Network Working Group P. Hoffman
Internet-Draft VPN Consortium
Intended status: Standards Track December 26, 2010
Expires: June 29, 2011
Specifying That a Server Supports TLS
draft-hoffman-server-has-tls-02
Abstract
A server that hosts applications that can be run with or without TLS
may want to communicate with clients whether the server is hosting an
application only using TLS or also hosting the application without
TLS. Many clients have a policy to try to set up a TLS session but
fall back to insecure if the TLS session cannot be set up. If the
server can securely communicate whether or not it can fall back to
insecure tells such a client whether or not they should even try to
set up an insecure session with the server. This document describes
the use cases for this type of communication and a secure method for
communicating that information.
Status of this Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
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This Internet-Draft will expire on June 29, 2011.
Copyright Notice
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document authors. All rights reserved.
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publication of this document. Please review these documents
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carefully, as they describe your rights and restrictions with respect
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described in the Simplified BSD License.
1. Introduction
Most client-server application standardized in the IETF has two
modes: an insecure mode that involves no authentication or integrity
protection, and a secure mode that requires (at a minimum) that the
client authenticate the server and set up a communication channel
with integrity protection. In most cases, the secure mode is
achieved by starting a TLS session and, when successful, running the
insecure mode inside of it.
People within the IETF and application developers have historically
had widely varying views on what a client should and should not do
about the two modes. Phrases like "assured security" and "client
flexibility" are used, often without clear definition. Deployed
clients and servers from different vendors act differently for the
two modes, often relegating the control of the two modes to
"advanced" configuration options (if such control is given at all).
Section 2 of this document lays out the choices for clients and
servers for handling the two modes in different circumstances, and
gives specific semantics for each type of client and server. Section
3 gives a protocol for a domain owner to specify whether they offer
one or both modes for any given application, and to specify a client
policy preference. Section 4 defines how to implement various
policies using the protocol. Using the protocol given here, a server
can completely specify what it offers and allows a client to reliably
choose which mode it wants to use.
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119 [RFC2119].
2. Security Options for Clients and Servers
This section describes the different types of clients and servers
that deal with insecure protocols that can be secured by wrapping the
protocol in TLS. It also describes the types of security policies
that those clients and servers can embody. It explicitly does not
argue that one policy is better than another in any particular
environment; instead, it assumes that the server operator and the
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client implementor (and, hopefully, the human operating the client)
can make that decision themselves if given the proper tools.
This discussion assumes a client-server protocol that is defined for
an insecure fashion, and is also defined for a secure fashion that
uses a TLS session for security. For example, "HTTP run over port
80" and "HTTP-in-TLS run over port 443" would meet this definition;
"SMTP without STARTTLS" and "SMTP with STARTTLS" (see [RFC3207])
would also meet this definition. Some peer-to-peer protocols might
meet this definition if the startup actions resemble the typical
client-server interaction, but this discussion makes no extra attempt
to cover such protocols.
Given a particular client application configuration, there are three
interesting types of clients:
Insecure Only (CIO) -- The client is configured to only attempt
communication for the application in its insecure form. For
example, a POP client might be configured to only try insecure POP
on port 110.
Secure Only (CSO) -- The client is configured to only attempt
communication for the application in its secure, TLS-wrapped form.
For example, a POP client might be configured to only try secure
POP on port 995.
Allows Fallback From Secure to Insecure (CFB) -- The client is
configured to attempt communication for the application in its
secure, TLS-wrapped form, but if it fails to set up a TLS session,
the client will attempt to attempt communication to the same
server using the insecure form.
Given a particular server configuration, there are three interesting
types of servers:
Insecure Only (SIO) -- The server responds without TLS on the main
port for the application. For example, a host for a web server
only responds to HTTP requests on port 80.
Secure Only (SSO) -- The server responds using TLS on the TLS-
specific port for the application. For example, a host for a web
server only responds to HTTP requests on port 443. Alternately,
if the application supports in-band security update (such as
STARTTTLS for SMTP), the server responds on the normal port, tries
to establish a TLS session, and does not proceed with the protocol
if a TLS session cannot be established.
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Serves Both Secure and Insecure (SSB) -- The server responds
without TLS on the main port for the application *and* responds
using TLS on the TLS-specific port for the application, such as
both ports 80 and 443 for HTTP. Alternately, if the application
supports in-band security update (such as STARTTTLS for SMTP), the
server responds on the normal port, tries to establish a TLS
session, and proceeds with the normal protocol if a TLS session
cannot be established.
It is expected that client configuration will be per-host. That is,
a client that is CSO for some hosts might be CFB for other hosts.
The server configuration, of course, applies to all clients accessing
it.
In this taxonomy, a CIO can always communicate with an SIO and SSB.
A CSO can communicate with an SSO, and can communicate with an SSB as
long as the TLS session is set up successfully. A CFB can
communicate with an SIO, an SSO, and an SSB.
Given this, a host that only allows clients to use the secure form of
a protocol MUST only be configured to be SSO; a client that wants to
only communicate with a server securely MUST only be configured to be
CSO.
Note that a host might want to serve both insecure and secure form of
a protocol, but wants clients to only use the secure form. For
example, the insecure form might immediately do an upgrade to the
secure form, or it might do a protocol-based redirection to a server
doing the secure form. Such a host will want to be able to indicate
that, even if it has both secure and insecure ports for a protocol
open, it wants clients that can be configured as CFB or CSO to only
be configured as CSO.
This taxonomy exposes a problem with the way that clients and servers
interact today: a CIO that starts an insecure communication with a
server, or a CFB that falls back to insecure communication with a
server, has no idea whether the site they wish to communication with
even hosts an insecure server. The server might be configured to be
SIO or SSO or SSB, but the client cannot tell. If a CIO or CFB
client knows ahead of time that a host did not support insecure
communication, the client would not even start communication because
it would either just waste time waiting for a timeout, or it would
communicate with an impostor.
3. The HASTLS Resource Record
The HASTLS resource record type, whose value is TBD1, lists all of
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the pairs of insecure/secure port pairs that are served on the host
named by the domain name. It only applies to applications that are
secured with TLS, not to applications that have insecure and secure
versions that use some other security protocol. It applies to TLS
used over any transport (which will usually be TCP, but can also be
SCTP and others), and also applies to DTLS.
Data in the HASTLS record MUST be received securely by a DNS
requester, such as through validated DNSSEC.
The presentation form is:
IN HASTLS (porttriple[1] ...)
where "porttriple" consists of exactly five octets: two octets for
the insecure port number (called "insecure-port"), two for the secure
port number (called "secure-port"), and one fo the client policy
preference. At least one porttriple needs to be present, but many
can be listed; not including an porttriples is explicitly undefined.
If a server does not offer one of the the two services, that service
is indicated by port 0. For protocols that use in-band signaling for
security upgrades, "insecure-port" and "secure-port" have the same
value. Setting both the "insecure-port" and "secure-port" to 0 in a
porttriple is explicitly undefined.
The client policy preference octet specifies the host's preference
for client policy. It has two possible values:
0 -- The host's administrator has no client policy preference.
1 -- If the client could be configured as either CFB or CSO, and
the host's administrator was able to configure the client, that
administrator would configure the client as CSO. Stated another
way, the host's administrator does not want any CFB client to
access the host.
Note that specifying 1 for the client policy preference when a host
does not support a protocol securely makes no sense, but it also does
no harm. Further, for a host that is CSO, both policy preferences
have an identical result.
For example, a server that offers SMTP both securely and insecurely,
and offers HTTP only securely. For SMTP, the host's administrator
has a client policy preference that CFB clients not access the host.
The resulting HASTLS record could be either:
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www.example.com IN HASTLS (25 25 1 0 443 0)
or
www.example.com IN HASTLS (25 25 1 0 443 1)
[[ NEED TO ADD: show example with hex values instead of decimal
values. ]]
4. Implementing Policy with HASTLS
Servers that have a policy to declare the server as SIO, SSO, or SSB
can use HASTLS to announce that policy for each application it
serves. A server whose policy is that it is an SIO would set the
insecure-port to a non-zero number and the secure-port to 0. A
server whose policy is that it is an SSO would set the insecure-port
to 0 and the secure-port to a non-zero number. A server whose policy
is that it is an SSB would set both the insecure-port and secure-port
to a non-zero number.
The conformance requirements for a client using the HASTLS record
depend on the policy configured for the client or the server:
o A client communicating with a server that has set its client
policy preference to 1 MUST NOT try to communicate insecurely with
that server, even if the server has set the insecure-port to a
non-zero number; this is the equivalent of temporarily setting its
policy for the server to CSO. This temporary policy based on the
server's client policy preference overrides any others for the
server.
o A client whose policy is that it is a CIO MUST NOT try to
communicate insecurely with a server that has the insecure-port
set to 0.
o A client whose policy is that it is a CSO MUST only try to
communicate securely with a server that has the secure-port set to
a non-zero number; it MUST NOT try to communicate with the server
on the insecure-port value given.
o A client whose policy is that it is a CFB MUST NOT try to
communicate securely with a server that has the secure-port set to
0.
o A client whose policy is that it is a CFB MUST NOT try to
communicate insecurely with a server that has the insecure-port
set to 0.
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o A client whose policy is that it is a CFB trying to communicate
with a server whose secure-port is set to a non-zero number SHOULD
first try to communicate securely over the secure port unless it
knows from other sources that the TLS session will not be set up
properly.
5. IANA Considerations
This document requests that IANA allocate a new DNS resource record
type called HASTLS from the data types range; it will have the value
TBD1.
Submission template:
A. Submission Date: Date of this document
B. Submission Type: New RRTYPE
C. Contact Information for submitter: Author of this document
D. Motivation for the new RRTYPE application: Contents of
this document
E. Description of the proposed RR type: Contents of this document
F. What existing RRTYPE or RRTYPEs come closest to filling that
need and why are they unsatisfactory: None are even close to
that given in this document.
G. What mnemonic is requested for the new RRTYPE (optional):
HASTLS
H. Does the requested RRTYPE make use of any existing IANA
Registry or require the creation of a new IANA sub-registry in
DNS Parameters: No
I. Does the proposal require/expect any changes in DNS
servers/resolvers that prevent the new type from being
processed as an unknown RRTYPE (see [RFC3597]): No
J. Comments: None
6. Security Considerations
If the HASTLS information is received by the client system without
security, an attacker could change the HASTLS information to fool the
client into thinking that a host provides insecure application
services and/or does not provide secure application services. Thus,
cryptographic protection of the contents of the HASTLS information
(such as with DNSSEC) is mandatory.
7. References
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7.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
7.2. Informative References
[RFC3207] Hoffman, P., "SMTP Service Extension for Secure SMTP over
Transport Layer Security", RFC 3207, February 2002.
Author's Address
Paul Hoffman
VPN Consortium
Email: paul.hoffman@vpnc.org
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