rfc6876
Internet Engineering Task Force (IETF) P. Sangster
Request for Comments: 6876 Symantec Corporation
Category: Standards Track N. Cam-Winget
ISSN: 2070-1721 J. Salowey
Cisco Systems
February 2013
A Posture Transport Protocol over TLS (PT-TLS)
Abstract
This document specifies PT-TLS, a TLS-based Posture Transport (PT)
protocol. The PT-TLS protocol carries the Network Endpoint
Assessment (NEA) message exchange under the protection of a Transport
Layer Security (TLS) secured tunnel.
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/rfc6876.
Copyright Notice
Copyright (c) 2013 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.
Sangster, et al. Standards Track [Page 1]
RFC 6876 PT-TLS February 2013
Table of Contents
1. Introduction ....................................................3
1.1. Prerequisites ..............................................4
1.2. Message Diagram Conventions ................................4
1.3. Conventions Used in This Document ..........................4
1.4. Compatibility with Other Specifications ....................4
2. Design Considerations ...........................................5
2.1. Benefits of TCP/IP Connectivity ............................5
2.2. Leveraging Proven TLS Security .............................6
2.3. TLV-Based Message Encapsulation ............................6
2.4. No Change to Base TLS Protocol .............................6
3. PT-TLS Protocol .................................................7
3.1. Initiating a PT-TLS Session ................................8
3.1.1. Issues with Server-Initiated PT-TLS Sessions ........8
3.1.2. Establish or Re-Use Existing PT-TLS Session .........9
3.2. TCP Port Usage .............................................9
3.3. Preventing MITM Attacks with Channel Bindings ..............9
3.4. PT-TLS Message Flow .......................................10
3.4.1. Assessment Triggers ................................10
3.4.2. PT-TLS Message Exchange Phases .....................11
3.4.2.1. TLS Setup Phase ...........................12
3.4.2.2. PT-TLS Negotiation Phase ..................13
3.4.2.3. PT-TLS Data Transport Phase ...............14
3.4.3. TLS Requirements ...................................14
3.5. PT-TLS Message Format .....................................15
3.6. IETF Namespace PT-TLS Message Types .......................18
3.7. PT-TLS Version Negotiation ................................20
3.7.1. Version Request Message ............................21
3.7.2. Version Response Message ...........................22
3.8. Client Authentication Using SASL ..........................22
3.8.1. SASL Client Authentication Requirements ............23
3.8.2. SASL in PT-TLS Overview ............................24
3.8.3. SASL Authentication Flow ...........................24
3.8.4. Aborting SASL Authentication .......................25
3.8.5. Linkages to SASL Framework .........................25
3.8.5.1. SASL Service Name .........................25
3.8.5.2. SASL Authorization Identity ...............25
3.8.5.3. SASL Security Layer .......................25
3.8.5.4. Multiple Authentications ..................25
3.8.6. SASL Channel Bindings ..............................25
3.8.7. SASL Mechanisms ....................................26
3.8.8. SASL Mechanism Selection ...........................26
3.8.9. SASL Authentication Data ...........................27
3.8.10. SASL Result .......................................28
3.9. Error Message .............................................29
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4. Security Considerations ........................................32
4.1. Trust Relationships .......................................32
4.1.1. Posture Transport Client ...........................33
4.1.2. Posture Transport Server ...........................34
4.2. Security Threats and Countermeasures ......................35
4.2.1. Message Theft ......................................35
4.2.2. Message Fabrication ................................36
4.2.3. Message Modification ...............................36
4.2.4. Denial of Service ..................................37
4.2.5. NEA Asokan Attacks .................................37
4.2.6. Trust Anchors ......................................38
5. Privacy Considerations .........................................38
6. IANA Considerations ............................................38
6.1. Designated Expert Guidelines ..............................39
6.2. Registry for PT-TLS Message Types .........................40
6.3. Registry for PT-TLS Error Codes ...........................41
7. Acknowledgments ................................................41
8. References .....................................................42
8.1. Normative References ......................................42
8.2. Informative References ....................................43
1. Introduction
The NEA architecture [RFC5209] defines a system for communicating
posture between a client, where it is collected, and server, where it
is assessed. Posture is configuration and/or status of hardware or
software on an endpoint as it pertains to an organization's security
policy. This document specifies PT-TLS, a TLS-based Posture
Transport (PT) protocol protected by a TLS channel.
NEA protocols are intended to be used for pre-admission assessment of
endpoints joining the network and to assess endpoints already present
on the network. In order to support both usage models, two different
types (or bindings) of PT protocols are necessary to operate before
and after the endpoint has an assigned IP address and other network-
layer information. This specification focuses on the PT protocol
used to assess endpoints already present on the network and thus is
able to use TCP/IP-based transport protocols. NEA has defined
another protocol called PT-EAP [PT-EAP] to address assessment prior
to the endpoint having an assigned IP address.
The Posture Transport protocol in the NEA architecture [RFC5209] is
responsible for transporting Posture Broker (PB-TNC [RFC5793])
batches, often containing Posture Attributes (PA-TNC [RFC5792]) over
the network between the Posture Transport Client component of the NEA
Client and the Posture Transport Server component of the NEA Server.
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The PT protocol also offers strong security protections to ensure
that the exchanged messages are protected from a variety of threats
from hostile intermediaries.
1.1. Prerequisites
This document does not define an architecture or reference model.
Instead, it defines one binding of the PT protocol that works within
the reference model described in the NEA Overview and Requirements
specification [RFC5209]. The reader is assumed to be thoroughly
familiar with [RFC5209]. The NEA working group compared the
functionality described in this specification with the requirements
in [RFC5209] and found that each applicable requirement was
addressed.
1.2. Message Diagram Conventions
This specification defines the syntax of PT-TLS messages using
diagrams. Each diagram depicts the format and size of each field in
bits. Implementations MUST send the bits in each diagram as they are
shown, traversing the diagram from top to bottom and then from left
to right within each line (which represents a 32-bit quantity).
Multi-byte fields representing numeric values must be sent in network
(big endian) byte order.
Bit field (e.g., flag) values are described referring to the position
of the bit within the field. These bit positions are numbered from
the most significant bit through the least significant bit, so a
one-octet field with only bit 0 set has the value 0x80.
1.3. Conventions Used in This Document
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
RFC 2119 [RFC2119].
1.4. Compatibility with Other Specifications
One of the goals of the NEA effort is to deliver a single set of
endpoint assessment standards, agreed upon by all parties. For this
reason, the authors understand that the Trusted Computing Group (TCG)
will be replacing its existing posture transport protocols with new
versions that are equivalent to and interoperable with the NEA
specifications.
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2. Design Considerations
This section discusses some of the key design considerations for the
PT protocol. This document specifies the PT binding for use when
performing an assessment or reassessment after the endpoint has been
admitted to the network and is capable of using TCP/IP to communicate
with the NEA Server. If the endpoint does not yet have TCP/IP-layer
access to the NEA Server (and vice versa), the endpoint can use the
PT-EAP (Posture Transport (PT) Protocol for Extensible Authentication
Protocol (EAP) Tunnel Methods) protocol when performing an
assessment.
Because the endpoint has TCP/IP access to the NEA Server (potentially
on a restricted portion of the network), the NEA Client and NEA
Server have the ability to establish (or re-use) a reliable TCP/IP
connection in order to perform the assessment. The TCP/IP connection
enables the assessment to occur over a relatively high-performance,
reliable channel capable of supporting multiple roundtrip message
exchanges in a full-duplex manner. These connection properties are
very different from what is available when the endpoint is initially
joining the network (e.g., during an 802.1X-based assessment);
therefore, the design described in this specification follows a
different path to maximize the benefits of the underlying TCP/IP
connection.
2.1. Benefits of TCP/IP Connectivity
The PT protocol over TLS is typically able to offer to the NEA Client
and NEA Server significantly higher quality of service and
flexibility of operation than PT-EAP. However, there may be some
added risks when the endpoint is on the network prior to its initial
assessment (if no admission time assessment had been performed).
Because of these risks, the combined use of an EAP-based assessment
during admission followed by reassessment using TCP/IP may be
appropriate in some environments.
Some of the benefits to having a TCP/IP-based transport during an
assessment include:
o Full-Duplex Connectivity - used to support asynchronous initiation
of posture exchanges within a single TLS connection (e.g.,
triggered by alerts of posture or policy changes)
o High Bandwidth - potentially much higher bandwidth than other
transports (e.g., EAP), allowing more in-band data (e.g.,
remediation, verbose posture information)
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o Large Messages - ability to send very large Posture Attribute
messages without directly fragmenting them (underlying carrier
protocol may introduce fragmentation)
o Bidirectional - NEA Client and NEA Server can initiate an
assessment or reassessment
o Multiple Roundtrips - NEA Client and NEA Server can exchange
numerous messages without fear of infrastructure timeouts.
However, the entire exchange should be kept as brief as possible
if the user has to wait for its completion.
2.2. Leveraging Proven TLS Security
All PT protocol bindings must be capable of providing strong
authentication, integrity, and confidentiality protection for the
PB-TNC batches. Rather than define a new protocol over TCP/IP to
provide adequate protection, this specification requires the use of
Transport Layer Security [RFC5246] to secure the connection. TLS was
selected because it's a widely deployed protocol with parallel
protections to a number of the EAP tunnel methods, and it meets all
of the security requirements.
2.3. TLV-Based Message Encapsulation
The design of the PT-TLS protocol is based upon the use of a
type-length-value (TLV)-oriented protocol message that identifies the
type of message, the message's length, and a potentially variable-
length payload value. The use of a TLV-oriented encoding was chosen
to match the Internet standard PA-TNC and PB-TNC protocols. Because
the PA-TNC, PB-TNC, and PT-TLS protocols are typically implemented
inside the same process space, this allows a common set of message-
parsing code to be used. Similarly, creation of debugging tools is
simplified by the common encoding methodologies. TLV-based encoding
was used in each of the NEA protocols in part because it enables a
very space-efficient representation on the network and is simpler to
parse than some other encodings to benefit lower-powered (or battery
constrained) devices.
2.4. No Change to Base TLS Protocol
During the design of the PT-TLS protocol, several approaches were
considered with different costs and benefits. Several considered
approaches involved integrating the PT protocol into the TLS
handshake protocol. Because the PT protocol requires the underlying
TLS carrier to provide security protections, the PT protocol couldn't
operate before the cipher suites were negotiated and in use. One
option was to integrate into the TLS handshake protocol after the
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ChangeCipherSpec phase, allowing the PT message to be protected. The
benefit of this approach is that the assessment protocol could
operate below the application protocols, allowing for easier
integration into applications. However, making this change would
require some extensions to the TLS handshake protocol standards and
existing widely deployed TLS implementations, so it wasn't clear that
the cost was warranted, particularly because the application
independence can also be offered by a shim library between the
application and TLS library that provides the PT protocol
encapsulation/decapsulation.
The other general approach considered was to have PT-TLS layer on top
of TLS as an application protocol (using the standard
application_data ContentType). This has the advantage that existing
TLS software could be used. However, the PB-TNC traffic would need
to be encapsulated/decapsulated by a new PT-TLS protocol layer before
being passed to the TLS library. This didn't seem like a significant
issue, as PB-TNC is architected to layer on PT anyway.
After considering the different options, it was determined that
layering the PT protocol on top of the TLS protocol without requiring
current TLS protocol implementations to change met all the
requirements and offered the best path toward rapid adoption and
deployment. Therefore, the following sections describe a PT protocol
that is carried on top of TLS.
3. PT-TLS Protocol
This section specifies the PT-TLS protocol, a Posture Transport (PT)
protocol carried by the Transport Layer Security (TLS) protocol over
a TCP/IP network. As shown in Figure 1, this protocol runs directly
on top of TLS as an application. This means PT-TLS is encapsulated
within the TLS Record Layer protocol using the standard ContentType
for applications (application_data).
+---------------------------------------------------------------+
| TLV Encapsulation of PB-PA message |
+---------------------------------------------------------------+
| TLS |
+---------------------------------------------------------------+
| TCP |
+---------------------------------------------------------------+
Figure 1. PT-TLS Layering Model
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3.1. Initiating a PT-TLS Session
The PT-TLS protocol may be initiated by a Posture Transport Client or
a Posture Transport Server. This flexibility supports different use
cases. For example, a Posture Transport Client that wishes to
trigger a NEA assessment to determine whether its security posture is
good can start up a PT-TLS session and request a posture assessment.
On the other hand, when an endpoint requests access to a protected
network or resource, a Posture Transport Server can start up a PT-TLS
session and perform a posture assessment before deciding whether to
grant access.
The party that initiates a PT-TLS session is known as the "PT-TLS
Initiator". The other party in the session (which receives the
request to open a PT-TLS session) is known as the "PT-TLS Responder".
3.1.1. Issues with Server-Initiated PT-TLS Sessions
In order for a NEA Server to establish a PT-TLS session, the NEA
Client needs to be listening for a connection request on a TCP port
known by the NEA Server. In many deployments, the security policies
of an endpoint (e.g., firewall software) or the security policies of
a network (e.g., firewall devices) are designed to minimize the
number of open inbound TCP/UDP ports that are available to the
network to reduce the potential attack footprint. This is one issue
that makes it difficult for a NEA Server to initiate a PT-TLS
session.
Another issue with this scenario involves X.509 certificates. When
the NEA Server creates a TLS session to the NEA Client, the NEA
Client is effectively acting as the TLS server during the TLS
protocol exchange. This means the NEA Client would typically need to
possess an X.509 certificate to protect the initial portion of the
TLS handshake. In situations where the NEA Server initiates the
creation of the TLS session, both the NEA Client and NEA Server MUST
possess X.509 certificates to fully authenticate the session. For
many deployments, provisioning X.509 certificates to all NEA Clients
has scalability and cost issues; therefore, it is recommended that
the NEA Client not listen for connection requests from the NEA Server
but instead establish and maintain a TLS session to the NEA Server
proactively, so either party can initiate an assessment using the
preexisting TLS session as required.
In most cases, the traditional methods of server certificate ID
validation will not apply when the NEA Server initiates the
connection. In this case, the NEA Client and Server need to follow
the certificate path validation rules in RFC 5280 [RFC5280]. In
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addition, each side needs to be able to authorize its peer based upon
matching Subject and SubjectAltName fields for certificates issued by
a particular trust anchor.
Therefore, NEA Clients SHOULD be capable of establishing and holding
open a TLS session with the NEA Server immediately after obtaining
network access. A NEA Client MAY listen for connection requests from
the NEA Server and establish a new PT-TLS session when one does not
already exist. Because of the potential added complexity, a NEA
Client's support for accepting inbound PT-TLS connections is optional
to implement. Having an existing PT-TLS session allows either party
to initiate an assessment without requiring the NEA Client to be
listening for new connection requests. In order to keep the TLS
session alive, the NEA Client and NEA Server SHOULD be capable of
supporting the TLS heartbeat protocol [RFC6520].
3.1.2. Establish or Re-Use Existing PT-TLS Session
A single PT-TLS session can support multiple NEA assessments, which
can be started by either party (the PT-TLS Initiator or the PT-TLS
Responder). The party that starts a NEA assessment is known as the
"assessment initiator", and the other party is known as the
"assessment responder".
If the assessment initiator already has a PT-TLS session to the
assessment responder, the initiator can re-use this session;
otherwise, a new PT-TLS session needs to be established.
3.2. TCP Port Usage
In order for a PT-TLS Initiator to establish a TCP connection to a
PT-TLS Responder, the initiator needs to know the TCP port number on
which the responder is listening for assessment requests. The IANA
has reserved TCP port number 271 for use by "pt-tls".
3.3. Preventing MITM Attacks with Channel Bindings
As described in "The Network Endpoint Assessment (NEA) Asokan Attack
Analysis" [RFC6813], a sophisticated Man-in-the-Middle (MITM) attack
can be mounted against NEA systems. The attacker forwards PA-TNC
messages from a healthy machine through an unhealthy one so that the
unhealthy machine can gain network access. Because there are easier
attacks on NEA systems, like having the unhealthy machine lie about
its configuration, this attack is generally only mounted against
machines with an External Measurement Agent (EMA). The EMA is a
separate entity, difficult to compromise, that measures and attests
to the configuration of the endpoint.
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To protect against NEA Asokan attacks, the Posture Broker Client on
an EMA-equipped endpoint should pass the tls-unique channel binding
[RFC5929] for PT-TLS's underlying TLS session to the EMA. This value
can then be included in the EMA's attestation, and the Posture
Validator responsible for communicating with the EMA may then confirm
that the value matches the tls-unique channel binding for its end of
the connection. If the values match, the posture sent by the EMA and
NEA Client is from the same endpoint as the client side of the TLS
connection (since the endpoint knows the tls-unique value), so no
man-in-the-middle is forwarding posture. If they differ, the Asokan
attack has been detected. The Posture Validator MUST fail its
verification of the endpoint if the Asokan attack has been detected.
3.4. PT-TLS Message Flow
This section discusses the general flow of messages between the NEA
Client's Posture Transport Client and the NEA Server's Posture
Transport Server in order to perform NEA assessments using the PT-TLS
protocol.
3.4.1. Assessment Triggers
Initially, the NEA Client or NEA Server will decide that an
assessment is needed. What stimulates the decision to perform an
assessment is outside the scope of this specification, but some
examples include:
o NEA Server becoming aware of suspicious behavior on an endpoint
o NEA Server receiving new policies requiring immediate action
o NEA Client noticing a change in local security posture
o NEA Client wishing to access a protected network or resource
Because either the NEA Client or NEA Server can trigger the
establishment of the TLS session and initiate the assessment, this
document will use the terms "assessment initiator" and "assessment
responder". This nomenclature allows either NEA component to fill
either of the PT-TLS roles.
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3.4.2. PT-TLS Message Exchange Phases
The PT-TLS message exchange occurs in three distinct phases:
o TLS Setup (including TLS handshake protocol)
o PT-TLS Negotiation
o PT-TLS Data Transport
The TLS Setup phase is responsible for the establishment of the TCP
connection and the TLS protections for the PT-TLS messages. The TLS
Setup phase starts with the establishment of a TCP connection between
the Posture Transport Client and Posture Transport Server. The new
connection triggers the TLS server to start the TLS handshake
protocol to establish the cryptographic protections for the session.
Once the TLS Setup phase has completed (after the TLS Finished
messages), the TLS session MUST NOT be renegotiated. TLS session
renegotiation MAY be used before the TLS Setup phase ends and the
PT-TLS Negotiation phase begins. This phase also enables the
establishment of the tls-unique shared secret. The tls-unique shared
secret can later be used by the PA protocol to protect against some
forms of man-in-the-middle attacks.
The PT-TLS Negotiation phase is only performed at the start of the
first assessment on a TLS session. During this phase, the NEA Client
and NEA Server discover each other's PT-TLS capabilities and
establish a context that will apply to all future PT-TLS messages
sent over the TLS session. The PT-TLS Negotiation phase MUST NOT be
repeated after the session has entered the Data Transport phase. NEA
assessment messages (PB-TNC batches) MUST NOT be sent by the NEA
Client or NEA Server prior to the completion of the PT-TLS
Negotiation phase to ensure that the security protections for the
session are properly established and applied to the NEA assessment
messages.
Finally, the Data Transport phase allows the NEA Client and NEA
Server to exchange PT messages under the protection of the TLS
session consistent with the capabilities established in earlier
phases. The exchanged messages can be a PT-TLS protected NEA
assessment as described in this specification or other vendor-defined
PT-TLS exchanged messages.
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3.4.2.1. TLS Setup Phase
After a new TCP connection is established between the Posture
Transport Client and Posture Transport Server, a standard TLS
exchange is performed to negotiate a common security context for
protecting subsequent communications. As discussed in Section 3.1,
the TCP connection establishment and/or the TLS handshake protocol
could be initiated by either the NEA Client or NEA Server. The most
common situation would be for the assessment initiator to trigger the
creation of the TCP connection and TLS handshake, so an assessment
could begin when no session already exists. When the NEA Server has
initiated the TLS Setup, the NEA Server is acting as a TLS client and
the NEA Client is the TLS server (accepting the inbound TLS session
request). The expected normal case is that the NEA Client initiates
this phase, so that the NEA Server is acting as the TLS server and
therefore the bootstrapping of the security of the TLS session is
using the NEA Server's certificate. Having the NEA Client initiate
the TLS session avoids the need for the NEA Client to also possess a
certificate.
During the TLS Setup phase of PT-TLS, the PT-TLS Initiator contacts
the listening port of the PT-TLS Responder and performs a TLS
handshake. The PT-TLS Responder MUST possess a trustworthy X.509
certificate used to authenticate to the PT-TLS Initiator and used to
bootstrap the security protections of the TLS session. The PT-TLS
Initiator MAY also use an X.509 certificate to authenticate to the
PT-TLS Responder providing for a bidirectional authentication of the
PT-TLS session. The NEA Client MUST provide certificate validation
according to the rules in RFC 5280 when evaluating the server
certificate. The NEA Client MAY perform certificate revocation
checking on the NEA Server's certificate. This specification allows
the NEA Client implementation to decide on what certificate
revocation technique is to be implemented. If revocation information
is not provided in a TLS handshake extension, then clients performing
certificate validation will require some network access (e.g., HTTP)
to be allowed during the assessment. NEA Client network access to
other non-essential services might be restricted during assessments
in some situations. If the client cannot access the status
information, then its policy may prevent it from completing the TLS
handshake.
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In addition, the NEA Client MUST follow the recommendations in
RFC 6125 [RFC6125] when validating the NEA Server domain name against
the contents of the server certificate, taking into consideration the
following restrictions:
o Any SRV-IDs and URI-IDs in the certificate are ignored.
o Use of CN-IDs in certificates is NOT RECOMMENDED.
o Wildcards MUST NOT appear in the DNS-ID or CN-ID of a certificate
identifying a PT-TLS server.
Details for the reverse direction are given in Section 3.1.
Due to deployment issues with issuing and distributing certificates
to a potentially large number of NEA Clients, this specification
allows the NEA Client to be authenticated during the PT-TLS
Negotiation phase using other more cost-effective methods, as
described in Section 3.8.1. At the conclusion of a successful
initial TLS Setup phase, the NEA Client and NEA Server have a
protected session to exchange messages. This allows the protocol to
transition to the PT-TLS Negotiation phase.
3.4.2.2. PT-TLS Negotiation Phase
Once a TLS session has been established between a Posture Transport
Client and Posture Transport Server, the PT-TLS Initiator sends a
Version Request message indicating its supported PT-TLS protocol
version range. Next, the PT-TLS Responder sends a Version Response
message, which selects a protocol version from within the range
offered. The PT-TLS Responder SHOULD select the preferred version
offered if supported; otherwise, the highest version that the
responder is able to support from the received Version Request
message will be used. If the PT-TLS Responder is unable or unwilling
to support any of the versions included in the Version Request
message, the responder SHOULD send a Version Not Supported error
message.
If no client-side authentication occurred during the TLS Setup phase,
the Posture Transport Server can authenticate the client using PT-TLS
client authentication messages as described in Section 3.8. The NEA
Server initiates the client authentication and indicates when the
authentication is complete.
When the NEA Client receives the Simple Authentication and Security
Layer (SASL) [RFC4422] Mechanisms list, the NEA Client responds with
a SASL Mechanism Selection TLV indicating the method of
authentication to be used. Upon selecting an appropriate SASL
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mechanism, the NEA Client and Server exchange SASL-mechanism-specific
messages in order to authenticate the NEA Client. When the client
authentication successfully completes and no additional
authentications are required (as indicated by the NEA Server sending
an empty SASL Mechanisms list), the PT-TLS session transitions into
the Data Transport phase, where it will remain for the duration of
the session. Note that the NEA Server could choose to not
authenticate the client (indicated by only sending an empty SASL
Mechanisms list) or to continue performing a posture assessment even
if the authentication did not complete successfully.
3.4.2.3. PT-TLS Data Transport Phase
Once a PT-TLS session is available to carry NEA assessments, PT-TLS
allows either side of the connection to send the first PB-TNC batch.
The PB-TNC standard prescribes whether the Posture Broker Client or
Posture Broker Server starts the assessment. The assessment
initiator first envelopes the PB-TNC batch in a PT-TLS message, then
assigns a message identifier to the message and finally transmits it
over the session. The assessment responder validates the PT-TLS
message and delivers the encapsulated PB-TNC batch to its upstream
component (Posture Broker Client or Server).
Most PT-TLS messages contain PB-TNC batches that house PA-TNC
requests for posture information or a response containing the
requested posture information. The Posture Transport Client and
Posture Transport Server may also exchange messages between them,
such as a PT-TLS Error message indicating that a problem occurred
processing a message. During an assessment, the Posture Transport
Client and Server merely encapsulate and exchange the PB-TNC batches
and are unaware of the state of the assessment.
The PT-TLS protocol allows either party to send a PT-TLS message at
any time, reflecting the full-duplex nature of the underlying TLS
session. For example, an assessment initiator may send several
PT-TLS messages prior to receiving any responses from the assessment
responder. All implementations of PT-TLS MUST support full-duplex
PT-TLS message exchange. However, some higher-layer NEA protocols
(e.g., PB-TNC) may not be able to fully make use of the full-duplex
message exchange.
3.4.3. TLS Requirements
In order to ensure that strong security is always available for
deployers and to improve interoperability, this section discusses
some requirements on the underlying TLS transport used by PT-TLS.
Whenever TLS is used by this specification, the appropriate version
(or versions) of TLS will vary over time, based on the widespread
Sangster, et al. Standards Track [Page 14]
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deployment and known security vulnerabilities. At the time of this
writing, TLS version 1.2 [RFC5246] is the most recent version, but it
has a very limited deployment base and might not be readily available
for implementation. TLS version 1.0 [RFC2246] and version 1.1
[RFC4346] are the most widely deployed versions and will provide the
broadest interoperability. Implementations of PT-TLS SHOULD support
use of TLS 1.2.
For each TLS version supported, implementations of the PT-TLS
protocol MUST at least support the TLS_RSA_WITH_AES_128_CBC_SHA
cipher suite. This cipher suite requires the server to provide a
certificate that can be used during the key exchange.
Implementations SHOULD NOT include support for cipher suites that do
not minimally offer PT-TLS Responder (typically Posture Transport
Server) authentication, such as the anonymous Diffie-Hellman cipher
suites (e.g., TLS_DH_anon_WITH_AES_128_CBC_SHA). Implementations
MUST support RFC 5746 [RFC5746]. Implementations MAY allow
renegotiation to provide confidentiality for the client certificate.
If renegotiation is allowed, implementations need to select the
appropriate handshake messages as described in RFC 5929 for the
tls-unique value.
3.5. PT-TLS Message Format
This section describes the format and semantics of the PT-TLS
message. Every message sent over a PT-TLS session MUST start with
the PT-TLS header described in this section.
The PT-TLS header format is as follows:
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved | Message Type Vendor ID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Type |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Length |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Identifier |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Message Value (e.g., PB-TNC Batch) . . . |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Reserved
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Sangster, et al. Standards Track [Page 15]
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Message Type Vendor ID
This field indicates the owner of the namespace associated with
the message type. This is accomplished by specifying the 24-bit
Structure of Management Information (SMI) Private Enterprise
Number [PEN] (Vendor ID) of the party who owns the message type
namespace. Consistent with PA-TNC and PB-TNC, we depend on the
PEN fitting in 24 bits, so if IANA were to register a wider PEN,
then that PEN could not be used with NEA. IETF namespace PT-TLS
Message Types MUST use zero (0) in this field. For more
information about the intended use of NEA namespace identifiers,
see the PA-TNC specification (RFC 5792), Sections 2.1 and 2.2.
The PT-TLS Message Type Vendor ID 0xffffff is reserved. Posture
Transport Clients and Servers MUST NOT send PT-TLS messages in
which the PT-TLS Message Type Vendor ID has this reserved value
(0xffffff). If a Posture Transport Client or Posture Transport
Server receives a message containing this reserved value
(0xffffff) in the PT-TLS Message Type Vendor ID, the recipient
SHOULD respond with an Invalid Parameter error code in a PT-TLS
Error message.
Message Type
This field defines the type of the PT-TLS message within the scope
of the specified Message Type Vendor ID that is included in the
Message Value field. The specific IETF-defined values allowable
in this field when the Message Type Vendor ID is the IETF SMI
Private Enterprise Number value (0) are defined in Section 3.6.
Recipients of a message containing a Message Type Vendor ID and a
message type that is unrecognized SHOULD respond with a Type Not
Supported error code in a PT-TLS Error message.
Posture Transport Clients and Posture Transport Servers MUST NOT
require support for particular vendor-defined PT-TLS Message Types
in order to interoperate with other PT-TLS compliant
implementations (although implementations MAY permit
administrators to configure them to require support for specific
vendor-defined PT-TLS Message Types).
If the PT-TLS Message Type Vendor ID field has the value zero (0),
then the PT-TLS Message Type field contains an IETF namespace
PT-TLS Message Type, as listed in the IANA registry. IANA
maintains a registry of PT-TLS Message Types. Entries in this
registry are added following the IANA Specification Required
policy, following the guidelines in Section 6.1. Section 3.6 of
this specification defines the initial set of IETF-defined PT-TLS
Message Types.
Sangster, et al. Standards Track [Page 16]
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The PT-TLS Message Type 0xffffffff is reserved. Posture Transport
Clients and Posture Transport Servers MUST NOT send PT-TLS
messages in which the PT-TLS Message Type has this reserved value
(0xffffffff). If a Posture Transport Client or Posture Transport
Server receives a message in which the PT-TLS Message Type has
this reserved value (0xffffffff), it SHOULD respond with an
Invalid Parameter error code in a PT-TLS Error message.
Message Length
This field contains the length in octets of the entire PT-TLS
message (including the entire header). Therefore, this value MUST
always be at least 16. Any Posture Transport Client or Posture
Transport Server that receives a message with a PT-TLS Message
Length field whose value is less than 16 SHOULD respond with an
Invalid Parameter PT-TLS Error Code. Similarly, if a Posture
Transport Client or Posture Transport Server receives a PT-TLS
message for a Message Type that has a known Message Length and the
Message Length indicates a different value (greater or less than
the expected value), the recipient SHOULD respond with an Invalid
Parameter PT-TLS Error Code.
Message Identifier
This field contains a value that uniquely identifies the PT-TLS
message on a per message sender (Posture Transport Client or
Server) basis. This value is copied into the body of the PT-TLS
Error message so the recipient can determine which message caused
the error.
The Message Identifier MUST be a monotonically increasing counter
starting at zero indicating the number of the messages the sender
has transmitted over the TLS session. It is possible that a busy
or long-lived session might exceed 2^32-1 messages sent, so the
message sender MUST roll over to zero upon reaching the 2^32nd
message, thus restarting the increasing counter. During a
rollover, it is feasible that the message recipient could be
confused if it keeps track of every previously received Message
Identifier, so recipients MUST be able to handle rollover
situations without generating errors.
Sangster, et al. Standards Track [Page 17]
RFC 6876 PT-TLS February 2013
Message Value
The contents of this field vary depending on the particular
Message Type Vendor ID and Message Type given in the PT-TLS header
for this PT-TLS message. This field most frequently contains a
PB-TNC batch. The contents of this field for each of the initial
IETF namespace PT-TLS Message Types are defined in this
specification.
3.6. IETF Namespace PT-TLS Message Types
This section defines the NEA standard PT-TLS Message Types used to
carry PT-TLS messages and PB-TNC batches between the Posture
Transport Client and Posture Transport Server.
The following table summarizes the initial set of IETF-defined
message type values, which are used with the PT-TLS Message Type
Vendor ID field set to the IETF SMI PEN (0). Note that the IANA
administers a PEN value of 0 on behalf of the IETF. These
descriptions only apply to the IETF namespace.
Value (Name) Definition
---------------------------- ---------------------------------------
0 (Experimental) Reserved for experimental use. This
type will not offer interoperability
but allows for experimentation. This
message type MUST only be sent when the
NEA Client and NEA Server are in the
Data Transport phase and only on a
restricted, experimental network.
Compliant implementations MUST send an
Invalid Message error code in a PT-TLS
Error message if an Experimental
message is received.
1 (Version Request) Version negotiation request including
the range of versions supported by the
sender. This message type MUST only be
sent by the TLS session initiator as
the first PT-TLS message in the PT-TLS
Negotiation phase. Recipients MUST
send an Invalid Message error code in a
PT-TLS Error message if a Version
Request is received at another time.
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2 (Version Response) PT-TLS protocol version selected by the
responder. This message type MUST only
be sent by the PT-TLS Responder as the
second message in the PT-TLS
Negotiation phase. Recipients MUST
send an Invalid Message error code in a
PT-TLS Error message if a Version
Response is received at another time.
3 (SASL Mechanisms) Sent by the NEA Server to indicate what
SASL mechanisms it is willing to use
for authentication on this session.
This message type MUST only be sent by
the NEA Server in the PT-TLS
Negotiation phase. The NEA Client MUST
send an Invalid Message error code in a
PT-TLS Error message if a SASL
Mechanisms message is received at
another time.
4 (SASL Mechanism Selection) Sent by the NEA Client to select a SASL
mechanism from the list offered by the
NEA Server. This message type MUST
only be sent by the NEA Client in the
PT-TLS Negotiation phase. The NEA
Server MUST send an Invalid Message
error code in a PT-TLS Error message if
a SASL Mechanism Selection is received
after the PT-TLS Negotiation phase.
Once a SASL mechanism has been
selected, it may not change until the
mechanism completes either successfully
or as a failure.
5 (SASL Authentication Data) Opaque octets exchanged between the NEA
Client and NEA Server's SASL mechanisms
to perform the client authentication.
This message type MUST only be sent
during the PT-TLS Negotiation phase.
Recipients MUST send an Invalid Message
error code in a PT-TLS Error message if
a SASL Authentication Data message is
received after the PT-TLS Negotiation
phase.
Sangster, et al. Standards Track [Page 19]
RFC 6876 PT-TLS February 2013
6 (SASL Result) Indicates the result code of the SASL
mechanism authentication as described
in Section 3.8.10. This message type
MUST only be sent by the NEA Server
when the NEA Client and NEA Server are
in the PT-TLS Negotiation phase. The
NEA Client MUST send an Invalid Message
error code in a PT-TLS Error message if
a SASL Result is received after the
PT-TLS Negotiation phase.
7 (PB-TNC Batch) Contains a PB-TNC batch. For more
information on PB-TNC batches, see
RFC 5793 (PB-TNC) Section 4. This
message type MUST only be sent when the
NEA Client and NEA Server are in the
PT-TLS Data Transport phase.
Recipients SHOULD send an Invalid
Message error code in a PT-TLS Error
message if a PB-TNC Batch is received
outside of the Data Transport phase.
8 (PT-TLS Error) PT-TLS Error message as described in
Section 3.9. This message type may be
used during any PT-TLS phase.
9-4294967294 (Unassigned) These values are for future allocation
following guidelines defined in the
IANA Considerations section (see
Section 6.1). Recipients of
unsupported messages in the IETF
namespace using a message type of 9 to
4294967294 MUST respond with a Type Not
Supported PT-TLS Error Code in a PT-TLS
Error message.
4294967295 Reserved
3.7. PT-TLS Version Negotiation
This section describes the message format and semantics for the
PT-TLS protocol version negotiation. This exchange is used by the
PT-TLS Initiator to trigger a version negotiation at the start of an
assessment. The PT-TLS Initiator MUST send a Version Request message
as its first PT-TLS message and MUST NOT send any other PT-TLS
messages on this connection until it receives a Version Response
message or an Error message. The PT-TLS Responder MUST complete the
version negotiation (or cause an error) prior to sending or accepting
Sangster, et al. Standards Track [Page 20]
RFC 6876 PT-TLS February 2013
reception of any additional messages. After the successful
completion of the version negotiation, both the Posture Transport
Client and Posture Transport Server MUST only send messages compliant
with the negotiated protocol version. Subsequent assessments on the
same session MUST use the negotiated version number and therefore
MUST NOT send additional version negotiation messages.
3.7.1. Version Request Message
This message is sent by a PT-TLS Initiator as the first PT-TLS
message in a PT-TLS session. This message discloses the sender's
supported versions of the PT-TLS protocol. To ensure compatibility,
this message MUST always be sent using version 1 of the PT-TLS
protocol. Recipients of this message MUST respond with a Version
Response or with a PT-TLS Error message (Version Not Supported or
Invalid Message). The following diagram shows the format of the
Version Request message:
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved | Min Vers | Max Vers | Pref Vers |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Reserved
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Min Vers
This field contains the minimum version of the PT-TLS protocol
supported by the sender. This field MUST be set to 1 indicating
support for the first version of PT-TLS. However, future versions
of this specification will probably remove this requirement, so
PT-TLS Responders MUST be prepared to receive other values.
Max Vers
This field contains the maximum version of the PT-TLS protocol
supported by the sender. This field MUST be set to 1 indicating
support for the first version of PT-TLS. However, future versions
of this specification will probably remove this requirement, so
PT-TLS Responders MUST be prepared to receive other values.
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RFC 6876 PT-TLS February 2013
Pref Vers
This field contains the sender's preferred version of the PT-TLS
protocol. This is a hint to the recipient that the sender would
like this version selected if supported. The value of this field
MUST fall within the range of Min Vers to Max Vers. This field
MUST be set to 1 indicating support for the first version of
PT-TLS. However, future versions of this specification will
probably remove this requirement, so PT-TLS Responders MUST be
prepared to receive other values.
3.7.2. Version Response Message
This message is sent in response to receiving a Version Request
message at the start of a new assessment session. If a recipient
receives a Version Request after a successful version negotiation has
occurred on the session, the recipient MUST send an Invalid Message
error code in a PT-TLS Error message and have TLS close the session.
This message MUST be sent using the syntax, semantics, and
requirements of the protocol version specified in this message.
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved | Version |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Reserved
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Version
This field contains the version selected by the sender of this
message. The version selected MUST be within the Min Vers to Max
Vers inclusive range sent in the Version Request message. If a
PT-TLS Initiator receives a message with an invalid Version
selected, the PT-TLS Initiator MUST respond with a Version Not
Supported PT-TLS Error message.
3.8. Client Authentication Using SASL
This section includes a description of the message format and
semantics necessary to perform client authentication (authentication
of the NEA Client) over PT-TLS. Client authentication could be
necessary if the NEA Server requires such an authentication and it
was not performed during the TLS handshake. The general model used
Sangster, et al. Standards Track [Page 22]
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for performing an authentication of the client using PT-TLS messages
is to integrate the Simple Authentication and Security Layer (SASL)
[RFC4422] framework. SASL provides a number of standards-based
authentication mechanisms capable of authenticating the NEA Client
using a variety of base technologies.
Client authentication could occur during the TLS handshake using TLS-
defined authentication techniques. Because this client
authentication is optional, the NEA Server's policy might require the
client to be authenticated by PT-TLS before performing the
assessment. Similarly, the NEA Server may require a PT-TLS
authentication even if the NEA Client was authenticated during the
TLS handshake (e.g., to allow a user authentication after a system-
level authentication occurred during the TLS handshake). The
decision of whether a SASL client authentication is to occur is left
to the NEA Server's policy.
As discussed in Section 3.1.1, it is possible that the NEA Server may
initiate the TLS session to the NEA Client, thus causing it to fill
the role of TLS client during the TLS handshake. Because the NEA
Server is required to possess an X.509 certificate for those times
when it is acting as the TLS server (normal case), PT-TLS requires
that the NEA Server MUST use its X.509 certificate for TLS client
authentication during the TLS handshake to authenticate itself even
when it is acting as the TLS client. In this case, the NEA Client
and NEA Server will authenticate using certificates during the TLS
handshake, so the PT-TLS SASL client authentication might not be
required unless NEA Server policy required an additional
authentication of the NEA Client. Therefore, the normal usage for
the SASL messages is when the NEA Client acted as the TLS client and
did not authenticate during the TLS handshake.
3.8.1. SASL Client Authentication Requirements
Implementations compliant with the PT-TLS specification MUST
implement the PT-TLS client authentication messages described in this
section. These PT-TLS client authentication messages are capable of
carrying a variety of SASL authentication mechanisms' exchanges. In
order to ensure interoperability, all PT-TLS implementations
compliant with this specification MUST at least support the PLAIN
SASL mechanism [RFC4616]. Similarly, implementations MUST provide
the EXTERNAL SASL mechanism if both parties are authenticated during
the TLS establishment. In order to be able to take advantage of
other strong, widely deployed authentication technologies such as
Kerberos and support for channel bindings, implementations MAY
Sangster, et al. Standards Track [Page 23]
RFC 6876 PT-TLS February 2013
include support for GS2 (the second Generic Security Service
Application Program Interface (GSS-API) bridge for SASL) [RFC5801].
GS2 includes negotiable support for channel binding for use with SASL
(see Section 5 of RFC 5801).
Implementations MUST also support the case where no client
authentication is required.
3.8.2. SASL in PT-TLS Overview
Mechanism negotiation is initiated by the NEA Server sending the SASL
Mechanisms TLV to the NEA Client to indicate the zero or more SASL
mechanisms that the NEA Server's policy is willing to use with the
NEA Client. The NEA Client selects one SASL mechanism from the list
and sends a SASL Mechanism Selection TLV completing the negotiation.
Subsequent challenges and responses are carried within the SASL
Authentication Data TLV carrying the authentication data for the
selected mechanism. The authentication outcome is communicated in a
SASL Result TLV containing a status code. If additional
authentications are required, the NEA Server could trigger the next
authentication by sending another SASL Mechanisms TLV after sending
the SASL Result TLV for the current authentication mechanism.
3.8.3. SASL Authentication Flow
The SASL client authentication starts when the NEA Server enters the
PT-TLS Negotiation phase and its policy indicates that an
authentication of the NEA Client is necessary, such as if it was not
performed during the TLS handshake protocol. The NEA Server is
responsible for triggering the client authentication by sending the
SASL Mechanisms TLV to the NEA Client listing the set of SASL
mechanisms the server is willing to use based upon its policy.
The NEA Client selects a SASL mechanism from the list proposed by the
NEA Server or sends a PT-TLS Invalid Message error code indicating
that it is unable or unwilling to perform any of the mechanisms that
were offered. If the NEA Server receives a SASL Mechanism Selection
TLV that contains an unacceptable SASL mechanism, the NEA Server
would respond with a SASL Mechanism Error in a PT-TLS Error TLV.
In situations where the NEA Server does not require a client
authentication, the NEA Server MUST send a SASL Mechanisms TLV with
no mechanisms included (only the PT-TLS header) indicating that the
connection should transition to the PT-TLS Data Transport phase. The
same mechanism is employed to indicate that a SASL authentication
already performed in this session is adequate to permit transition to
the PT-TLS Data Transport phase. So the NEA Server MUST always send
Sangster, et al. Standards Track [Page 24]
RFC 6876 PT-TLS February 2013
a SASL Mechanisms TLV with no mechanisms as the last message in the
PT-TLS Negotiation phase, and the NEA Client MUST NOT transition to
the PT-TLS Data Transport phase until it receives such a message.
If the NEA Server receives a NEA assessment message before the
completion of the client authentication, the NEA Server MUST send an
Authentication Required PT-TLS Error message indicating to the NEA
Client that an authentication exchange is required prior to entering
the PT-TLS Data Transport phase.
3.8.4. Aborting SASL Authentication
The NEA Server may abort the authentication exchange by sending the
SASL Result TLV with a status code of Abort. The NEA Client may
abort the authentication exchange by sending a PT-TLS Error message
with an Error Code of SASL Mechanism Error.
3.8.5. Linkages to SASL Framework
3.8.5.1. SASL Service Name
The service name for PT-TLS is "nea-pt-tls".
3.8.5.2. SASL Authorization Identity
The PT-TLS protocol does not make use of a SASL authorization
identity string as described in RFC 4422.
3.8.5.3. SASL Security Layer
The NEA PT-TLS protocol always runs under the protection of TLS.
SASL security layers are not used and thus MUST be negotiated off
during SASL authentication.
3.8.5.4. Multiple Authentications
Only one SASL mechanism authentication may be in progress at any one
time. Once a SASL mechanism completes (successfully or
unsuccessfully), the NEA Server MAY trigger an additional
authentication by sending a SASL Mechanisms TLV.
3.8.6. SASL Channel Bindings
SASL channel bindings are used to bind the SASL authentication to the
outer TLS tunnel to ensure that the authenticating endpoints are the
same as the TLS endpoints. For SASL mechanisms that support channel
bindings, the tls-unique value defined in RFC 5929 is carried by the
SASL mechanism. For most mechanisms, this means including the
Sangster, et al. Standards Track [Page 25]
RFC 6876 PT-TLS February 2013
tls-unique value with the appropriate prefix defined in RFC 5929 in
the application data portion of the SASL Mechanism channel-binding
data. If the validation of the channel binding fails, then the
connection MUST be aborted.
3.8.7. SASL Mechanisms
This TLV is sent by the NEA Server to indicate the list of SASL
mechanisms that it is willing and able to use to authenticate the NEA
Client. Each mechanism name consists of a length followed by a name.
The total length of the list is determined by the TLV Length field.
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Rsvd| Mech Len| Mechanism Name (1-20 bytes) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Rsvd| Mech Len| Mechanism Name (1-20 bytes) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| . . . . . . . . . . . |
Rsvd (Reserved)
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Mech Len (Mechanism Name Length)
The length of the Mechanism Name field in octets.
Mechanism Name
SASL mechanism name adhering to the rules defined in RFC 4422 with
no padding.
3.8.8. SASL Mechanism Selection
This TLV is sent by the NEA Client in order to select a SASL
mechanism for use on this session.
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Rsvd| Mech Len| Mechanism Name (1-20 bytes) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Optional Initial Mechanism Response |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Sangster, et al. Standards Track [Page 26]
RFC 6876 PT-TLS February 2013
Rsvd (Reserved)
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Mech Len (Mechanism Name Length)
The length of the Mechanism Name field in octets.
Mechanism Name
SASL mechanism name adhering to the rules defined in RFC 4422.
Optional Initial Mechanism Response
Initial set of authentication information required from the NEA
Client to kick-start the authentication. This data is optional
and if not provided would be solicited by the NEA Server in the
first SASL Authentication Data TLV request.
3.8.9. SASL Authentication Data
This TLV carries an opaque (to PT-TLS) blob of octets being exchanged
between the NEA Client and the NEA Server. This TLV facilitates
their communications without interpreting any of the bytes. The SASL
Authentication Data TLV MUST NOT be sent until a SASL mechanism has
been established for a session. The SASL Authentication Data TLV
associated with the current authentication mechanism MUST NOT be sent
after a SASL Result is sent with a Result Code of Success.
Additional SASL Authentication Data TLVs would be sent if the PT-TLS
Initiator and Responder desire a subsequent SASL authentication to
occur but only after another SASL mechanism selection exchange
occurs.
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
~ SASL Mechanism Data (Variable Length) ~
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
SASL Mechanism Data
Opaque, variable-length set of bytes exchanged between the PT-TLS
Initiator's SASL mechanism and its peer PT-TLS Responder's SASL
mechanism. These bytes MUST NOT be interpreted by the PT-TLS
layer.
Sangster, et al. Standards Track [Page 27]
RFC 6876 PT-TLS February 2013
3.8.10. SASL Result
This TLV is sent by the NEA Server at the conclusion of the SASL
exchange to indicate the authentication result. Upon reception of a
SASL Result TLV indicating an Abort, the NEA Client MUST terminate
the current authentication conversation. The recipient may retry the
authentication in the event of an authentication failure. Similarly,
the NEA Server may request that additional SASL authentication(s) be
performed after the completion of a SASL mechanism by sending another
SASL Mechanisms TLV including any mechanisms dictated by its policy.
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Result Code | Optional Result Data |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| . . . . . . . . . . . |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
Result Code
This field contains the result of the SASL authentication
exchange.
Value (Name) Definition
--------------------- -------------------------------------------
0 (Success) SASL authentication was successful, and
identity was confirmed.
1 (Failure) SASL authentication failed. This might be
caused by the client providing an invalid
user identity and/or credential pair. Note
that this is not the same as a mechanism's
failure to process the authentication as
reported by the Mechanism Failure code.
2 (Abort) SASL authentication exchange was aborted by
the sender.
3 (Mechanism Failure) SASL "mechanism failure" during the
processing of the client's authentication
(e.g., not related to the user's input).
For example, this could occur if the
mechanism is unable to allocate memory
(e.g., malloc) that is needed to process a
received SASL mechanism message.
Sangster, et al. Standards Track [Page 28]
RFC 6876 PT-TLS February 2013
Optional Result Data
This field contains a variable-length set of additional data for a
successful result. This field MUST be zero length unless the NEA
Server is returning a Result Code of Success and has more data to
return. For more information on the additional data with success
in SASL, see RFC 4422.
3.9. Error Message
This section describes the format and contents of the PT-TLS Error
message sent by the NEA Client or NEA Server when it detects a
PT-TLS-level protocol error. Each error message contains an error
code indicating the error that occurred, followed by a copy of the
message that caused the error.
When a PT-TLS error is received, the recipient MUST NOT respond with
a PT-TLS error, because this could result in an infinite loop of
error messages being sent. Instead, the recipient MAY log the error,
modify its behavior to avoid future errors, ignore the error,
terminate the assessment, or take other action as appropriate (as
long as it is consistent with the requirements of this
specification).
The Message Value portion of a PT-TLS Error message contains the
following information:
1 2 3
0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Reserved | Error Code Vendor ID |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Error Code |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| Copy of Original Message (Variable Length) |
+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
| . . . . . . . |
Reserved
Reserved for future use. This field MUST be set to 0 on
transmission and ignored upon reception.
Sangster, et al. Standards Track [Page 29]
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Error Code Vendor ID
This field contains the IANA-assigned SMI Private Enterprise
Number for the vendor whose Error Code namespace is being used in
the message. For IETF namespace Error Code values, this field
MUST be set to zero (0). For other vendor-defined Error Code
namespaces, this field MUST be set to the SMI Private Enterprise
Number of the vendor.
Error Code
This field contains the error code. This error code exists within
the scope of Error Code Vendor ID in this message. Posture
Transport Clients and Posture Transport Servers MUST NOT require
support for particular vendor-specific PT-TLS Error Codes in order
to interoperate with other PT-TLS-compliant implementations
(although implementations MAY permit administrators to configure
them to require support for specific PT-TLS Error Codes).
When the Error Code Vendor ID is set to the IETF Private
Enterprise Number, the following table lists the initial supported
IETF-defined numeric error codes:
Value (Name) Definition
------------------------- ---------------------------------------
0 (Reserved) Reserved value indicates that the
PT-TLS Error message SHOULD be ignored
by all recipients. This MAY be used
for debugging purposes to allow a
sender to see a copy of the message
that was received.
1 (Malformed Message) PT-TLS message unrecognized or
unsupported. This error code SHOULD be
sent when the basic message content
sanity test fails. The sender of this
error code MUST consider it a fatal
error and abort the assessment.
2 (Version Not Supported) This error SHOULD be sent when a PT-TLS
Responder receives a PT-TLS Version
Request message containing a range of
version numbers that doesn't include
any version numbers that the recipient
is willing and able to support on the
session. All PT-TLS messages carrying
the Version Not Supported error code
MUST use a version number of 1. All
Sangster, et al. Standards Track [Page 30]
RFC 6876 PT-TLS February 2013
parties that receive or send PT-TLS
messages MUST be able to properly
process an error message that meets
this description, even if they cannot
process any other aspect of PT-TLS
version 1. The sender and receiver of
this error code MUST consider it a
fatal error and close the TLS session
after sending or receiving this PT-TLS
message.
3 (Type Not Supported) PT-TLS Message Type unknown or not
supported. When a recipient receives a
PT-TLS Message Type that it does not
support, it MUST send back this error,
ignore the message, and proceed. For
example, this could occur if the sender
used a Vendor ID for the Message Type
that is not supported by the recipient.
This error message does not indicate
that a fatal error has occurred, so the
assessment is allowed to continue.
4 (Invalid Message) PT-TLS message received was invalid
based on the protocol state. For
example, this error would be sent if a
recipient receives a message associated
with the PT-TLS Negotiation Phase (such
as Version messages) after the protocol
has reached the PT-TLS Data Transport
Phase. The sender and receiver of this
error code MUST consider it a fatal
error and close the TLS session after
sending or receiving this PT-TLS
message.
5 (SASL Mechanism Error) A fatal error occurred while trying to
perform the client authentication. For
example, the NEA Client is unable to
support any of the offered SASL
mechanisms. The sender and receiver of
this error code MUST consider it a
fatal error and close the TLS session
after sending or receiving this PT-TLS
message.
Sangster, et al. Standards Track [Page 31]
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6 (Invalid Parameter) The PT-TLS Error message sender has
received a message with an invalid or
unsupported value in the PT-TLS header.
This could occur if the NEA Client
receives a PT-TLS message from the NEA
Server with a Message Length of zero
(see Section 3.5 for details). The
sender and receiver of this error code
MUST consider it a fatal error and
close the TLS session after sending or
receiving this PT-TLS message.
Copy of Original Message
This variable-length value MUST contain a copy (up to 1024 bytes)
of the original PT-TLS message that caused the error. If the
original message is longer than 1024 bytes, only the initial 1024
bytes will be included in this field. This field is included so
the error recipient can determine which message sent caused the
error. In particular, the recipient can use the Message
Identifier field from the Copy of Original Message data to
determine which message caused the error.
4. Security Considerations
This section discusses the major threats potentially faced by each
binding of the PT protocol and countermeasures provided by the PT-TLS
protocol.
4.1. Trust Relationships
In order to understand where security countermeasures are necessary,
this section starts with a discussion of where the NEA architecture
envisions some trust relationships between the processing elements of
the PT-TLS protocol. Implementations or deployments where these
trust relationships are not present would need to provide additional
countermeasures to ensure the proper operation and security of PT-TLS
(which relies upon these relationships to be trustworthy). The
following subsections discuss the trust properties associated with
each portion of the NEA reference model directly involved with the
processing of the PT-TLS protocol.
Sangster, et al. Standards Track [Page 32]
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4.1.1. Posture Transport Client
The Posture Transport Client is trusted by the Posture Broker
Client to:
o Not observe, fabricate, or alter the contents of the PB-TNC
batches received from the network
o Not observe, fabricate, or alter the PB-TNC batches passed down
from the Posture Broker Client for transmission on the network
o Transmit on the network any PB-TNC batches passed down from the
Posture Broker Client
o Deliver properly security protected messages received from the
network that are destined for the Posture Broker Client
o Provide configured security protections (e.g., authentication,
integrity, and confidentiality) for the Posture Broker Client's
PB-TNC batches sent on the network
o Expose the authenticated identity of the Posture Transport Server
only to the PB-TNC layer within the NEA Client
o Verify the security protections placed upon messages received from
the network to ensure that the messages are authentic and
protected from attacks on the network
o Provide a secure, reliable, "in-order delivery", full-duplex
transport for the Posture Broker Client's messages
The Posture Transport Client is trusted by the Posture Transport
Server to:
o Not send malicious traffic intending to harm (e.g., denial of
service) the Posture Transport Server
o Not send malformed messages (e.g., messages lacking a PT-TLS
header)
o Not send invalid or incorrect responses to messages (e.g., errors
when no error is warranted)
o Not ignore or drop messages when such an action would cause issues
for the protocol processing (e.g., dropping PT-TLS SASL
Authentication Data messages)
Sangster, et al. Standards Track [Page 33]
RFC 6876 PT-TLS February 2013
o Verify the security protections placed upon messages received from
the network to ensure that the messages are authentic and
protected from attacks on the network
4.1.2. Posture Transport Server
The Posture Transport Server is trusted by the Posture Broker
Server to:
o Not observe, fabricate, or alter the contents of the PB-TNC
batches received from the network
o Not observe, fabricate, or alter the PB-TNC batches passed down
from the Posture Broker Server for transmission on the network
o Transmit on the network any PB-TNC batches passed down from the
Posture Broker Server
o Deliver properly security protected messages received from the
network that are destined for the Posture Broker Server
o Provide configured security protections (e.g., authentication,
integrity, and confidentiality) for the Posture Broker Server's
messages sent on the network
o Expose the authenticated identity of the Posture Transport Client
only to the PB-TNC layer within the NEA Server
o Verify the security protections placed upon messages received from
the network to ensure that the messages are authentic and
protected from attacks on the network
o Provide a secure, reliable, "in-order delivery", full-duplex
transport for the Posture Broker Server's messages
The Posture Transport Server is trusted by the Posture Transport
Client to:
o Not send malicious traffic intending to harm (e.g., denial of
service) the Posture Transport Client
o Not send malformed messages (e.g., messages lacking a PT-TLS
header)
o Not send invalid or incorrect responses to messages (e.g., errors
when no error is warranted)
Sangster, et al. Standards Track [Page 34]
RFC 6876 PT-TLS February 2013
o Not ignore or drop messages when such an action would cause issues
for the protocol processing (e.g., dropping PT-TLS SASL Result
messages)
o Verify the security protections placed upon messages received from
the network to ensure that the messages are authentic and
protected from attacks on the network
4.2. Security Threats and Countermeasures
Beyond the trust relationships assumed in Section 4.1, the PT-TLS
protocol faces a number of potential security attacks that could
require security countermeasures.
Generally, the PT-TLS protocol is responsible for offering strong
security protections for all of the NEA protocols, so any threats to
its ability to protect NEA protocol messages could be very damaging
to deployments. Once the message is delivered to the Posture Broker
Client or Posture Broker Server, the posture brokers are trusted to
properly and safely process the messages.
4.2.1. Message Theft
When PT-TLS messages are sent over unprotected network links or
spanning local software stacks that are not trusted, the contents of
the messages may be subject to information theft by an intermediary
party. This theft could result in information being recorded for
future use or analysis by the adversary. Messages observed by
eavesdroppers could contain information that exposes potential
weaknesses in the security of the endpoint, or system fingerprinting
information; this information would make it easier for the attacker
to employ attacks more likely to be successful against the endpoint.
The eavesdropper might also learn information about the endpoint or
network policies that either singularly or collectively is considered
sensitive information. For example, if PT-TLS does not provide
confidentiality protection, an adversary could observe the PA-TNC
attributes included in the PT-TLS message and determine that the
endpoint is lacking patches or that particular sub-networks have more
lenient policies.
In order to protect against NEA assessment message theft, the PT-TLS
protocol provides strong cryptographic authentication, integrity, and
confidentiality protection. Deployers are strongly encouraged to
employ "best practice of the day" TLS ciphers to ensure that the
information remains safe despite advances in technology and
discovered cipher weaknesses. The use of bidirectional
authentication of the assessment transport session ensures that only
properly authenticated and authorized parties may be involved in an
Sangster, et al. Standards Track [Page 35]
RFC 6876 PT-TLS February 2013
assessment dialog. The PT-TLS protocol also provides strong
cryptography for all of the PB-TNC and PA-TNC protocol messages
traveling over the network, allowing the message contents to be
hidden from potential theft by the adversary even if the attacker is
able to observe the encrypted PT-TLS session.
4.2.2. Message Fabrication
Attackers on the network or present within the NEA system could
introduce fabricated PT-TLS messages intending to trick or create a
denial of service against aspects of an assessment. For example, an
adversary could attempt to insert into the message exchange fake
PT-TLS Error Codes in order to disrupt communications.
The PT-TLS protocol provides strong security protections for the
complete message exchange over the network. These security
protections prevent an intermediary from being able to insert fake
messages into the assessment. In particular, TLS's use of hashing
algorithms provides strong integrity protections that allow for
detection of any changes in the content of the message stream.
Additionally, adversaries are unable to observe the PT-TLS protocol
exchanges because they are encrypted by the TLS ciphers and so would
have difficulty determining where to insert the falsified message,
since the attacker is unable to determine where the message
boundaries exist. Even if a successful message insertion did occur,
the recipient would be able to detect it due to failure of the TLS
cipher suite's integrity check.
4.2.3. Message Modification
This attack could allow an active attacker capable of intercepting a
message to modify a PT-TLS message or transported PA-TNC attribute to
a desired value to make it easier to compromise an endpoint. Without
the ability for message recipients to detect whether a received
message contains the same content as what was originally sent, active
attackers can stealthily modify the attribute exchange.
The PT-TLS protocol leverages the TLS protocol to provide strong
authentication and integrity protections as a countermeasure to this
threat. The bidirectional authentication prevents the attacker from
acting as an active man-in-the-middle to the protocol that could be
used to modify the message exchange. The strong integrity protection
(e.g., hashing) offered by TLS allows PT-TLS message recipients to
detect message alterations by other types of network-based
adversaries.
Sangster, et al. Standards Track [Page 36]
RFC 6876 PT-TLS February 2013
4.2.4. Denial of Service
A variety of types of denial-of-service attacks are possible against
the PT-TLS protocol if the message exchanges are left unprotected
while traveling over the network. The Posture Transport Client and
Posture Transport Server are trusted not to participate in the denial
of service of the assessment session, leaving the threats to come
from the network.
The PT-TLS protocol provides bidirectional authentication
capabilities in order to prevent a man-in-the-middle on the network
from becoming an undetected active proxy of PT-TLS messages. Because
the PT-TLS protocol runs after the TLS handshake and thus cipher
establishment/use, all of the PT-TLS messages are protected from
undetected modification that could create a denial-of-service
situation. However, it is possible for an adversary to alter the
message flows, causing each message to be rejected by the recipient
because it fails the integrity checking.
The PT-TLS protocol operates as an application protocol on top of TLS
and thus TCP/IP protocols, so is subject to denial-of-service attacks
against the TLS, TCP, and IP protocols.
4.2.5. NEA Asokan Attacks
As described in Section 3.3 and in [RFC6813], a sophisticated MITM
attack can be mounted against NEA systems. The attacker forwards
PA-TNC messages from a healthy machine through an unhealthy one so
that the unhealthy machine can gain network access. Section 3.3 and
[RFC6813] provide a detailed description of this attack and of the
countermeasures that can be employed against it.
Because lying endpoint attacks are much easier than Asokan attacks
and the only known effective countermeasure against lying endpoint
attacks is the use of an External Measurement Agent (EMA),
countermeasures against an Asokan attack are not necessary unless an
EMA is in use. However, PT-TLS implementers may not know whether an
EMA will be used with their implementation. Therefore, PT-TLS
implementers SHOULD support the Asokan attack countermeasures
described in Section 3.3 by providing the value of the tls-unique
channel binding to higher layers in the NEA reference model: Posture
Broker Clients, Posture Broker Servers, Posture Collectors, and
Posture Validators.
The Asokan attack can also apply to authentication mechanisms carried
within TLS. SASL mechanisms providing channel bindings use the
tls-unique channel-binding data as defined in Section 3.3 to protect
against the attack.
Sangster, et al. Standards Track [Page 37]
RFC 6876 PT-TLS February 2013
4.2.6. Trust Anchors
The TLS protocol bases its trust decision about the signer of the
certificates received during the TLS authentication on using a set of
trust anchor certificates. It is essential that these trust anchor
certificates are integrity protected from unauthorized modification.
Many common software components (e.g., browsers, operating systems,
security protocols) include a set of trust anchor certificates that
are relevant to their operation. The PT-TLS SHOULD use a PT-TLS-
specific set of trust anchor certificates in order to limit what
Certificate Authorities are authorized to issue certificates for use
with NEA.
5. Privacy Considerations
The role of PT-TLS is to act as a secure transport for PB-TNC and
other higher-layer protocols. As such, PT-TLS does not directly
utilize personally identifiable information (PII) except when client
authentication is enabled. When client authentication is being used,
the NEA Client will be asked to use SASL, which may disclose a local
identifier (e.g., username) associated with the endpoint and an
authenticator (e.g., password) to authenticate that identity.
Because the identity and authenticator are potentially privacy-
sensitive information, the NEA Client MUST offer a mechanism to
restrict which NEA Servers will be sent this information. Similarly,
the NEA Client SHOULD provide an indication to the person being
identified that a request for their identity has been made in case
they choose to opt out of the authentication to remain anonymous
unless no user interface is available. PT-TLS provides cryptographic
peer authentication, message integrity, and data confidentiality
protections to higher-layer NEA protocols that may exchange data
potentially including PII. These security services can be used to
protect any PII involved in an assessment from passive and active
attackers on the network. Endpoints sending potentially privacy-
sensitive information SHOULD ensure that the PT-TLS security
protections (TLS cipher suites) negotiated for an assessment of the
endpoint are adequate to avoid interception and off-line attacks of
any long-term privacy-sensitive information unless other network
protections are already present.
6. IANA Considerations
Per this specification, two new IANA registries have been created and
a TCP port number has been assigned. IANA has permanently reserved
the early allocated TCP port number 271 for use with the PT-TLS
protocol.
Sangster, et al. Standards Track [Page 38]
RFC 6876 PT-TLS February 2013
This section defines the contents of two new IANA registries, PT-TLS
Message Types and PT-TLS Error Codes, and explains how these
registries work.
Each of the registries defined in this document support IETF-defined
values and vendor-defined values. To explain this phenomenon, we
will use the PT-TLS Message Type as an example, but the other
registry works the same way.
Whenever a PT-TLS Message Type appears on a network, it is always
accompanied by an SMI Private Enterprise Number (PEN), also known as
a vendor ID. If this vendor ID is zero, the accompanying PT-TLS
Message Type is an IETF namespace value listed in the IANA registry
for PT-TLS Message Types, and its meaning is defined in the
specification listed for that PT-TLS Message Type in that registry.
If the vendor ID is not zero, the meaning of the PT-TLS Message Type
is defined by the vendor identified by the vendor ID (as listed in
the IANA registry for SMI PENs). The identified vendor is encouraged
but not required to register with IANA some or all of the PT-TLS
Message Types used with their vendor ID and publish a specification
for each of these values.
6.1. Designated Expert Guidelines
For each of the IANA registries defined by this specification, new
values are added to the registry by following the IANA Specification
Required policy [RFC5226].
This section provides guidance to designated experts so that they may
make decisions using a philosophy appropriate for these registries.
The registries defined in this document have plenty of values. In
most cases, the IETF has approximately 2^32 values available for it
to define, and each vendor has the same number of values for its use.
Because there are so many values available, designated experts should
not be terribly concerned about exhausting the set of values.
Instead, designated experts should focus on the following
requirements. All values in these IANA registries are required to be
documented in a specification that is permanently and publicly
available. IETF namespace values must also be useful not harmful to
the Internet, and defined in a manner that is clear and likely to
ensure interoperability.
Designated experts should encourage vendors to avoid defining similar
but incompatible values and instead agree on a single IETF-reviewed
approach and value. However, it is beneficial to document existing
practice.
Sangster, et al. Standards Track [Page 39]
RFC 6876 PT-TLS February 2013
There are several ways to ensure that a specification is permanently
and publicly available. It may be published as an RFC.
Alternatively, it may be published in another manner that makes it
freely available to anyone. However, in this latter case, the vendor
will need to supply a copy to the IANA and authorize the IANA to
archive this copy and make it freely available to all if at some
point the document becomes no longer freely available to all through
other channels.
The following two sections provide guidance to the IANA in creating
and managing the new IANA registries defined by this specification.
6.2. Registry for PT-TLS Message Types
The name for this registry is "PT-TLS Message Types". Each entry in
this registry should include a human-readable name, an SMI Private
Enterprise Number, a decimal integer value between 0 and 4294967294,
and a reference to the specification where the contents of this
message type are defined. This specification must define the meaning
of the PT-TLS Message Type and the format and semantics of the PT-TLS
Message Value field that include the designated Private Enterprise
Number in the PT-TLS Message Type Vendor ID field and the designated
numeric value in the PT-TLS Message Type field.
The following entries for this registry are defined in this document.
Additional entries to this registry are added by following the IANA
Specification Required policy, consistent with the guidelines in
Section 6.1.
PEN Value Name Reference
--- -------- ------------------------ ---------
0 0 Experimental RFC 6876
0 1 Version Request RFC 6876
0 2 Version Response RFC 6876
0 3 SASL Mechanisms RFC 6876
0 4 SASL Mechanism Selection RFC 6876
0 5 SASL Authentication Data RFC 6876
0 6 SASL Result RFC 6876
0 7 PB-TNC Batch RFC 6876
0 8 PT-TLS Error RFC 6876
0 9-4294967294 Unassigned
0 4294967295 Reserved RFC 6876
The PEN 0 (IETF) PT-TLS Message Type values between 9 and 4294967294
inclusive are allocated for future assignment by the IANA.
Sangster, et al. Standards Track [Page 40]
RFC 6876 PT-TLS February 2013
6.3. Registry for PT-TLS Error Codes
The name for this registry is "PT-TLS Error Codes". Each entry in
this registry should include a human-readable name, an SMI Private
Enterprise Number, a decimal integer value between 0 and 4294967295,
and a reference to the specification where this error code is
defined. This specification must define the meaning of this error
code, a PT-TLS Message Type of PT-TLS Error, the designated Private
Enterprise Number in the PT-TLS Error Code Vendor ID field, and the
designated numeric value in the PT-TLS Error Code field.
The following entries for this registry are defined in this document.
Additional entries to this registry are added following the IANA
Specification Required policy, consistent with the guidelines in
Section 6.1.
PEN Value Name Reference
--- ------------ --------------------- ---------
0 0 Reserved RFC 6876
0 1 Malformed Message RFC 6876
0 2 Version Not Supported RFC 6876
0 3 Type Not Supported RFC 6876
0 4 Invalid Message RFC 6876
0 5 SASL Mechanism Error RFC 6876
0 6 Invalid Parameter RFC 6876
0 7-4294967295 Unassigned
The PEN 0 (IETF) PT-TLS Error Codes between 7 and 4294967295
inclusive are allocated for future assignment by the IANA.
7. Acknowledgments
Thanks to the Trusted Computing Group for contributing the initial
text upon which this document was based [IFT-TLS].
The authors of this document would also like to acknowledge the
following people who have contributed to or provided substantial
input on the preparation of this document or predecessors to it: Syam
Appala, Stuart Bailey, Lauren Giroux, Steve Hanna, Josh Howlett,
Scott Kelly, Carolin Latze, Sung Lee, Lisa Lorenzin, Alexey Melnikov,
Ravi Sahita, Subbu Srinivasan, Susan Thomson, and Mark Townsend.
Sangster, et al. Standards Track [Page 41]
RFC 6876 PT-TLS February 2013
8. References
8.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC4422] Melnikov, A., Ed., and K. Zeilenga, Ed., "Simple
Authentication and Security Layer (SASL)", RFC 4422,
June 2006.
[RFC4616] Zeilenga, K., Ed., "The PLAIN Simple Authentication and
Security Layer (SASL) Mechanism", RFC 4616, August 2006.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
[RFC5246] Dierks, T. and E. Rescorla, "The Transport Layer Security
(TLS) Protocol Version 1.2", RFC 5246, August 2008.
[RFC5280] Cooper, D., Santesson, S., Farrell, S., Boeyen, S.,
Housley, R., and W. Polk, "Internet X.509 Public Key
Infrastructure Certificate and Certificate Revocation
List (CRL) Profile", RFC 5280, May 2008.
[RFC5746] Rescorla, E., Ray, M., Dispensa, S., and N. Oskov,
"Transport Layer Security (TLS) Renegotiation Indication
Extension", RFC 5746, February 2010.
[RFC5792] Sangster, P. and K. Narayan, "PA-TNC: A Posture Attribute
(PA) Protocol Compatible with Trusted Network Connect
(TNC)", RFC 5792, March 2010.
[RFC5793] Sahita, R., Hanna, S., Hurst, R., and K. Narayan,
"PB-TNC: A Posture Broker (PB) Protocol Compatible with
Trusted Network Connect (TNC)", RFC 5793, March 2010.
[RFC5929] Altman, J., Williams, N., and L. Zhu, "Channel Bindings
for TLS", RFC 5929, July 2010.
[RFC6125] Saint-Andre, P. and J. Hodges, "Representation and
Verification of Domain-Based Application Service Identity
within Internet Public Key Infrastructure Using X.509
(PKIX) Certificates in the Context of Transport Layer
Security (TLS)", RFC 6125, March 2011.
Sangster, et al. Standards Track [Page 42]
RFC 6876 PT-TLS February 2013
[RFC6520] Seggelmann, R., Tuexen, M., and M. Williams, "Transport
Layer Security (TLS) and Datagram Transport Layer
Security (DTLS) Heartbeat Extension", RFC 6520,
February 2012.
8.2. Informative References
[IFT-TLS] Trusted Computing Group, "TNC IF-T: Binding to TLS",
<http://www.trustedcomputinggroup.org/>, May 2009.
[PEN] IANA Private Enterprise Numbers (PEN) registry,
<http://www.iana.org/assignments/enterprise-numbers>.
[PT-EAP] Cam-Winget, N. and P. Sangster, "PT-EAP: Posture
Transport (PT) Protocol For EAP Tunnel Methods", Work in
Progress, January 2013.
[RFC2246] Dierks, T. and C. Allen, "The TLS Protocol Version 1.0",
RFC 2246, January 1999.
[RFC4346] Dierks, T. and E. Rescorla, "The Transport Layer Security
(TLS) Protocol Version 1.1", RFC 4346, April 2006.
[RFC5209] Sangster, P., Khosravi, H., Mani, M., Narayan, K., and J.
Tardo, "Network Endpoint Assessment (NEA): Overview and
Requirements", RFC 5209, June 2008.
[RFC5801] Josefsson, S. and N. Williams, "Using Generic Security
Service Application Program Interface (GSS-API)
Mechanisms in Simple Authentication and Security Layer
(SASL): The GS2 Mechanism Family", RFC 5801, July 2010.
[RFC6813] Salowey, J. and S. Hanna, "The Network Endpoint
Assessment (NEA) Asokan Attack Analysis", RFC 6813,
December 2012.
Sangster, et al. Standards Track [Page 43]
RFC 6876 PT-TLS February 2013
Authors' Addresses
Paul Sangster
Symantec Corporation
6825 Citrine Dr.
Carlsbad, CA 92009
EMail: paul_sangster@symantec.com
Nancy Cam-Winget
Cisco Systems
80 West Tasman Drive
San Jose, CA 95134
US
EMail: ncamwing@cisco.com
Joseph Salowey
Cisco Systems
2901 Third Avenue
Seattle, WA 98121
US
EMail: jsalowey@cisco.com
Sangster, et al. Standards Track [Page 44]
ERRATA