP. Because of this, a
normal Jabber connection on port 80/tcp will not suffice.
</p>
<p>
In addition, many firewalls/proxy servers will also not allow or not
honor HTTP Keep-alives (as defined in section 19.7.1.1 of &rfc2068;)
and will consider long-lived socket connections as security issues.
Because of this the traditional Jabber connection model, where one
socket is one stream is one session, will not work reliably.
</p>
<p>
In light of all of the ways that default firewall rules can interfere
with Jabber connectivity, a lowest-common denominator approach was
selected. HTTP is used to send XML as POST requests and receieve pending
XML within the responses. Additional information is prepended in the
request body to ensure an equivalent level of security to TCP/IP sockets.
</p>
</section1>
<section1 topic="Normal data transfer">
<p>
The client makes HTTP requests periodically to the server. Whenever the
client has something to send, that XML is included in the body of the
request. When the server has something to send to the client, it must be
contained in the body of the response.
</p>
<p>
In some browser/platform combinations, sending cookies from the client is
not possible due to design choices and limitations in the
browser. Therefore, a work-around was needed to support clients based on
these application platforms.
</p>
<p>
All requests to the server are HTTP POST requests, with Content-Type:
application/x-www-form-urlencoded. Responses from the server have
Content-Type: text/xml. Both the request and response bodies are UTF-8
encoded text, even if an HTTP header to the contrary exists. All
responses contain a Set-Cookie header with an identifier, which is sent
along with future requests as described below. This identifier cookie
must have a name of 'ID'. The first request to a server always uses 0 as
the identifier. The server must always return a 200 response code,
sending any session errors as specially-formatted identifiers.
</p>
<p>The client sends requests with bodies in the following format:</p>
<example caption="Request Format">
identifier ; key [ ; new_key] , [xml_body]
</example>
<p>If the identifier is zero, key indicates an initial key. In this case,
new_key should not be specified, and must be ignored.</p>
<table caption="Request Values">
<tr>
<th>Identifier</th>
<th>Purpose</th>
</tr>
<tr>
<td>identifier</td>
<td>
To uniquely identify the session server-side. This field is only
used to identify the session, and provides no security.
</td>
</tr>
<tr>
<td>key</td>
<td>
To verify this request is from the originator of the session. The
client generates a new key in the manner described below for each
request, which the server then verifies before processing the
request.
</td>
</tr>
<tr>
<td>new_key</td>
<td>
The key algorithm can exhaust valid keys in a sequence, which
requires a new key sequence to be used in order to continue the
session. The new key is sent along with the last used key in the
old sequence.
</td>
</tr>
<tr>
<td>xml_body</td>
<td>
The body of text to send. Since a POST must be sent in order for
the server to respond with recent messages, a client may send
a request without an xml_body in order to just retrieve new
incoming packets. This is not required to be a full XML document or
XML fragment, it does not need to start or end on element boundaries.
</td>
</tr>
</table>
<p>
The identifier is everything before the first semicolon, and must consist
of the characters [A-Za-z0-9:-]. The identifier returned from the first
request is the identifier for the session. Any new identifier that ends
in ':0' indicates an error, with the entire identifier indicating the
specific error condition. Any new identifier that does not end in ':0' is
a server programming error, the client should discontinue the
session. For new sessions, the client identifier is considered to be 0.
</p>
<section2 topic="Error conditions">
<p>
Any identifier that ends in ':0' indicates an error. Any previous
identifier associated with this session is no longer valid.
</p>
<section3 topic="Unknown Error">
<p>
Server returns ID=0:0. The response body can contain a textual error
message.
</p>
</section3>
<section3 topic="Server Error">
<p>Server returns ID=-1:0</p>
</section3>
<section3 topic="Bad Request">
<p>Server returns ID=-2:0</p>
</section3>
<section3 topic="Key Sequence Error">
<p>Server returns ID=-3:0</p>
</section3>
</section2>
<p>
The key is a client security feature to allow TCP/IP socket equivalent
security. It does not protect against intermediary attacks, but does
prevent a person who is capable of listening to the HTTP traffic from
sending messages and receiving incoming traffic from another machine.
</p>
<p>The key algorithm should be familiar with those with knowledge of Jabber zero-knowledge authentication.</p>
<example caption="Key Algorithm">
K(n, seed) = Base64Encode(SHA1(K(n - 1, seed))), for n &gt; 0
K(0, seed) = seed, which is client-determined
</example>
<p>Note: Base64 encoding is defined in &rfc3548;. SHA1 is defined in &rfc3174;.</p>
<p>
No framing is implied by a single request or reply. A single request can
have no content sent, in which case the body contains only the identifier
followed by a comma. A reply may have no content to send, in which case
the body is empty. Zero or more XMPP packets may be sent in a single
request or reply, including partial XMPP packets.
</p>
<p>
The absense of a long-lived connection requires the server to consider
client traffic as a heartbeat to keep the session alive. If a
server-configurable period of time passes without a successful POST
request sent by the client, the server must end the client session. Any
client requests using the identifier associated with that now dead
session must return an error of '0:0'.
</p>
<p>
The maximum period of time to keep a client session active without an
incoming POST request is not defined, but five minutes is the recommended
minimum. The maximum period of time recommended for clients between
requests is two minutes; if the client has not sent any XML out for two
minutes, a request without an XML body should be sent. If a client is
disconnecting from the server, a closing &lt;stream:stream&gt; must be
sent to end the session. Failure to do this may have the client continue
to be represented to other users as available.
</p>
<p>
If the server disconnects the user do to a session timeout, the server
MUST bounce pending IQ requests and either bounce or store offline
incoming messages.
</p>
</section1>
<section1 topic="Usage">
<p>The following is the sequence used for client communication:</p>
<ol>
<li>
The client generates some initial K(0, seed) and runs the algorithm
above 'n' times to determine the initial key sent to the server,
K(n, seed)
</li>
<li>
The client sends the request to the server to start the stream,
including an identifier with a value of zero and K(n, seed)
</li>
<li>
The server responds with the session identifier in the headers
(within the Set-Cookie field).
</li>
<li>
For each further request done by the client, the identifier from the
server and K(n - 1, seed) are sent along.
</li>
<li>
The server verifies the incoming value by generating
K(1, incoming_value), and verifying that value against the value sent
along with the last client request. If the values do not match, the
request should be ignored or logged, with an error code being
returned of -3:0. The request must not be processed, and must not
extend the session keepalive.
</li>
<li>
The client may send a new key K(m, seed') at any point, but should
do this for n &gt; 0 and must do this for n = 0. If K(0, seed) is
sent without a new key, the client will not be able to continue the
session.
</li>
</ol>
<example caption="Initial request (without keys)">
<![CDATA[POST /wc12/webclient HTTP/1.1
Content-Type: application/x-www-form-urlencoded
Host: webim.jabber.com
0,<stream:stream to="jabber.com"
xmlns="jabber:client"
xmlns:stream="http://etherx.jabber.org/streams">]]>
</example>
<example caption="Initial response">
<![CDATA[Date: Fri, 15 Mar 2002 20:30:30 GMT
Server: Apache/1.3.20
Set-Cookie: ID=7776:2054; path=/webclient/; expires=-1
Content-Type: text/xml
<?xml version='1.0'?>
<stream:stream xmlns:stream='http://etherx.jabber.org/streams'
id='3C9258BB'
xmlns='jabber:client' from='jabber.com'>]]>
</example>
<example caption="Next request (without keys)">
<![CDATA[POST /wc12/webclient HTTP/1.1
Content-Type: application/x-www-form-urlencoded
Host: webim.jabber.com
7776:2054,<iq type="get" id="WEBCLIENT3">
<query xmlns="jabber:iq:auth">
<username>hildjj</username>
</query>
</iq>]]>
</example>
<example caption='key sequence'>
K(0, "foo") = "foo"
K(1, "foo") = "C+7Hteo/D9vJXQ3UfzxbwnXaijM="
K(2, "foo") = "6UU8CDmH3O4aHFmCqSORCn721+M="
K(3, "foo") = "vFFYSOhGyaGUgLrldtMBX7x91Wc="
K(4, "foo") = "ZaDxCilBVTHS9dJfbBo1NsC2b+8="
K(5, "foo") = "moPFsvHytDGiJQOjp186AMXAeP0="
K(6, "foo") = "VvxEk07IFy6hUmG/PPBlTLE2fiA="
</example>
<example caption="Initial request (with keys)">
<![CDATA[POST /wc12/webclient HTTP/1.1
Content-Type: application/x-www-form-urlencoded
Host: webim.jabber.com
0;VvxEk07IFy6hUmG/PPBlTLE2fiA=,<stream:stream to="jabber.com"
xmlns="jabber:client"
xmlns:stream="http://etherx.jabber.org/streams">]]>
</example>
<example caption="Next request (with keys)">
<![CDATA[POST /wc12/webclient HTTP/1.1
Content-Type: application/x-www-form-urlencoded
Host: webim.jabber.com
7776:2054;moPFsvHytDGiJQOjp186AMXAeP0=,<iq type="get" id="WEBCLIENT3">
<query xmlns="jabber:iq:auth">
<username>hildjj</username>
</query>
</iq>]]>
</example>
<example caption='Changing key'>
<![CDATA[POST /wc12/webclient HTTP/1.1
Content-Type: application/x-www-form-urlencoded
Host: webim.jabber.com
7776:2054;C+7Hteo/D9vJXQ3UfzxbwnXaijM=;Tr697Eff02+32FZp38Xaq2+3Bv4=,<presence/>]]>
</example>
</section1>
<section1 topic="Known issues">
<ul>
<li>This method works over HTTPS, which is good from the standpoint of functionality, but bad in the sense that a massive amount of hardware would be needed to support reasonable polling intervals for non-trivial numbers of clients.</li>
</ul>
</section1>
</xep>