| Rfc | 5403 |
|---|
| Title | RPCSEC_GSS Version 2 |
|---|
| Author | M. Eisler |
|---|
| Date | February 2009 |
|---|
| Format: | TXT, HTML |
|---|
| Updates | RFC2203 |
|---|
| Updated by | RFC7861 |
|---|
| Status: | PROPOSED STANDARD |
|---|
|
Network Working Group M. Eisler
Request for Comments: 5403 NetApp
Updates: 2203 February 2009
Category: Standards Track
RPCSEC_GSS Version 2
Status of This Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (c) 2009 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.
Abstract
This document describes version 2 of the RPCSEC_GSS protocol.
Version 2 is the same as version 1 (specified in RFC 2203) except
that support for channel bindings has been added. RPCSEC_GSS allows
remote procedure call (RPC) protocols to access the Generic Security
Services Application Programming Interface (GSS-API).
Table of Contents
1. Introduction and Motivation .....................................2
1.1. Requirements Language ......................................3
2. Channel Bindings Explained ......................................3
3. The RPCSEC_GSSv2 Protocol .......................................4
3.1. Compatibility with RPCSEC_GSSv1 ............................4
3.2. New Version Number .........................................5
3.3. New Procedure - RPCSEC_GSS_BIND_CHANNEL ....................7
3.4. New Security Service - rpc_gss_svc_channel_prot ...........10
4. Version Negotiation ............................................11
5. Native GSS Channel Bindings ....................................11
6. Operational Recommendation for Deployment ......................11
7. Implementation Notes ...........................................11
8. Acknowledgments ................................................11
9. Security Considerations ........................................11
10. References ....................................................13
10.1. Normative References .....................................13
10.2. Informative References ...................................14
1. Introduction and Motivation
This document describes RPCSEC_GSS version 2 (RPCSEC_GSSv2).
RPCSEC_GSSv2 is the same as RPCSEC_GSS version 1 (RPCSEC_GSSv1) [1]
except that support for channel bindings [2] has been added. The
primary motivation for channel bindings is to securely take advantage
of hardware-assisted encryption that might exist at lower levels of
the networking protocol stack, such as at the Internet Protocol (IP)
layer in the form of IPsec (see [7] and [8] for information on IPsec
channel bindings). The secondary motivation is that even if lower
levels are not any more efficient at encryption than the RPCSEC_GSS
layer, if encryption is occurring at the lower level, it can be
redundant at the RPCSEC_GSS level.
RPCSEC_GSSv2 and RPCSEC_GSSv1 are protocols that exchange tokens
emitted by the Generic Security Services (GSS) framework, which is
defined in [3], and differ only in the support for GSS channel
bindings in RPCSEC_GSSv2. GSS itself supports channel bindings, and
in theory RPCSEC_GSSv2 could use native GSS channel bindings to
achieve the effects described in this section. However, as Section
1.1.6 of [3] states, not all implementations of all GSS mechanisms
support channel bindings. This is sufficient justification for the
approach taken in this document: modify the RPCSEC_GSS protocol to
support channel bindings independent of the capabilities of the GSS
mechanism being used.
Once an RPCSEC_GSS target and initiator are mutually assured that
they are each using the same secure, end-to-end channel, the overhead
of computing message integrity codes (MICs) for authenticating and
integrity-protecting RPC requests and replies can be eliminated
because the channel is performing the same function. Similarly, if
the channel also provides confidentiality, the overhead of RPCSEC_GSS
privacy protection can also be eliminated.
The External Data Representation (XDR) [4] description is provided in
this document in a way that makes it simple for the reader to extract
into a ready-to-compile form. The reader can feed this document into
the following shell script to produce the machine-readable XDR
description of RPCSEC_GSSv2:
<CODE BEGINS>
#!/bin/sh
grep "^ *///" | sed 's?^ *///??'
<CODE ENDS>
That is, if the above script is stored in a file called "extract.sh",
and this document is in a file called "spec.txt", then the reader can
do:
<CODE BEGINS>
sh extract.sh < spec.txt > rpcsec_gss_v2.x
<CODE ENDS>
The effect of the script is to remove leading white space from each
line of the specification, plus a sentinel sequence of "///".
1.1. Requirements Language
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 [5].
2. Channel Bindings Explained
If a channel between two parties is secure, there must be shared
information between the two parties. This information might be
secret or not. The requirement for secrecy depends on the specifics
of the channel.
For example, the shared information could be the concatenation of the
public key of the source and destination of the channel (where each
public key has a corresponding private key). Suppose the channel is
not end-to-end, i.e., a man-in-the-middle (MITM) exists, and there
are two channels, one from the initiator to the MITM, and one from
the MITM to the target. The MITM cannot simply force each channel to
use the same public keys, because a public key derives from a private
key, and the key management system for each node will surely assign
unique or random private keys. At most, the MITM can force one end
of each channel to use the same public key. The MIC of the public
keys from the initiator will not be verified by the target, because
at least one of the public keys will be different. Similarly, the
MIC of the public keys from the target will not be verified by the
initiator because at least one of the public keys will be different.
A higher-layer protocol using the secure channel can safely exploit
the channel to the mutual benefit of the higher-level parties if each
higher-level party can prove:
o They each know the channel's shared information.
o The proof of the knowledge of the shared information is in fact
being conveyed by each of the higher-level parties, and not some
other entities.
RPCSEC_GSSv2 simply adds an optional round-trip that has the
initiator compute a GSS MIC on the channel binding's shared
information, and sends the MIC to the target. The target verifies
the MIC, and in turn sends its own MIC of the shared information to
the initiator that then verifies the target's MIC. This accomplishes
three things. First, the initiator and target are mutually
authenticated. Second, the initiator and target prove they know the
channel's shared information, and thus are using the same channel.
Third, the first and second things are done simultaneously.
3. The RPCSEC_GSSv2 Protocol
The RPCSEC_GSSv2 protocol will now be explained. The entire protocol
is not presented. Instead the differences between RPCSEC_GSSv2 and
RPCSEC_GSSv1 are shown.
3.1. Compatibility with RPCSEC_GSSv1
The functionality of RPCSEC_GSSv1 is fully supported by RPCSEC_GSSv2.
3.2. New Version Number
<CODE BEGINS>
/// /*
/// * Copyright (c) 2009 IETF Trust and the persons identified
/// * as the document authors. All rights reserved.
/// *
/// * The document authors are identified in [RFC2203] and
/// * [RFC5403].
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/// * or without modification, are permitted provided that the
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/// *
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/// * following disclaimer.
/// *
/// * o Redistributions in binary form must reproduce the above
/// * copyright notice, this list of conditions and the
/// * following disclaimer in the documentation and/or other
/// * materials provided with the distribution.
/// *
/// * o Neither the name of Internet Society, IETF or IETF
/// * Trust, nor the names of specific contributors, may be
/// * used to endorse or promote products derived from this
/// * software without specific prior written permission.
/// *
/// * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS
/// * AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED
/// * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
/// * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
/// * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
/// * EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
/// * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
/// * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
/// * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
/// * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
/// * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
/// * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
/// * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
/// * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
/// * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
/// */
/// /*
/// * This code was derived from [RFC2203]. Please
/// * reproduce this note if possible.
/// */
///
/// enum rpc_gss_service_t {
/// /* Note: the enumerated value for 0 is reserved. */
/// rpc_gss_svc_none = 1,
/// rpc_gss_svc_integrity = 2,
/// rpc_gss_svc_privacy = 3,
/// rpc_gss_svc_channel_prot = 4 /* new */
/// };
///
/// enum rpc_gss_proc_t {
/// RPCSEC_GSS_DATA = 0,
/// RPCSEC_GSS_INIT = 1,
/// RPCSEC_GSS_CONTINUE_INIT = 2,
/// RPCSEC_GSS_DESTROY = 3,
/// RPCSEC_GSS_BIND_CHANNEL = 4 /* new */
/// };
///
/// struct rpc_gss_cred_vers_1_t {
/// rpc_gss_proc_t gss_proc; /* control procedure */
/// unsigned int seq_num; /* sequence number */
/// rpc_gss_service_t service; /* service used */
/// opaque handle<>; /* context handle */
/// };
///
/// const RPCSEC_GSS_VERS_1 = 1;
/// const RPCSEC_GSS_VERS_2 = 2; /* new */
///
/// union rpc_gss_cred_t switch (unsigned int rgc_version) {
/// case RPCSEC_GSS_VERS_1:
/// case RPCSEC_GSS_VERS_2: /* new */
/// rpc_gss_cred_vers_1_t rgc_cred_v1;
/// };
///
<CODE ENDS>
Figure 1
As is apparent from the above, the RPCSEC_GSSv2 credential has the
same format as the RPCSEC_GSSv1 credential (albeit corrected so that
the definition is in legal XDR description language that is also
compatible with [9]; hence, the field "version", a keyword in RFC
1831, is replaced with "rgc_version"). Setting the rgc_version field
to 2 indicates that the initiator and target support channel
bindings.
3.3. New Procedure - RPCSEC_GSS_BIND_CHANNEL
<CODE BEGINS>
/// struct rgss2_bind_chan_MIC_in_args {
/// opaque rbcmia_bind_chan_hash<>;
/// };
///
/// typedef opaque rgss2_chan_pref<>;
/// typedef opaque rgss2_oid<>;
///
/// struct rgss2_bind_chan_verf_args {
/// rgss2_chan_pref rbcva_chan_bind_prefix;
/// rgss2_oid rbcva_chan_bind_oid_hash;
/// opaque rbcva_chan_mic<>;
/// };
///
<CODE ENDS>
Figure 2
Once an RPCSEC_GSSv2 handle has been established over a secure
channel, the initiator MAY issue RPCSEC_GSS_BIND_CHANNEL (Figure 1).
Targets MUST support RPCSEC_GSS_BIND_CHANNEL. Like RPCSEC_GSS_INIT
and RPCSEC_GSS_CONTINUE_INIT requests, the NULL RPC procedure MUST be
used. Unlike those two requests, the arguments of the NULL procedure
are not overloaded, because the verifier is of sufficient size for
the purpose of RPCSEC_GSS_BIND_CHANNEL. The gss_proc field is set to
RPCSEC_GSS_BIND_CHANNEL. The seq_num field is set as if gss_proc
were set to RPCSEC_GSS_DATA. The service field is set to
rpc_gss_svc_none. The handle field is set to that of an RPCSEC_GSS
handle as returned by RPCSEC_GSS_INIT or RPCSEC_GSS_CONTINUE_INIT.
The RPCSEC_GSS_BIND_CHANNEL request is similar to the RPCSEC_GSS_DATA
request in that the verifiers of both contain MICs. As described in
Section 5.3.1 of [1], when gss_proc is RPCSEC_GSS_DATA, the verifier
of an RPC request is set to the output of GSS_GetMIC() on the RPC
header. When gss_proc is RPCSEC_GSS_BIND_CHANNEL the verifier of an
RPC request is set to the XDR encoding on a value of data type
rgss2_bind_chan_verf_args, which includes a MIC as described below.
The rgss2_bind_chan_verf_args data type consists of three fields:
o rbcva_chan_bind_prefix. This is the channel binding prefix as
described in [2] up to, but excluding, the colon (ASCII 0x3A) that
separates the prefix from the suffix.
o rbcva_chan_bind_hash_oid. This is the object identifier (OID) of
the hash algorithm used to compute rbcmia_bind_chan_hash. This
field contains an OID encoded in ASN.1 as used by GSS-API in the
mech_type argument to GSS_Init_sec_context ([3]). See [6] for the
OIDs of the SHA one-way hash algorithms.
o rbcva_chan_mic. This is the output of GSS_GetMIC() on the
concatenation of the XDR-encoded RPC header ("up to and including
the credential" as per [1]) and the XDR encoding of an instance of
type data rgss2_bind_chan_MIC_in_args. The data type
rgss2_bind_chan_MIC_in_args consists of one field,
rbcmia_bind_chan_hash, which is a hash of the channel bindings as
defined in [2]. The channel bindings are a "canonical octet
string encoding of the channel bindings", starting "with the
channel bindings prefix followed by a colon (ASCII 0x3A)". The
reason a hash of the channel bindings and not the actual channel
bindings are used to compute rbcva_chan_mic is that some channel
bindings, such as those composed of public keys, can be relatively
large, and thus place a higher space burden on the implementations
to manage. One way hashes consume less space.
<CODE BEGINS>
/// enum rgss2_bind_chan_status {
/// RGSS2_BIND_CHAN_OK = 0,
/// RGSS2_BIND_CHAN_PREF_NOTSUPP = 1,
/// RGSS2_BIND_CHAN_HASH_NOTSUPP = 2
/// };
///
/// union rgss2_bind_chan_res switch
/// (rgss2_bind_chan_status rbcr_stat) {
///
/// case RGSS2_BIND_CHAN_OK:
/// void;
///
/// case RGSS2_BIND_CHAN_PREF_NOTSUPP:
/// rgss2_chan_pref rbcr_pref_list<>;
///
/// case RGSS2_BIND_CHAN_HASH_NOTSUPP:
/// rgss2_oid rbcr_oid_list<>;
/// };
///
/// struct rgss2_bind_chan_MIC_in_res {
/// unsigned int rbcmr_seq_num;
/// opaque rbcmr_bind_chan_hash<>;
/// rgss2_bind_chan_res rbcmr_res;
/// };
///
/// struct rgss2_bind_chan_verf_res {
/// rgss2_bind_chan_res rbcvr_res;
/// opaque rbcvr_mic<>;
/// };
///
<CODE ENDS>
Figure 3
The RPCSEC_GSS_BIND_CHANNEL reply is similar to the RPCSEC_GSS_DATA
reply in that the verifiers of both contain MICs. When gss_proc is
RPCSEC_GSS_DATA, the verifier of an RPC reply is set to the output of
GSS_GetMIC() on the seq_num of the credential of the corresponding
request (as described in Section 5.3.3.2 of [1]). When gss_proc is
RPCSEC_GSS_BIND_CHANNEL, the verifier of an RPC reply is set to the
XDR encoding of an instance of data type rgss2_bind_chan_verf_res,
which includes a MIC as described below. The data type
rgss2_bind_chan_verf_res consists of two fields.
o rbcvr_res. The data type of this field is rgss2_bind_chan_res.
The rgss2_bind_chan_res data type is a switched union consisting
of three cases switched on the status contained in the rbcr_stat
field.
* RGSS2_BIND_CHAN_OK. If this status is returned, the target
accepted the channel bindings, and successfully verified
rbcva_chan_mic in the request. No additional results will be
in rbcvr_res.
* RGSS2_BIND_CHAN_PREF_NOTSUPP. If this status is returned, the
target did not support the prefix in the rbcva_chan_bind_prefix
field of the arguments, and thus the RPCSEC_GSS_BIND_CHANNEL
request was rejected. The target returned a list of prefixes
it does support in the field rbcr_pref_list. Note that a
channel can have multiple channel bindings each with different
prefixes. The initiator is free to pick its preferred prefix.
If the target does not support the prefix, the status
RGSS2_BIND_CHAN_PREF_NOTSUPP will be returned, and the
initiator can select its next most preferred prefix among the
prefixes the target does support.
* RGSS2_BIND_CHAN_HASH_NOTSUPP. If this status is returned, the
target did not support the hash algorithm identified in the
rbcva_chan_bind_hash_oid field of the arguments, and thus the
RPCSEC_GSS_BIND_CHANNEL request was rejected. The target
returned a list of OIDs of hash algorithms it does support in
the field rbcr_oid_list. The array rbcr_oid_list MUST have one
or more elements.
o rbcvr_mic. The value of this field is equal to the output of
GSS_GetMIC() on the XDR encoding of an instance of data type
rgss2_bind_chan_MIC_in_res. The data type
rgss2_bind_chan_MIC_in_res consists of three fields.
* rbcmr_seq_num. The value of this field is equal to the field
seq_num in the RPCSEC_GSS credential (data type
rpc_gss_cred_vers_1_t).
* rbcmr_bind_chan_hash. This is the result of the one way hash
of the channel bindings (including the prefix). If rbcr_stat
is not RGSS2_BIND_CHAN_HASH_NOTSUPP, then the hash algorithm
that is used to compute rbcmr_bind_chan_hash is that identified
by the rbcva_chan_bind_oid_hash field in the arguments to
RPCSEC_GSS_BIND_CHANNEL. If rbcr_stat is
RGSS2_BIND_CHAN_HASH_NOTSUPP, then the hash algorithm used to
compute rbcmr_bind_chan_hash is that identified by
rbcr_oid_list[0] in the results.
* rbcmr_res. The value of this field is equal to the value of
the rbcvr_res field.
3.4. New Security Service - rpc_gss_svc_channel_prot
RPCSEC_GSSv2 targets MUST support rpc_gss_svc_channel_prot.
The rpc_gss_svc_channel_prot service (Figure 1) is valid only if
RPCSEC_GSSv2 is being used, an RPCSEC_GSS_BIND_CHANNEL procedure has
been executed successfully, and the secure channel still exists.
When rpc_gss_svc_channel_prot is used, the RPC requests and replies
are similar to those of rpc_gss_svc_none except that the verifiers on
the request and reply always have the flavor set to AUTH_NONE, and
the contents are zero length.
Note that even though NULL verifiers are used when
rpc_gss_svc_channel_prot is used, non-NULL RPCSEC_GSS credentials are
used. In order to identify the principal sending the request, the
same credential is used as before, except that service field is set
to rpc_gss_svc_channel_prot.
4. Version Negotiation
An initiator that supports version 2 of RPCSEC_GSS simply issues an
RPCSEC_GSS request with the rgc_version field set to
RPCSEC_GSS_VERS_2. If the target does not recognize
RPCSEC_GSS_VERS_2, the target will return an RPC error per Section
5.1 of [1].
The initiator MUST NOT attempt to use an RPCSEC_GSS handle returned
by version 2 of a target with version 1 of the same target. The
initiator MUST NOT attempt to use an RPCSEC_GSS handle returned by
version 1 of a target with version 2 of the same target.
5. Native GSS Channel Bindings
To ensure interoperability, implementations of RPCSEC_GSSv2 SHOULD
NOT transfer tokens between the initiator and target that use native
GSS channel bindings (as defined in Section 1.1.6 of [3]).
6. Operational Recommendation for Deployment
RPCSEC_GSSv2 is a superset of RPCSEC_GSSv1, and so can be used in all
situations where RPCSEC_GSSv1 is used. RPCSEC_GSSv2 should be used
when the new functionality, channel bindings, is desired or needed.
7. Implementation Notes
Once a successful RPCSEC_GSS_BIND_CHANNEL procedure has been
performed on an RPCSEC_GSSv2 context handle, the initiator's
implementation may map application requests for rpc_gss_svc_none and
rpc_gss_svc_integrity to rpc_gss_svc_channel_prot credentials. And
if the secure channel has privacy enabled, requests for
rpc_gss_svc_privacy can also be mapped to rpc_gss_svc_channel_prot.
8. Acknowledgments
Nicolas Williams had the idea for extending RPCSEC_GSS to support
channel bindings. Alex Burlyga, Lars Eggert, Pasi Eronen, and Dan
Romascanu reviewed the document and gave valuable feedback for
improving its readability.
9. Security Considerations
The base security considerations consist of:
o All security considerations from [1].
o All security considerations from [2].
o All security considerations from the actual secure channel being
used.
Even though RPCSEC_GSS_DATA requests that use
rpc_gss_svc_channel_prot protection do not involve construction of
more GSS tokens, the target SHOULD stop allowing RPCSEC_GSS_DATA
requests with rpc_gss_svc_channel_prot protection once the GSS
context expires.
With the use of channel bindings, it becomes extremely critical that
the message integrity code (MIC) used by the GSS mechanism that
RPCSEC_GSS is using be difficult to forge. While this requirement is
true for RPCSEC_GSSv1, and indeed any protocol that uses GSS MICs,
the distinction in the seriousness is that for RPCSEC_GSSv1, forging
a single MIC at most allows the attacker to succeed in injecting one
bogus request. Whereas, with RPCSEC_GSSv2 combined with channel
bindings, by forging a single MIC the attacker will succeed in
injecting bogus requests as long as the channel exists. An example
illustrates. Suppose we have an RPCSEC_GSSv1 initiator, a man-in-
the-middle (MITM), an RPCSEC_GSSv1 target, and an RPCSEC_GSSv2
target. The attack is as follows.
o The MITM intercepts the initiator's RPCSEC_GSSv1 RPCSEC_GSS_INIT
message and changes the version number from 1 to 2 before
forwarding to the RPCSEC_GSSv2 target, and changes the reply's
version number from 2 to 1 before forwarding to the RPCSEC_GSSv1
initiator. Neither the client nor the server notice.
o Once the RPCSEC_GSS handle is in an established state, the
initiator sends its first RPCSEC_GSS_DATA request. The MITM
constructs an RPCSEC_GSS_BIND_CHANNEL request, using the message
integrity code (MIC) of the RPCSEC_GSS_DATA request. It is likely
the RPCSEC_GSSv2 target will reject the request. The MITM
continues to reiterate each time the initiator sends another
RPCSEC_GSS_DATA request. With enough iterations, the probability
of a MIC from an RPCSEC_GSS_DATA being successfully verified in
the forged RPCSEC_GSS_BIND_CHANNEL increases. Once the MITM
succeeds, it can send RPCSEC_GSS_DATA requests with a security
service of rpc_gss_svc_channel_prot, which does not have MICs in
the RPC request's verifier.
The implementation of RPCSEC_GSSv2 can use at least two methods to
thwart these attacks.
o The target SHOULD require a stronger MIC when sending an
RPCSEC_GSS_BIND_CHANNEL request instead of an RPCSEC_GSS_DATA
request -- e.g., if HMACs are used for the MICs, require the
widest possible HMAC (in terms of bit length) that the GSS
mechanism supports. If HMACs are being used, and the target
expects N RPCSEC_GSS_DATA requests to be sent on the context
before it expires, then the target SHOULD require an HMAC for
RPCSEC_GSS_BIND_CHANNEL that is log base 2 N bits longer than what
it normally requires for RPCSEC_GSS_DATA requests. If a long
enough MIC is not available, then the target could artificially
limit the number of RPCSEC_GSS_DATA requests it will allow on the
context before deleting the context.
o Each time an RPCSEC_GSSv2 target experiences a failure to verify
the MIC of an RPCSEC_GSS_BIND_CHANNEL request, it SHOULD reduce
the lifetime of the underlying GSS context, by a significant
fraction, thereby preventing the MITM from using the established
context for its attack. A possible heuristic is that if the
target believes the possibility that failure to verify the MIC was
because of an attack is X percent, then the context's lifetime
would be reduced by X percent. For simplicity, an implementer
might set X to be 50 percent, so that the context lifetime is
halved on each failed verification of an RPCSEC_GSS_BIND_CHANNEL
request and thus rapidly reduced to zero on subsequent requests.
For example, with a context lifetime of 8 hours (or 28800
seconds), 15 failed attempts by the MITM would cause the context
to be destroyed.
A method of mitigation that was considered was to protect the
RPCSEC_GSS version number with RPCSEC_GSSv2's RPCSEC_GSS_INIT and
RPCSEC_GSS_CONTINUE_INIT tokens. Thus, the version number of
RPCSEC_GSS would be in the tokens. This method does not completely
mitigate the attack; it just moves the MIC guessing to the
RPCSEC_GSS_INIT message. In addition, without changing GSS, or the
GSS mechanism, there is no way to include the RPCSEC_GSS version
number in the tokens. So for these reasons this method was not
selected.
10. References
10.1. Normative References
[1] Eisler, M., Chiu, A., and L. Ling, "RPCSEC_GSS Protocol
Specification", RFC 2203, September 1997.
[2] Williams, N., "On the Use of Channel Bindings to Secure
Channels", RFC 5056, November 2007.
[3] Linn, J., "Generic Security Service Application Program
Interface Version 2, Update 1", RFC 2743, January 2000.
[4] Eisler, M., "XDR: External Data Representation Standard",
STD 67, RFC 4506, May 2006.
[5] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[6] Schaad, J., Kaliski, B., and R. Housley, "Additional Algorithms
and Identifiers for RSA Cryptography for use in the Internet
X.509 Public Key Infrastructure Certificate and Certificate
Revocation List (CRL) Profile", RFC 4055, June 2005.
10.2. Informative References
[7] Williams, N., "IPsec Channels: Connection Latching", Work
in Progress, November 2008.
[8] Williams, N., "End-Point Channel Bindings for IPsec Using IKEv2
and Public Keys", Work in Progress, April 2008.
[9] Srinivasan, R., "RPC: Remote Procedure Call Protocol
Specification Version 2", RFC 1831, August 1995.
Author's Address
Mike Eisler
NetApp
5765 Chase Point Circle
Colorado Springs, CO 80919
US
Phone: +1-719-599-9026
EMail: mike@eisler.com