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RFC 8374
Independent Submission K. Sriram, Ed.
Request for Comments: 8374 USA NIST
Category: Informational April 2018
ISSN: 2070-1721
BGPsec Design Choices and Summary of Supporting Discussions
Abstract
This document captures the design rationale of the initial draft
version of what became RFC 8205 (the BGPsec protocol specification).
The designers needed to balance many competing factors, and this
document lists the decisions that were made in favor of or against
each design choice. This document also presents brief summaries of
the arguments that aided the decision process. Where appropriate,
this document also provides brief notes on design decisions that
changed as the specification was reviewed and updated by the IETF
SIDR Working Group and that resulted in RFC 8205. These notes
highlight the differences and provide pointers to details and
rationale regarding those design changes.
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for informational purposes.
This is a contribution to the RFC Series, independently of any other
RFC stream. The RFC Editor has chosen to publish this document at
its discretion and makes no statement about its value for
implementation or deployment. Documents approved for publication by
the RFC Editor are not candidates for any level of Internet Standard;
see Section 2 of RFC 7841.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
https://www.rfc-editor.org/info/rfc8374.
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Copyright Notice
Copyright (c) 2018 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.
Table of Contents
1. Introduction ....................................................4
2. Creating Signatures and the Structure of BGPsec Update
Messages ........................................................5
2.1. Origin Validation Using ROAs ...............................5
2.2. Attributes Signed by an Originating AS .....................6
2.3. Attributes Signed by an Upstream AS ........................7
2.4. Attributes That Are Not Signed .............................8
2.5. Receiving Router Actions ...................................9
2.6. Prepending of ASes in AS Path .............................10
2.7. RPKI Data That Needs to Be Included in Updates ............10
3. Withdrawal Protection ..........................................11
3.1. Withdrawals Not Signed ....................................11
3.2. Signature Expire Time for Withdrawal Protection
(a.k.a. Mitigation of Replay Attacks) .....................12
3.3. Should Route Expire Time be Communicated in a
Separate Message? .........................................13
3.4. Effect of Expire Time Updates in BGPsec on RFD ............14
4. Signature Algorithms and Router Keys ...........................16
4.1. Signature Algorithms ......................................16
4.2. Agility of Signature Algorithms ...........................17
4.3. Sequential Aggregate Signatures ...........................18
4.4. Protocol Extensibility ....................................19
4.5. Key per Router (Rogue Router Problem) .....................20
4.6. Router ID .................................................20
5. Optimizations and Resource Sizing ..............................21
5.1. Update Packing and Repacking ..............................21
5.2. Signature per Prefix vs. Signature per Update .............22
5.3. Maximum BGPsec Update PDU Size ............................22
5.4. Temporary Suspension of Attestations and Validations ......23
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6. Incremental Deployment and Negotiation of BGPsec ...............24
6.1. Downgrade Attacks .........................................24
6.2. Inclusion of Address Family in Capability Advertisement ...24
6.3. Incremental Deployment: Capability Negotiation ............25
6.4. Partial Path Signing ......................................25
6.5. Consideration of Stub ASes with Resource
Constraints: Encouraging Early Adoption ...................26
6.6. Proxy Signing .............................................27
6.7. Multiple Peering Sessions between ASes ....................28
7. Interaction of BGPsec with Common BGP Features .................29
7.1. Peer Groups ...............................................29
7.2. Communities ...............................................29
7.3. Consideration of iBGP Speakers and Confederations .........30
7.4. Consideration of Route Servers in IXPs ....................31
7.5. Proxy Aggregation (a.k.a. AS_SETs) ........................32
7.6. 4-Byte AS Numbers .........................................32
8. BGPsec Validation ..............................................33
8.1. Sequence of BGPsec Validation Processing in a Receiver ....33
8.2. Signing and Forwarding Updates when Signatures
Failed Validation .........................................34
8.3. Enumeration of Error Conditions ...........................35
8.4. Procedure for Processing Unsigned Updates .................36
8.5. Response to Syntactic Errors in Signatures and
Recommendations for How to React to Them ..................36
8.6. Enumeration of Validation States ..........................37
8.7. Mechanism for Transporting Validation State through iBGP ..39
9. Operational Considerations .....................................41
9.1. Interworking with BGP Graceful Restart ....................41
9.2. BCP Recommendations for Minimizing Churn:
Certificate Expiry/Revocation and Signature Expire Time ...42
9.3. Outsourcing Update Validation .............................42
9.4. New Hardware Capability ...................................43
9.5. Signed Peering Registrations ..............................44
10. Security Considerations .......................................44
11. IANA Considerations ...........................................44
12. Informative References ........................................44
Acknowledgements ..................................................49
Contributors ......................................................49
Author's Address ..................................................50
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1. Introduction
The goal of the BGPsec effort is to enhance the security of BGP by
enabling full Autonomous System (AS) path validation based on
cryptographic principles. Standards work on route origin validation
based on a Resource PKI (RPKI) is already completed or nearing
completion in the IETF SIDR WG [RFC6480] [RFC6482] [RFC6483]
[RFC6487] [RFC6811]. The BGPsec effort is aimed at taking advantage
of the same RPKI infrastructure developed in the SIDR WG to add
cryptographic signatures to BGP updates, so that routers can perform
full AS path validation [RFC7132] [RFC7353] [RFC8205]. The BGPsec
protocol specification, [RFC8205], was published recently. The key
high-level design goals of the BGPsec protocol are as follows
[RFC7353]:
o Rigorous path validation for all announced prefixes -- not merely
showing that a path is not impossible.
o Incremental deployment capability -- no flag-day requirement for
global deployment.
o Protection of AS paths only in inter-domain routing (External BGP
(eBGP)) -- not applicable to Internal BGP (iBGP) (or to IGPs).
o Aiming for no increase in a provider's data exposure (e.g., not
requiring any disclosure of peering relations).
This document provides design justifications for the initial draft
version of the BGPsec protocol specification [BGPsec-Initial]. The
designers needed to balance many competing factors, and this document
lists the decisions that were made in favor of or against each design
choice. This document also presents brief summaries of the
discussions that weighed in on the pros and cons and aided the
decision process. Where appropriate, this document provides brief
notes (starting with "Note:") on design decisions that changed from
the approach taken in the initial draft version of the BGPsec
protocol specification as the specification was reviewed and updated
by the IETF SIDR WG. (These design decisions resulted in RFC 8205
[RFC8205].) The notes provide pointers to the details and/or
discussions about the design changes.
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The design choices and discussions are presented in the following
sections (under the following eight broad categories, with many
subtopics within each category):
o Section 2 ("Creating Signatures and the Structure of BGPsec Update
Messages")
o Section 3 ("Withdrawal Protection")
o Section 4 ("Signature Algorithms and Router Keys")
o Section 5 ("Optimizations and Resource Sizing")
o Section 6 ("Incremental Deployment and Negotiation of BGPsec")
o Section 7 ("Interaction of BGPsec with Common BGP Features")
o Section 8 ("BGPsec Validation")
o Section 9 ("Operational Considerations")
2. Creating Signatures and the Structure of BGPsec Update Messages
2.1. Origin Validation Using ROAs
2.1.1. Decision
Route origin validation using Route Origin Authorizations (ROAs)
[RFC6482] [RFC6811] is necessary and complements AS path attestation
based on signed updates. Thus, the BGPsec design makes use of the
origin validation capability facilitated by the ROAs in the RPKI.
Note: In the finalized BGPsec protocol specification [RFC8205],
BGPsec is synonymous with cryptographic AS path attestation. Origin
validation and BGPsec (path signatures) are the two key pieces of the
SIDR WG solution for BGP security.
2.1.2. Discussion
Route origin validation using RPKI constructs, as developed in the
IETF SIDR WG, is a necessary component of BGP security. It provides
cryptographic validation that the first-hop AS is authorized to
originate a route for the prefix in question.
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2.2. Attributes Signed by an Originating AS
2.2.1. Decision
An originating AS will sign over the Network Layer Reachability
Information (NLRI) length, NLRI prefix, its own AS number (ASN), the
next ASN, the signature algorithm suite ID, and a signature
Expire Time (see Section 3.2) for the update. The update signatures
will be carried in a new optional, non-transitive BGP attribute.
Note: The finalized BGPsec protocol specification [RFC8205] differs
from the above. There is no mention in RFC 8205 of a signature
Expire Time field in the BGPsec update. Further, there are some
additional details concerning attributes signed by the origin AS that
can be found in Figure 8 in Section 4.2 of RFC 8205 [RFC8205]. In
particular, the signed data also includes the Address Family
Identifier (AFI) as described in RFC 8205. By adding the AFI in the
data covered by a signature, a specific security concern was
alleviated; see [Mandelberg1] (post to the SIDR WG Mailing List) and
the discussion thread that followed on the topic. The AFI is
obtained from the MP_REACH_NLRI attribute in the BGPsec update. As
stated in Section 4.1 of RFC 8205, a BGPsec update message "MUST use
the MP_REACH_NLRI attribute [RFC4760] to encode the prefix."
2.2.2. Discussion
The next-hop ASN is included in the data covered by the signature.
Without this inclusion, the AS path cannot be secured; for example,
the path can be shortened (by a MITM (man in the middle)) without
being detected.
It was decided that only the originating AS needs to insert a
signature Expire Time in the update, as it is the originator of the
route. The origin AS also will re-originate, i.e., beacon, the
update prior to the Expire Time of the advertisement (see
Section 3.2). (For an explanation of why upstream ASes do not insert
their respective signature Expire Times, please see Section 3.2.2.)
Note: Expire Time and beaconing were eventually replaced by router
key rollover. The BGPsec protocol [RFC8205] is expected to make use
of router key rollover to mitigate replay attacks and withdrawal
suppression [BGPsec-Rollover] [Replay-Protection].
It was decided that each signed update would include only one NLRI
prefix. If more than one NLRI prefix were included and an upstream
AS elected to propagate the advertisement for a subset of the
prefixes, then the signature(s) on the update would break (see
Sections 5.1 and 5.2). If a mechanism were employed to preserve
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prefixes that were dropped, this would reveal information to
subsequent ASes that is not revealed in normal BGP operation. Thus,
a trade-off was made to preserve the level of route information
exposure that is intrinsic to BGP over the performance hit implied by
limiting each update to carry only one prefix.
The signature data is carried in an optional, non-transitive BGP
attribute. The attribute is optional because this is the standard
mechanism available in BGP to propagate new types of data. It was
decided that the attribute should be non-transitive because of
concern about the impact of sending the (potentially large)
signatures to routers that don't understand them. Also, if a router
that does not understand BGPsec somehow gets an update message with
path signatures (i.e., the update includes the BGPsec_PATH attribute
(see Section 3 of RFC 8205)), then it would be undesirable for that
router to forward the update to all of its neighbors, especially
those who do not understand BGPsec and may choke if they receive many
updates with large optional BGP attributes. It is envisioned that
BGPsec and traditional BGP will coexist while BGPsec is deployed
incrementally.
2.3. Attributes Signed by an Upstream AS
In the context of BGPsec and throughout this document, an "upstream
AS" simply refers to an AS that is further along in an AS path (the
origin AS being the nearest to a prefix). In principle, an AS that
is upstream from an originating AS would digitally sign the combined
information, including the NLRI length, NLRI prefix, AS path, next
ASN, signature algorithm suite ID, and Expire Time. There are
multiple choices regarding what is signed by an upstream AS, as
follows:
o Method 1: The signature protects the combination of the NLRI
length, NLRI prefix, AS path, next ASN, signature algorithm suite
ID, and Expire Time,
o Method 2: The signature protects just the combination of the
previous signature (i.e., the signature of the neighbor AS who
forwarded the update) and the next ASN, or
o Method 3: The signature protects everything that was received from
the preceding AS plus the next (i.e., target) ASN; thus, ASi signs
over the NLRI length, NLRI prefix, signature algorithm suite ID,
Expire Time, {ASi, AS(i-1), AS(i-2), ..., AS2, AS1}, AS(i+1)
(i.e., the next ASN), and {Sig(i-1), Sig(i-2), ..., Sig2, Sig1}.
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Note: Please see the notes in Sections 2.2.1 and 2.2.2 regarding the
elimination of the Expire Time field in the finalized BGPsec protocol
specification [RFC8205].
2.3.1. Decision
It was decided that Method 2 will be used. Please see
[BGPsec-Initial] for additional protocol details and syntax.
Note: The finalized BGPsec protocol specification [RFC8205]
essentially uses Method 3 (except for Expire Time). Additional
details concerning attributes signed by an upstream AS can be found
in Figure 8 in Section 4.2 of RFC 8205 [RFC8205]. The decision to go
with Method 3 (with suitable additions to the data signed) was
motivated by a security concern that was associated with Method 2;
see [Mandelberg2] (post to the SIDR WG Mailing List) and the
discussion thread that followed on the topic. Also, there is a
strong rationale for the sequence of octets to be hashed (as shown in
Figure 8 in Section 4.2 of RFC 8205); this sequencing of data is
motivated by implementation efficiency considerations. See
[Borchert] (post to the SIDR WG Mailing List) for an explanation.
2.3.2. Discussion
The rationale for this choice (Method 2) was as follows. Signatures
are performed over hash blocks. When the number of bytes to be
signed exceeds one hash block, the remaining bytes will overflow into
a second hash block, resulting in a performance penalty. So, it is
advantageous to minimize the number of bytes being hashed. Also, an
analysis of the three options noted above did not identify any
vulnerabilities associated with this approach.
2.4. Attributes That Are Not Signed
2.4.1. Decision
Any attributes other than those identified in Sections 2.2 and 2.3
are not signed. Examples of such attributes include the community
attribute, the NO-EXPORT attribute, and Local_Pref.
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2.4.2. Discussion
Any of the above-mentioned attributes that are not signed are viewed
as local (e.g., do not need to propagate beyond the next hop) or lack
clear security needs. NO-EXPORT is sent over a secured next hop and
does not need signing. The BGPsec design should work with any
transport-layer protections. It is well understood that the
transport layer must be protected hop by hop (if only to prevent
malicious session termination).
2.5. Receiving Router Actions
2.5.1. Decision
The following example describes the expected router actions on
receipt of a signed update. Consider an update that was originated
by AS1 with NLRI prefix p and has traversed the AS path [AS(i-1)
AS(i-2) ... AS2 AS1] before arriving at ASi. Let the Expire Time
(inserted by AS1) for the signature in this update be denoted as Te.
Let AlgID represent the ID of the signature algorithm suite that is
in use. The update is to be processed at ASi and possibly forwarded
to AS(i+1). Let the attestations (signatures) inserted by each
router in the AS path be denoted by Sig1, Sig2, ..., Sig(i-2), and
Sig(i-1) corresponding to AS1, AS2, ..., AS(i-2), and AS(i-1),
respectively.
The method (Method 2 in Section 2.3) selected for signing requires a
receiving router in ASi to perform the following actions:
o Validate the route origin pair (p, AS1) by performing a ROA match.
o Verify that Te is greater than the clock time at the router
performing these checks.
o Check Sig1 with inputs {NLRI length, p, AlgID, Te, AS1, AS2}.
o Check Sig2 with inputs {Sig1, AS3}.
o Check Sig3 with inputs {Sig2, AS4}.
o ...
o ...
o Check Sig(i-2) with inputs {Sig(i-3), AS(i-1)}.
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o Check Sig(i-1) with inputs {Sig(i-2), ASi}.
o If the route that has been verified is selected as the best path
(for prefix p), then generate Sig(i) with inputs {Sig(i-1),
AS(i+1)}, and generate an update including Sig(i) to AS(i+1).
Note: The above description of BGPsec update validation and
forwarding differs in its details from the published BGPsec protocol
specification [RFC8205]. Please see Sections 4 and 5 of [RFC8205].
2.5.2. Discussion
See Section 8.1 for suggestions regarding efficient sequencing of
BGPsec validation processing in a receiving router. Some or all of
the validation actions may be performed by an off-board server (see
Section 9.3).
2.6. Prepending of ASes in AS Path
2.6.1. Decision
Prepending will be allowed. Prepending is defined as including more
than one instance of the AS number (ASN) of the router that is
signing the update.
Note: The finalized BGPsec protocol specification [RFC8205] uses a
pCount field associated with each AS in the path to indicate the
number of prepends for that AS (see Figure 5 in Section 3.1 of
[RFC8205]).
2.6.2. Discussion
The initial version [BGPsec-Initial] of the BGPsec specification
calls for a signature to be associated with each prepended AS. The
optimization of having just one signature for multiple prepended ASes
was pursued later. The pCount field is now used to represent AS
prepends; see Section 3.1 in RFC 8205.
2.7. RPKI Data That Needs to Be Included in Updates
2.7.1. Decision
Concerning the inclusion of RPKI data in an update, it was decided
that only the Subject Key Identifier (SKI) of the router certificate
must be included in a signed update. This information identifies the
router certificate, based on the SKI generation criteria defined in
[RFC6487].
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2.7.2. Discussion
Whether or not each router public key certificate should be included
in a signed update was discussed. Inclusion of this information
might be helpful for routers that do not have access to RPKI servers
or temporarily lose connectivity to them. It is safe to assume that
in the majority of network environments, intermittent connectivity
would not be a problem. So, it is best to avoid this complexity,
because the majority of the use environments do not have connectivity
constraints. Because the SKI of a router certificate is a hash of
the public key of that certificate, it suffices to select the public
key from that certificate. This design assumes that each BGPsec
router has access to a cache containing the relevant data from
(validated) router certificates.
3. Withdrawal Protection
3.1. Withdrawals Not Signed
3.1.1. Decision
Withdrawals are not signed.
3.1.2. Discussion
In the current BGP protocol, any AS can withdraw, at any time, any
prefix it previously announced. The rationale for not signing
withdrawals is that BGPsec assumes the use of transport security
between neighboring BGPsec routers. Thus, no external entity can
inject an update that withdraws a route or replay a previously
transmitted update containing a withdrawal. Because the rationale
for withdrawing a route is not visible to a neighboring BGPsec
router, there are residual vulnerabilities associated with
withdrawals. For example, a router that advertised a (valid) route
may fail to withdraw that route when it is no longer viable. A
router also might re-advertise a route that it previously withdrew,
before the route is again viable. This latter vulnerability is
mitigated by the Expire Time associated with the origin AS's
signature (see Section 3.2).
Repeated withdrawals and announcements for a prefix can run up the
BGP Route Flap Damping (RFD) penalty [RFC2439] and may result in
unreachability for that prefix at upstream routers. But what can the
attacker gain from doing so? This phenomenon is intrinsic to the
design and operation of RFD.
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3.2. Signature Expire Time for Withdrawal Protection (a.k.a.
Mitigation of Replay Attacks)
3.2.1. Decision
Note: As mentioned earlier (Section 2.2.2), the Expire Time approach
to mitigation of replay attacks and withdrawal suppression was
subsequently changed to an approach based on router key rollover
[BGPsec-Rollover] [Replay-Protection].
Only the originating AS inserts a signature Expire Time in the
update; all other ASes along an AS path do not insert Expire Times
associated with their respective signatures. Further, the
originating AS will re-originate a route sufficiently in advance of
the Expire Time of its signature so that other ASes along an AS path
will typically receive the re-originated route well ahead of the
current Expire Time for that route.
It is recommended that the duration of the signature Expire Time be
on the order of days (preferably), but it may be on the order of
hours (about 4 to 8 hours) in some cases on the basis of perceived
need for extra protection from replay attacks (i.e., where extra
replay protection is perceived to be critical).
Each AS should stagger the Expire Time values in the routes it
originates. Re-origination will be done, say, at time Tb after
origination or the last re-origination, where Tb will equal a certain
percentage of the Expire Time, Te (for example, Tb = 0.75 x Te). The
percentage will be configurable. Additional guidance can be provided
via an operational considerations document later. Further, the
actual re-origination time should be jittered with a uniform random
distribution over a short interval {Tb1, Tb2} centered at Tb.
It is also recommended that a receiving BGPsec router detect that the
only attribute change in an announcement (relative to the current
best path) is the Expire Time (besides, of course, the signatures).
In that case, assuming that the update is found valid, the route
processor should not re-announce the route to non-BGPsec peers. (It
should sign and re-announce the route to BGPsec speakers only.) This
procedure will reduce BGP chattiness for the non-BGPsec border
routers.
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3.2.2. Discussion
Mitigation of BGPsec update replay attacks can be thought of as
protection against malicious re-advertisements of withdrawn routes.
If each AS along a path were to insert its own signature Expire Time,
then there would be much additional BGP chattiness and an increase in
BGP processing load due to the need to detect and react to multiple
(possibly redundant) signature Expire Times. Furthermore, there
would be no extra benefit from the point of view of mitigation of
replay attacks as compared to having a single Expire Time
corresponding to the signature of the originating AS.
As noted in Section 3.2.1, the recommended Expire Time value is on
the order of days, but 4 to 8 hours may be used in some cases on the
basis of perceived need for extra protection from replay attacks.
Thus, different ASes may choose different values based on the
perceived need to protect against malicious route replays. (A
shorter Expire Time reduces the window during which an AS can
maliciously replay the route. However, shorter Expire Time values
cause routes to be refreshed more often, thus causing more BGP
chatter.) Even a 4-hour duration seems long enough to keep the
re-origination workload manageable. For example, if 500K routes are
re-originated every 4 hours, it amounts to an increase in BGP update
load of 35 updates per second; this can be considered reasonable.
However, further analysis is needed to confirm these recommendations.
As stated in Section 3.2.1, the originating AS will re-originate a
route sufficiently in advance of its Expire Time. What is considered
"sufficiently in advance"? To answer this question, modeling should
be performed to determine the 95th-percentile convergence time of
update propagation in a BGPsec-enabled Internet.
Each BGPsec router should stagger the Expire Time values in the
updates it originates, especially during table dumps to a neighbor or
during its own recovery from a BGP session failure. By doing this,
the re-origination (i.e., beaconing) workload at the router will be
dispersed.
3.3. Should Route Expire Time be Communicated in a Separate Message?
3.3.1. Decision
The idea of sending a new signature Expire Time in a special message
(rather than retransmitting the entire update with signatures) was
considered. However, the decision was made to not do this.
Re-origination to communicate a new signature Expire Time will be
done by propagating a normal update message; no special type of
message will be required.
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3.3.2. Discussion
It was suggested that if the re-beaconing of the signature
Expire Time is carried in a separate special message, then any
processing load related to the update may be reduced. But it was
recognized that such a re-beaconing message by necessity entails AS
path and prefix information and, hence, cannot be separated from the
update.
It was observed that at the edge of the Internet, there are frequent
updates that may result from such simple situations as a BGP session
being switched from one interface to another (e.g., from primary to
backup) between two peering ASes (e.g., customer and provider). With
traditional BGP, these updates do not propagate beyond the two ASes
involved. But with BGPsec, the customer AS will put in a new
signature Expire Time each time such an event happens; hence, the
update will need to propagate throughout the Internet (limited only
by the process of best-path selection). It was accepted that this
cost of added churn will be unavoidable.
3.4. Effect of Expire Time Updates in BGPsec on RFD
3.4.1. Decision
With regard to the RFD protocol [RFC2439] [JunOS] [CiscoIOS], no
differential treatment is required for Expire-Time-triggered
(re-beaconed) BGPsec updates.
However, it was noted that it would be preferable if these updates
did not cause route churn (and perhaps did not even require any
RFD-related processing), since they are identical except for the
change in the Expire Time value. This can be accomplished by not
assigning an RFD penalty to Expire-Time-triggered updates. If the
community agrees, this could be accommodated, but a change to the
BGP-RFD protocol will be required.
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3.4.2. Discussion
To summarize, this decision is supported by the following
observations:
1. Expire-Time-triggered updates are generally not preceded by
withdrawals; hence, the path hunting and associated RFD
exacerbation [Mao02] [RIPE580] problems are not anticipated.
2. Such updates would not normally change the best path (unless
another concurrent event impacts the best path).
3. Expire-Time-triggered updates would have a negligible impact on
RFD penalty accumulation because the re-advertisement interval is
much longer relative to the half-time of RFD penalty decay.
Elaborating further on the third observation above, it may be noted
that the re-advertisements (i.e., beacons) of a route for a given
address prefix from a given peer will be received at intervals of
several hours (see Section 3.2). During that time period, any
incremental contribution to the RFD penalty due to an Expire-Time-
triggered update would decay sufficiently to have negligible (if any)
impact on damping the address prefix in question.
Additional details regarding this analysis and justification are as
follows:
The frequency with which RFD penalty increments may be triggered for
a given prefix from a given peer is the same as the re-beaconing
frequency for that prefix from its origin AS. The re-beaconing
frequency is on the order of once every several hours (see
Section 3.2). The incremental RFD penalty assigned to a prefix due
to a re-beaconed update varies, depending on the implementation. For
example, it appears that the JunOS implementation [JunOS] would
assign a penalty of 1000 or 500, depending on whether the re-beaconed
update is regarded as a re-advertisement or an attribute change,
respectively. Normally, a re-beaconed update would be treated as an
attribute change. On the other hand, the Cisco implementation
[CiscoIOS] assigns an RFD penalty only in the case of an actual flap
(i.e., a route is available, then unavailable, or vice versa). So,
it appears that Cisco's implementation of RFD would not assign any
penalty for a re-beaconed update (i.e., a route was already
advertised previously and was not withdrawn, and the re-beaconed
update is merely updating the Expire Time attribute). Even if one
assumes that an RFD penalty of 500 is assigned (corresponding to an
attribute change according to the JunOS RFD implementation), it can
be illustrated that the incremental effect it would have on damping
the prefix in question would be negligible: the half-time of RFD
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penalty decay is normally set to 15 minutes, whereas the re-beaconing
frequency is on the order of once every several hours. An
incremental penalty of 500 would decay to 31.25 in 1 hour, 0.12 in
2 hours, and 3x10^(-5) in 3 hours. It may also be noted that the
threshold for route suppression is 3000 in JunOS and 2000 in
Cisco IOS. Based on the foregoing analysis, it may be concluded that
routine re-beaconing by itself would not result in RFD suppression of
routes in the BGPsec protocol.
4. Signature Algorithms and Router Keys
4.1. Signature Algorithms
4.1.1. Decision
Initially, the Elliptic Curve Digital Signature Algorithm (ECDSA)
with curve P-256 and SHA-256 will be used for generating BGPsec path
signatures. One other signature algorithm, e.g., RSA-2048, will also
be used during prototyping and testing. The use of a second
signature algorithm is needed to verify the ability of the BGPsec
implementations to change from a current algorithm to the next
algorithm.
Note: The BGPsec cryptographic algorithms document [RFC8208]
specifies only the ECDSA with curve P-256 and SHA-256.
4.1.2. Discussion
Initially, the RSA-2048 algorithm for BGPsec update signatures was
considered as a choice because it is being used ubiquitously in the
RPKI system. However, the use of ECDSA P-256 was decided upon
because it yields a smaller signature size; hence, the update size
and (in turn) the RIB size needed in BGPsec routers would be much
smaller [RIB_size].
Using two different signature algorithms (e.g., ECDSA P-256 and
RSA-2048) to test the transition from one algorithm to the other will
increase confidence in prototype implementations.
Optimizations and specialized algorithms (e.g., for speedups) built
on Elliptic Curve Cryptography (ECC) algorithms may have active IPR
(intellectual property rights), but at the time of publication of
this document no IPR had been disclosed to the IETF for the basic
(unoptimized) algorithms. (To understand this better, [RFC6090] can
be useful as a starting point.)
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Note: Recently, even open-source implementations have incorporated
certain cryptographic optimizations and demonstrated significant
performance speedup [Gueron]. Researchers continue to devote
significant effort toward demonstrating substantial speedup for the
ECDSA as part of BGPsec implementations [Mehmet1] [Mehmet2].
4.2. Agility of Signature Algorithms
4.2.1. Decision
During the transition period from one algorithm (i.e., the current
algorithm) to the next (new) algorithm, the updates will carry two
sets of signatures (i.e., two Signature_Blocks), one corresponding to
each algorithm. Each Signature_Block will be preceded by its
type-length field and an algorithm suite identifier. A BGPsec
speaker that has been upgraded to handle the new algorithm should
validate both Signature_Blocks and then add its corresponding
signature to each Signature_Block for forwarding the update to the
next AS. A BGPsec speaker that has not been upgraded to handle the
new algorithm will strip off the Signature_Block of the new algorithm
and then will forward the update after adding its own signature to
the Signature_Block of the current algorithm.
It was decided that there will be at most two Signature_Blocks per
update.
Note: BGPsec path signatures are carried in the Signature_Block,
which is an attribute contained in the BGPsec_PATH attribute (see
Section 3.2 in [RFC8205]). The algorithm agility scheme described in
the published BGPsec protocol specification is consistent with the
above; see Section 6.1 of [RFC8205].
4.2.2. Discussion
A length field in the Signature_Block allows for delineation of the
two signature blocks. Hence, a BGPsec router that doesn't know about
a particular algorithm suite (and, hence, doesn't know how long
signatures were for that algorithm suite) could still skip over the
corresponding Signature_Block when parsing the message.
The overlap period between the two algorithms is expected to last
2 to 4 years. The RIB memory and cryptographic processing capacity
will have to be sized to cope with such overlap periods when updates
would contain two sets of signatures [RIB_size].
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The lifetime of a signature algorithm is anticipated to be much
longer than the duration of a transition period from the current
algorithm to a new algorithm. It is fully expected that all ASes
will have converted to the required new algorithm within a certain
amount of time that is much shorter than the interval in which a
subsequent newer algorithm may be investigated and standardized for
BGPsec. Hence, the need for more than two Signature_Blocks per
update is not envisioned.
4.3. Sequential Aggregate Signatures
4.3.1. Decision
There is currently weak or no support for the Sequential Aggregate
Signature (SAS) approach. Please see Section 4.3.2 for a brief
description of what the SAS is and what its pros and cons are.
4.3.2. Discussion
In the SAS method, there would be only one (aggregated) signature per
signature block, irrespective of the number of AS hops. For example,
ASn (the nth AS) takes as input the signatures of all previous ASes
[AS1, ..., AS(n-1)] and produces a single composite signature. This
composite signature has the property that a recipient who has the
public keys for AS1, ..., ASn can verify (using only the single
composite signature) that all of the ASes actually signed the
message. The SAS could potentially result in savings in bandwidth
and in Protocol Data Unit (PDU) size, and maybe in RIB size, but the
signature generation and validation costs will be higher as compared
to one signature per AS hop.
SAS schemes exist in the literature, typically based on RSA or its
equivalent. For a SAS with RSA and for the cryptographic strength
needed for BGPsec signatures, a 2048-bit signature size (RSA-2048)
would be required. However, without a SAS, the ECDSA with a 512-bit
signature (256-bit key) would suffice for equivalent cryptographic
strength. The larger signature size of RSA used with a SAS
undermines the advantages of the SAS, because the average hop count,
i.e., the number of ASes, for a route is about 3.8. In the end, it
may turn out that the SAS has more complexity and does not provide
sufficient savings in PDU size or RIB size to merit its use. Further
exploration of this is needed to better understand SAS properties and
applicability for BGPsec. There is also a concern that the SAS is
not a time-tested cryptographic technique, and thus its adoption is
potentially risky.
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4.4. Protocol Extensibility
There is clearly a need to specify a transition path from a current
protocol specification to a new version. When changes to the
processing of the BGPsec path signatures are required, a new version
of BGPsec will be required. Examples of this include changes to the
data that is protected by the BGPsec signatures or adoption of a
signature algorithm in which the number of signatures in the
signature block may not correspond to one signature per AS in the
AS path (e.g., aggregate signatures).
4.4.1. Decision
This protocol-version transition mechanism is analogous to the
algorithm transition discussed in Section 4.2. During the transition
period from one protocol version (i.e., the current version) to the
next (new) version, updates will carry two sets of signatures (i.e.,
two Signature_Blocks), one corresponding to each version. A
protocol-version identifier is associated with each Signature_Block.
Hence, each Signature_Block will be preceded by its type-length field
and a protocol-version identifier. A BGPsec speaker that has been
upgraded to handle the new version should validate both
Signature_Blocks and then add its corresponding signature to each
Signature_Block for forwarding the update to the next AS. A BGPsec
speaker that has not been upgraded to handle the new protocol version
will strip off the Signature_Block of the new version and then will
forward the update with an attachment of its own signature to the
Signature_Block of the current version.
Note: The details of protocol extensibility (i.e., transition to a
new version of BGPsec) in the published BGPsec protocol specification
(see Section 6.3 in [RFC8205]) differ somewhat from the above. In
particular, the protocol-version identifier is not part of the BGPsec
update. Instead, it is negotiated during the BGPsec capability
exchange portion of BGPsec session negotiation.
4.4.2. Discussion
In the case that a change to BGPsec is deemed desirable, it is
expected that a subsequent version of BGPsec would be created and
that this version of BGPsec would specify a new BGP path attribute
(let's call it "BGPsec_PATH_TWO") that is designed to accommodate the
desired changes to BGPsec. At this point, a transition would begin
that is analogous to the algorithm transition discussed in
Section 4.2. During the transition period, all BGPsec speakers will
simultaneously include both the BGPsec_PATH (current) attribute (see
Section 3 of RFC 8205) and the new BGPsec_PATH_TWO attribute. Once
the transition is complete, the use of BGPsec_PATH could then be
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deprecated, at which point BGPsec speakers will include only the new
BGPsec_PATH_TWO attribute. Such a process could facilitate a
transition to new BGPsec semantics in a backwards-compatible fashion.
4.5. Key per Router (Rogue Router Problem)
4.5.1. Decision
Within each AS, each individual BGPsec router can have a unique pair
of private and public keys [RFC8207].
4.5.2. Discussion
Given a unique key pair per router, if a router is compromised, its
key pair can be revoked independently, without disrupting the other
routers in the AS. Each per-router key pair will be represented in
an end-entity certificate issued under the certification authority
(CA) certificate of the AS. The Subject Key Identifier (SKI) in the
signature points to the router certificate (and thus the unique
public key) of the router that affixed its signature, so that a
validating router can reliably identify the public key to use for
signature verification.
4.6. Router ID
4.6.1. Decision
The router certificate subject name will be the string "ROUTER"
followed by a decimal representation of a 4-byte ASN followed by the
router ID. (Note: The details are specified in Section 3.1 in
[RFC8209].)
4.6.2. Discussion
Every X.509 certificate requires a subject name [RFC6487]. The
stylized subject name adopted here is intended to facilitate
debugging by including the ASN and router ID.
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5. Optimizations and Resource Sizing
5.1. Update Packing and Repacking
With traditional BGP [RFC4271], an originating BGP router normally
packs multiple prefix announcements into one update if the prefixes
all share the same BGP attributes. When an upstream BGP router
forwards eBGP updates to its peers, it can also pack multiple
prefixes (based on the shared AS path and attributes) into one
update. The update propagated by the upstream BGP router may include
only a subset of the prefixes that were packed in a received update.
5.1.1. Decision
Each update contains exactly one prefix. This avoids a level of
complexity that would otherwise be inevitable if the origin had
packed and signed multiple prefixes in an update and an upstream AS
decided to propagate an update containing only a subset of the
prefixes in that update. BGPsec recommendations regarding packing
and repacking may be revisited when optimizations are considered in
the future.
5.1.2. Discussion
Currently, with traditional BGP, there are, on average, approximately
four prefixes announced per update [RIB_size]. So, the number of BGP
updates (carrying announcements) is about four times fewer, on
average, as compared to the number of prefixes announced.
The current decision is to include only one prefix per secured update
(see Section 2.2.2). When optimizations are considered in the
future, the possibility of packing multiple prefixes into an update
can also be considered. (Please see Section 5.2 for a discussion of
signature per prefix vs. signature per update.) Repacking could be
performed if signatures were generated on a per-prefix basis.
However, one problem regarding this approach -- multiple prefixes in
a BGP update but with a separate signature for each prefix -- is that
the resulting BGP update violates the basic definition of a BGP
update: the different prefixes will have different signatures and
Expire Time attributes, while a BGP update (by definition) must have
the same set of shared attributes for all prefixes it carries.
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5.2. Signature per Prefix vs. Signature per Update
5.2.1. Decision
The initial design calls for including exactly one prefix per update;
hence, there is only one signature in each secured update (modulo
algorithm transition conditions).
5.2.2. Discussion
Some notes to assist in future optimization discussions follow:
In the general case of one signature per update, multiple prefixes
may be signed with one signature together with their shared AS path,
next ASN, and Expire Time. If the "signature per update" technique
is used, then there are potential savings in update PDU size as well
as RIB memory size. But if there are any changes made to the
announced prefix set along the AS path, then the AS where the change
occurs would need to insert an Explicit Path Attribute (EPA)
[Secure-BGP]. The EPA conveys information regarding what the prefix
set contained prior to the change. There would be one EPA for each
AS that made such a modification, and there would be a way to
associate each EPA with its corresponding AS. This enables an
upstream AS to know and verify what was announced and signed by prior
ASes in the AS path (in spite of changes made to the announced prefix
set along the way). The EPA adds complexity to processing (signature
generation and validation); further increases the size of updates
and, thus, of the RIB; and exposes data to downstream ASes that would
not otherwise be exposed. Not all of the pros and cons of packing
and repacking in the context of signature per prefix vs. signature
per update (with packing) have been evaluated. But the current
recommendation is for having only one prefix per update (no packing),
so there is no need for the EPA.
5.3. Maximum BGPsec Update PDU Size
The current BGP update message PDU size is limited to 4096 bytes
[RFC4271]. The question was raised as to whether or not BGPsec would
require a larger update PDU size.
5.3.1. Decision
The current thinking is that the maximum PDU size should be increased
to 64 KB [BGP-Ext-Msg] so that there is sufficient room to
accommodate two Signature_Blocks (i.e., one block with a current
algorithm and another block with a new signature algorithm during a
future transition period) for long AS paths.
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Note: RFC 8205 states the following: "All BGPsec UPDATE messages MUST
conform to BGP's maximum message size. If the resulting message
exceeds the maximum message size, then the guidelines in Section 9.2
of RFC 4271 [RFC4271] MUST be followed."
5.3.2. Discussion
The current maximum message size for BGP updates is 4096 octets. An
effort is underway in the IETF to extend it to a larger size
[BGP-Ext-Msg]. BGPsec will conform to whatever maximum message size
is available for BGP while adhering to the guidelines in Section 9.2
of RFC 4271 [RFC4271].
Note: Estimates for the average and maximum sizes anticipated for
BGPsec update messages are provided in [MsgSize].
5.4. Temporary Suspension of Attestations and Validations
5.4.1. Decision
If a BGPsec-capable router needs to temporarily suspend/defer signing
and/or validation of BGPsec updates during periods of route processor
overload, the router may do so even though such suspension/deferment
is not desirable; the specification does not forbid it. Following
any temporary suspension, the router should subsequently send signed
updates corresponding to the updates for which validation and signing
were skipped. The router also may choose to skip only validation but
still sign and forward updates during periods of congestion.
5.4.2. Discussion
In some situations, a BGPsec router may be unable to keep up with the
workload of performing signing and/or validation. This can happen,
for example, during BGP session recovery when a router has to send
the entire routing table to a recovering router in a neighboring AS
(see [CPUworkload]). So, it is possible that a BGPsec router
temporarily pauses performing the validation or signing of updates.
When the workload eases, the BGPsec router should clear the
validation or signing backlog and send signed updates corresponding
to the updates for which validation and signing were skipped. During
periods of overload, the router may simply send unsigned updates
(with signatures dropped) or may sign and forward the updates with
signatures (even though the router itself has not yet verified the
signatures it received).
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A BGPsec-capable AS may request (out of band) that a BGPsec-capable
peer AS never downgrade a signed update to an unsigned update.
However, in partial-deployment scenarios, it is not possible for a
BGPsec router to require a BGPsec-capable eBGP peer to send only
signed updates, except for prefixes originated by the peer's AS.
Note: If BGPsec has not been negotiated with a peer, then a BGPsec
router forwards only unsigned updates to that peer; the sending
router does so by following the reconstruction procedure in
Section 4.4 of [RFC8205] to generate an AS_PATH attribute
corresponding to the BGPsec_PATH attribute in a received signed
update. If the above-mentioned temporary suspension is ever applied,
then the same AS_PATH reconstruction procedure should be utilized.
6. Incremental Deployment and Negotiation of BGPsec
6.1. Downgrade Attacks
6.1.1. Decision
No attempt will be made in the BGPsec design to prevent downgrade
attacks, i.e., a BGPsec-capable router sending unsigned updates when
it is capable of sending signed updates.
6.1.2. Discussion
BGPsec allows routers to temporarily suspend signing updates (see
Section 5.4). Therefore, it would be contradictory if we were to try
to incorporate in the BGPsec protocol a way to detect and reject
downgrade attacks. One proposed way to detect downgrade attacks was
considered, based on signed peering registrations (see Section 9.5).
6.2. Inclusion of Address Family in Capability Advertisement
6.2.1. Decision
It was decided that during capability negotiation, the address family
for which the BGPsec speaker is advertising support for BGPsec will
be shared using the Address Family Identifier (AFI). Initially, two
address families would be included, namely, IPv4 and IPv6. BGPsec
for use with other address families may be specified in the future.
Simultaneous use of the two (i.e., IPv4 and IPv6) address families
for the same BGPsec session will require that the BGPsec speaker
include two instances of this capability (one for each address
family) during BGPsec capability negotiation.
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6.2.2. Discussion
If new address families are supported in the future, they will be
added in future versions of the specification. A comment was made
that too many version numbers are bad for interoperability.
Renegotiation on the fly to add a new address family (i.e., without
changeover to a new version number) is desirable.
6.3. Incremental Deployment: Capability Negotiation
6.3.1. Decision
BGPsec will be incrementally deployable. BGPsec routers will use
capability negotiation to agree to run BGPsec between them. If a
BGPsec router's peer does not agree to run BGPsec, then the BGPsec
router will run only traditional BGP with that peer, i.e., it will
not send BGPsec (i.e., signed) updates to the peer.
Note: See Section 7.9 of [RFC8205] for a discussion of incremental /
partial-deployment considerations. Also, Section 6 of [RFC8207]
describes how edge sites (stub ASes) can sign updates that they
originate but can receive only unsigned updates. This facilitates a
less expensive upgrade to BGPsec in resource-limited stub ASes and
expedites incremental deployment.
6.3.2. Discussion
The partial-deployment approach to incremental deployment will result
in "BGPsec islands". Updates that originate within a BGPsec island
will generally propagate with signed AS paths to the edges of that
island. As BGPsec adoption grows, the BGPsec islands will expand
outward (subsuming non-BGPsec portions of the Internet) and/or pairs
of islands may join to form larger BGPsec islands.
6.4. Partial Path Signing
"Partial path signing" means that a BGPsec AS can be permitted to
sign an update that was received unsigned from a downstream neighbor.
That is, the AS would add its ASN to the AS path and sign the
(previously unsigned) update to other neighboring (upstream)
BGPsec ASes.
6.4.1. Decision
It was decided that partial path signing in BGPsec will not be
allowed. A BGPsec update must be fully signed, i.e., each AS in the
AS path must sign the update. So, in a signed update, there must be
a signature corresponding to each AS in the AS path.
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6.4.2. Discussion
Partial path signing (as described above) implies that the AS path is
not rigorously protected. Rigorous AS path protection is a key
requirement of BGPsec [RFC7353]. Partial path signing clearly
reintroduces the following attack vulnerability: if a BGPsec speaker
is allowed to sign an unsigned update and if signed (i.e., partially
or fully signed) updates would be preferred over unsigned updates,
then a faulty, misconfigured, or subverted BGPsec speaker can
manufacture any unsigned update it wants (by inserting a valid origin
AS) and add a signature to it to increase the chance that its update
will be preferred.
6.5. Consideration of Stub ASes with Resource Constraints: Encouraging
Early Adoption
6.5.1. Decision
The protocol permits each pair of BGPsec-capable ASes to
asymmetrically negotiate the use of BGPsec. Thus, a stub AS (or
downstream customer AS) can agree to perform BGPsec only in the
transmit direction and speak traditional BGP in the receive
direction. In this arrangement, the ISP's (upstream) AS will not
send signed updates to this stub or customer AS. Thus, the stub AS
can avoid the need to hardware-upgrade its route processor and RIB
memory to support BGPsec update validation.
6.5.2. Discussion
Various other options were also considered for accommodating a
resource-constrained stub AS, as discussed below:
1. An arrangement that can be effected outside of the BGPsec
specification is as follows. Through a private arrangement
(invisible to other ASes), an ISP's AS (upstream AS) can truncate
the stub AS (or downstream AS) from the path and sign the update
as if the prefix is originating from the ISP's AS (even though
the update originated unsigned from the customer AS). This way,
the path will appear fully signed to the rest of the network.
This alternative will require the owner of the prefix at the stub
AS to issue a ROA for the upstream AS, so that the upstream AS is
authorized to originate routes for the prefix.
2. Another type of arrangement that can also be effected outside of
the BGPsec specification is as follows. The stub AS does not
sign updates, but it obtains an RPKI (CA) certificate and issues
a router certificate under that CA certificate. It passes on the
private key for the router certificate to its upstream provider.
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That ISP (i.e., the second-hop AS) would insert a signature on
behalf of the stub AS using the private key obtained from the
stub AS. This arrangement is called "proxy signing" (see
Section 6.6).
3. An extended ROA is created that includes the stub AS as the
originator of the prefix and the upstream provider as the
second-hop AS, and partial signatures would be allowed (i.e., the
stub AS need not sign the updates). It is recognized that this
approach is also authoritative and not trust based. It was
observed that the extended ROA is not much different from what is
done with the ROA (in its current form) when a Provider-
Independent (PI) address is originated from a provider's AS.
This approach was rejected due to possible complications with the
creation and use of a new RPKI object, namely, the extended ROA.
Also, the validating BGPsec router has to perform a level of
indirection with this approach, i.e., it must detect that an
update is not fully signed and then look for the extended ROA to
validate.
4. Another method, based on a different form of indirection, would
be as follows. The customer (stub) AS registers something like a
Proxy Signer Authorization, which authorizes the second-hop
(i.e., provider) AS to sign on behalf of the customer AS using
the provider's own key [Dynamics]. This method allows for fully
signed updates (unlike the approach based on the extended ROA).
But this approach also requires the creation of a new RPKI
object, namely, the Proxy Signer Authorization. In this
approach, the second-hop AS and validating ASes have to perform a
level of indirection. This approach was also rejected.
The various inputs regarding ISP preferences were taken into
consideration, and eventually the decision in favor of asymmetric
BGPsec was reached (Section 6.5.1). An advantage for a stub AS that
does asymmetric BGPsec is that it only needs to minimally upgrade to
BGPsec so it can sign updates to its upstream AS while it receives
only unsigned updates. Thus, it can avoid the cost of increased
processing and memory needed to perform update validations and to
store signed updates in the RIBs, respectively.
6.6. Proxy Signing
6.6.1. Decision
An ISP's AS (or upstream AS) can proxy-sign BGP announcements for a
customer (downstream) AS, provided that the customer AS obtains an
RPKI (CA) certificate, issues a router certificate under that CA
certificate, and passes on the private key for that certificate to
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its upstream provider. That ISP (i.e., the second-hop AS) would
insert a signature on behalf of the customer AS using the private key
provided by the customer AS. This is a private arrangement between
the two ASes and is invisible to other ASes. Thus, this arrangement
is not part of the BGPsec protocol specification.
BGPsec will not make any special provisions for an ISP to use its own
private key to proxy-sign updates for a customer's AS. This type of
proxy signing is considered a bad idea.
6.6.2. Discussion
Consider a scenario when a customer's AS (say, AS8) is multihomed to
two ISPs, i.e., AS8 peers with AS1 and AS2 of ISP-1 and ISP-2,
respectively. In this case, AS8 would have an RPKI (CA) certificate;
it issues two separate router certificates (corresponding to AS1 and
AS2) under that CA certificate, and it passes on the respective
private keys for those two certificates to its upstream providers AS1
and AS2. Thus, AS8 has a proxy-signing service from both of its
upstream ASes. In the future, if AS8 were to disconnect from ISP-2,
then it would revoke the router certificate corresponding to AS2.
6.7. Multiple Peering Sessions between ASes
6.7.1. Decision
No problems are anticipated when BGPsec-capable ASes have multiple
peering sessions between them (between distinct routers).
6.7.2. Discussion
In traditional BGP, multiple peering sessions between different pairs
of routers (between two neighboring ASes) may be simultaneously used
for load sharing. Similarly, BGPsec-capable ASes can also have
multiple peering sessions between them. Because routers in an AS can
have distinct private keys, the same update, when propagated over
these multiple peering sessions, will result in multiple updates that
may differ in their signatures. The peer (upstream) AS will apply
its normal procedures for selecting a best path from those multiple
updates (and updates from other peers).
This decision regarding load balancing (vs. using one peering session
as the primary for carrying data and another as the backup) is
entirely local and is up to the two neighboring ASes.
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7. Interaction of BGPsec with Common BGP Features
7.1. Peer Groups
In traditional BGP, the idea of peer groups is used in BGP routers to
save on processing when generating and sending updates. Multiple
peers for whom the same policies apply can be organized into peer
groups. A peer group can typically have tens of ASes (and maybe as
many as 300) in it.
7.1.1. Decision
It was decided that BGPsec updates are generated to target unique AS
peers, so there is no support for peer groups in BGPsec.
7.1.2. Discussion
BGPsec router processing can make use of peer groups preceding the
signing of updates to peers. Some of the update processing prior to
forwarding to members of a peer group can be done only once per
update, as is done in traditional BGP. Prior to forwarding the
update, a BGPsec speaker adds the peer's ASN to the data that needs
to be signed and signs the update for each peer AS in the group
individually.
If updates were to be signed per peer group, information about the
forward AS set that constitutes a peer group would have to be
divulged (since the ASN of each peer would have to be included in the
update). Some ISPs do not like to share this kind of information
globally.
7.2. Communities
The need to provide protection in BGPsec for the community attribute
was discussed.
7.2.1. Decision
Community attribute(s) will not be included in any message that is
signed in BGPsec.
7.2.2. Discussion
From a security standpoint, the community attribute, as currently
defined, may be inherently defective. A substantial amount of work
on the semantics of the community attribute is needed, and additional
work on its security aspects also needs to be done. The community
attribute is not necessarily transitive; it is often used only
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between neighbors. In those contexts, transport-security mechanisms
suffice to provide integrity and authentication. (There is no need
to sign data when it is passed only between peers.) It was suggested
that one could include only the transitive community attributes in
any message that is signed and propagated (across the AS path). It
was noted that there is a flag available (i.e., unused) in the
community attribute, and it might be used by BGPsec (in some
fashion). However, little information is available at this point
about the use and function of this flag. It was speculated that this
flag could potentially be used to indicate to BGPsec whether or not
the community attribute needs protection. For now, community
attributes will not be secured by BGPsec path signatures.
7.3. Consideration of iBGP Speakers and Confederations
7.3.1. Decision
An iBGP speaker that is also an eBGP speaker and that executes BGPsec
will by necessity carry BGPsec data and perform eBGPsec functions.
Confederations are eBGP clouds for administrative purposes and
contain multiple Member-ASes. A Member-AS is not required to sign
updates sent to another Member-AS within the same confederation.
However, if BGPsec signing is applied in eBGP within a confederation,
i.e., each Member-AS signs to the next Member-AS in the path within
the confederation, then upon egress from the confederation, the
Member-AS at the boundary must remove any and all signatures applied
within the confederation. The Member-AS at the boundary of the
confederation will sign the update to an eBGPsec peer using the
public ASN of the confederation and its private key. The BGPsec
specification will not specify how to perform this process.
Note: In RFC 8205, signing a BGPsec update between Member-ASes within
a confederation is required if the update were to propagate with
signatures within the confederation. A Confed_Segment flag exists in
each Secure_Path segment, and when set, it indicates that the
corresponding signature belongs to a Member-AS. At the confederation
boundary, all signatures with Confed_Segment flags set are removed
from the update. RFC 8205 specifies in detail how all of this is
done. Please see Figure 5 in Section 3.1 of [RFC8205], as well as
Section 4.3 of [RFC8205], for details.
7.3.2. Discussion
This topic may need to be revisited to flesh out the details
carefully.
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7.4. Consideration of Route Servers in IXPs
7.4.1. Decision
[BGPsec-Initial] made no special provisions to accommodate route
servers in Internet Exchange Points (IXPs).
Note: The above decision subsequently changed: RFC 8205 allows the
accommodation of IXPs, especially for transparent route servers. The
pCount (AS prepend count) field is set to zero for transparent route
servers (see Section 4.2 of [RFC8205]). The operational guidance for
preventing the misuse of pCount=0 is given in Section 7.2 of
RFC 8205. Also, see Section 8.4 of RFC 8205 for a discussion of
security considerations concerning pCount=0.
7.4.2. Discussion
There are basically three methods that an IXP may use to propagate
routes: (A) direct bilateral peering through the IXP, (B) BGP peering
between clients via peering with a route server at the IXP (without
the IXP inserting its ASN in the path), and (C) BGP peering with an
IXP route server, where the IXP inserts its ASN in the path.
(Note: The IXP's route server does not change the NEXT_HOP attribute
even if it inserts its ASN in the path.) It is very rare for an IXP
to use Method C because it is less attractive for the clients if
their AS path length increases by one due to the IXP. A measure of
the extent of the use of Method A vs. Method B is given in terms of
the corresponding IP traffic load percentages. As an example, at a
major European IXP, these percentages are about 80% and 20% for
Methods A and B, respectively (this data is based on private
communication with IXPs circa 2011). However, as the IXP grows (in
terms of number of clients), it tends to migrate more towards
Method B because of the difficulties of managing up to n x (n-1)/2
direct interconnections between n peers in Method A.
To the extent that an IXP is providing direct bilateral peering
between clients (Method A), that model works naturally with BGPsec.
Also, if the route server in the IXP plays the role of a regular
BGPsec speaker (minus the routing part for payload) and inserts its
own ASN in the path (Method C), then that model would also work well
in the BGPsec Internet and this case is trivially supported in
BGPsec.
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7.5. Proxy Aggregation (a.k.a. AS_SETs)
7.5.1. Decision
Proxy aggregation (i.e., the use of AS_SETs in the AS path) will not
be supported in BGPsec. There is no provision in BGPsec to sign an
update when an AS_SET is part of an AS path. If a BGPsec-capable
router receives an update that contains an AS_SET and also finds that
the update is signed, then the router will consider the update
malformed (i.e., a protocol error).
Note: Section 5.2 of RFC 8205 specifies that a receiving BGPsec
router "MUST handle any syntactical or protocol errors in the
BGPsec_PATH attribute by using the 'treat-as-withdraw' approach as
defined in RFC 7606 [RFC7606]."
7.5.2. Discussion
Proxy aggregation does occur in the Internet today, but it is very
rare. Only a very small fraction (about 0.1%) of observed updates
contain AS_SETs in the AS path [ASset]. Since traditional BGP
currently allows for proxy aggregation with the inclusion of AS_SETs
in the AS path, it is necessary that BGPsec specify what action a
receiving router must take if such an update is received with
attestation. BCP 172 [RFC6472] recommends against the use of AS_SETs
in updates, so it is anticipated that the use of AS_SETs will
diminish over time.
7.6. 4-Byte AS Numbers
Not all (currently deployed) BGP speakers are capable of dealing with
4-byte ASNs [RFC6793]. The standard mechanism used to accommodate
such speakers requires a peer AS to translate each 4-byte ASN in the
AS path to a reserved 2-byte ASN (23456) before forwarding the
update. This mechanism is incompatible with the use of BGPsec, since
the ASN translation is equivalent to a route modification attack and
will cause signatures corresponding to the translated 4-byte ASNs to
fail validation.
7.6.1. Decision
BGP speakers that are BGPsec capable are required to process
4-byte ASNs.
7.6.2. Discussion
It is reasonable to assume that upgrades for 4-byte ASN support will
be in place prior to the deployment of BGPsec.
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8. BGPsec Validation
8.1. Sequence of BGPsec Validation Processing in a Receiver
It is natural to ask in what sequence a receiver must perform BGPsec
update validation so that if a failure were to occur (i.e., the
update was determined to be invalid) the processor would have spent
the least amount of processing or other resources.
8.1.1. Decision
There was agreement that the following sequence of receiver
operations is quite meaningful; the following steps are included in
[BGPsec-Initial]. However, the ordering of these validation-
processing steps is not a normative part of the BGPsec specification.
1. Verify that the signed update is syntactically correct. For
example, check to see if the number of signatures matches the
number of ASes in the AS path (after duly accounting for AS
prepending).
2. Verify that the origin AS is authorized to advertise the prefix
in question. This verification is based on data from ROAs and
does not require any cryptographic operations.
3. Verify that the advertisement has not yet expired.
4. Verify that the target ASN in the signature data matches the ASN
of the router that is processing the advertisement. Note that
the target-ASN check is also a non-cryptographic operation and
is fast.
5. Validate the signature data starting from the most recent AS to
the origin.
6. Locate the public key for the router from which the advertisement
was received, using the SKI from the signature data.
7. Hash the data covered by the signature algorithm. Invoke the
signature validation algorithm on the following three inputs: the
locally computed hash, the received signature, and the public
key. There will be one output: valid or invalid.
8. Repeat steps 5 and 6 for each preceding signature in the
Signature_Block until (a) the signature data for the origin AS is
encountered and processed or (b) either of these steps fails.
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Note: Significant refinements to the above list occurred in the
progress towards RFC 8205. The detailed syntactic-error checklist is
presented and explained in Section 5.2 of [RFC8205]. Also, a logical
sequence of steps to be followed in the validation of
Signature_Blocks is described in Section 5.2 of [RFC8205].
8.1.2. Discussion
If the goal is to minimize computational costs associated with
cryptographic operations, the sequence of receiver operations that is
suggested above is viewed as appropriate. One additional interesting
suggestion was that when there are two Signature_Blocks in an update,
the validating router can first verify which of the two algorithms is
cheaper, to save on processing. If that Signature_Block verifies,
then the router can skip validating the other Signature_Block.
8.2. Signing and Forwarding Updates when Signatures Failed Validation
8.2.1. Decision
A BGPsec router should sign and forward a signed update to upstream
peers if it selected the update as the best path, regardless of
whether the update passed or failed validation (at this router).
8.2.2. Discussion
The availability of RPKI data at different routers (in the same AS or
different ASes) may differ, depending on the sources used to acquire
RPKI data. Hence, an update may fail validation in one AS, and the
same update may pass validation in another AS. Also, an update may
fail validation at one router in an AS, and the same update may pass
validation at another router in the same AS.
A BCP may be published later that will identify some update-failure
conditions that may present unambiguous cases for rejecting the
update (in which case the router would not select the AS path in the
update). These cases are "TBD" (to be determined).
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8.3. Enumeration of Error Conditions
Enumeration of error conditions and the recommendations for how to
react to them are still under discussion.
8.3.1. Decision
TBD. Also, please see Section 8.5 for the decision and discussion
specifically related to syntactic errors in signatures.
Note: Section 5.2 of RFC 8205 describes the detection of syntactic
and protocol errors in BGPsec updates as well as how the updates with
such errors are to be handled.
8.3.2. Discussion
The following list is a first attempt to provide some possible error
conditions and recommended receiver reactions in response to the
detection of those errors. Refinements will follow after further
discussions.
E1 Abnormalities where a peer (i.e., the preceding AS) should
definitely not have propagated to a receiving eBGPsec router.
For example, (A) the number of signatures does not match the
number of ASes in the AS path (after accounting for AS
prepending), (B) there is an AS_SET in the received update and
the update has signatures, or (C) other syntactic errors with
signatures have occurred.
Reaction: See Section 8.5.
E2 Situations where a receiving eBGPsec router cannot find the
certificate for an AS in the AS path.
Reaction: Mark the update as "Invalid". It is acceptable to
consider the update in the best-path selection. If it is chosen,
then the router should sign and propagate the update.
E3 Situations where a receiving eBGPsec router cannot find a ROA for
the {prefix, origin} pair in the update.
Reaction: Same as in (E2) above.
E4 Situations where the receiving eBGPsec router verifies signatures
and finds that the update is "Invalid" (even though its peer
might not have known, e.g., due to RPKI skew).
Reaction: Same as in (E2) above.
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In some networks, the best-path-selection policy may specify
choosing an unsigned update over one with invalid signature(s).
Hence, the signatures must not be stripped even if the update is
"Invalid". No evil bit is set in the update (when it is
"Invalid") because an upstream peer may not get that same answer
when it tries to validate.
8.4. Procedure for Processing Unsigned Updates
An update may come in unsigned from an eBGP peer or internally (e.g.,
as an iBGP update). In the latter case, the route is being
originated from within the AS in question.
8.4.1. Decision
If an unsigned route is received from an eBGP peer and if it is
selected, then the route will be forwarded unsigned to other eBGP
peers -- even BGPsec-capable peers. If the route originated in this
AS (IGP or iBGP) and is unsigned, then it should be signed and
announced to external BGPsec-capable peers.
8.4.2. Discussion
It is also possible that an update received in IGP (or iBGP) may have
private ASNs in the AS path. These private ASNs would normally
appear in the rightmost portion of the AS path. It was noted that in
this case the private ASNs to the right would be removed (as done in
traditional BGP), and then the update will be signed by the
originating AS and announced to BGPsec-capable eBGP peers.
Note: See Section 7.5 of [RFC8205] for operational considerations for
BGPsec in the context of private ASNs.
8.5. Response to Syntactic Errors in Signatures and Recommendations for
How to React to Them
Note: The contents of this subsection (i.e., Section 8.5) differ
substantially from the recommendations in RFC 8205 regarding the
handling of syntactic errors and protocol errors. Hence, the reader
may skip this subsection and instead read Section 5.2 of [RFC8205].
This subsection (Section 8.5) is kept here for the sake of archival
value concerning design discussions.
Different types of error conditions were discussed in Section 8.3.
Here, the focus is only on syntactic-error conditions in signatures.
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8.5.1. Decision
If there are syntactic-error conditions such as (A) AS_SET and
BGPsec_PATH both appearing in an update, (B) the number of signatures
not matching the number of ASes (after accounting for any AS
prepending), or (C) a parsing issue occurring with the BGPsec_PATH
attribute, then the update (with the signatures stripped) will still
be considered in the best-path-selection algorithm. (**Note: This is
not true in RFC 8205**.) If the update is selected as the best path,
then the update will be propagated unsigned. The error condition
will be logged locally.
A BGPsec router will follow whatever the current IETF (IDR WG)
recommendations are for notifying a peer that it is sending malformed
messages.
In the case when there are two Signature_Blocks in an update, and one
or more syntactic errors are found to occur within one of them but
the other one is free of any syntactic errors, then the update will
still be considered in the best-path-selection algorithm after the
syntactically bad Signature_Block has been removed. (**Note: This is
not true in RFC 8205**.) If the update is selected as the best path,
then the update will be propagated with only one (i.e., the
error-free) Signature_Block. The error condition will be logged
locally.
8.5.2. Discussion
As stated above, a BGPsec router will follow whatever the current
IETF (IDR WG) recommendations are for notifying a peer that it is
sending malformed messages. Question: If the error is persistent and
a full BGP table dump occurs, then would there be 500K such errors
resulting in 500K "notify" messages sent to the peer that is
generating the errors? Answer: Rate limiting would be applied to the
notify messages and should prevent any overload due to these
messages.
8.6. Enumeration of Validation States
Various validation conditions are possible that can be mapped to
validation states for possible input to the BGPsec decision process.
These conditions can be related to whether an update is signed,
Expire Time is checked, route origin validation is checked against a
ROA, signature verification passed, etc.
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8.6.1. Decision
It was decided that BGPsec validation outcomes will be mapped to one
of only two validation states: (1) Valid -- passed all validation
checks (i.e., Expire Time check, route origin and Signature_Block
validation) and (2) Invalid -- all other possibilities. "Invalid"
would include situations such as the following:
1. Due to a lack of RPKI data or insufficient RPKI data, validation
was not performed.
2. The signature Expire Time check failed.
3. Route origin validation failed.
4. Signature checks were performed, and one or more of them failed.
Note: Expire Time is obsolete (see the notes in Sections 2.2.1 and
2.2.2). RFC 8205 uses the states "Valid" and "Not Valid", but only
with respect to AS path validation (i.e., not including the result of
origin validation); see Section 5.1 of [RFC8205]. "Not Valid"
includes all conditions in which path validation was attempted but a
"Valid" result could not be reached. (Note: Path validation is not
attempted in the case of syntactic or protocol errors in a BGPsec
update; see Section 5.2 of [RFC8205].) Each Relying Party (RP) is
expected to devise its own policy to suitably factor the results of
origin validation [RFC6811] and path validation [RFC8205] into its
path-selection decision.
8.6.2. Discussion
It may be noted that the result of update validation is just an
additional input for the BGP decision process. The router's local
policy ultimately has control over what action (regarding BGP path
selection) is taken.
Initially, four validation states were considered:
1. The update is not signed.
2. The update is signed, but the router does not have corresponding
RPKI data to perform a validation check.
3. The validation check was performed, and the check failed
(Invalid).
4. The validation check was performed, and the check passed (Valid).
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As stated above, it was later decided that BGPsec validation outcomes
will be mapped to one of only two validation states. It was observed
that an update can be invalid for many different reasons. To begin
to differentiate these numerous reasons and to try to enumerate
different flavors of the Invalid state will not likely be
constructive in route-selection decisions and may even introduce new
vulnerabilities in the system. However, some questions remain, such
as the following:
Question: Is there a need to define a separate validation state for
the case when an update is not signed but the {prefix, origin} pair
matches the ROA information? After some discussion, a tentative
conclusion was reached: this is in principle similar to validation
based on partial path signing (which was ruled out; see Section 6.4).
So, there is no need to add another validation state for this case;
treat it as "Invalid", considering that it is unsigned.
Another remaining question: Would the RP want to give the update a
higher preference over another unsigned update that failed origin
validation or over a signed update that failed both signature and ROA
validation?
8.7. Mechanism for Transporting Validation State through iBGP
8.7.1. Decision
BGPsec validation need be performed only at eBGP edges. The
validation status of a BGP signed/unsigned update may be conveyed via
iBGP from an ingress edge router to an egress edge router. Local
policy in the AS will determine how the validation status is conveyed
internally, using various preexisting mechanisms, e.g., setting a BGP
community, or modifying a metric value such as Local_Pref or MED. A
signed update that cannot be validated (except those with syntax
errors) should be forwarded with signatures from the ingress router
to the egress router, where it is signed when propagated towards
other eBGPsec speakers in neighboring ASes. Based entirely on local
policy settings, an egress router may trust the validation status
conveyed by an ingress router, or it may perform its own validation.
The latter approach may be used at an operator's discretion, under
circumstances when RPKI skew is known to happen at different routers
within an AS.
Note: An extended community for carrying the origin validation state
in iBGP has been specified in RFC 8097 [RFC8097].
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8.7.2. Discussion
The attribute used to represent the validation state can be carried
between ASes, if desired. ISPs may like to carry it over their eBGP
links between their own ASes (e.g., sibling ASes). A peer (or
customer) may receive it over an eBGP link from a provider and may
want to use it to shortcut their own validation check. However, the
peer (or customer) should be aware that this validation-state
attribute is just a preview of a neighbor's validation and must
perform their own validation check to be sure of the actual state of
the update's validation. Question: Should validation-state
propagation be protected by attestation in cases where it is useful
for diagnostics purposes? The decision was made to not protect the
validation-state information using signatures.
The following validation states may be needed for propagation via
iBGP between edge routers in an AS:
o Validation states communicated in iBGP for an unsigned update
(route origin validation result): (1) Valid, (2) Invalid,
(3) NotFound (see [RFC6811]), (4) Validation Deferred.
* An update could be unsigned for either of the following two
reasons, but they need not be distinguished: (a) it had no
signatures (i.e., came in unsigned from an eBGP peer) or
(b) signatures were present but stripped.
o Validation states communicated in iBGP for a signed update:
(1) Valid, (2) Invalid, (3) Validation Deferred.
The reason for conveying the additional "Validation Deferred" state
may be illustrated as follows. An ingress edge Router A receiving an
update from an eBGPsec peer may not attempt to validate signatures
(e.g., in a processor overload situation), and in that case Router A
should convey "Validation Deferred" state for that signed update (if
selected for best path) in iBGP to other edge routers. An egress
edge Router B, upon receiving the update from ingress Router A, would
then be able to perform its own validation (origin validation for an
unsigned update or origin/signature validation for a signed update).
As stated before, the egress router (Router B in this example) may
always choose to perform its own validation when it receives an
update from iBGP (independently of the update's validation status
conveyed in iBGP) to account for the possibility of RPKI data skew at
different routers. These various choices are local and entirely at
the operator's discretion.
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9. Operational Considerations
Note: Significant thought has been devoted to operations and
management considerations subsequent to the writing of
[BGPsec-Initial]. The reader is referred to [RFC8207] and Section 7
of [RFC8205] for details.
9.1. Interworking with BGP Graceful Restart
BGP Graceful Restart (BGP-GR) [RFC4724] is a mechanism currently used
to facilitate nonstop packet forwarding when the control plane is
recovering from a fault (i.e., the BGP session is restarted) but the
data plane is functioning. Two questions were raised: Are there any
special concerns about how BGP-GR works while BGPsec is operational?
Also, what happens if the BGP router operation transitions from
traditional BGP operation to BGP-GR to BGPsec, in that order?
9.1.1. Decision
No decision was made relative to this issue (at the time that
[BGPsec-Initial] was written).
Note: See Section 7.7 of [RFC8205] for comments concerning the
operation of BGP-GR with BGPsec. They are consistent with the
discussion below.
9.1.2. Discussion
BGP-GR can be implemented with BGPsec, just as it is currently
implemented with traditional BGP. The Restart State bit, Forwarding
State bit, End-of-RIB marker, staleness marker (in the Adj-RIB-In),
and Selection_Deferral_Timer are key parameters associated with
BGP-GR [RFC4724]. These parameters would apply to BGPsec, just as
they apply to traditional BGP.
Regarding what happens if the BGP router transitions from traditional
BGP to BGP-GR to BGPsec, the answer would simply be as follows. If
there is a software upgrade to BGPsec during BGP-GR (assuming that
the upgrade is being done on a live BGP speaker), then the BGP-GR
session should be terminated before a BGPsec session is initiated.
Once the eBGPsec peering session is established, the receiving
eBGPsec speaker will see signed updates from the sending (newly
upgraded) eBGPsec speaker. There is no apparent harm (it may, in
fact, be desirable) if the receiving speaker continues to use
previously learned unsigned BGP routes from the sending speaker until
they are replaced by new BGPsec routes. However, if the Forwarding
State bit is set to zero by the sending speaker (i.e., the newly
upgraded speaker) during BGPsec session negotiation, then the
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receiving speaker would mark all previously learned unsigned BGP
routes from that sending speaker as "stale" in its Adj-RIB-In. Then,
as BGPsec updates are received (possibly interspersed with unsigned
BGP updates), the "stale" routes will be replaced or refreshed.
9.2. BCP Recommendations for Minimizing Churn: Certificate Expiry/
Revocation and Signature Expire Time
9.2.1. Decision
Work related to this topic is still in progress.
9.2.2. Discussion
BCP recommendations for minimizing churn in BGPsec have been
discussed. There are various potential strategies on how routers
should react to such events as certificate expiry/revocation and
signature Expire Time exhaustion [Dynamics]. The details will be
documented in the near future after additional work is completed.
9.3. Outsourcing Update Validation
9.3.1. Decision
Update signature validation and signing can be outsourced to an
off-board server or processor.
9.3.2. Discussion
Possibly, an off-router box (one or more per AS) can be used that
performs path validation. For example, these capabilities might be
incorporated into a route reflector. At an ingress router, one needs
the Adj-RIB-In entries validated but not the RIB-out entries. So,
the off-router box is probably unlike the traditional route
reflector; it sits at the network edge and validates all incoming
BGPsec updates. Thus, it appears that each router passes each BGPsec
update it receives to the off-router box and receives a validation
result before it stores the route in the Adj-RIB-In. Question: What
about failure modes here? The failure modes would be dependent on
the following:
1. How much of the control plane is outsourced.
2. How reliable the off-router box is (or, equivalently,
communication to and from it).
3. How centralized vs. distributed this arrangement is.
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When any kind of outsourcing is done, the user needs to be watchful
and ensure that the outsourcing does not cross trust/security
boundaries.
9.4. New Hardware Capability
9.4.1. Decision
It is assumed that BGPsec routers (Provider Edge (PE) routers and
route reflectors) will require significantly upgraded hardware --
much more memory for RIBs and hardware cryptographic assistance.
However, stub ASes would not need to make such upgrades because they
can negotiate asymmetric BGPsec capability with their upstream ASes,
i.e., they sign updates to the upstream AS but receive only unsigned
BGP updates (see Section 6.5).
9.4.2. Discussion
It is accepted that it might take several years to go beyond test
deployment of BGPsec because of the need for additional route
processor CPU and memory. However, because BGPsec deployment will be
incremental and because signed updates are not sent outside of a set
of contiguous BGPsec-enabled ASes, it is not clear how much
additional (RIB) memory will be required during initial deployment.
See [RIB_size] for preliminary results on modeling and estimation of
BGPsec RIB size and its projected growth. Hardware cryptographic
support reduces the computation burden on the route processor and
offers good security for router private keys. However, given the
incremental-deployment model, it also is not clear how substantial a
cryptographic processing load will be incurred in the early phases of
deployment.
Note: There are recent detailed studies that considered software
optimizations for BGPsec. In [Mehmet1] and [Mehmet2], computational
optimizations for cryptographic processing (i.e., ECDSA speedup) are
considered for BGPsec implementations on general-purpose CPUs. In
[V_Sriram], software optimizations at the level of update processing
and path selection are proposed and quantified for BGPsec
implementations.
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9.5. Signed Peering Registrations
9.5.1. Decision
The idea of signed BGP peering registrations (for the purpose of path
validation) was rejected.
9.5.2. Discussion
The idea of using a secure map of AS relationships to "validate"
updates was discussed and rejected: such solutions were not pursued
because they cannot provide strong guarantees regarding the validity
of updates. Using these techniques, one can say only that an update
is "plausible"; one cannot say that it is "definitely" valid (based
on signed peering relations alone).
10. Security Considerations
This document requires no security considerations. See [RFC8205] for
security considerations for the BGPsec protocol.
11. IANA Considerations
This document has no IANA actions.
12. Informative References
[ASset] Sriram, K. and D. Montgomery, "Measurement Data on AS_SET
and AGGREGATOR: Implications for {Prefix, Origin}
Validation Algorithms", IETF SIDR WG presentation,
IETF 78, July 2010, <http://www.nist.gov/itl/antd/upload/
AS_SET_Aggregator_Stats.pdf>.
[BGP-Ext-Msg]
Bush, R., Patel, K., and D. Ward, "Extended Message
support for BGP", Work in Progress, draft-ietf-idr-bgp-
extended-messages-24, November 2017.
[BGPsec-Initial]
Lepinski, M., "BGPSEC Protocol Specification", Work in
Progress, draft-lepinski-bgpsec-protocol-00, March 2011.
[BGPsec-Rollover]
Weis, B., Gagliano, R., and K. Patel, "BGPsec Router
Certificate Rollover", Work in Progress, draft-ietf-
sidrops-bgpsec-rollover-04, December 2017.
Sriram Informational [Page 44]
RFC 8374 BGPsec Design Choices April 2018
[Borchert]
Borchert, O. and M. Baer, "Subject: Modifiation [sic]
request: draft-ietf-sidr-bgpsec-protocol-14", message to
the IETF SIDR WG Mailing List, 10 February 2016,
<https://www.ietf.org/mail-archive/web/sidr/current/
msg07509.html>.
[CiscoIOS]
"Cisco IOS: Configuring Route Dampening", February 2014,
<https://www.cisco.com/c/en/us/td/docs/ios/12_2/ip/
configuration/guide/fipr_c/1cfbgp.html>.
[CPUworkload]
Sriram, K. and R. Bush, "Estimating CPU Cost of BGPSEC on
a Router", Presented at RIPE-63; also at IETF 83 SIDR WG
Meeting, March 2012, <https://www.ietf.org/proceedings/
83/slides/slides-83-sidr-7.pdf>.
[Dynamics]
Sriram, K., Montgomery, D., Borchert, O., Kim, O., and P.
Gleichmann, "Potential Impact of BGPSEC Mechanisms on
Global BGP Dynamics", Presentation to the BGPsec
authors/designers team, October 2009,
<https://www.nist.gov/file/448631>.
[Gueron] Gueron, S. and V. Krasnov, "Fast and side channel
protected implementation of the NIST P-256 Elliptic Curve
for x86-64 platforms", OpenSSL patch ID 3149,
October 2013, <https://rt.openssl.org/Ticket/
Display.html?id=3149&user=guest&pass=guest>.
[JunOS] "Juniper JunOS: Using Routing Policies to Damp BGP Route
Flapping", November 2010, <http://www.juniper.net/
techpubs/en_US/junos10.4/topics/usage-guidelines/
policy-using-routing-policies-to-damp-bgp-route-
flapping.html>.
[Mandelberg1]
Mandelberg, D., "Subject: wglc for draft-ietf-sidr-bgpsec-
protocol-11 (Specific topic: Include Address Family
Identifier in the data protected under signature -- to
alleviate a security concern)", message to the IETF SIDR
WG Mailing List, 10 February 2015, <https://www.ietf.org/
mail-archive/web/sidr/current/msg06930.html>.
Sriram Informational [Page 45]
RFC 8374 BGPsec Design Choices April 2018
[Mandelberg2]
Mandelberg, D., "Subject: draft-ietf-sidr-bgpsec-
protocol-13's security guarantees (Specific topic: Sign
all of the preceding signed data (rather than just the
immediate, previous signature) -- to alleviate a security
concern)", message to the IETF SIDR WG Mailing List,
26 August 2015, <https://www.ietf.org/mail-archive/
web/sidr/current/msg07241.html>.
[Mao02] Mao, Z., et al., "Route Flap Damping Exacerbates Internet
Routing Convergence", August 2002,
<http://www.eecs.umich.edu/~zmao/Papers/sig02.pdf>.
[Mehmet1] Adalier, M., "Efficient and Secure Elliptic Curve
Cryptography Implementation of Curve P-256", NIST Workshop
on ECC Standards, June 2015,
<http://csrc.nist.gov/groups/ST/ecc-workshop-2015/papers/
session6-adalier-Mehmet.pdf>.
[Mehmet2] Adalier, M., Sriram, K., Borchert, O., Lee, K., and D.
Montgomery, "High Performance BGP Security: Algorithms and
Architectures", North American Network Operators Group
Meeting NANOG69, February 2017,
<https://www.nanog.org/meetings/abstract?id=3043>.
[MsgSize] Sriram, K., "Decoupling BGPsec Documents and Extended
Messages draft", Presented at the IETF SIDROPS WG
Meeting, IETF 98, March 2017,
<https://www.ietf.org/proceedings/98/slides/
slides-98-sidrops-decoupling-bgpsec-documents-and-
extended-messages-draft-00.pdf>.
[Replay-Protection]
Sriram, K. and D. Montgomery, "Design Discussion and
Comparison of Protection Mechanisms for Replay Attack and
Withdrawal Suppression in BGPsec", Work in Progress,
draft-sriram-replay-protection-design-discussion-10,
April 2018.
[RFC2439] Villamizar, C., Chandra, R., and R. Govindan, "BGP Route
Flap Damping", RFC 2439, DOI 10.17487/RFC2439,
November 1998, <https://www.rfc-editor.org/info/rfc2439>.
[RFC4271] Rekhter, Y., Ed., Li, T., Ed., and S. Hares, Ed., "A
Border Gateway Protocol 4 (BGP-4)", RFC 4271,
DOI 10.17487/RFC4271, January 2006,
<https://www.rfc-editor.org/info/rfc4271>.
Sriram Informational [Page 46]
RFC 8374 BGPsec Design Choices April 2018
[RFC4724] Sangli, S., Chen, E., Fernando, R., Scudder, J., and Y.
Rekhter, "Graceful Restart Mechanism for BGP", RFC 4724,
DOI 10.17487/RFC4724, January 2007,
<https://www.rfc-editor.org/info/rfc4724>.
[RFC4760] Bates, T., Chandra, R., Katz, D., and Y. Rekhter,
"Multiprotocol Extensions for BGP-4", RFC 4760,
DOI 10.17487/RFC4760, January 2007,
<https://www.rfc-editor.org/info/rfc4760>.
[RFC6090] McGrew, D., Igoe, K., and M. Salter, "Fundamental Elliptic
Curve Cryptography Algorithms", RFC 6090,
DOI 10.17487/RFC6090, February 2011,
<https://www.rfc-editor.org/info/rfc6090>.
[RFC6472] Kumari, W. and K. Sriram, "Recommendation for Not Using
AS_SET and AS_CONFED_SET in BGP", BCP 172, RFC 6472,
DOI 10.17487/RFC6472, December 2011,
<https://www.rfc-editor.org/info/rfc6472>.
[RFC6480] Lepinski, M. and S. Kent, "An Infrastructure to Support
Secure Internet Routing", RFC 6480, DOI 10.17487/RFC6480,
February 2012, <https://www.rfc-editor.org/info/rfc6480>.
[RFC6482] Lepinski, M., Kent, S., and D. Kong, "A Profile for Route
Origin Authorizations (ROAs)", RFC 6482,
DOI 10.17487/RFC6482, February 2012,
<https://www.rfc-editor.org/info/rfc6482>.
[RFC6483] Huston, G. and G. Michaelson, "Validation of Route
Origination Using the Resource Certificate Public Key
Infrastructure (PKI) and Route Origin Authorizations
(ROAs)", RFC 6483, DOI 10.17487/RFC6483, February 2012,
<https://www.rfc-editor.org/info/rfc6483>.
[RFC6487] Huston, G., Michaelson, G., and R. Loomans, "A Profile for
X.509 PKIX Resource Certificates", RFC 6487,
DOI 10.17487/RFC6487, February 2012,
<https://www.rfc-editor.org/info/rfc6487>.
[RFC6793] Vohra, Q. and E. Chen, "BGP Support for Four-Octet
Autonomous System (AS) Number Space", RFC 6793,
DOI 10.17487/RFC6793, December 2012,
<https://www.rfc-editor.org/info/rfc6793>.
Sriram Informational [Page 47]
RFC 8374 BGPsec Design Choices April 2018
[RFC6811] Mohapatra, P., Scudder, J., Ward, D., Bush, R., and R.
Austein, "BGP Prefix Origin Validation", RFC 6811,
DOI 10.17487/RFC6811, January 2013,
<https://www.rfc-editor.org/info/rfc6811>.
[RFC7132] Kent, S. and A. Chi, "Threat Model for BGP Path Security",
RFC 7132, DOI 10.17487/RFC7132, February 2014,
<https://www.rfc-editor.org/info/rfc7132>.
[RFC7353] Bellovin, S., Bush, R., and D. Ward, "Security
Requirements for BGP Path Validation", RFC 7353,
DOI 10.17487/RFC7353, August 2014,
<https://www.rfc-editor.org/info/rfc7353>.
[RFC7606] Chen, E., Ed., Scudder, J., Ed., Mohapatra, P., and K.
Patel, "Revised Error Handling for BGP UPDATE Messages",
RFC 7606, DOI 10.17487/RFC7606, August 2015,
<https://www.rfc-editor.org/info/rfc7606>.
[RFC8097] Mohapatra, P., Patel, K., Scudder, J., Ward, D., and R.
Bush, "BGP Prefix Origin Validation State Extended
Community", RFC 8097, DOI 10.17487/RFC8097, March 2017,
<https://www.rfc-editor.org/info/rfc8097>.
[RFC8205] Lepinski, M., Ed., and K. Sriram, Ed., "BGPsec Protocol
Specification", RFC 8205, DOI 10.17487/RFC8205,
September 2017, <https://www.rfc-editor.org/info/rfc8205>.
[RFC8207] Bush, R., "BGPsec Operational Considerations", BCP 211,
RFC 8207, DOI 10.17487/RFC8207, September 2017,
<https://www.rfc-editor.org/info/rfc8207>.
[RFC8208] Turner, S. and O. Borchert, "BGPsec Algorithms, Key
Formats, and Signature Formats", RFC 8208,
DOI 10.17487/RFC8208, September 2017,
<https://www.rfc-editor.org/info/rfc8208>.
[RFC8209] Reynolds, M., Turner, S., and S. Kent, "A Profile for
BGPsec Router Certificates, Certificate Revocation Lists,
and Certification Requests", RFC 8209,
DOI 10.17487/RFC8209, September 2017,
<https://www.rfc-editor.org/info/rfc8209>.
[RIB_size]
Sriram, K., et al., "RIB Size Estimation for BGPSEC",
May 2011, <http://www.nist.gov/itl/antd/upload/
BGPSEC_RIB_Estimation.pdf>.
Sriram Informational [Page 48]
RFC 8374 BGPsec Design Choices April 2018
[RIPE580] Bush, R., et al., "RIPE-580: RIPE Routing Working Group
Recommendations on Route Flap Damping", January 2013,
<http://www.ripe.net/ripe/docs/ripe-580>.
[Secure-BGP]
Lynn, C., Mikkelson, J., and K. Seo, "Secure BGP (S-BGP)",
Work in Progress, draft-clynn-s-bgp-protocol-01,
June 2003.
[V_Sriram]
Sriram, V. and D. Montgomery, "Design and analysis of
optimization algorithms to minimize cryptographic
processing in BGP security protocols", Computer
Communications, Vol. 106, pp. 75-85,
DOI 10.1016/j.comcom.2017.03.007, July 2017,
<https://www.sciencedirect.com/science/article/pii/
S0140366417303365>.
Acknowledgements
The author would like to thank Jeff Haas and Wes George for serving
as reviewers for this document for the Independent Submissions
stream. The author is grateful to Nevil Brownlee for shepherding
this document through the Independent Submissions review process.
Many thanks are also due to Michael Baer, Oliver Borchert, David
Mandelberg, Sean Turner, Alvaro Retana, Matthias Waehlisch, Tim Polk,
Russ Mundy, Wes Hardaker, Sharon Goldberg, Ed Kern, Chris Hall, Shane
Amante, Luke Berndt, Doug Maughan, Pradosh Mohapatra, Mark Reynolds,
Heather Schiller, Jason Schiller, Ruediger Volk, and David Ward for
their review, comments, and suggestions during the course of
this work.
Contributors
The following people made significant contributions to this document
and should be considered co-authors:
Rob Austein
Dragon Research Labs
Email: sra@hactrn.net
Steven Bellovin
Columbia University
Email: smb@cs.columbia.edu
Russ Housley
Vigil Security, LLC
Email: housley@vigilsec.com
Sriram Informational [Page 49]
RFC 8374 BGPsec Design Choices April 2018
Stephen Kent
Independent
Email: kent@alum.mit.edu
Warren Kumari
Google
Email: warren@kumari.net
Matt Lepinski
New College of Florida
Email: mlepinski@ncf.edu
Doug Montgomery
USA National Institute of Standards and Technology
Email: dougm@nist.gov
Chris Morrow
Google, Inc.
Email: morrowc@google.com
Sandy Murphy
Parsons, Inc.
Email: sandy@tislabs.com
Keyur Patel
Arrcus
Email: keyur@arrcus.com
John Scudder
Juniper Networks
Email: jgs@juniper.net
Samuel Weiler
W3C/MIT
Email: weiler@csail.mit.edu
Author's Address
Kotikalapudi Sriram (editor)
USA National Institute of Standards and Technology
100 Bureau Drive
Gaithersburg, MD 20899
United States of America
Email: ksriram@nist.gov
Sriram Informational [Page 50]