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This document specifies "XTLS", a protocol for end-to-end encryption of Extensible Messaging and Presence Protocol (XMPP) traffic via an application-level usage of Transport Layer Security (TLS). XTLS treats the end-to-end exchange of XML stanzas as a virtual transport and uses TLS to secure that transport, thus enabling XMPP entities to communicate in a way that is designed to prevent eavesdropping, tampering, and forgery of XML stanzas. The protocol can be used for secure end-to-end messaging as well as any others application such as file transfer.
1.
Introduction
2.
Requirements
3.
Approach
4.
XTLS Protocol Flow
5.
End-to-End Streams over XTLS Protocol Flow
6.
Bootstrapping Trust on First Communication
6.1.
Exchanging Certificates
6.2.
Verification of Non-Human Parties
7.
Session Termination
8.
Determining Support
9.
Security Considerations
9.1.
Mandatory-to-Implement Technologies
9.2.
Certificates
9.3.
Denial of Service
10.
IANA Considerations
11.
References
11.1.
Normative References
11.2.
Informative References
Appendix A.
XML Schema
Appendix B.
Copying Conditions
§
Authors' Addresses
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End-to-end encryption of traffic sent over the Extensible Messaging and Presence Protocol (XMPP) is a desirable goal. Since 1999, the Jabber/XMPP developer community has experimented with several such technologies, including OpenPGP [XEP‑0027] (Muldowney, T., “Current Jabber OpenPGP Usage,” November 2006.), S/MIME ([RFC3923] (Saint-Andre, P., “End-to-End Signing and Object Encryption for the Extensible Messaging and Presence Protocol (XMPP),” October 2004.), and encrypted sessions or "ESessions" [XEP‑0218] (Saint-Andre, P. and I. Paterson, “Bootstrapping Implementation of Encrypted Sessions,” May 2007.). For various reasons, these technologies have not been widely implemented and deployed. When the XMPP Standards Foundation asked various Internet security experts to complete a security review of encrypted sessions, it was recommended to explore the possibility of instead using the Transport Layer Security [TLS] (Dierks, T. and E. Rescorla, “The Transport Layer Security (TLS) Protocol Version 1.2,” August 2008.) as the base technology for XMPP. That possibility is explored in this document.
TLS is the most widely implemented protocol for securing network traffic. In addition to applications in the email infrastructure, the World Wide Web [HTTP‑TLS] (Rescorla, E., “HTTP Over TLS,” May 2000.), and datagram transport for multimedia session negotiation [DTLS] (Rescorla, E. and N. Modadugu, “Datagram Transport Layer Security,” April 2006.), TLS is used in XMPP to secure TCP connections from client to server and from server to server, as specified in [rfc3920bis] (Saint-Andre, P., “Extensible Messaging and Presence Protocol (XMPP): Core,” October 2008.). Therefore TLS is already familiar to XMPP developers.
This specification, called "XTLS", defines a method whereby any XMPP entity that supports the XMPP Jingle negotiation framework [XEP‑0166] (Ludwig, S., Beda, J., Saint-Andre, P., McQueen, R., Egan, S., and J. Hildebrand, “Jingle,” December 2008.) can use TLS semantics for end-to-end encryption, whether the application data is sent over a streaming transport (like TCP) or a datagram transport (like UDP). The basic use case is to tunnel XMPP stanzas between two IM users for end-to-end secure chat using end-to-end XML streams. However, XTLS is not limited to encryption of one-to-one text chat, since it can be used between two XMPP clients for encryption of any XMPP payloads, between an XMPP client and a remote XMPP service (i.e., a service with which a client does not have a direct XML stream, such as a [XEP‑0045] (Saint-Andre, P., “Multi-User Chat,” July 2008.) chatroom), or between two remote XMPP services. Furthermore, XTLS can be used for encrypted file transfer using [XEP‑0234] (Saint-Andre, P., “Jingle File Transfer,” February 2009.), for encrypted voice or video sessions using [XEP‑0167] (Ludwig, S., Saint-Andre, P., Egan, S., McQueen, R., and D. Cionoiu, “Jingle RTP Sessions,” December 2008.) and [DTLS‑SRTP] (McGrew, D. and E. Rescorla, “Datagram Transport Layer Security (DTLS) Extension to Establish Keys for Secure Real-time Transport Protocol (SRTP),” October 2008.), and other applications.
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This specification is intended to meet the requirements defined in [XEP‑0210] (Paterson, I., “Requirements for Encrypted Sessions,” May 2007.) using building blocks that are already widely supported in XMPP clients, such as TLS, XML streams, Jingle, and in-band bytestreams [XEP‑0047] (Karneges, J., “In-Band Bytestreams (IBB),” November 2006.). It is possible that some of those requirements can be met only with particular TLS cipher suites, or cannot be met at all without defining extensions to TLS itself. A full gap analysis has not yet been completed.
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In broad outline, XTLS takes the following approach to end-to-end encryption of XMPP traffic:
We expand on this approach in the following section.
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The basic flow for an XTLS session is as follows, where traffic represented by single dashes (---) is sent over the XMPP signalling channel and traffic represented by double lines (===) is sent over the negotiated transport.
Initiator Responder | | | session-initiate | | (with security info) | |--------------------------->| | ack | |<---------------------------| | session-accept | |<---------------------------| | ack | |--------------------------->| | open transport | |<==========================>| | TLS ClientHello | |===========================>| | TLS ServerHello, [...] | |<===========================| | TLS [...], Finished | |===========================>| | TLS [...], Finished | |<===========================| | application data | |<==========================>| | session-terminate | |<---------------------------| | ack | |--------------------------->| | |
To simplify the description we assume here that the parties already trust each other's certificates. See discussion under Section 6 (Bootstrapping Trust on First Communication) for information about bootstrapping of certificate trust on the first communication.
First the initiator sends a Jingle session-initiate request (here the simple case of an end-to-end text chat session using in-band bytestreams [XEP‑0047] (Karneges, J., “In-Band Bytestreams (IBB),” November 2006.). This request includes a <security/> element that contains the fingerprint of the certificate that the initiator will use during the TLS negotiation.
<iq from='romeo@montague.lit/orchard' id='xn28s7gk' to='juliet@capulet.lit/balcony' type='set'> <jingle xmlns='urn:xmpp:jingle:0'> action='session-initiate' initiator='romeo@montague.lit/orchard' sid='a73sjjvkla37jfea'> <content creator='initiator' name='xmlstream'> <description xmlns='urn:xmpp:jingle:apps:xmlstream:0'/> <transport xmlns='urn:xmpp:jingle:transports:ibb:0' block-size='4096' sid='ch3d9s71'/> <security xmlns='urn:xmpp:jingle:security:xtls:0'> <fingerprint>RomeoX509CertificateHash</fingerprint> <method name='x509'/> <method name='srp'/> </security> </content> </jingle> </iq>
The responder immediately acknowledges receipt of the session-initiate by sending an IQ stanza of type "result" (not shown here).
Depending on the application type, a user agent controlled by a human user might need to wait for the user to affirm a desire to proceed with the session before continuing. When the user agent has received such affirmation (or if the user agent can automatically proceed for any reason, e.g. because no human intervention is expected or because a human user has configured the user agent to automatically accept sessions with a given entity), it returns a Jingle session-accept message. This message will typically contain the offered application type, transport method, and a <security/> element that includes the fingerprint of the responder's X.509 certificate as well as the responder's supported TLS methods.
<iq from='juliet@capulet.com/balcony' id='hf64hl' to='romeo@montague.net/orchard' type='set'> <jingle xmlns='urn:xmpp:jingle:0'> action='session-accept' initiator='romeo@montague.lit/orchard' sid='a73sjjvkla37jfea'> <content creator='initiator' name='xmlstream'> <description xmlns='urn:xmpp:jingle:apps:xmlstream:0'/> <transport xmlns='urn:xmpp:jingle:transports:ibb:0' block-size='4096' sid='ch3d9s71'/> <security xmlns='urn:xmpp:jingle:security:xtls:0'/> <fingerprint>JulietX509CertificateHash</fingerprint> <method name='x509'/> <method name='srp'/> </security> </content> </jingle> </iq>
The following rules apply to the responder's handling of the session-initiate message:
When the responder sends the session-accept message, the initiator acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
The following rules apply to the initiator's handling of the session-accept message:
The initiator can now determine if X.509 certificate based authentication will work or if TLS-SRP will be used. It sends an additional security-info message to the responder to signal its choice. This step is not really necessary because the responder will see the initiator's choice in the first message of the TLS handshake, but it can help an implementation to set up its TLS library properly. Because in this section we assume that the parties already have validated each other's certificates, the security method signalled here is "x509".
<iq from='romeo@montague.lit/orchard' id='hf749j' to='juliet@capulet.lit/balcony' type='set'> <jingle xmlns='urn:xmpp:jingle:0'> action='security-info' initiator='romeo@montague.lit/orchard' sid='a73sjjvkla37jfea'> <content creator='initiator' name='xmlstream'> <security xmlns='urn:xmpp:jingle:security:xtls:0'> <method name='x509'/> </security> </content> </jingle> </iq>
The responder acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
Parallel to the security-info exchange, the clients negotiate a transport for the Jingle session (here the transport is an in-band bytestream as defined in [XEP‑0047] (Karneges, J., “In-Band Bytestreams (IBB),” November 2006.), for which the Jingle negotiation process is specified in [XEP‑0261] (Saint-Andre, P., “Jingle In-Band Bytestreams Transport,” February 2009.); however other transports could be used, for example SOCKS5 bytestreams as defined in [XEP‑0065] (Smith, D., Miller, M., and P. Saint-Andre, “SOCKS5 Bytestreams,” May 2007.) and negotiated for Jingle as specified in [XEP‑0260] (Saint-Andre, P. and D. Meyer, “Jingle SOCKS5 Bytestreams Transport Method,” February 2009.)). Because the parties wish to establish end-to-end encryption, they do not send application data over the transport until the transport has been secured. Therefore the first data that they exchange over the transport consists of the standard four-way TLS handshake, encoded in accordance with the negotiated transport method.
Note: Each transport MUST define a specific time when both cients know that the transport is secured. When XTLS is not used, the Jingle implementation would signal to the using application that the transport is open when the session-accept is sent or received, or when connectivity checks determine media can flow over one of the transport candidates. When XTLS is used, the Jingle implementation starts a TLS handshake on the transport and signals to the using application that the transport is open only after the TLS handshake has finished successfully.
During the TLS handshake, the responder MUST take the role of the TLS server and the initiator MUST take the role of the TLS client. Because the transport is an in-band bytestream, the TLS handshake data is prepared as described in [XEP‑0047] (Karneges, J., “In-Band Bytestreams (IBB),” November 2006.) (i.e., Base64-encoded). First the initiator (acting as the TLS client) constructs a TLS ClientHello, encodes it according to IBB, and sends it to the responder.
<iq from='romeo@montague.net/orchard' id='vh38s618' to='juliet@capulet.com/balcony' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='0' sid='vj3hs98y'> Base64-encoded-TLS-data </data> </iq>
The responder (acting as the TLS server) then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
The responder then constructs an appropriate TLS message or messages, such as a ServerHello and a CertificateRequest.
Note: The responder MUST send a CertificateRequest to the initiator.
<iq from='juliet@capulet.com/balcony' id='xyw516d0' from='romeo@montague.net/orchard' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='0' sid='vj3hs98y'> Base64-encoded-TLS-data </data> </iq>
(Because in-band bytestreams are bidirectional and this data is sent from the responder to the initiator, the IBB 'seq' attribute has a value of zero, not 1.)
The initiator then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
After some number of TLS messages, the initiator eventually sends a TLS Finished message to the responder.
<iq from='romeo@montague.net/orchard' id='s91vd527' to='juliet@capulet.com/balcony' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='3' sid='vj3hs98y'> Base64-encoded-TLS-data </data> </iq>
The responder then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
The responder then also sends a TLS Finished message.
<iq from='juliet@capulet.com/balcony' id='z71gs73t' from='romeo@montague.net/orchard' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='3' sid='vj3hs98y'> Base64-encoded-TLS-data </data> </iq>
The initiator then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
If the TLS negotiation has finished successfully, then the Jingle implementation shall signal to the using application that the transport has been secured and is ready to be used. The parties can then begin to exchange application data over the encrypted transport.
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For end-to-end encryption of XMPP traffic, the application data is an end-to-end XML stream. After the XTLS session is set up, the peers open an XML stream to excahnge messages. The XML streams are sent though the XTLS connection. In this example the streams are sent over TLS over IBB.
First the initiator constructs an initial stream header.
<stream:stream xmlns='jabber:client' xmlns:stream='http://etherx.jabber.org/streams' from='romeo@montague.lit/orchard' to='juliet@capulet.lit/balcony' version='1.0'>
Note: In accordance with [rfc3920bis] (Saint-Andre, P., “Extensible Messaging and Presence Protocol (XMPP): Core,” October 2008.), the initial stream header SHOULD include the 'to' and 'from' attributes, which SHOULD specify the full JIDs of the clients. The initiator SHOULD include the version='1.0' flag as shown in the previous example.
The initiator then sends the stream header through the TLS stream and encodes the TLS data in IBB and sends it to the responder.
<iq from='romeo@montague.net/orchard' id='ur73n153' to='juliet@capulet.com/balcony' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='4' sid='vj3hs98y'> Base64-TLS-data-of-the-stream-header </data> </iq>
The responder then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
The responder then constructs a response stream header back to the initiator.
<stream:stream xmlns='jabber:client' xmlns:stream='http://etherx.jabber.org/streams' from='juliet@capulet.lit/balcony' id='hs91gh1836d8s717' to='romeo@montague.lit/orchard' version='1.0'>
The responder then sends the response stream header over the TLS link it to the initiator.
<iq from='juliet@capulet.com/balcony' id='pd61g397' to='romeo@montague.net/orchard' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='4' sid='vj3hs98y'> Base64-TLS-data-of-the-responce-stream-header </data> </iq>
The initiator then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
Once the streams are established over the bytestreams, either entity then can send XMPP message, presence, and IQ stanzas, with or without 'to' and 'from' addresses.
For example, the initiator could construct an XMPP message.
<message from='romeo@montague.lit/orchard' to='juliet@capulet.lit/balcony'> <body> M'lady, I would be pleased to make your acquaintance. </body> </message>
The initiator then sends the message over the XTLS connection to the responder.
<iq from='romeo@montague.net/orchard' id='iq7dh294' to='juliet@capulet.com/balcony' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='5' sid='vj3hs98y'> Base64-TLS-data </data> </iq>
The responder then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
The responder could then construct a reply.
<message from='juliet@capulet.lit/balcony' to='romeo@montague.lit/orchard'> <body>Art thou not Romeo, and a Montague?</body> </message>
The responder then sends the reply over the XTLS connection to the initiator.
<iq from='juliet@capulet.com/balcony' id='hr91hd63' to='romeo@montague.net/orchard' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='5' sid='vj3hs98y'> Base64-TLS-data </data> </iq>
The initiator then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
To close the end-to-end XML stream, either party (here the responder) constructs a closing </stream:stream> element.
</stream:stream>
The client sends the closing element to the peer over the XTLS connection.
<iq from='juliet@capulet.com/balcony' id='kr91n475' to='romeo@montague.net/orchard' type='set'> <data xmlns='http://jabber.org/protocol/ibb' seq='6' sid='vj3hs98y'> Base64-TLS-data </data> </iq>
The peer then acknowledges receipt by sending an IQ stanza of type "result" (not shown here).
However, even after the application-level XML stream is terminated, the negotiated Jingle transport (here in-band bytestream) continues and could be re-used. To completely terminate the Jingle session, the terminating party would then also send a Jingle session-terminate message.
<iq from='juliet@capulet.lit/balcony' id='psy617r4' to='romeo@montague.lit/orchard' type='set'> <jingle xmlns='urn:xmpp:jingle:0' action='session-terminate' initiator='romeo@montague.lit/orchard' sid='851ba2'/> </iq>
The other party then acknowledges the Jingle session-terminate by sending an IQ stanza of type "result" (not shown here).
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When two parties first attempt to use XTLS, their certificates might not be accepted (e.g., because they are self-signed or issued by unknown certification authorities). Therefore each party needs to accept the other's certificate for use in future communication sessions. There are several ways to do so:
If the parties use a password or channel binding via SASL, the process needs to be completed only once. After the clients have authenticated with the shared secret, they can exchange their certificates for future communication.
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To retrieve the certificate of the peer for future communications, a client SHOULD request the certificate according to [XEP‑0189] (Paterson, I., Saint-Andre, P., and D. Meyer, “Public Key Publishing,” September 2008.) over the secure connection. This works only if XTLS was used to set up an end-to-end secure XML stream; exchanging certificates if XTLS was used for other purposes like file transfer is not possible. A client MUST NOT request the certificate over the insecure stream based on the connection to the XMPP server.
<iq from='romeo@montague.lit/orchard' id='hf7634k4' to='juliet@capulet.lit/balcony' type='get'> <pubkeys xmlns='urn:xmpp:tmp:pubkey'/> </iq>
The peer MUST return its own client certificate. If the user has different clients with different client certificates and one user certificate, the user certificate SHOULD also be returned. The user certificate allows it to verify other client certificates using public key retrieval described in [XEP‑0189] (Paterson, I., Saint-Andre, P., and D. Meyer, “Public Key Publishing,” September 2008.).
<iq from='juliet@capulet.com/balcony' id='hf7634k4' to='romeo@montague.lit/orchard' type='result'> <pubkeys xmlns='urn:xmpp:tmp:pubkey'> <keyinfo> <name>JulietX509CertificateHash</name> <x509cert> MIICCTCCAXKgAwIBAgIJALhU0Id6xxwQMA0GCSqGSIb3DQEBBQUAMA4xDDAKBgNV BAMTA2ZvbzAeFw0wNzEyMjgyMDA1MTRaFw0wODEyMjcyMDA1MTRaMA4xDDAKBgNV BAMTA2ZvbzCBnzANBgkqhkiG9w0BAQEFAAOBjQAwgYkCgYEA0DPcfeJzKWLGE22p RMINLKr+CxqozF14DqkXkLUwGzTqYRi49yK6aebZ9ssFspTTjqa2uNpw1U32748t qU6bpACWHbcC+eZ/hm5KymXBhL3Vjfb/dW0xrtxjI9JRFgrgWAyxndlNZUpN2s3D hKDfVgpPSx/Zp8d/ubbARxqZZZkCAwEAAaNvMG0wHQYDVR0OBBYEFJWwFqmSRGcx YXmQfdF+XBWkeML4MD4GA1UdIwQ3MDWAFJWwFqmSRGcxYXmQfdF+XBWkeML4oRKk EDAOMQwwCgYDVQQDEwNmb2+CCQC4VNCHesccEDAMBgNVHRMEBTADAQH/MA0GCSqG SIb3DQEBBQUAA4GBAIhlUeGZ0d0msNVxYWAXg2lRsJt9INHJQTCJMmoUeTtaRjyp ffJtuopguNNBDn+MjrEp2/+zLNMahDYLXaTVmBf6zvY0hzB9Ih0kNTh23Fb5j+yK QChPXQUo0EGCaODWhfhKRNdseUozfNWOz9iTgMGw8eYNLllQRL//iAOfOr/8 </x509cert> </keyinfo> </pubkeys> </iq>
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If one of the parties is a "bot" (e.g., an automated service or a device such as a set-top box), the password exchange is a bit more complicated. It is similar to Bluetooth peering if the user has access to both clients at the same time. One of the following scenarios might apply:
A user might have different X.509 certificates for each device. [XEP‑0189] (Paterson, I., Saint-Andre, P., and D. Meyer, “Public Key Publishing,” September 2008.) can be used to manage the user's certificates. A client SHOULD check the peer's PubSub node for certificates. This makes it possible to use the password method only once between two users even if one or both users switch clients. A user can also communicate with a friend's bots: they first open a secure link between two chat clients with a password and exchange the user certificates. After that each device of a user can verify all devices of the other without the need of a password.
The retrieved certificate from the PubSub node may be signed by a CA the client can verify. In that case the client MAY skip the password authentication and rely on the X.509 certificate chain. The client SHOULD ask the user if the certificate should be accepted or if a password exchange is desired.
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If either client cannot verify the certificate of the peer or receives an invalid message on the TLS layer, it MUST terminate the Jingle session immediately by sending a Jingle session-terminate message that includes a Jingle reason of <security-error/>.
<iq from='romeo@montague.lit/orchard' id='hz81vf48' to='juliet@capulet.lit/balcony' type='set'> <jingle xmlns='urn:xmpp:jingle:0' action='session-terminate' initiator='romeo@montague.lit/orchard' sid='a73sjjvkla37jfea'> <reason><security-error/></reason> </jingle> </iq>
The other party then acknowledges the session-terminate by sending an IQ stanza of type "result" (not shown here), and the Jingle session is finished.
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If an entity wishes to request the use of XTLS, it SHOULD first determine whether the intended responder supports the protocol. This can be done directly via [XEP‑0030] (Hildebrand, J., Millard, P., Eatmon, R., and P. Saint-Andre, “Service Discovery,” June 2008.) or indirectly via [XEP‑0115] (Hildebrand, J., Saint-Andre, P., Tronçon, R., and J. Konieczny, “Entity Capabilities,” February 2008.).
If an entity supports XTLS, it MUST report that by including a service discovery feature of "urn:xmpp:jingle:security:xtls:0" in response to disco#info requests.
<iq from='romeo@montague.lit/orchard' id='disco1' to='juliet@capulet.lit/chamber' type='get'> <query xmlns='http://jabber.org/protocol/disco#info'/> </iq>
<iq from='juliet@capulet.lit/chamber' id='disco1' to='romeo@montague.lit/orchard' type='result'> <query xmlns='http://jabber.org/protocol/disco#info'> <feature var='urn:xmpp:jingle:security:xtls:0'/> <feature var='urn:xmpp:jingle:apps:xmlstream:0'/> </query> </iq>
Both service discovery and entity capabilities information could be corrupted or intercepted; for details, see under Section 9.3 (Denial of Service).
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This entire document addresses security. Particular security-related issues are discussed in the following sections.
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An implementation MUST at a minimum support the "srp" and "x509" methods. A future version of this specification will document mandatory-to-implement TLS ciphers.
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As noted, XTLS can be used between XMPP clients, between an XMPP client and a remote XMPP service (i.e., a service with which a client does not have a direct XML stream), or between remote XMPP services. Therefore, a party to an XTLS bytestream will present either a client certificate or a server certificate as appropriate. Such certificates MUST be generated and validated in accordance with the certificate guidelines guidelines provided in [rfc3920bis] (Saint-Andre, P., “Extensible Messaging and Presence Protocol (XMPP): Core,” October 2008.).
A future version of this specification might provide additional guidelines regarding certificate validation in the context of client-to-client encryption.
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Currently XMPP stanzas such as Jingle negotiation messages and service discovery exchanges are not encrypted or signed. As a result, it is possible for an attacker to intercept these stanzas and modify them, thus convincing one party that the other party does not support XTLS and therefore denying the parties an opportunity to use XTLS.
This is a more general problem with XMPP technologies and needs to be addressed at the core XMPP layer.
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It might be helpful to create a registry of TLS methods that can be used in the context of XTLS (e.g., "openpgp" for use of [RFC5081] (Mavrogiannopoulos, N., “Using OpenPGP Keys for Transport Layer Security (TLS) Authentication,” November 2007.), "srp" for use of [SRP] (Taylor, D., Wu, T., Mavrogiannopoulos, N., and T. Perrin, “Using the Secure Remote Password (SRP) Protocol for TLS Authentication,” November 2007.), and "x509" for use of [TLS] (Dierks, T. and E. Rescorla, “The Transport Layer Security (TLS) Protocol Version 1.2,” August 2008.) with certificates). The registry could be maintained by the IANA or by the XMPP Registrar. A future version of this specification will provide more detailed information about the registration requirements.
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[rfc3920bis] | Saint-Andre, P., “Extensible Messaging and Presence Protocol (XMPP): Core,” draft-saintandre-rfc3920bis-08 (work in progress), October 2008 (TXT). |
[TLS] | Dierks, T. and E. Rescorla, “The Transport Layer Security (TLS) Protocol Version 1.2,” RFC 5246, August 2008 (TXT). |
[XEP-0047] | Karneges, J., “In-Band Bytestreams (IBB),” XSF XEP 0047, November 2006. |
[XEP-0166] | Ludwig, S., Beda, J., Saint-Andre, P., McQueen, R., Egan, S., and J. Hildebrand, “Jingle,” XSF XEP 0166, December 2008. |
[XEP-0210] | Paterson, I., “Requirements for Encrypted Sessions,” XSF XEP 0210, May 2007. |
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The XML schema will be provided in a later version of this document.
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Regarding this entire document or any portion of it, the authors make no guarantees and are not responsible for any damage resulting from its use. The authors grant irrevocable permission to anyone to use, modify, and distribute it in any way that does not diminish the rights of anyone else to use, modify, and distribute it, provided that redistributed derivative works do not contain misleading author or version information. Derivative works need not be licensed under similar terms.
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Dirk Meyer | |
Universitaet Bremen TZI | |
Email: | dmeyer@tzi.de |
Peter Saint-Andre | |
Cisco | |
Email: | psaintan@cisco.com |