RSVP Cryptographic Authentication, Version 2
draft-atkinson-teas-rsvp-auth-v2-00
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| Last updated | 2024-10-21 | ||
| Replaced by | draft-ietf-teas-rsvp-auth-v2 | ||
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draft-atkinson-teas-rsvp-auth-v2-00
TEAS Working Group R. Atkinson
Internet-Draft Consultant
Obsoletes: 3097 (if approved) T. Li
Intended status: Standards Track Juniper Networks
Expires: 24 April 2025 21 October 2024
RSVP Cryptographic Authentication, Version 2
draft-atkinson-teas-rsvp-auth-v2-00
Abstract
This document provides an algorithm-independent description of the
format and use of RSVP's INTEGRITY object. The RSVP INTEGRITY object
is widely used to provide hop-by-hop integrity and authentication of
RSVP messages, particularly in MPLS deployments using RSVP-TE. This
replaces and obsoletes RFC 2747 and RFC 3097.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF). Note that other groups may also distribute
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Internet-Drafts are draft documents valid for a maximum of six months
and may be updated, replaced, or obsoleted by other documents at any
time. It is inappropriate to use Internet-Drafts as reference
material or to cite them other than as "work in progress."
This Internet-Draft will expire on 24 April 2025.
Copyright Notice
Copyright (c) 2024 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 (https://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 Revised BSD License text as
described in Section 4.e of the Trust Legal Provisions and are
provided without warranty as described in the Revised BSD License.
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Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 2
1.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4
1.2. Requirements Language . . . . . . . . . . . . . . . . . . 5
2. INTEGRITY Object Format . . . . . . . . . . . . . . . . . . . 5
2.1. Backward Compatibility . . . . . . . . . . . . . . . . . 7
3. Generating Sequence Numbers . . . . . . . . . . . . . . . . . 8
3.1. Simple Sequence Numbers . . . . . . . . . . . . . . . . . 9
3.2. Sequence Numbers Based on a Real-Time Clock . . . . . . . 9
3.3. Sequence Numbers Based on a Network-Recovered Clock . . . 10
4. Message Processing . . . . . . . . . . . . . . . . . . . . . 10
4.1. Per-Interface Implementations . . . . . . . . . . . . . . 10
4.1.1. Message Generation (Per-Interface) . . . . . . . . . 11
4.1.2. Message Reception (Per-Interface) . . . . . . . . . . 12
4.2. Per-Peer Implementations . . . . . . . . . . . . . . . . 14
4.2.1. Message Generation (Per-Peer) . . . . . . . . . . . . 14
4.2.2. Message Reception (Per-Peer) . . . . . . . . . . . . 14
4.3. Integrity Handshake at Restart or Initialization of the
Receiver . . . . . . . . . . . . . . . . . . . . . . . . 15
5. Key Management . . . . . . . . . . . . . . . . . . . . . . . 17
5.1. RSVP Security Association . . . . . . . . . . . . . . . . 18
5.1.1. Additional State . . . . . . . . . . . . . . . . . . 20
5.2. Key Management Procedures . . . . . . . . . . . . . . . . 20
5.3. Key Management Requirements . . . . . . . . . . . . . . . 21
5.4. Pathological Case . . . . . . . . . . . . . . . . . . . . 22
5.5. Kerberos . . . . . . . . . . . . . . . . . . . . . . . . 23
6. Security Considerations . . . . . . . . . . . . . . . . . . . 23
7. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 24
8. Acknowledgments . . . . . . . . . . . . . . . . . . . . . . . 24
Appendix A: Changes since RFC 2747 . . . . . . . . . . . . . . . 25
References . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Normative References . . . . . . . . . . . . . . . . . . . . . 25
Informative References . . . . . . . . . . . . . . . . . . . . 26
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 28
1. Introduction
The Resource ReSerVation Protocol RSVP [RFC2205] is a protocol for
setting up distributed state in routers and hosts. It has two common
uses in the deployed Internet. First, it is used to reserve
resources to deploy Integrated Services. When used in this way, RSVP
allows particular users to obtain preferential access to network
resources, under the control of an admission control mechanism.
Permission to make a reservation will depend upon the availability of
the requested resources along the path of the data and satisfaction
of policy rules. Second, it is used to create and manage MPLS Label
Switched Paths (LSPs), possibly with resources being reserved on a
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per-LSP basis.
To ensure the integrity of the admission control mechanism RSVP
requires the ability to protect its messages against corruption and
forgery. Where RSVP-TE is used to manage MPLS Label Switched Paths
(LSPs), it is also important to mitigate the risk of unauthorized
creation, modification, or deletion of a Label Switched Path.
This document defines a mechanism to protect RSVP messages in a hop-
by-hop manner. When this mechanism is employed, the sending RSVP
system transmits a cryptographic value in the Authentication Data
field of the RSVP INTEGRITY object which is contained within each
RSVP message. The cryptographic value is computed using information
within an RSVP Security Association, which is precisely defined in
Section 5.1. Hence, this mechanism can significantly reduce the
security risks from forgery or modification of RSVP (including RSVP-
TE) messages.
The INTEGRITY object of each RSVP message is also tagged with a one-
time-use sequence number, which is described in more detail in
Section 3. This helps the message receiver identify replayed RSVP
messages and hence thwart replay attacks.
This mechanism does not provide confidentiality, since messages stay
in the clear; however, the mechanism is also believed to be
importable to and exportable from all countries, which would be
impossible were a confidentiality mechanism included.
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This document is a revision of [RFC2747]. The most important
difference is that this document specifies an authentication
mechanism in a manner which is independent of the cryptographic
algorithm (e.g., MD5, SHA-256, SHA-3) used and the cryptographic mode
(e.g., HMAC, GMAC, KMAC) used. This supports future evolution with a
variety of other cryptographic algorithms and cryptographic modes
without needing to change the RSVP Authentication mechanism. An
algorithm-independent specification is important because historically
all published cryptographic algorithms eventually become
computationally weak or will have cryptographic flaws
discovered.[DS-1981] Separately, different cryptographic algorithms
will have different cryptologic and mathematical properties, which
can mean that the cryptographic mode suitable for one algorithm is
either unsuitable or less appropriate for some other cryptographic
algorithm. As an example, while the HMAC construction [RFC2104]
[NIST-HMAC] is sensible for Merkle-Damgard hash functions (e.g., SHA-
1, SHA-2), the Keccak Message Authentication Code (KMAC) construction
[NIST-KMAC] is preferable for the newer NIST SHA-3 hash function.
[WAGNER] NIST also has defined the GCM Message Authentication Code
(GMAC), which is another cryptographic authentication algorithm that
might be used in the future. [NIST-GMAC]
This document only specifies the RSVP authentication mechanism and
protocol and does not specify a particular cryptographic algorithm or
cryptographic mode that MUST be implemented. Instead, this
specification creates a new IANA Registry for the "RSVP Cryptographic
Transform". This enables the set of mandatory, optional, and
deprecated cryptographic mechanisms to be updated over time without
needing to update or modify this document.
The RSVP checksum MAY be disabled (i.e., set to zero) when the
INTEGRITY object is included in the RSVP message, as cryptographic
authentication inherently provides a much stronger integrity check.
1.1. Terminology
Within this document, there are certain terms and concepts the reader
should be familiar with.
First, this document uses the terms "sender" and "receiver"
differently from [RFC2205]. They are used here to refer to systems
that face each other across an RSVP hop, the "sender" being the
system generating RSVP messages.
An "Authentication Key" is an unpredictable cryptographic key that is
used in the calculation of the Authentication Data field of the RSVP
Integrity Object. It is defined precisely in Section 5.1
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The term "Cryptographic Transform" is the combination of a
cryptographic algorithm (e.g., MD5, SHA-1, SHA-256), the length of
the secret Authentication Key, and a cryptographic mode (e.g., HMAC,
GMAC, KMAC). Each different Cryptographic Transform ought to be
defined in its own RFC and provide a clear specification of how the
Authentication Data field is calculated when that Cryptographic
Transform is used in an RSVP Security Association.
The term "RSVP Security Association" and its contents are precisely
defined in Section 5.1. It contains the Cryptographic Transform in
use, the cryptographic key, and several other parameters.
1.2. Requirements Language
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
BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
capitals, as shown here. These words may also appear in this
document in lower case as plain English words, absent their normative
meanings.
2. INTEGRITY Object Format
An RSVP message consists of a sequence of "objects," which are type-
length-value encoded fields having specific purposes. The
information required for hop-by-hop integrity checking is carried in
an INTEGRITY object. The same INTEGRITY object type is used for both
IPv4 and IPv6.
The INTEGRITY object has the following format:
Authentication Information INTEGRITY Object: Class = 4, C-Type = 1
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+-------------+-------------+-------------+-------------+
| Flags | AAL | |
+-------------+-------------+ +
| Key Identifier |
+-------------+-------------+-------------+-------------+
| Sequence Number |
| |
+-------------+-------------+-------------+-------------+
| |
+ +
| |
+ Authentication Data |
| |
+ +
| |
+-------------+-------------+-------------+-------------+
* Flags: An 8-bit field with the following format:
Flags
0 1 2 3 4 5 6 7
+---+---+---+---+---+---+---+---+
| H | |
| F | 0 |
+---+---+---+---+---+---+---+---+
Currently, only one flag (HF) is defined. The remaining flags are
reserved for future use and MUST be set to 0.
* Bit 0: Handshake Flag (HF) concerns the integrity handshake
mechanism (Section 4.3). Message senders willing to respond to
integrity handshake messages SHOULD set this flag to 1 whereas
those that will reject integrity handshake messages SHOULD set
this to 0.
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* Additional Authentication Length (AAL): This 8-bit field contains
an unsigned integer. If this value is 0, the Authentication Data
field contains 16 bytes. If this value is greater than 0, it
specifies how many additional 4-byte increments (i.e., beyond the
default 16 bytes) exist in the Authentication Data field. For
example, a value of 1 indicates that the Authentication Data field
is 20 bytes long (16 bytes of default plus one 4-byte addition).
This counts in 4-byte increments so that 32-bit alignment is
maintained within the RSVP message. If some future cryptographic
transform has a result that is not 32-bit aligned, then the RFC
specifying the cryptographic transform MUST document the length of
the actual output and MUST also document that any trailing bytes
after the length of the actual cryptographic result are padding.
* Key Identifier: An unsigned 48-bit number that MUST be unique for
a given sender. Locally unique Key Identifiers can be generated
using some combination of the address (IP or MAC or Logical
Interface Handle (LIH)) of the sending interface and the key
number. The combination of the Key Identifier and the sending
system's IP address uniquely identifies the security association
(Section 5.1).
* Sequence Number: An unsigned 64-bit sequence number. Sequence
Number values may be any monotonically increasing (modulo 2^64)
sequence that provides the INTEGRITY object of each RSVP message
with a unique tag for the associated key's lifetime. Sequence
number generation is specified below in Section 3.
* Authentication Data: This is an unsigned variable length field
containing the cryptographic authentication data. The field
length MUST be a multiple of 4 octets (i.e., 32 bits) long. If
one knows the RSVP Cryptographic Transform used for a given RSVP
packet, then one will know the correct length of this field.
Given the combination of the Key Identifier and the Sender, one
knows the RSVP Security Association, which includes the RSVP
Cryptographic Transform.
2.1. Backward Compatibility
In [RFC2747], the INTEGRITY object contained a fixed 16-octet field
for "Keyed Message Digest" for HMAC-MD5. This field is now renamed
to "Authentication Data". Further, the second octet in the object
was reserved and its contents were specified as 0. This field has
now been redefined as the AAL field.
These changes should be fully backward compatible. A legacy
implementation will continue to generate a 16-octet "Keyed Message
Digest" and new implementations that expect HMAC-MD5 should continue
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to expect 16 octets. Legacy implementations will continue to
generate a reserved field containing 0. Similarly, an implementation
conforming to this document that is generating HMAC-MD5 should
continue to generate an Authentication Data field of 16 octets and an
AAL field containing 0. These should be received by a legacy
implementation without any differences noted.
3. Generating Sequence Numbers
In this section, we describe methods that could be chosen to generate
sequence numbers for the INTEGRITY object of an RSVP message.
The sequence number field is chosen to be a 64-bit unsigned quantity.
This should be large enough to avoid exhaustion over the key
lifetime. For example, if a key lifetime is conservatively defined
as one year, there would be enough sequence number values to send
RSVP messages at an average rate of about 585 gigaMessages per
second. A 32-bit sequence number would limit this average rate to
about 136 messages per second.
As previously stated, two important properties MUST be satisfied by
the generation procedure. The first property is that the sequence
numbers are unique, or one-time, for the lifetime of the integrity
key that is in current use. A receiver can use this property to
distinguish unambiguously between a new and a replayed message. The
second property is that the sequence numbers are generated in
monotonically increasing order, modulo 2^64. This greatly reduces
the amount of saved state.
It is desirable that RSVP Sequence Numbers not be trivially
predictable. Therefore, the sequence numbers might not begin with
"0", "1", or any other fixed number. At the start of an RSVP
session, a receiver MUST handshake with the sender to get an initial
sequence number. Since the starting sequence number might be
arbitrarily large, the modulo operation described above accommodates
sequence number rollover within the key's lifetime. This solution
draws from TCP's approach [RFC9293].
This memo later discusses ways to relax the strictness of the in-
order delivery of messages as well as techniques to generate
monotonically increasing sequence numbers that are robust across
sender failures and restarts.
The ability to generate unique monotonically increasing sequence
numbers across a failure and restart implies some form of stable
storage local to the device. Three sequence number generation
procedures are described below.
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3.1. Simple Sequence Numbers
The most straightforward approach is to generate a unique sequence
number using a message counter. Each time a message is transmitted
for a given key, the sequence number counter is incremented. The
current value of this counter is continually or periodically saved to
stable storage. After a restart, the counter is recovered using this
stable storage. If the counter was saved periodically to stable
storage, the count should be recovered by increasing the saved value
to be larger than any possible value of the counter at the time of
the failure. This can be computed by knowing the interval at which
the counter was saved to stable storage and incrementing the stored
value by that amount.
The periodicity of saving the sequence numbers need not be tied to
time. This could also be implemented in terms of the usage of
sequence numbers themselves. For example, an implementation could
record the sequence number once every 1000 messages. On recovery,
the implementation could recover the stored sequence number, advance
it by 1000, and be reasonably assured that the new number is unique.
3.2. Sequence Numbers Based on a Real-Time Clock
Most devices will probably not have the capability to save sequence
number counters to stable storage for each RSVP session.
A more universal solution is to base sequence numbers on the stable
storage of a real-time clock. Many computing devices have a real-
time clock module that includes stable storage for the clock. These
modules generally include either some form of nonvolatile memory to
retain clock information in the event of a power failure or have a
small on-board battery to keep the clock running even when the device
is not in use.
Also, many systems have deployed the Network Time Protocol (NTP)
[RFC5905], the Precision Time Protocol (PTP) [IEEE-1588-2019] or a
related ITU-T profile of the Precision Time Protocol [G.8265.1].
In this approach, we could use a Network Time Protocol (NTP)
timestamp value or a Precision Time Protocol (PTP) timestamp value as
the sequence number. The rollover period of an NTP timestamp is
about 136 years, much longer than any reasonable lifetime for a key.
In addition, the granularity of the NTP timestamp is fine enough to
allow the generation of an RSVP message every 200 picoseconds for a
given key. PTP timestamps have even finer granularity. Many real-
time clock modules do not have the resolution of an NTP timestamp or
PTP timestamp. In these cases, the least significant bits of the
timestamp can be generated using a message counter, which is reset
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every clock tick. For example, when the real-time clock provides a
resolution of 1 second, the 32 least significant bits of the sequence
number can be generated using a message counter. The remaining 32
bits are filled with the 32 least significant bits of the timestamp.
Assuming that the recovery time after failure takes longer than one
tick of the real-time clock, the message counter for the low-order
bits can be safely reset to zero after a restart.
3.3. Sequence Numbers Based on a Network-Recovered Clock
If the device does not contain any stable storage of sequence number
counters or of a real-time clock, it could recover the real-time
clock from the network using either NTP, PTP, or the ITU-T profile of
PTP. Once the clock has been recovered following a restart, the
sequence number generation procedure would be identical to the
procedure described above. To reduce the risk of forgery attacks and
the risk of time-based RSVP attacks generally, deployments using NTP,
PTP, or a different distributed clock protocol always SHOULD enable
cryptographic authentication for time distribution.
4. Message Processing
Implementations MUST support the specification of RSVP Authentication
on a per-interface basis. Implementations SHOULD also support the
specification of RSVP Authentication on a per-peer basis.
4.1. Per-Interface Implementations
Implementations MUST allow the specification of the interfaces to be
secured, for either sending messages, receiving them, or both. The
sender must ensure that all RSVP messages sent on secured interfaces
include an INTEGRITY object, generated using the appropriate Key.
Receivers verify whether RSVP messages, except for the type
"Integrity Challenge" (Section 4.3), arriving from a secured peer
contain the INTEGRITY object. If the INTEGRITY object is absent, the
receiver discards the message.
Security associations are simplex - the keys that an originating
system uses to sign its messages MAY be different from the keys that
its responder systems use to sign their messages back to the
originator. Hence, each association corresponds to a unique sending
system and one or more responding systems.
Each sender SHOULD have distinct security associations (and keys) per
secured interface (or LIH). While administrators MAY configure all
the routers and hosts on a subnet (or MAY, for that matter, all
devices in their network) using a single security association,
implementations MUST assume that each sender might send using a
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distinct security association for each secured interface. At the
sender, security association selection is based on the egress
interface through which the message is sent. This selection MAY also
include additional criteria, such as (a) the destination address
(when sending the message unicast, over a broadcast LAN with a large
number of hosts) or (b) user identities at the sender or receivers
[RFC2752][RFC3182]. Finally, all intended message recipients need to
participate in this security association. Route flaps in a non-RSVP
cloud might cause messages for the same receiver to be sent on
different interfaces at different times. In such cases, the
receivers should participate in all possible security associations
that might be selected for the interfaces through which the message
might be sent.
Receivers select keys based on the Key Identifier and the sending
system's IP address. The Key Identifier is included in the INTEGRITY
object. The sending system's address can be obtained either from the
RSVP_HOP object, or if that's not present (as is the case with
PathErr and ResvConf messages) from the IP source address. The
combination of the sending system's IP address and Key Identifier
uniquely identifies the Security Association, including all of the
data elements of a Security Association.
The integrity mechanism slightly modifies the processing rules for
RSVP messages, both when including the INTEGRITY object in a message
sent over a secured sending interface and when accepting a message
received on a secured receiving interface. These modifications are
detailed below.
4.1.1. Message Generation (Per-Interface)
For an RSVP message sent over a secured sending interface, the
message is created as described in [RFC2205], with these exceptions:
1. The RSVP checksum field is set to zero. If required, an RSVP
checksum can be calculated when the processing of the INTEGRITY
object is complete.
2. The INTEGRITY object is inserted in the appropriate place, and
its location in the message is remembered for later use.
3. The sending interface and other appropriate criteria (as
described above) are used to determine the correct Security
Association to use. The Security Association will specify the
Cryptographic Algorithm, Cryptographic Mode, and Authentication
Key to use.
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4. The unused flags in the INTEGRITY object MUST be set to 0. The
Additional Authentication Length (AAL) and the Handshake Flag
(HF) should be set according to the rules specified in Section 2.
5. The sending sequence number MUST be updated to ensure a unique,
monotonically increasing number. It is then placed in the
Sequence Number field of the INTEGRITY object.
6. The Authentication Data field is set to zero.
7. The Key Identifier is placed into the INTEGRITY object.
8. Authentication Data for the message is computed over the message,
using the Authentication Algorithm and Mode in conjunction with
the Authentication Key.
9. The computed Authentication Data is written into the
Authentication Data field of the INTEGRITY object.
4.1.2. Message Reception (Per-Interface)
When the message is received on a secured receiving interface and is
not of the type "Integrity Challenge", it is processed in the
following manner:
1. The RSVP checksum field is saved and the field is subsequently
set to zero.
2. The Authentication Data field of the INTEGRITY object is saved
and the field is subsequently set to zero.
3. The Key Identifier field and the sending system address determine
the precise Security Association to use for the received message.
If the RSVP Security Association has expired AND a different RSVP
Security Association is valid, then the packet MUST be discarded
without cryptographic processing AND a security error SHOULD be
logged in an implementation-specific manner (e.g., via SYSLOG or
SNMP). Any such logging MUST be rate-limited to mitigate the
potential for Denial of Service attacks.
If the RSVP Security Association has expired AND there is no RSVP
Security Association valid at the time the RSVP packet was received,
then the expired RSVP Security Association should be used to validate
the received RSVP packet just as if the RSVP Security Association
were not expired.
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The RSVP Security Association is defined in Section 5.1. It includes
the Cryptographic Transform, Authentication Key, and other parameters
needed to validate the received RSVP packet.
1. A new Authentication Data value is calculated using the indicated
Cryptographic Algorithm, Cryptographic Mode, and and
Authentication Key.
2. If the calculated Authentication Data is not identical to the
received Authentication Data, then the message MUST be discarded
without further processing. A security error message SHOULD be
logged (e.g., using SYSLOG or SNMP) if the received RSVP message
is discarded for that reason, but any such error messages MUST be
rate-limited to reduce risks from Denial of Service attacks.
3. If the message is of type "Integrity Response", verify that the
CHALLENGE object identically matches the originated challenge.
If it matches, save the sequence number in the INTEGRITY object
as the largest sequence number received to date.
Otherwise, for all other RSVP Messages, the sequence number is
validated to prevent replay attacks, and messages with invalid
sequence numbers are ignored by the receiver. Validation is
discussed in more detail in the following paragraphs.
When a message is accepted, the sequence number of that message
SHOULD update a stored value corresponding to the largest sequence
number received to date. In a naive implementation, each subsequent
message would need to have a larger (modulo 2^64) sequence number to
be accepted to reduce risks from replay attacks. However, this
simple processing rule SHOULD be modified to tolerate limited out-of-
order message delivery. For example, if several RSVP messages were
sent in a burst (e.g., in a periodic refresh generated by a router,
or as a result of a tear-down operation), then some of those RSVP
messages might get reordered during transit and then the RSVP
sequence numbers would not be received in a strictly increasing
order.
An implementation SHOULD allow administrative configuration that sets
the receiver's tolerance to out-of-order message delivery. A simple
approach would allow administrators to specify a received RSVP
message window corresponding to the worst-case reordering behavior.
For example, one might specify that packets reordered within a 32
message window would be accepted. If no reordering is allowed by
policy, then the out-of-order received RSVP message window is set to
one.
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The receiver MUST store a list of all RSVP sequence numbers seen
within the reordering window. A received RSVP sequence number is
valid if it lies within the reordering window AND it is not a
sequence number in the received sequence number list. Acceptance of
a sequence number by an implementation requires adding that number to
the received sequence number list. If the oldest sequence number
within the window is received, then the window advances. A single
message can cause the window to advance multiple times.
Implementations MUST discard RSVP messages received with RSVP
sequence numbers either (a) lying outside of the reordering window or
(b) marked as already received in the RSVP received sequence number
list.
When an "Integrity Challenge" message is received on a secured
sending interface it is processed in the following manner:
1. An "Integrity Response" message is formed using the Challenge
object received in the challenge message.
2. The message is sent back to the receiver, based on the source IP
address of the challenge message, using the "Message Generation"
steps outlined above. The selection of the Authentication Key
and the hash algorithm to be used is determined by the key
identifier supplied in the challenge message.
4.2. Per-Peer Implementations
Per-peer implementations follow the procedures in Section 4.1 but use
the security associations defined for the specific peer.
4.2.1. Message Generation (Per-Peer)
Per-peer implementations follow the procedures in Section 4.1.1 for
Message Generation, except using the security associations for the
specific peer.
4.2.2. Message Reception (Per-Peer)
Per-peer implementations follow the procedures in Section 4.1.2 for
Message Reception, except using the security associations for the
specific peer.
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4.3. Integrity Handshake at Restart or Initialization of the Receiver
To obtain the starting sequence number for a live Authentication Key,
the receiver SHOULD initiate an integrity handshake with the sender.
This Integrity Handshake consists of a receiver's Challenge and the
sender's Response. The Integrity Handshake MAY either be initiated
during restart or postponed until a message signed with that key
arrives.
To ensure interoperability, and mindful that the Integrity Handshake
might be essential to synchronize understanding of the starting
sequence number, implementations of this specification MUST implement
this Integrity Handshake capability.
Implementations of the older [RFC2747] RSVP Cryptographic
Authentication specification might not have implemented the Integrity
Handshake. The Handshake Flag (HF) enables backwards compatibility
with those legacy implementations by allowing implementations the
ability to indicate they do not implement the Integrity Handshake
mechanism. An implementation that does not implement the Integrity
Handshake MUST set the HF flag to 0. Message senders that implement
the integrity handshake MUST set the HF flag to 1. Receivers SHOULD
NOT attempt to handshake with senders whose INTEGRITY object has HF =
0.
Once the receiver initiates an Integrity Handshake for a particular
RSVP Security Association, it identifies the sender using the sending
system's address configured in the corresponding RSVP Security
Association. The receiver then sends an RSVP Integrity Challenge
message to the sender. This message contains the Key Identifier to
identify the sender's key and MUST have a unique challenge cookie
based on an unpredictable local secret to prevent guessing. See
Section 2.5.3 of [RFC2408]. One implementation option is to have the
cookie be a cryptographic hash of an unpredictable local secret, an
unpredictable nonce, and a timestamp to provide uniqueness (see
Section 3.2).
An RSVP Integrity Challenge message will carry a message type of 25.
The message format is as follows:
<Integrity Challenge message> ::= <Common Header> <CHALLENGE>
The CHALLENGE object has the following format:
CHALLENGE Object: Class = 64, C-Type = 1
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+-------------+-------------+-------------+-------------+
| 0 (Reserved) | |
+-------------+-------------+ +
| Key Identifier |
+-------------+-------------+-------------+-------------+
| Challenge Cookie |
| |
+-------------+-------------+-------------+-------------+
The sender accepts the "Integrity Challenge" without doing an
integrity check. It returns an RSVP "Integrity Response" message
that contains the original CHALLENGE object. It also includes an
INTEGRITY object, signed with the key specified by the Key Identifier
included in the "Integrity Challenge".
An RSVP Integrity Response message will carry a message type of 26.
The message format is as follows:
<Integrity Response message> ::= <Common Header> <INTEGRITY>
<CHALLENGE>
The "Integrity Response" message is accepted by the receiver
(challenger) only if the returned CHALLENGE object matches the one
sent in the "Integrity Challenge" message. This prevents the replay
of old "Integrity Response" messages. If the match is successful,
the receiver saves the Sequence Number from the INTEGRITY object as
the latest sequence number received with the key identifier included
in the CHALLENGE.
If a response is not received within a given period, the challenge is
repeated. When the integrity handshake succeeds, the receiver begins
accepting normal RSVP signaling messages from that sender and ignores
any other "Integrity Response" messages.
Implementations SHOULD enable the Integrity Handshake by default when
RSVP Cryptographic Authentication is in use. In some special-case
environments it might not be required. One use of RSVP
Authentication might be between peering domain routers that are
processing a steady stream of RSVP messages due to aggregation
effects. When a router restarts after a crash, valid RSVP messages
from peering senders probably will arrive shortly. If replay
messages are injected into the stream of valid RSVP messages, there
might be only a small window of opportunity for a replay attack
before a valid message is processed. This valid message will set the
largest sequence number seen to a value greater than any number
before the crash, preventing any further replays. This attack can be
mitigated if the router has stable storage for the RSVP sequence
number state.
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If an implementation does not enable the Integrity Handshake, this
creates a broad exposure to replay attacks, especially if there is a
long period of silence from a given sender following a restart of a
receiver.
Hence, it SHOULD be an administrative decision by the network
operator whether or not the receiver performs an Integrity Handshake
with senders that are willing to respond to its "Integrity Challenge"
messages, and whether it accepts any messages from senders that
refuse to do so. These operational decisions ought to be based on
risk assessments [NIST-RMF] for the particular network environment.
Each RSVP session MUST be protected either by the Integrity Handshake
or by sequence numbers recorded in stable storage.
5. Key Management
As of the publication date for this document, support for the IETF
Network Configuration (NetConf) protocol standard [RFC6241] has been
widely available in commercial routers and switches for at least 15
years. Further, NetConf is widely deployed for networked device
configuration in medium-sized and large-sized IP network deployments
around the globe. When properly configured and deployed, NetConf can
provide secure automated, distributed network device configuration
management. Further, NetConf has for many years been commonly used
to provision RSVP Security Associations (and also Security
Associations for IS-IS, OSPF, LDP, and BGP) into networking devices
throughout a network. Network devices usually need secure automated
configuration management for other reasons, so using that same
mechanism to distribute RSVP Security Associations is practical,
avoids creating additional implementation burden on vendors, and
avoids creating a further operational burden on network operations
staff.
As of the publication date for this document, it appears very
unlikely that the IETF will define a standard key management protocol
for use with RSVP. However, if the IETF does so, then it would be
strongly desirable to use that key management protocol to distribute
RSVP Security Associations (including keys) among the communicating
RSVP implementations. Such a protocol could improve scalability and
significantly reduce the human administrative burden. The Key
Identifier can be used as a hook between RSVP and such a future
protocol.
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Key management protocols have a long history of subtle flaws that
often are discovered long after the protocol was first described in
public [DS-1981]. To avoid changing all RSVP implementations if such
a flaw is discovered, integrated key management protocol techniques
were deliberately omitted from this specification.
5.1. RSVP Security Association
An RSVP Security Association consists of the following parameters:
* RSVP Key Identifier (48 bits)
This unsigned 48-bit item is the Key Identifier used on the wire in
the RSVP INTEGRITY object.
* RSVP Message Processing Mode
This value indicates whether this RSVP Security Association is using
per-interface message processing rules or is using per-neighbor
message processing rules.
* RSVP Sending Interface
This is the implementation-specific name for the sending interface
associated with this RSVP Security Association. This only exists (a)
when the per-interface message processing rules are in use for this
RSVP Security Association and (b) only on the sending RSVP node.
* RSVP Receiving Interface
This is the implementation-specific name for the receiving interface
associated with this RSVP Security Association. This only exists (a)
when the per-interface message processing rules are in use for this
RSVP Security Association and (b) on the receiving RSVP node.
* RSVP Sending IP Address
This is the IP address (IPv4 or IPv6) used by the sending node. This
is only pertinent when the per-neighbor message processing rules are
used for this RSVP Security Association.
* RSVP Receiving IP Address
This is the IP address (IPv4 or IPv6) used by the receiving node.
This is only pertinent when the per-neighbor message processing rules
are used for this RSVP Security Association.
* RSVP Cryptographic Transform
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This item specifies the combination of the cryptographic algorithm
(e.g., MD5, SHA-1, SHA-256) to be used, the cryptographic
authentication mode (e.g., GMAC, HMAC, KMAC) to be used, and the
length in bits of the Authentication Key. RSVP Cryptographic
Transforms are defined in an IANA Registry (defined below) and
corresponding transform-specific RFCs.
* RSVP Authentication Key
This item specifies the cryptographic authentication key to be used.
Its size varies depending on which Cryptographic Transform is in use.
For any specific RSVP Cryptographic Transform, the key size will be
fixed. RSVP Authentication Keys need to be cryptographically
random.[RFC4086][NIST-ENTROPY]
* RSVP Security Association Start Time
This item, referred to as KeyStartValid in [RFC2747], specifies the
calendar date (e.g., 01 June 1970) and 24-hour clock time (e.g.,
18:05) when this RSVP Security Association begins being valid for
operational use. This value MUST NOT be later than the RSVP Security
Association End value.
* RSVP Security Association End Time
This item, referred to as KeyEndValid in [RFC2747], specifies the
calendar date (e.g., 01 June 1970) and 24-hour clock time (e.g.,
18:05) when this RSVP Security Association stops being valid for
operational use. This value MUST NOT be earlier than RSVP Security
Association Start value.
RSVP Cryptographic Authentication has always implicitly required that
all communicating RSVP-capable devices have at least loosely
synchronized clocks. In some cases, hardware clocks inside a network
device might be sufficient. However, many network deployments use
the Network Time Protocol (NTP), Precision Time Protocol (PTP), or
another method to keep such clocks sufficiently synchronized. When
possible, RSVP deployments SHOULD also deploy a distributed time
synchronization protocol and SHOULD enable cryptographic
authentication for that time synchronization protocol.
Certain key generation mechanisms, such as Kerberos or some public
key schemes, might directly produce ephemeral keys for use with RSVP.
In that case, the lifetime of the key MAY be defined as part of that
key generation process.
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In normal operation, an RSVP Security Association is never used
outside its lifetime, but see Section 5.3 for a degenerative special
case.
5.1.1. Additional State
Implementations will require additional state associated with, but
not part of the Security Association. This information is not part
of a Security Association's configuration.
* Initial RSVP Authentication Sequence Number
For an RSVP Security Association which has not yet been used, this
MUST be initialized to an unpredictable (i.e., cryptographically
random) value.[RFC4086][NIST-ENTROPY] Both sender and receiver either
MUST be configured with this initial sequence number (e.g., via
NetConf or the device's operator console) or MUST learn it via the
Integrity Handshake, so that the RSVP Authentication sequence number
windowing scheme can work properly.
After the RSVP Security Association has been used by the sender, the
sender uses the Latest Sent RSVP Authentication Sequence Number
instead. After the RSVP Security Association has been used by the
receiver, the receiver uses the List of Received RSVP Authentication
Sequence Numbers instead.
* Latest Sent RSVP Authentication Sequence Number
This exists only on the RSVP Authentication sending node. It
contains the most recently transmitted Sequence Number within the
RSVP Integrity Object.
* List of Received RSVP Authentication Sequence Numbers
This list exists only on the RSVP Authentication receiving node. It
contains an ordered list of the most recently seen sequence numbers.
The list MUST support at least 5 sequence numbers and MAY support
more than 5. This is used as part of the replay mitigation
mechanism. It is a list rather than a single number because IP
packets might be reordered in transit from a sender to a receiver.
5.2. Key Management Procedures
To maintain security, it is advisable to change the RSVP Security
Association regularly. Operational considerations mean it needs to
be possible to switch the RSVP Security Association smoothly (i.e.,
without loss of RSVP state or denial of its reservation service), and
also without requiring people to change all the keys simultaneously.
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Supporting smooth key rollover in an RSVP implementation is
essential. Therefore, RSVP implementations MUST support the storage
and use of at least 2 active RSVP Security Associations concurrently
(a) for each RSVP-enabled interface when using the per-interface
message processing rules and (b) for each RSVP peer when using per-
peer message processing rules. To best support resilient network
operations, the number of concurrent RSVP Security Associations
SHOULD NOT merely be two (2), but instead SHOULD be a much larger
number.
Since Security Associations are shared between an RSVP sender and one
or more RSVP receivers, there is a region of uncertainty around the
time of key switch-over during which some systems may still be using
the old key and others might have switched to the new RSVP Security
Association. The size of this uncertainty region relates directly to
the clock synchrony of the systems. Administrators ought to
configure the overlap between the expiration time of the older RSVP
Security Association and the validity of its replacement RSVP
Security Association to be at least twice the size of this
uncertainty interval. In many deployments, five (5) minutes of RSVP
Security Association overlap will suffice. This will allow the
sender to make the RSVP Security Association switch-over at the
midpoint of this interval and be confident that all receivers are now
accepting the new Security Association. For the duration of the
overlap in RSVP Security Association lifetimes, a receiver must be
prepared to authenticate messages using either Security Association.
The combination of the sender's IP address and the Key Identifier
will inform the receiver of which Security Association to use for
validation.
During rollover of the RSVP Security Association, it will be
necessary for each receiver to handshake with the sender using the
new RSVP Security Association. As stated above, an RSVP receiver has
the choice of initiating a handshake during the switchover or
postponing the handshake until the receipt of a message using that
key.
5.3. Key Management Requirements
Requirements for an implementation are as follows:
* It is strongly desirable that a hypothetical security breach in
one Internet protocol does not automatically compromise other
Internet protocols. The Authentication Key of this specification
SHOULD NOT (a) be stored in an insecure manner or (b) transmitted
either in clear-text or using protocols, algorithms, or methods
that have known flaws.
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* An implementation MUST support the storage and use of more than
one Security Association at the same time for the same interface
(when per-interface processing rules apply) or for the same RSVP
peer (when per-peer processing rules apply). It is impossible to
support smooth key rollover if an implementation does not support
at least 2 concurrent RSVP Security Associations of each type.
* An implementation MUST associate a specific lifetime with each
RSVP Security Association and the corresponding RSVP Key
Identifier.
* An implementation MUST support manual key distribution (e.g., the
privileged user manually typing in all the RSVP Security
Association parameters on the console). A manually entered RSVP
Security Association lifetime MAY be used forever, although this
is neither recommended nor best practice.
* Keys that are out of date MAY be automatically deleted by the
implementation ONLY IF a replacement RSVP Security Association is
already configured and active.
* Manual deletion of active keys (e.g., from an operator console)
also MUST be supported.
* RSVP Security Association storage MUST persist across a system
restart, warm or cold, to ease operational usage -- EXCEPT that
the RSVP Sequence Number information need not be persistent across
a system restart.
5.4. Pathological Case
It is possible, although strongly undesirable, that all applicable
RSVP Security Associations have expired. If this happens, it is
unacceptable to revert to an unauthenticated condition, and it is not
wise to disrupt current reservations.
Therefore, in that event, the system SHOULD send a "last RSVP
Security Association expiration" notification to the network manager
(e.g., via SYSLOG or SNMP) and also SHOULD treat the RSVP Security
Association as having an infinite lifetime until either (a) the RSVP
Security Association's lifetime is extended, (b) the RSVP Security
Association is deleted by network management, or (c) a new RSVP
Security Association is configured.
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5.5. Kerberos
Use of Kerberos with RSVP Authentication is outside the scope of this
document. Such use might be specified in the future in some other
RFC.
6. Security Considerations
This entire memo describes and specifies an algorithm-independent
authentication mechanism for RSVP that is believed to be secure
against passive attacks and against most active attacks provided the
selected cryptographic transform is secure, the RSVP Security
Association is known only to appropriate devices, and the devices'
RSVP implementations have been appropriately configured.
The quality of the security provided by this mechanism depends on the
strength of the implemented authentication algorithms, the strength
of the key being used, and the correct implementation of the security
mechanism in all communicating RSVP implementations. This mechanism
also depends on the RSVP Authentication Keys being kept confidential
by all parties. If any of these assumptions are incorrect or
operational procedures are insufficiently secure, then no real
security will be provided to the users of this mechanism.
While the handshake "Integrity Response" message is integrity-
checked, the handshake "Integrity Challenge" message is not. This
was done intentionally to avoid the case when both peering routers do
not have a starting sequence number for each other's key. Without
this, both routers will each keep sending handshake "Integrity
Challenge" messages that will be dropped by the other end. Moreover,
requiring only the response to be integrity-checked eliminates a
dependency on a security association in the opposite direction.
However, this allows a potential intruder to generate fake
handshaking challenges with a certain challenge cookie. It could
then save the response and attempt to play it against a receiver in
recovery. If it were lucky enough to have guessed the challenge
cookie used by the receiver at recovery time, then it could use the
saved response. This response would be accepted, since it is
properly signed, and would have a smaller sequence number for the
sender because it was an old message. This opens the receiver up to
replays. Still, this seems difficult to exploit. It requires not
only guessing the challenge cookie (which is based on a locally known
secret, possibly including a timestamp) in advance, but also being
able to masquerade as the receiver to generate a handshake "Integrity
Challenge" with the proper IP address without being caught.
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Confidentiality and protection against traffic analysis are not
provided by this mechanism. Mechanisms such as bulk link encryption
(e.g., IEEE 802.1 MAC Security [IEEE-802.1AE-2018] for an Ethernet
link) can be used to provide hop-by-hop confidentiality and some
mitigation against traffic analysis. [NSA-MSCCP]
7. IANA Considerations
IANA is requested to create a new registry named "RSVP Cryptographic
Transforms" within the existing "Resource Reservation Protocol (RSVP)
Parameters" registry.
It is helpful for implementers of this specification to know the
current set of defined cryptographic transforms, the corresponding
RFC(s) for each cryptographic transform, and the Implementation
Status for each cryptographic transform.
Each registry entry will need to contain, the Name of the specific
Cryptographic Transform (e.g., HMAC-MD5), the RFC(s) which specify
that Method (e.g., RFC 2747), and the current Implementation Status
of that Method. The Name of the Method is limited to printable
uppercase US-ASCII letters, printable US-ASCII numbers, and the
character "-". The "Implementation Status" field of any method MUST
be one of the following values (MUST NOT, SHOULD NOT, MAY, SHOULD, or
MUST) which are to be interpreted as per [RFC2119].
The Implementation Status can be updated either (a) due to the
publication of an IETF Standards-track RFC or (b) by IESG Protocol
Action.
There is one initial value in the new registry:
Name Reference(s) Implementation Status
--------- ------------ ---------------------
HMAC-MD5 RFC 2747 SHOULD
8. Acknowledgments
This document's predecessor, [RFC2747], was authored by Fred Baker,
Bob Lindell, and Mohit Talwar. That was derived directly from
similar work done for OSPF version 2 and RIP Version 2, jointly by
Ran Atkinson and Fred Baker. Significant editing of the text in
[RFC2747] was done by Bob Braden, resulting in increased clarity.
Significant comments on [RFC2747] were submitted by Steve Bellovin.
Matt Crawford and Dan Harkins also helped revise draft versions of
[RFC2747]. In April 2001, [RFC3097] updated the RSVP message type
value used for the RSVP Integrity Object to resolve an issue caused
by a conflicting assignment.
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Appendix A: Changes since RFC 2747
This document has made the following substantive changes since
[RFC2747]:
* This specification is algorithm-independent and cryptographic-mode
independent. So adding support for a new cryptographic algorithm
or cryptographic mode will not require changes to this protocol
specification. Those algorithm-dependent and mode-dependent
specifications will be in separate RFCs, which can be
standardized, recommended, and/or deprecated over time without
changes to this RFC or protocol specification.
* The Authentication Data field of the INTEGRITY object now supports
an increased length so that other algorithms can be supported.
The reserved field has been repurposed to indicate any increased
length of the Authentication Data field. This allows the
authentication mechanism to support other algorithms and modes
robustly.
* Discussions of Security Associations have been made RSVP-specific
and moved to Section 5.1.
* Peer-specific Security Associations are explicitly supported.
* Implementation of the Integrity Handshake is now required.
* The discussion of Key Management has been updated.
* The discussion of Kerberos has been greatly reduced.
References
Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
[RFC2205] Braden, R., Ed., Zhang, L., Berson, S., Herzog, S., and S.
Jamin, "Resource ReSerVation Protocol (RSVP) -- Version 1
Functional Specification", RFC 2205, DOI 10.17487/RFC2205,
September 1997, <https://www.rfc-editor.org/info/rfc2205>.
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[RFC3097] Braden, R. and L. Zhang, "RSVP Cryptographic
Authentication -- Updated Message Type Value", RFC 3097,
DOI 10.17487/RFC3097, April 2001,
<https://www.rfc-editor.org/info/rfc3097>.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
Informative References
[RFC2104] Krawczyk, H., Bellare, M., and R. Canetti, "HMAC: Keyed-
Hashing for Message Authentication", RFC 2104,
DOI 10.17487/RFC2104, February 1997,
<https://www.rfc-editor.org/info/rfc2104>.
[RFC2408] Maughan, D., Schertler, M., Schneider, M., and J. Turner,
"Internet Security Association and Key Management Protocol
(ISAKMP)", RFC 2408, DOI 10.17487/RFC2408, November 1998,
<https://www.rfc-editor.org/info/rfc2408>.
[RFC2747] Baker, F., Lindell, B., and M. Talwar, "RSVP Cryptographic
Authentication", RFC 2747, DOI 10.17487/RFC2747, January
2000, <https://www.rfc-editor.org/info/rfc2747>.
[RFC2752] Yadav, S., Yavatkar, R., Pabbati, R., Ford, P., Moore, T.,
and S. Herzog, "Identity Representation for RSVP",
RFC 2752, DOI 10.17487/RFC2752, January 2000,
<https://www.rfc-editor.org/info/rfc2752>.
[RFC3182] Yadav, S., Yavatkar, R., Pabbati, R., Ford, P., Moore, T.,
Herzog, S., and R. Hess, "Identity Representation for
RSVP", RFC 3182, DOI 10.17487/RFC3182, October 2001,
<https://www.rfc-editor.org/info/rfc3182>.
[RFC4086] Eastlake 3rd, D., Schiller, J., and S. Crocker,
"Randomness Requirements for Security", BCP 106, RFC 4086,
DOI 10.17487/RFC4086, June 2005,
<https://www.rfc-editor.org/info/rfc4086>.
[RFC5905] Mills, D., Martin, J., Ed., Burbank, J., and W. Kasch,
"Network Time Protocol Version 4: Protocol and Algorithms
Specification", RFC 5905, DOI 10.17487/RFC5905, June 2010,
<https://www.rfc-editor.org/info/rfc5905>.
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[RFC6241] Enns, R., Ed., Bjorklund, M., Ed., Schoenwaelder, J., Ed.,
and A. Bierman, Ed., "Network Configuration Protocol
(NETCONF)", RFC 6241, DOI 10.17487/RFC6241, June 2011,
<https://www.rfc-editor.org/info/rfc6241>.
[RFC9293] Eddy, W., Ed., "Transmission Control Protocol (TCP)",
STD 7, RFC 9293, DOI 10.17487/RFC9293, August 2022,
<https://www.rfc-editor.org/info/rfc9293>.
[DS-1981] Denning, D. and G. Sacco, "Timestamps in Key Distribution
Protocols", August 1981. Communications of the ACM, Vol.
24, No. 8
[G.8265.1] ITU-T, "Precision Time Protocol Telecom Profile for
Frequency Synchronization", ITU-T Recommendation G.8265.1,
July 2014.
[IEEE-802.1AE-2018]
Institute of Electrical and Electronics Engineers (IEEE),
"IEEE Standard for Local and Metropolitan Area Networks -
Media Access Control (MAC) Security", December 2018,
<https://standards.ieee.org/IEEE/802.1AE/7154/>. IEEE
Standard 802.1AE
[IEEE-1588-2019]
Institute of Electrical and Electronics Engineers (IEEE),
"IEEE Standard for Precision Clock Synchronization
Protocol for Networked Measurement and Control Systems
(PTP v2.1)", June 2020,
<https://ieeexplore.ieee.org/document/9120376>. IEEE
Standard 1588
[NIST-ENTROPY]
Turan, M., "Recommendation for the Entropy Sources Used
for Random Bit Generation", January 2018,
<https://csrc.nist.gov/pubs/sp/800/90/b/final>. Special
Publication 800-90B
[NIST-GMAC]
Dworkin, M., "Recommendation for Block Cipher Modes of
Operation: Galois Counter Mode (GCM) and GMAC", November
2007, <http://csrc.nist.gov/Projects/message-
authentication-codes>. Special Publication 800-38D
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[NIST-HMAC]
(US) National Institute of Standards and Technology,
Gaithersburg, MD, USA, "Keyed-Hash Message Authentication
Code (HMAC)", July 2008, <http://csrc.nist.gov/Projects/
message-authentication-codes>. (US) Federal Information
Processing Standard 198-1 (FIPS-198-1)
[NIST-KMAC]
Kelsey, J., Chang, S.-J., and R. Perlner, "SHA-3 Derived
Functions - cSHAKE, KMAC, TupleHash, and ParallelHash",
December 2016, <http://csrc.nist.gov/Projects/message-
authentication-codes>. Special Publication 800-185
[NIST-RMF] Joint Task Force, "Risk Management Framework for
Information Systems and Organizations", December 2018,
<http://csrc.nist.gov/Projects/risk-management>. Special
Publication 800-37, Revision 2
[NSA-MSCCP]
(US) National Security Agency, Ft. Meade, MD, USA, "Multi-
Site Connectivity Capability Package", June 2018,
<https://www.nsa.gov/Resources/Commercial-Solutions-for-
Classified-Program/Capability-Packages/>. Version 1.1
[WAGNER] Wagner, R., "Comments on Decision Proposal to convert
FIPS-198-1 to a NIST Special Publication", October 2022,
<https://csrc.nist.gov/csrc/media/Projects/crypto-
publication-review-project/documents/decision-proposal-
comments/fips198-1-decision-proposal-comments-2022.pdf>.
Authors' Addresses
Ran Atkinson
Consultant
Email: rja.lists@gmail.com
Tony Li
Juniper Networks
Email: tony.li@tony.li
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