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+Internet Engineering Task Force (IETF) M. Lepinski, Ed.
+Request for Comments: 8205 NCF
+Category: Standards Track K. Sriram, Ed.
+ISSN: 2070-1721 NIST
+ September 2017
+
+
+ BGPsec Protocol Specification
+
+Abstract
+
+ This document describes BGPsec, an extension to the Border Gateway
+ Protocol (BGP) that provides security for the path of Autonomous
+ Systems (ASes) through which a BGP UPDATE message passes. BGPsec is
+ implemented via an optional non-transitive BGP path attribute that
+ carries digital signatures produced by each AS that propagates the
+ UPDATE message. The digital signatures provide confidence that every
+ AS on the path of ASes listed in the UPDATE message has explicitly
+ authorized the advertisement of the route.
+
+Status of This Memo
+
+ This is an Internet Standards Track document.
+
+ This document is a product of the Internet Engineering Task Force
+ (IETF). It represents the consensus of the IETF community. It has
+ received public review and has been approved for publication by the
+ Internet Engineering Steering Group (IESG). Further information on
+ Internet Standards is available in Section 2 of RFC 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/rfc8205.
+
+Copyright Notice
+
+ Copyright (c) 2017 IETF Trust and the persons identified as the
+ document authors. All rights reserved.
+
+ This document is subject to BCP 78 and the IETF Trust's Legal
+ Provisions Relating to IETF Documents
+ (https://trustee.ietf.org/license-info) in effect on the date of
+ publication of this document. Please review these documents
+ carefully, as they describe your rights and restrictions with respect
+ to this document. Code Components extracted from this document must
+ include Simplified BSD License text as described in Section 4.e of
+ the Trust Legal Provisions and are provided without warranty as
+ described in the Simplified BSD License.
+
+
+
+Lepinski & Sriram Standards Track [Page 1]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+Table of Contents
+
+ 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
+ 1.1. Requirements Language . . . . . . . . . . . . . . . . . . 3
+ 2. BGPsec Negotiation . . . . . . . . . . . . . . . . . . . . . 3
+ 2.1. The BGPsec Capability . . . . . . . . . . . . . . . . . . 4
+ 2.2. Negotiating BGPsec Support . . . . . . . . . . . . . . . 5
+ 3. The BGPsec_PATH Attribute . . . . . . . . . . . . . . . . . . 6
+ 3.1. Secure_Path . . . . . . . . . . . . . . . . . . . . . . . 8
+ 3.2. Signature_Block . . . . . . . . . . . . . . . . . . . . . 10
+ 4. BGPsec UPDATE Messages . . . . . . . . . . . . . . . . . . . 11
+ 4.1. General Guidance . . . . . . . . . . . . . . . . . . . . 11
+ 4.2. Constructing the BGPsec_PATH Attribute . . . . . . . . . 14
+ 4.3. Processing Instructions for Confederation Members . . . . 18
+ 4.4. Reconstructing the AS_PATH Attribute . . . . . . . . . . 19
+ 5. Processing a Received BGPsec UPDATE Message . . . . . . . . . 21
+ 5.1. Overview of BGPsec Validation . . . . . . . . . . . . . . 22
+ 5.2. Validation Algorithm . . . . . . . . . . . . . . . . . . 23
+ 6. Algorithms and Extensibility . . . . . . . . . . . . . . . . 27
+ 6.1. Algorithm Suite Considerations . . . . . . . . . . . . . 27
+ 6.2. Considerations for the SKI Size . . . . . . . . . . . . . 28
+ 6.3. Extensibility Considerations . . . . . . . . . . . . . . 28
+ 7. Operations and Management Considerations . . . . . . . . . . 29
+ 7.1. Capability Negotiation Failure . . . . . . . . . . . . . 29
+ 7.2. Preventing Misuse of pCount=0 . . . . . . . . . . . . . . 29
+ 7.3. Early Termination of Signature Verification . . . . . . . 30
+ 7.4. Non-deterministic Signature Algorithms . . . . . . . . . 30
+ 7.5. Private AS Numbers . . . . . . . . . . . . . . . . . . . 30
+ 7.6. Robustness Considerations for Accessing RPKI Data . . . . 32
+ 7.7. Graceful Restart . . . . . . . . . . . . . . . . . . . . 32
+ 7.8. Robustness of Secret Random Number in ECDSA . . . . . . . 32
+ 7.9. Incremental/Partial Deployment Considerations . . . . . . 33
+ 8. Security Considerations . . . . . . . . . . . . . . . . . . . 33
+ 8.1. Security Guarantees . . . . . . . . . . . . . . . . . . . 33
+ 8.2. On the Removal of BGPsec Signatures . . . . . . . . . . . 34
+ 8.3. Mitigation of Denial-of-Service Attacks . . . . . . . . . 36
+ 8.4. Additional Security Considerations . . . . . . . . . . . 36
+ 9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 38
+ 10. References . . . . . . . . . . . . . . . . . . . . . . . . . 39
+ 10.1. Normative References . . . . . . . . . . . . . . . . . . 39
+ 10.2. Informative References . . . . . . . . . . . . . . . . . 41
+ Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . . 43
+ Contributors . . . . . . . . . . . . . . . . . . . . . . . . . . 44
+ Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 45
+
+
+
+
+
+
+
+Lepinski & Sriram Standards Track [Page 2]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+1. Introduction
+
+ This document describes BGPsec, a mechanism for providing path
+ security for Border Gateway Protocol (BGP) [RFC4271] route
+ advertisements. That is, a BGP speaker who receives a valid BGPsec
+ UPDATE message has cryptographic assurance that the advertised route
+ has the following property: every Autonomous System (AS) on the path
+ of ASes listed in the UPDATE message has explicitly authorized the
+ advertisement of the route to the subsequent AS in the path.
+
+ This document specifies an optional (non-transitive) BGP path
+ attribute, BGPsec_PATH. It also describes how a BGPsec-compliant BGP
+ speaker (referred to hereafter as a BGPsec speaker) can generate,
+ propagate, and validate BGP UPDATE messages containing this attribute
+ to obtain the above assurances.
+
+ BGPsec is intended to be used to supplement BGP origin validation
+ [RFC6483] [RFC6811], and when used in conjunction with origin
+ validation, it is possible to prevent a wide variety of route
+ hijacking attacks against BGP.
+
+ BGPsec relies on the Resource Public Key Infrastructure (RPKI)
+ certificates that attest to the allocation of AS number and IP
+ address resources. (For more information on the RPKI, see RFC 6480
+ [RFC6480] and the documents referenced therein.) Any BGPsec speaker
+ who wishes to send, to external (eBGP) peers, BGP UPDATE messages
+ containing the BGPsec_PATH needs to possess a private key associated
+ with an RPKI router certificate [RFC8209] that corresponds to the
+ BGPsec speaker's AS number. Note, however, that a BGPsec speaker
+ does not need such a certificate in order to validate received UPDATE
+ messages containing the BGPsec_PATH attribute (see Section 5.2).
+
+1.1. Requirements Language
+
+ The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
+ "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and
+ "OPTIONAL" in this document are to be interpreted as described in
+ BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all
+ capitals, as shown here.
+
+2. BGPsec Negotiation
+
+ This document defines a BGP capability [RFC5492] that allows a BGP
+ speaker to advertise to a neighbor the ability to send or to receive
+ BGPsec UPDATE messages (i.e., UPDATE messages containing the
+ BGPsec_PATH attribute).
+
+
+
+
+
+Lepinski & Sriram Standards Track [Page 3]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+2.1. The BGPsec Capability
+
+ This capability has capability code 7.
+
+ The capability length for this capability MUST be set to 3.
+
+ The 3 octets of the capability format are specified in Figure 1.
+
+ 0 1 2 3 4 5 6 7
+ +---------------------------------------+
+ | Version | Dir | Unassigned |
+ +---------------------------------------+
+ | |
+ +------ AFI -----+
+ | |
+ +---------------------------------------+
+
+ Figure 1: BGPsec Capability Format
+
+ The first 4 bits of the first octet indicate the version of BGPsec
+ for which the BGP speaker is advertising support. This document
+ defines only BGPsec version 0 (all 4 bits set to 0). Other versions
+ of BGPsec may be defined in future documents. A BGPsec speaker MAY
+ advertise support for multiple versions of BGPsec by including
+ multiple versions of the BGPsec capability in its BGP OPEN message.
+
+ The fifth bit of the first octet is a Direction bit, which indicates
+ whether the BGP speaker is advertising the capability to send BGPsec
+ UPDATE messages or receive BGPsec UPDATE messages. The BGP speaker
+ sets this bit to 0 to indicate the capability to receive BGPsec
+ UPDATE messages. The BGP speaker sets this bit to 1 to indicate the
+ capability to send BGPsec UPDATE messages.
+
+ The remaining 3 bits of the first octet are unassigned and for future
+ use. These bits are set to 0 by the sender of the capability and
+ ignored by the receiver of the capability.
+
+ The second and third octets contain the 16-bit Address Family
+ Identifier (AFI), which indicates the address family for which the
+ BGPsec speaker is advertising support for BGPsec. This document only
+ specifies BGPsec for use with two address families, IPv4 and IPv6,
+ with AFI values 1 and 2, respectively [IANA-AF]. BGPsec for use with
+ other address families may be specified in future documents.
+
+
+
+
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+Lepinski & Sriram Standards Track [Page 4]
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+RFC 8205 BGPsec Protocol September 2017
+
+
+2.2. Negotiating BGPsec Support
+
+ In order to indicate that a BGP speaker is willing to send BGPsec
+ UPDATE messages (for a particular address family), a BGP speaker
+ sends the BGPsec capability (see Section 2.1) with the Direction bit
+ (the fifth bit of the first octet) set to 1. In order to indicate
+ that the speaker is willing to receive BGP UPDATE messages containing
+ the BGPsec_PATH attribute (for a particular address family), a BGP
+ speaker sends the BGPsec capability with the Direction bit set to 0.
+ In order to advertise the capability to both send and receive BGPsec
+ UPDATE messages, the BGP speaker sends two copies of the BGPsec
+ capability (one with the Direction bit set to 0 and one with the
+ Direction bit set to 1).
+
+ Similarly, if a BGP speaker wishes to use BGPsec with two different
+ address families (i.e., IPv4 and IPv6) over the same BGP session,
+ then the speaker includes two instances of this capability (one for
+ each address family) in the BGP OPEN message. A BGP speaker MUST NOT
+ announce BGPsec capability if it does not support the BGP
+ multiprotocol extension [RFC4760]. Additionally, a BGP speaker
+ MUST NOT advertise the capability of BGPsec support for a particular
+ AFI unless it has also advertised the multiprotocol extension
+ capability for the same AFI [RFC4760].
+
+ In a BGPsec peering session, a peer is permitted to send UPDATE
+ messages containing the BGPsec_PATH attribute if and only if:
+
+ o The given peer sent the BGPsec capability for a particular version
+ of BGPsec and a particular address family with the Direction bit
+ set to 1, and
+
+ o The other (receiving) peer sent the BGPsec capability for the same
+ version of BGPsec and the same address family with the Direction
+ bit set to 0.
+
+ In such a session, it can be said that the use of the particular
+ version of BGPsec has been negotiated for a particular address
+ family. Traditional BGP UPDATE messages (i.e., unsigned, containing
+ the AS_PATH attribute) MAY be sent within a session regardless of
+ whether or not the use of BGPsec is successfully negotiated.
+ However, if BGPsec is not successfully negotiated, then BGP UPDATE
+ messages containing the BGPsec_PATH attribute MUST NOT be sent.
+
+ This document defines the behavior of implementations in the case
+ where BGPsec version 0 is the only version that has been successfully
+ negotiated. Any future document that specifies additional versions
+ of BGPsec will need to specify behavior in the case that support for
+ multiple versions is negotiated.
+
+
+
+Lepinski & Sriram Standards Track [Page 5]
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+RFC 8205 BGPsec Protocol September 2017
+
+
+ BGPsec cannot provide meaningful security guarantees without support
+ for 4-byte AS numbers. Therefore, any BGP speaker that announces the
+ BGPsec capability, MUST also announce the capability for 4-byte AS
+ support [RFC6793]. If a BGP speaker sends the BGPsec capability but
+ not the 4-byte AS support capability, then BGPsec has not been
+ successfully negotiated, and UPDATE messages containing the
+ BGPsec_PATH attribute MUST NOT be sent within such a session.
+
+3. The BGPsec_PATH Attribute
+
+ The BGPsec_PATH attribute is an optional non-transitive BGP path
+ attribute.
+
+ This document registers an attribute type code for this attribute:
+ BGPsec_PATH (see Section 9).
+
+ The BGPsec_PATH attribute carries the secured information regarding
+ the path of ASes through which an UPDATE message passes. This
+ includes the digital signatures used to protect the path information.
+ The UPDATE messages that contain the BGPsec_PATH attribute are
+ referred to as "BGPsec UPDATE messages". The BGPsec_PATH attribute
+ replaces the AS_PATH attribute in a BGPsec UPDATE message. That is,
+ UPDATE messages that contain the BGPsec_PATH attribute MUST NOT
+ contain the AS_PATH attribute, and vice versa.
+
+ The BGPsec_PATH attribute is made up of several parts. The
+ high-level diagram in Figure 2 provides an overview of the structure
+ of the BGPsec_PATH attribute. ("SKI" as used in Figure 2 means
+ "Subject Key Identifier".)
+
+
+
+
+
+
+
+
+
+
+
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+Lepinski & Sriram Standards Track [Page 6]
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+RFC 8205 BGPsec Protocol September 2017
+
+
+ +---------------------------------------------------------+
+ | +-----------------+ |
+ | | Secure_Path | |
+ | +-----------------+ |
+ | | pCount X | |
+ | | Flags X | |
+ | | AS X | |
+ | | pCount Y | |
+ | | Flags Y | |
+ | | AS Y | |
+ | | ... | |
+ | +-----------------+ |
+ | |
+ | +---------------------+ +---------------------+ |
+ | | Signature_Block 1 | | Signature_Block 2 | |
+ | +---------------------+ +---------------------+ |
+ | | Algorithm Suite 1 | | Algorithm Suite 2 | |
+ | | SKI X1 | | SKI X2 | |
+ | | Signature X1 | | Signature X2 | |
+ | | SKI Y1 | | SKI Y2 | |
+ | | Signature Y1 | | Signature Y2 | |
+ | | ... | | .... | |
+ | +---------------------+ +---------------------+ |
+ | |
+ +---------------------------------------------------------+
+
+ Figure 2: High-Level Diagram of the BGPsec_PATH Attribute
+
+ Figure 3 provides the specification of the format for the BGPsec_PATH
+ attribute.
+
+ +-------------------------------------------------------+
+ | Secure_Path (variable) |
+ +-------------------------------------------------------+
+ | Sequence of one or two Signature_Blocks (variable) |
+ +-------------------------------------------------------+
+
+ Figure 3: BGPsec_PATH Attribute Format
+
+ The Secure_Path contains AS path information for the BGPsec UPDATE
+ message. This is logically equivalent to the information that is
+ contained in a non-BGPsec AS_PATH attribute. The information in the
+ Secure_Path is used by BGPsec speakers in the same way that
+ information from the AS_PATH is used by non-BGPsec speakers. The
+ format of the Secure_Path is described below in Section 3.1.
+
+ The BGPsec_PATH attribute will contain one or two Signature_Blocks,
+ each of which corresponds to a different algorithm suite. Each of
+
+
+
+Lepinski & Sriram Standards Track [Page 7]
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+RFC 8205 BGPsec Protocol September 2017
+
+
+ the Signature_Blocks will contain a Signature Segment for each AS
+ number (i.e., Secure_Path Segment) in the Secure_Path. In the
+ most common case, the BGPsec_PATH attribute will contain only a
+ single Signature_Block. However, in order to enable a transition
+ from an old algorithm suite to a new algorithm suite (without a
+ flag day), it will be necessary to include two Signature_Blocks (one
+ for the old algorithm suite and one for the new algorithm suite)
+ during the transition period. (See Section 6.1 for more discussion
+ of algorithm transitions.) The format of the Signature_Blocks is
+ described below in Section 3.2.
+
+3.1. Secure_Path
+
+ A detailed description of the Secure_Path information in the
+ BGPsec_PATH attribute is provided here. The specification for the
+ Secure_Path field is provided in Figures 4 and 5.
+
+ +-----------------------------------------------+
+ | Secure_Path Length (2 octets) |
+ +-----------------------------------------------+
+ | One or more Secure_Path Segments (variable) |
+ +-----------------------------------------------+
+
+ Figure 4: Secure_Path Format
+
+ The Secure_Path Length contains the length (in octets) of the entire
+ Secure_Path (including the 2 octets used to express this length
+ field). As explained below, each Secure_Path Segment is 6 octets
+ long. Note that this means the Secure_Path Length is two greater
+ than six times the number of Secure_Path Segments (i.e., the number
+ of AS numbers in the path).
+
+ The Secure_Path contains one Secure_Path Segment (see Figure 5) for
+ each AS in the path to the originating AS of the prefix specified in
+ the UPDATE message. (Note: Repeated ASes are "compressed out" using
+ the pCount field, as discussed below.)
+
+ +------------------------------------------------------+
+ | pCount (1 octet) |
+ +------------------------------------------------------+
+ | Confed_Segment flag (1 bit) | Unassigned (7 bits) | (Flags)
+ +------------------------------------------------------+
+ | AS Number (4 octets) |
+ +------------------------------------------------------+
+
+ Figure 5: Secure_Path Segment Format
+
+
+
+
+
+Lepinski & Sriram Standards Track [Page 8]
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+RFC 8205 BGPsec Protocol September 2017
+
+
+ The AS Number (in Figure 5) is the AS number of the BGP speaker that
+ added this Secure_Path Segment to the BGPsec_PATH attribute. (See
+ Section 4 for more information on populating this field.)
+
+ The pCount field contains the number of repetitions of the associated
+ AS number that the signature covers. This field enables a BGPsec
+ speaker to mimic the semantics of prepending multiple copies of their
+ AS to the AS_PATH without requiring the speaker to generate multiple
+ signatures. Note that Section 9.1.2.2 ("Breaking Ties (Phase 2)") in
+ [RFC4271] mentions the "number of AS numbers" in the AS_PATH
+ attribute that is used in the route selection process. This metric
+ (number of AS numbers) is the same as the AS path length obtained in
+ BGPsec by summing the pCount values in the BGPsec_PATH attribute.
+ The pCount field is also useful in managing route servers (see
+ Section 4.2), AS confederations (see Section 4.3), and AS Number
+ migrations (see [RFC8206] for details).
+
+ The leftmost (i.e., the most significant) bit of the Flags field in
+ Figure 5 is the Confed_Segment flag. The Confed_Segment flag is set
+ to 1 to indicate that the BGPsec speaker that constructed this
+ Secure_Path Segment is sending the UPDATE message to a peer AS within
+ the same AS confederation [RFC5065]. (That is, a sequence of
+ consecutive Confed_Segment flags are set in a BGPsec UPDATE message
+ whenever, in a non-BGPsec UPDATE message, an AS_PATH segment of type
+ AS_CONFED_SEQUENCE occurs.) In all other cases, the Confed_Segment
+ flag is set to 0.
+
+ The remaining 7 bits of the Flags field are unassigned. They MUST be
+ set to 0 by the sender and ignored by the receiver. Note, however,
+ that the signature is computed over all 8 bits of the Flags field.
+
+ As stated earlier in Section 2.2, BGPsec peering requires that the
+ peering ASes MUST each support 4-byte AS numbers. Currently assigned
+ 2-byte AS numbers are converted into 4-byte AS numbers by setting the
+ two high-order octets of the 4-octet field to 0 [RFC6793].
+
+
+
+
+
+
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+Lepinski & Sriram Standards Track [Page 9]
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+RFC 8205 BGPsec Protocol September 2017
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+
+3.2. Signature_Block
+
+ A detailed description of the Signature_Blocks in the BGPsec_PATH
+ attribute is provided here using Figures 6 and 7.
+
+ +---------------------------------------------+
+ | Signature_Block Length (2 octets) |
+ +---------------------------------------------+
+ | Algorithm Suite Identifier (1 octet) |
+ +---------------------------------------------+
+ | Sequence of Signature Segments (variable) |
+ +---------------------------------------------+
+
+ Figure 6: Signature_Block Format
+
+ The Signature_Block Length in Figure 6 is the total number of octets
+ in the Signature_Block (including the 2 octets used to express this
+ length field).
+
+ The Algorithm Suite Identifier is a 1-octet identifier specifying the
+ digest algorithm and digital signature algorithm used to produce the
+ digital signature in each Signature Segment. An IANA registry of
+ algorithm suite identifiers for use in BGPsec is specified in the
+ BGPsec algorithms document [RFC8208].
+
+ A Signature_Block in Figure 6 has exactly one Signature Segment (see
+ Figure 7) for each Secure_Path Segment in the Secure_Path portion of
+ the BGPsec_PATH attribute (that is, one Signature Segment for each
+ distinct AS on the path for the prefix in the UPDATE message).
+
+ +---------------------------------------------+
+ | Subject Key Identifier (SKI) (20 octets) |
+ +---------------------------------------------+
+ | Signature Length (2 octets) |
+ +---------------------------------------------+
+ | Signature (variable) |
+ +---------------------------------------------+
+
+ Figure 7: Signature Segment Format
+
+ The Subject Key Identifier (SKI) field in Figure 7 contains the value
+ in the Subject Key Identifier extension of the RPKI router
+ certificate [RFC6487] that is used to verify the signature (see
+ Section 5 for details on the validity of BGPsec UPDATE messages).
+ The SKI field has a fixed size of 20 octets. See Section 6.2 for
+ considerations for the SKI size.
+
+
+
+
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+
+ The Signature Length field contains the size (in octets) of the value
+ in the Signature field of the Signature Segment.
+
+ The Signature field in Figure 7 contains a digital signature that
+ protects the prefix and the BGPsec_PATH attribute (see Sections 4 and
+ 5 for details on signature generation and validation, respectively).
+
+4. BGPsec UPDATE Messages
+
+ Section 4.1 provides general guidance on the creation of BGPsec
+ UPDATE messages -- that is, UPDATE messages containing the
+ BGPsec_PATH attribute.
+
+ Section 4.2 specifies how a BGPsec speaker generates the BGPsec_PATH
+ attribute to include in a BGPsec UPDATE message.
+
+ Section 4.3 contains special processing instructions for members of
+ an AS confederation [RFC5065]. A BGPsec speaker that is not a member
+ of such a confederation MUST NOT set the Confed_Segment flag in its
+ Secure_Path Segment (i.e., leave the Confed_Segment flag at the
+ default value of 0) in all BGPsec UPDATE messages it sends.
+
+ Section 4.4 contains instructions for reconstructing the AS_PATH
+ attribute in cases where a BGPsec speaker receives an UPDATE message
+ with a BGPsec_PATH attribute and wishes to propagate the UPDATE
+ message to a peer who does not support BGPsec.
+
+4.1. General Guidance
+
+ The information protected by the signature on a BGPsec UPDATE message
+ includes the AS number of the peer to whom the UPDATE message is
+ being sent. Therefore, if a BGPsec speaker wishes to send a BGPsec
+ UPDATE message to multiple BGP peers, it MUST generate a separate
+ BGPsec UPDATE message for each unique peer AS to whom the UPDATE
+ message is sent.
+
+ A BGPsec UPDATE message MUST advertise a route to only a single
+ prefix. This is because a BGPsec speaker receiving an UPDATE message
+ with multiple prefixes would be unable to construct a valid BGPsec
+ UPDATE message (i.e., valid path signatures) containing a subset of
+ the prefixes in the received update. If a BGPsec speaker wishes to
+ advertise routes to multiple prefixes, then it MUST generate a
+ separate BGPsec UPDATE message for each prefix. Additionally, a
+ BGPsec UPDATE message MUST use the MP_REACH_NLRI attribute [RFC4760]
+ to encode the prefix.
+
+
+
+
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+RFC 8205 BGPsec Protocol September 2017
+
+
+ The BGPsec_PATH attribute and the AS_PATH attribute are mutually
+ exclusive. That is, any UPDATE message containing the BGPsec_PATH
+ attribute MUST NOT contain the AS_PATH attribute. The information
+ that would be contained in the AS_PATH attribute is instead conveyed
+ in the Secure_Path portion of the BGPsec_PATH attribute.
+
+ In order to create or add a new signature to a BGPsec UPDATE message
+ with a given algorithm suite, the BGPsec speaker MUST possess a
+ private key suitable for generating signatures for this algorithm
+ suite. Additionally, this private key must correspond to the public
+ key in a valid RPKI end entity certificate whose AS number resource
+ extension includes the BGPsec speaker's AS number [RFC8209]. Note
+ also that new signatures are only added to a BGPsec UPDATE message
+ when a BGPsec speaker is generating an UPDATE message to send to an
+ external peer (i.e., when the AS number of the peer is not equal to
+ the BGPsec speaker's own AS number).
+
+ The RPKI enables the legitimate holder of IP address prefix(es) to
+ issue a signed object, called a Route Origin Authorization (ROA),
+ that authorizes a given AS to originate routes to a given set of
+ prefixes (see RFC 6482 [RFC6482]). It is expected that most Relying
+ Parties (RPs) will utilize BGPsec in tandem with origin validation
+ (see RFC 6483 [RFC6483] and RFC 6811 [RFC6811]). Therefore, it is
+ RECOMMENDED that a BGPsec speaker only originate a BGPsec UPDATE
+ message advertising a route for a given prefix if there exists a
+ valid ROA authorizing the BGPsec speaker's AS to originate routes to
+ this prefix.
+
+ If a BGPsec router has received only a non-BGPsec UPDATE message
+ containing the AS_PATH attribute (instead of the BGPsec_PATH
+ attribute) from a peer for a given prefix, then it MUST NOT attach a
+ BGPsec_PATH attribute when it propagates the UPDATE message. (Note
+ that a BGPsec router may also receive a non-BGPsec UPDATE message
+ from an internal peer without the AS_PATH attribute, i.e., with just
+ the Network Layer Reachability Information (NLRI) in it. In that
+ case, the prefix is originating from that AS, and if it is selected
+ for advertisement, the BGPsec speaker SHOULD attach a BGPsec_PATH
+ attribute and send a signed route (for that prefix) to its external
+ BGPsec-speaking peers.)
+
+ Conversely, if a BGPsec router has received a BGPsec UPDATE message
+ (with the BGPsec_PATH attribute) from a peer for a given prefix and
+ it chooses to propagate that peer's route for the prefix, then it
+ SHOULD propagate the route as a BGPsec UPDATE message containing the
+ BGPsec_PATH attribute.
+
+
+
+
+
+
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+
+
+ Note that removing BGPsec signatures (i.e., propagating a route
+ advertisement without the BGPsec_PATH attribute) has significant
+ security ramifications. (See Section 8 for a discussion of the
+ security ramifications of removing BGPsec signatures.) Therefore,
+ when a route advertisement is received via a BGPsec UPDATE message,
+ propagating the route advertisement without the BGPsec_PATH attribute
+ is NOT RECOMMENDED, unless the message is sent to a peer that did not
+ advertise the capability to receive BGPsec UPDATE messages (see
+ Section 4.4).
+
+ Furthermore, note that when a BGPsec speaker propagates a route
+ advertisement with the BGPsec_PATH attribute, it is not attesting to
+ the validation state of the UPDATE message it received. (See
+ Section 8 for more discussion of the security semantics of BGPsec
+ signatures.)
+
+ If the BGPsec speaker is producing an UPDATE message that would, in
+ the absence of BGPsec, contain an AS_SET (e.g., the BGPsec speaker is
+ performing proxy aggregation), then the BGPsec speaker MUST NOT
+ include the BGPsec_PATH attribute. In such a case, the BGPsec
+ speaker MUST remove any existing BGPsec_PATH in the received
+ advertisement(s) for this prefix and produce a traditional
+ (non-BGPsec) UPDATE message. It should be noted that BCP 172
+ [RFC6472] recommends against the use of AS_SET and AS_CONFED_SET in
+ the AS_PATH of BGP UPDATE messages.
+
+ The case where the BGPsec speaker sends a BGPsec UPDATE message to an
+ iBGP (internal BGP) peer is quite simple. When originating a new
+ route advertisement and sending it to a BGPsec-capable iBGP peer, the
+ BGPsec speaker omits the BGPsec_PATH attribute. When originating a
+ new route advertisement and sending it to a non-BGPsec iBGP peer, the
+ BGPsec speaker includes an empty AS_PATH attribute in the UPDATE
+ message. (An empty AS_PATH attribute is one whose length field
+ contains the value 0 [RFC4271].) When a BGPsec speaker chooses to
+ forward a BGPsec UPDATE message to an iBGP peer, the BGPsec_PATH
+ attribute SHOULD NOT be removed, unless the peer doesn't support
+ BGPsec. In the case when an iBGP peer doesn't support BGPsec, then a
+ BGP UPDATE message with AS_PATH is reconstructed from the BGPsec
+ UPDATE message and then forwarded (see Section 4.4). In particular,
+ when forwarding to a BGPsec-capable iBGP (or eBGP) peer, the
+ BGPsec_PATH attribute SHOULD NOT be removed even in the case where
+ the BGPsec UPDATE message has not been successfully validated. (See
+ Section 5 for more information on validation and Section 8 for the
+ security ramifications of removing BGPsec signatures.)
+
+
+
+
+
+
+
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+
+
+ 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.
+
+4.2. Constructing the BGPsec_PATH Attribute
+
+ When a BGPsec speaker receives a BGPsec UPDATE message containing a
+ BGPsec_PATH attribute (with one or more signatures) from an (internal
+ or external) peer, it may choose to propagate the route advertisement
+ by sending it to its other (internal or external) peers. When
+ sending the route advertisement to an internal BGPsec-speaking peer,
+ the BGPsec_PATH attribute SHALL NOT be modified. When sending the
+ route advertisement to an external BGPsec-speaking peer, the
+ following procedures are used to form or update the BGPsec_PATH
+ attribute.
+
+ To generate the BGPsec_PATH attribute on the outgoing UPDATE message,
+ the BGPsec speaker first generates a new Secure_Path Segment. Note
+ that if the BGPsec speaker is not the origin AS and there is an
+ existing BGPsec_PATH attribute, then the BGPsec speaker prepends its
+ new Secure_Path Segment (places in first position) onto the existing
+ Secure_Path.
+
+ The AS number in this Secure_Path Segment MUST match the AS number in
+ the Subject field of the RPKI router certificate that will be used to
+ verify the digital signature constructed by this BGPsec speaker (see
+ Section 3.1.1 in [RFC8209] and RFC 6487 [RFC6487]).
+
+ The pCount field of the Secure_Path Segment is typically set to the
+ value 1. However, a BGPsec speaker may set the pCount field to a
+ value greater than 1. Setting the pCount field to a value greater
+ than 1 has the same semantics as repeating an AS number multiple
+ times in the AS_PATH of a non-BGPsec UPDATE message (e.g., for
+ traffic engineering purposes).
+
+ To prevent unnecessary processing load in the validation of BGPsec
+ signatures, a BGPsec speaker SHOULD NOT produce multiple consecutive
+ Secure_Path Segments with the same AS number. This means that to
+ achieve the semantics of prepending the same AS number k times, a
+ BGPsec speaker SHOULD produce a single Secure_Path Segment -- with a
+ pCount of k -- and a single corresponding Signature Segment.
+
+ A route server that participates in the BGP control plane but
+ does not act as a transit AS in the data plane may choose to set
+ pCount to 0. This option enables the route server to participate in
+ BGPsec and obtain the associated security guarantees without
+ increasing the length of the AS path. (Note that BGPsec speakers
+
+
+
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+
+ compute the length of the AS path by summing the pCount values in the
+ BGPsec_PATH attribute; see Section 5.) However, when a route server
+ sets the pCount value to 0, it still inserts its AS number into the
+ Secure_Path Segment, as this information is needed to validate the
+ signature added by the route server. See [RFC8206] for a discussion
+ of setting pCount to 0 to facilitate AS Number migration. Also, see
+ Section 4.3 for the use of pCount=0 in the context of an AS
+ confederation. See Section 7.2 for operational guidance for
+ configuring a BGPsec router for setting pCount=0 and/or accepting
+ pCount=0 from a peer.
+
+ Next, the BGPsec speaker generates one or two Signature_Blocks.
+ Typically, a BGPsec speaker will use only a single algorithm suite
+ and thus create only a single Signature_Block in the BGPsec_PATH
+ attribute. However, to ensure backwards compatibility during a
+ period of transition from a 'current' algorithm suite to a 'new'
+ algorithm suite, it will be necessary to originate UPDATE messages
+ that contain a Signature_Block for both the 'current' and the 'new'
+ algorithm suites (see Section 6.1).
+
+ If the received BGPsec UPDATE message contains two Signature_Blocks
+ and the BGPsec speaker supports both of the corresponding algorithm
+ suites, then the new UPDATE message generated by the BGPsec speaker
+ MUST include both of the Signature_Blocks. If the received BGPsec
+ UPDATE message contains two Signature_Blocks and the BGPsec speaker
+ only supports one of the two corresponding algorithm suites, then the
+ BGPsec speaker MUST remove the Signature_Block corresponding to the
+ algorithm suite that it does not understand. If the BGPsec speaker
+ does not support the algorithm suites in any of the Signature_Blocks
+ contained in the received UPDATE message, then the BGPsec speaker
+ MUST NOT propagate the route advertisement with the BGPsec_PATH
+ attribute. (That is, if it chooses to propagate this route
+ advertisement at all, it MUST do so as an unsigned BGP UPDATE
+ message. See Section 4.4 for more information on converting to an
+ unsigned BGP UPDATE message.)
+
+ Note that in the case where the BGPsec_PATH has two Signature_Blocks
+ (corresponding to different algorithm suites), the validation
+ algorithm (see Section 5.2) deems a BGPsec UPDATE message to be
+ 'Valid' if there is at least one supported algorithm suite (and
+ corresponding Signature_Block) that is deemed 'Valid'. This means
+ that a 'Valid' BGPsec UPDATE message may contain a Signature_Block
+ that is not deemed 'Valid' (e.g., contains signatures that BGPsec
+ does not successfully verify). Nonetheless, such Signature_Blocks
+ MUST NOT be removed. (See Section 8 for a discussion of the security
+ ramifications of this design choice.)
+
+
+
+
+
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+
+ For each Signature_Block corresponding to an algorithm suite that the
+ BGPsec speaker does support, the BGPsec speaker MUST add a new
+ Signature Segment to the Signature_Block. This Signature Segment is
+ prepended to the list of Signature Segments (placed in the first
+ position) so that the list of Signature Segments appears in the same
+ order as the corresponding Secure_Path Segments. The BGPsec speaker
+ populates the fields of this new Signature Segment as follows.
+
+ The Subject Key Identifier field in the new segment is populated with
+ the identifier contained in the Subject Key Identifier extension of
+ the RPKI router certificate corresponding to the BGPsec speaker
+ [RFC8209]. This Subject Key Identifier will be used by recipients of
+ the route advertisement to identify the proper certificate to use in
+ verifying the signature.
+
+ The Signature field in the new segment contains a digital signature
+ that binds the prefix and BGPsec_PATH attribute to the RPKI router
+ certificate corresponding to the BGPsec speaker. The digital
+ signature is computed as follows:
+
+ o For clarity, let us number the Secure_Path and corresponding
+ Signature Segments from 1 to N, as follows. Let Secure_Path
+ Segment 1 and Signature Segment 1 be the segments produced by the
+ origin AS. Let Secure_Path Segment 2 and Signature Segment 2 be
+ the segments added by the next AS after the origin. Continue this
+ method of numbering, and ultimately let Secure_Path Segment N and
+ Signature Segment N be those that are being added by the current
+ AS. The current AS (Nth AS) is signing and forwarding the UPDATE
+ message to the next AS (i.e., the (N+1)th AS) in the chain of ASes
+ that form the AS path.
+
+ o In order to construct the digital signature for Signature
+ Segment N (the Signature Segment being produced by the current
+ AS), first construct the sequence of octets to be hashed as shown
+ in Figure 8. This sequence of octets includes all the data that
+ the Nth AS attests to by adding its digital signature in the
+ UPDATE message that is being forwarded to a BGPsec speaker in the
+ (N+1)th AS. (For the design rationale for choosing the specific
+ structure in Figure 8, please see [Borchert].)
+
+
+
+
+
+
+
+
+
+
+
+
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+
+
+ +------------------------------------+
+ | Target AS Number |
+ +------------------------------------+----\
+ | Signature Segment : N-1 | \
+ +------------------------------------+ |
+ | Secure_Path Segment : N | |
+ +------------------------------------+ \
+ ... > Data from
+ +------------------------------------+ / N Segments
+ | Signature Segment : 1 | |
+ +------------------------------------+ |
+ | Secure_Path Segment : 2 | |
+ +------------------------------------+ /
+ | Secure_Path Segment : 1 | /
+ +------------------------------------+---/
+ | Algorithm Suite Identifier |
+ +------------------------------------+
+ | AFI |
+ +------------------------------------+
+ | SAFI |
+ +------------------------------------+
+ | NLRI |
+ +------------------------------------+
+
+ Figure 8: Sequence of Octets to Be Hashed
+
+ The elements in this sequence (Figure 8) MUST be ordered exactly
+ as shown. The 'Target AS Number' is the AS to whom the BGPsec
+ speaker intends to send the UPDATE message. (Note that the
+ 'Target AS Number' is the AS number announced by the peer in the
+ OPEN message of the BGP session within which the UPDATE message is
+ sent.) The Secure_Path and Signature Segments (1 through N-1) are
+ obtained from the BGPsec_PATH attribute. Finally, the Address
+ Family Identifier (AFI), Subsequent Address Family Identifier
+ (SAFI), and NLRI fields are obtained from the MP_REACH_NLRI
+ attribute [RFC4760]. Additionally, in the Prefix field within the
+ NLRI field (see Section 5 in RFC 4760 [RFC4760]), all of the
+ trailing bits MUST be set to 0 when constructing this sequence.
+
+ o Apply to this octet sequence (in Figure 8) the digest algorithm
+ (for the algorithm suite of this Signature_Block) to obtain a
+ digest value.
+
+ o Apply to this digest value the signature algorithm (for the
+ algorithm suite of this Signature_Block) to obtain the digital
+ signature. Then populate the Signature field (in Figure 7) with
+ this digital signature.
+
+
+
+
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+
+
+ The Signature Length field (in Figure 7) is populated with the length
+ (in octets) of the value in the Signature field.
+
+4.3. Processing Instructions for Confederation Members
+
+ Members of AS confederations [RFC5065] MUST additionally follow the
+ instructions in this section for processing BGPsec UPDATE messages.
+
+ When a BGPsec speaker in an AS confederation receives a BGPsec UPDATE
+ message from a peer that is external to the confederation and chooses
+ to propagate the UPDATE message within the confederation, it first
+ adds a signature signed to its own Member-AS (i.e., the 'Target AS
+ Number' is the BGPsec speaker's Member-AS Number). In this
+ internally modified UPDATE message, the newly added Secure_Path
+ Segment contains the public AS number (i.e., Confederation
+ Identifier), the segment's pCount value is set to 0, and
+ Confed_Segment flag is set to 1. Setting pCount=0 in this case helps
+ ensure that the AS path length is not unnecessarily incremented. The
+ newly added signature is generated using a private key corresponding
+ to the public AS number of the confederation. The BGPsec speaker
+ propagates the modified UPDATE message to its peers within the
+ confederation.
+
+ Any BGPsec_PATH modifications mentioned below in the context of
+ propagation of the UPDATE message within the confederation are in
+ addition to the modification described above (i.e., with pCount=0).
+
+ When a BGPsec speaker sends a BGPsec UPDATE message to a peer that
+ belongs within its own Member-AS, the confederation member SHALL NOT
+ modify the BGPsec_PATH attribute. When a BGPsec speaker sends a
+ BGPsec UPDATE message to a peer that is within the same confederation
+ but in a different Member-AS, the BGPsec speaker puts its Member-AS
+ Number in the AS Number field of the Secure_Path Segment that it adds
+ to the BGPsec UPDATE message. Additionally, in this case, the
+ Member-AS that generates the Secure_Path Segment sets the
+ Confed_Segment flag to 1. Further, the signature is generated with a
+ private key corresponding to the BGPsec speaker's Member-AS Number.
+ (Note: In this document, intra-Member-AS peering is regarded as iBGP,
+ and inter-Member-AS peering is regarded as eBGP. The latter is also
+ known as confederation-eBGP.)
+
+ Within a confederation, the verification of BGPsec signatures added
+ by other members of the confederation is optional. Note that if a
+ confederation chooses not to verify digital signatures within the
+ confederation, then BGPsec is not able to provide any assurances
+ about the integrity of the Member-AS Numbers placed in Secure_Path
+ Segments where the Confed_Segment flag is set to 1.
+
+
+
+
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+
+ When a confederation member receives a BGPsec UPDATE message from a
+ peer within the confederation and propagates it to a peer outside the
+ confederation, it needs to remove all of the Secure_Path Segments
+ added by confederation members as well as the corresponding Signature
+ Segments. To do this, the confederation member propagating the route
+ outside the confederation does the following:
+
+ o First, starting with the most recently added Secure_Path Segment,
+ remove all of the consecutive Secure_Path Segments that have the
+ Confed_Segment flag set to 1. Stop this process once a
+ Secure_Path Segment that has its Confed_Segment flag set to 0 is
+ reached. Keep a count of the number of segments removed in this
+ fashion.
+
+ o Second, starting with the most recently added Signature Segment,
+ remove a number of Signature Segments equal to the number of
+ Secure_Path Segments removed in the previous step. (That is,
+ remove the K most recently added Signature Segments, where K is
+ the number of Secure_Path Segments removed in the previous step.)
+
+ o Finally, add a Secure_Path Segment containing, in the AS field,
+ the AS Confederation Identifier (the public AS number of the
+ confederation) as well as a corresponding Signature Segment. Note
+ that all fields other than the AS field are populated as per
+ Section 4.2.
+
+ Finally, as discussed above, an AS confederation MAY optionally
+ decide that its members will not verify digital signatures added by
+ members. In such a confederation, when a BGPsec speaker runs the
+ algorithm in Section 5.2, the BGPsec speaker, during the process of
+ signature verifications, first checks whether the Confed_Segment flag
+ in a Secure_Path Segment is set to 1. If the flag is set to 1, the
+ BGPsec speaker skips the verification for the corresponding signature
+ and immediately moves on to the next Secure_Path Segment. Note that
+ as specified in Section 5.2, it is an error when a BGPsec speaker
+ receives, from a peer who is not in the same AS confederation, a
+ BGPsec UPDATE message containing a Confed_Segment flag set to 1.
+
+4.4. Reconstructing the AS_PATH Attribute
+
+ BGPsec UPDATE messages do not contain the AS_PATH attribute.
+ However, the AS_PATH attribute can be reconstructed from the
+ BGPsec_PATH attribute. This is necessary in the case where a route
+ advertisement is received via a BGPsec UPDATE message and then
+ propagated to a peer via a non-BGPsec UPDATE message (e.g., because
+ the latter peer does not support BGPsec). Note that there may be
+ additional cases where an implementation finds it useful to perform
+ this reconstruction. Before attempting to reconstruct an AS_PATH for
+
+
+
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+
+
+ the purpose of forwarding an unsigned (non-BGPsec) UPDATE message to
+ a peer, a BGPsec speaker MUST perform the basic integrity checks
+ listed in Section 5.2 to ensure that the received BGPsec UPDATE
+ message is properly formed.
+
+ The AS_PATH attribute can be constructed from the BGPsec_PATH
+ attribute as follows. Starting with a blank AS_PATH attribute,
+ process the Secure_Path Segments in order from least recently added
+ (corresponding to the origin) to most recently added. For each
+ Secure_Path Segment, perform the following steps:
+
+ 1. If the Secure_Path Segment has pCount=0, then do nothing (i.e.,
+ move on to process the next Secure_Path Segment).
+
+ 2. If the Secure_Path Segment has pCount greater than 0 and the
+ Confed_Segment flag is set to 1, then look at the most recently
+ added segment in the AS_PATH.
+
+ * In the case where the AS_PATH is blank or in the case where
+ the most recently added segment is of type AS_SEQUENCE, add
+ (prepend to the AS_PATH) a new AS_PATH segment of type
+ AS_CONFED_SEQUENCE. This segment of type AS_CONFED_SEQUENCE
+ shall contain a number of elements equal to the pCount field
+ in the current Secure_Path Segment. Each of these elements
+ shall be the AS number contained in the current Secure_Path
+ Segment. (That is, if the pCount field is X, then the segment
+ of type AS_CONFED_SEQUENCE contains X copies of the
+ Secure_Path Segment's AS Number field.)
+
+ * In the case where the most recently added segment in the
+ AS_PATH is of type AS_CONFED_SEQUENCE, then add (prepend to
+ the segment) a number of elements equal to the pCount field in
+ the current Secure_Path Segment. The value of each of these
+ elements shall be the AS number contained in the current
+ Secure_Path Segment. (That is, if the pCount field is X, then
+ add X copies of the Secure_Path Segment's AS Number field to
+ the existing AS_CONFED_SEQUENCE.)
+
+ 3. If the Secure_Path Segment has pCount greater than 0 and the
+ Confed_Segment flag is set to 0, then look at the most recently
+ added segment in the AS_PATH.
+
+ * In the case where the AS_PATH is blank or in the case where
+ the most recently added segment is of type AS_CONFED_SEQUENCE,
+ add (prepend to the AS_PATH) a new AS_PATH segment of type
+ AS_SEQUENCE. This segment of type AS_SEQUENCE shall contain a
+ number of elements equal to the pCount field in the current
+ Secure_Path Segment. Each of these elements shall be the AS
+
+
+
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+
+
+ number contained in the current Secure_Path Segment. (That
+ is, if the pCount field is X, then the segment of type
+ AS_SEQUENCE contains X copies of the Secure_Path Segment's AS
+ Number field.)
+
+ * In the case where the most recently added segment in the
+ AS_PATH is of type AS_SEQUENCE, then add (prepend to the
+ segment) a number of elements equal to the pCount field in the
+ current Secure_Path Segment. The value of each of these
+ elements shall be the AS number contained in the current
+ Secure_Path Segment. (That is, if the pCount field is X, then
+ add X copies of the Secure_Path Segment's AS Number field to
+ the existing AS_SEQUENCE.)
+
+ As part of the procedure described above, the following additional
+ actions are performed in order not to exceed the size limitations of
+ AS_SEQUENCE and AS_CONFED_SEQUENCE. While adding the next
+ Secure_Path Segment (with its prepends, if any) to the AS_PATH being
+ assembled, if it would cause the AS_SEQUENCE (or AS_CONFED_SEQUENCE)
+ at hand to exceed the limit of 255 AS numbers per segment [RFC4271]
+ [RFC5065], then the BGPsec speaker would follow the recommendations
+ in RFC 4271 [RFC4271] and RFC 5065 [RFC5065] of creating another
+ segment of the same type (AS_SEQUENCE or AS_CONFED_SEQUENCE) and
+ continue filling that.
+
+ Finally, one special case of reconstruction of AS_PATH is when the
+ BGPsec_PATH attribute is absent. As explained in Section 4.1, when a
+ BGPsec speaker originates a prefix and sends it to a BGPsec-capable
+ iBGP peer, the BGPsec_PATH is not attached. So, when received from a
+ BGPsec-capable iBGP peer, no BGPsec_PATH attribute in a BGPsec UPDATE
+ message is equivalent to an empty AS_PATH [RFC4271].
+
+5. Processing a Received BGPsec UPDATE Message
+
+ Upon receiving a BGPsec UPDATE message from an external (eBGP) peer,
+ a BGPsec speaker SHOULD validate the message to determine the
+ authenticity of the path information contained in the BGPsec_PATH
+ attribute. Typically, a BGPsec speaker will also wish to perform
+ origin validation (see RFC 6483 [RFC6483] and RFC 6811 [RFC6811]) on
+ an incoming BGPsec UPDATE message, but such validation is independent
+ of the validation described in this section.
+
+ Section 5.1 provides an overview of BGPsec validation, and
+ Section 5.2 provides a specific algorithm for performing such
+ validation. (Note that an implementation need not follow the
+ specific algorithm in Section 5.2 as long as the input/output
+ behavior of the validation is identical to that of the algorithm in
+ Section 5.2.) During exceptional conditions (e.g., the BGPsec
+
+
+
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+
+
+ speaker receives an incredibly large number of UPDATE messages at
+ once), a BGPsec speaker MAY temporarily defer validation of incoming
+ BGPsec UPDATE messages. The treatment of such BGPsec UPDATE
+ messages, whose validation has been deferred, is a matter of local
+ policy. However, an implementation SHOULD ensure that deferment of
+ validation and status of deferred messages is visible to the
+ operator.
+
+ The validity of BGPsec UPDATE messages is a function of the current
+ RPKI state. When a BGPsec speaker learns that the RPKI state has
+ changed (e.g., from an RPKI validating cache via the RPKI-Router
+ protocol [RFC8210]), the BGPsec speaker MUST rerun validation on all
+ affected UPDATE messages stored in its Adj-RIB-In [RFC4271]. For
+ example, when a given RPKI router certificate ceases to be valid
+ (e.g., it expires or is revoked), all UPDATE messages containing a
+ signature whose SKI matches the SKI in the given certificate MUST be
+ reassessed to determine if they are still valid. If this
+ reassessment determines that the validity state of an UPDATE message
+ has changed, then, depending on local policy, it may be necessary to
+ rerun best path selection.
+
+ BGPsec UPDATE messages do not contain an AS_PATH attribute. The
+ Secure_Path contains AS path information for the BGPsec UPDATE
+ message. Therefore, a BGPsec speaker MUST utilize the AS path
+ information in the Secure_Path in all cases where it would otherwise
+ use the AS path information in the AS_PATH attribute. The only
+ exception to this rule is when AS path information must be updated in
+ order to propagate a route to a peer (in which case the BGPsec
+ speaker follows the instructions in Section 4). Section 4.4 provides
+ an algorithm for constructing an AS_PATH attribute from a BGPsec_PATH
+ attribute. Whenever the use of AS path information is called for
+ (e.g., loop detection or the use of the AS path length in best path
+ selection), the externally visible behavior of the implementation
+ shall be the same as if the implementation had run the algorithm in
+ Section 4.4 and used the resulting AS_PATH attribute as it would for
+ a non-BGPsec UPDATE message.
+
+5.1. Overview of BGPsec Validation
+
+ Validation of a BGPsec UPDATE message makes use of data from RPKI
+ router certificates. In particular, it is necessary that the
+ recipient have access to the following data obtained from valid RPKI
+ router certificates: the AS Number, Public Key, and Subject Key
+ Identifier from each valid RPKI router certificate.
+
+ Note that the BGPsec speaker could perform the validation of RPKI
+ router certificates on its own and extract the required data, or it
+ could receive the same data from a trusted cache that performs RPKI
+
+
+
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+
+
+ validation on behalf of (some set of) BGPsec speakers. (For example,
+ the trusted cache could deliver the necessary validity information to
+ the BGPsec speaker by using the Router Key PDU (Protocol Data Unit)
+ for the RPKI-Router protocol [RFC8210].)
+
+ To validate a BGPsec UPDATE message containing the BGPsec_PATH
+ attribute, the recipient performs the validation steps specified in
+ Section 5.2. The validation procedure results in one of two states:
+ 'Valid' and 'Not Valid'.
+
+ It is expected that the output of the validation procedure will be
+ used as an input to BGP route selection. That said, BGP route
+ selection, and thus the handling of the validation states, is a
+ matter of local policy and is handled using local policy mechanisms.
+ Implementations SHOULD enable operators to set such local policy on a
+ per-session basis. (That is, it is expected that some operators will
+ choose to treat BGPsec validation status differently for UPDATE
+ messages received over different BGP sessions.)
+
+ BGPsec validation need only be performed at the eBGP edge. The
+ validation status of a BGP signed/unsigned UPDATE message MAY be
+ conveyed via iBGP from an ingress edge router to an egress edge
+ router via some mechanism, according to local policy within an AS.
+ As discussed in Section 4, when a BGPsec speaker chooses to forward a
+ (syntactically correct) BGPsec UPDATE message, it SHOULD be forwarded
+ with its BGPsec_PATH attribute intact (regardless of the validation
+ state of the UPDATE message). Based entirely on local policy, an
+ egress router receiving a BGPsec UPDATE message from within its own
+ AS MAY choose to perform its own validation.
+
+5.2. Validation Algorithm
+
+ This section specifies an algorithm for validation of BGPsec UPDATE
+ messages. A conformant implementation MUST include a BGPsec update
+ validation algorithm that is functionally equivalent to the
+ externally visible behavior of this algorithm.
+
+ First, the recipient of a BGPsec UPDATE message performs a check to
+ ensure that the message is properly formed. Both syntactical and
+ protocol violation errors are checked. The BGPsec_PATH attribute
+ MUST be present when a BGPsec UPDATE message is received from an
+ external (eBGP) BGPsec peer and also when such an UPDATE message is
+ propagated to an internal (iBGP) BGPsec peer (see Section 4.2). The
+ error checks specified in Section 6.3 of [RFC4271] are performed,
+ except that for BGPsec UPDATE messages the checks on the AS_PATH
+ attribute do not apply and instead the following checks on the
+ BGPsec_PATH attribute are performed:
+
+
+
+
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+
+
+ 1. Check to ensure that the entire BGPsec_PATH attribute is
+ syntactically correct (conforms to the specification in this
+ document).
+
+ 2. Check that the AS number in the most recently added Secure_Path
+ Segment (i.e., the one corresponding to the eBGP peer from which
+ the UPDATE message was received) matches the AS number of that
+ peer as specified in the BGP OPEN message. (Note: This check is
+ performed only at an ingress BGPsec router where the UPDATE
+ message is first received from a peer AS.)
+
+ 3. Check that each Signature_Block contains one Signature Segment
+ for each Secure_Path Segment in the Secure_Path portion of the
+ BGPsec_PATH attribute. (Note that the entirety of each
+ Signature_Block MUST be checked to ensure that it is well formed,
+ even though the validation process may terminate before all
+ signatures are cryptographically verified.)
+
+ 4. Check that the UPDATE message does not contain an AS_PATH
+ attribute.
+
+ 5. If the UPDATE message was received from a BGPsec peer that is not
+ a member of the BGPsec speaker's AS confederation, check to
+ ensure that none of the Secure_Path Segments contain a Flags
+ field with the Confed_Segment flag set to 1.
+
+ 6. If the UPDATE message was received from a BGPsec peer that is a
+ member of the BGPsec speaker's AS confederation, check to ensure
+ that the Secure_Path Segment corresponding to that peer contains
+ a Flags field with the Confed_Segment flag set to 1.
+
+ 7. If the UPDATE message was received from a peer that is not
+ expected to set pCount=0 (see Sections 4.2 and 4.3), then check
+ to ensure that the pCount field in the most recently added
+ Secure_Path Segment is not equal to 0. (Note: See Section 7.2
+ for router configuration guidance related to this item.)
+
+ 8. Using the equivalent of AS_PATH corresponding to the Secure_Path
+ in the UPDATE message (see Section 4.4), check that the local AS
+ number is not present in the AS path (i.e., rule out an AS loop).
+
+ If any of these checks fail, it is an error in the BGPsec_PATH
+ attribute. BGPsec speakers 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]. (Note: Since the AS
+ number of a transparent route server does appear in the Secure_Path
+ with pCount=0, the route server MAY check to see if its local AS is
+
+
+
+
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+
+
+ listed in the Secure_Path, and this check MAY be included in the
+ loop-detection check listed above.)
+
+ Next, the BGPsec speaker examines the Signature_Blocks in the
+ BGPsec_PATH attribute. A Signature_Block corresponding to an
+ algorithm suite that the BGPsec speaker does not support is not
+ considered in the validation process. If there is no Signature_Block
+ corresponding to an algorithm suite that the BGPsec speaker supports,
+ then in order to consider the UPDATE message in the route selection
+ process, the BGPsec speaker MUST strip the Signature_Block(s),
+ reconstruct the AS_PATH from the Secure_Path (see Section 4.4), and
+ treat the UPDATE message as if it were received as an unsigned BGP
+ UPDATE message.
+
+ For each remaining Signature_Block (corresponding to an algorithm
+ suite supported by the BGPsec speaker), the BGPsec speaker iterates
+ through the Signature Segments in the Signature_Block, starting with
+ the most recently added segment (and concluding with the
+ least recently added segment). Note that there is a one-to-one
+ correspondence between Signature Segments and Secure_Path Segments
+ within the BGPsec_PATH attribute. The following steps make use of
+ this correspondence:
+
+ o Step 1: Let there be K AS hops in a received BGPsec_PATH attribute
+ that is to be validated. Let AS(1), AS(2), ..., AS(K+1) denote
+ the sequence of AS numbers from the origin AS to the validating
+ AS. Let Secure_Path Segment N and Signature Segment N in the
+ BGPsec_PATH attribute refer to those corresponding to AS(N) (where
+ N = 1, 2, ..., K). The BGPsec speaker that is processing and
+ validating the BGPsec_PATH attribute resides in AS(K+1). Let
+ Signature Segment N be the Signature Segment that is currently
+ being verified.
+
+ o Step 2: Locate the public key needed to verify the signature (in
+ the current Signature Segment). To do this, consult the valid
+ RPKI router certificate data and look up all valid (AS Number,
+ Public Key, Subject Key Identifier) triples in which the AS
+ matches the AS number in the corresponding Secure_Path Segment.
+ Of these triples that match the AS number, check whether there is
+ an SKI that matches the value in the Subject Key Identifier field
+ of the Signature Segment. If this check finds no such matching
+ SKI value, then mark the entire Signature_Block as 'Not Valid' and
+ proceed to the next Signature_Block.
+
+ o Step 3: Compute the digest function (for the given algorithm
+ suite) on the appropriate data.
+
+
+
+
+
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+
+
+ In order to verify the digital signature in Signature Segment N,
+ construct the sequence of octets to be hashed as shown in Figure 9
+ (using the notations defined in Step 1). (Note that this sequence
+ is the same sequence that was used by AS(N) that created the
+ Signature Segment N (see Section 4.2 and Figure 8).)
+
+ +------------------------------------+
+ | Target AS Number |
+ +------------------------------------+----\
+ | Signature Segment : N-1 | \
+ +------------------------------------+ |
+ | Secure_Path Segment : N | |
+ +------------------------------------+ \
+ ... > Data from
+ +------------------------------------+ / N Segments
+ | Signature Segment : 1 | |
+ +------------------------------------+ |
+ | Secure_Path Segment : 2 | |
+ +------------------------------------+ /
+ | Secure_Path Segment : 1 | /
+ +------------------------------------+---/
+ | Algorithm Suite Identifier |
+ +------------------------------------+
+ | AFI |
+ +------------------------------------+
+ | SAFI |
+ +------------------------------------+
+ | NLRI |
+ +------------------------------------+
+
+ Figure 9: Sequence of Octets to Be Hashed for Signature Verification
+ of Signature Segment N; N = 1,2, ..., K, Where K Is the Number of
+ AS Hops in the BGPsec_PATH Attribute
+
+ The elements in this sequence (Figure 9) MUST be ordered exactly
+ as shown. For the first segment to be processed (the
+ most recently added segment (i.e., N = K) given that there are K
+ hops in the Secure_Path), the 'Target AS Number' is AS(K+1), the
+ AS number of the BGPsec speaker validating the UPDATE message.
+ Note that if a BGPsec speaker uses multiple AS Numbers (e.g., the
+ BGPsec speaker is a member of a confederation), the AS number used
+ here MUST be the AS number announced in the OPEN message for the
+ BGP session over which the BGPsec UPDATE message was received.
+
+ For each other Signature Segment (N smaller than K), the 'Target
+ AS Number' is AS(N+1), the AS number in the Secure_Path Segment
+ that corresponds to the Signature Segment added immediately after
+ the one being processed (that is, in the Secure_Path Segment that
+
+
+
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+
+
+ corresponds to the Signature Segment that the validator just
+ finished processing).
+
+ The Secure_Path and Signature Segment are obtained from the
+ BGPsec_PATH attribute. The AFI, SAFI, and NLRI fields are
+ obtained from the MP_REACH_NLRI attribute [RFC4760].
+ Additionally, in the Prefix field within the NLRI field (see
+ Section 5 in RFC 4760 [RFC4760]), all of the trailing bits MUST be
+ set to 0 when constructing this sequence.
+
+ o Step 4: Use the signature validation algorithm (for the given
+ algorithm suite) to verify the signature in the current segment.
+ That is, invoke the signature validation algorithm on the
+ following three inputs: the value of the Signature field in the
+ current segment, the digest value computed in Step 3 above, and
+ the public key obtained from the valid RPKI data in Step 2 above.
+ If the signature validation algorithm determines that the
+ signature is invalid, then mark the entire Signature_Block as
+ 'Not Valid' and proceed to the next Signature_Block. If the
+ signature validation algorithm determines that the signature is
+ valid, then continue processing Signature Segments (within the
+ current Signature_Block).
+
+ If all Signature Segments within a Signature_Block pass validation
+ (i.e., all segments are processed and the Signature_Block has not yet
+ been marked 'Not Valid'), then the Signature_Block is marked as
+ 'Valid'.
+
+ If at least one Signature_Block is marked as 'Valid', then the
+ validation algorithm terminates and the BGPsec UPDATE message is
+ deemed 'Valid'. (That is, if a BGPsec UPDATE message contains two
+ Signature_Blocks, then the UPDATE message is deemed 'Valid' if the
+ first Signature_Block is marked 'Valid' OR the second Signature_Block
+ is marked 'Valid'.)
+
+6. Algorithms and Extensibility
+
+6.1. Algorithm Suite Considerations
+
+ Note that there is currently no support for bilateral negotiation
+ (using BGP capabilities) between BGPsec peers to use a particular
+ (digest and signature) algorithm suite. This is because the
+ algorithm suite used by the sender of a BGPsec UPDATE message MUST be
+ understood not only by the peer to whom it is directly sending the
+ message but also by all BGPsec speakers to whom the route
+ advertisement is eventually propagated. Therefore, selection of an
+ algorithm suite cannot be a local matter negotiated by BGP peers but
+ instead must be coordinated throughout the Internet.
+
+
+
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+
+
+ To this end, [RFC8208] specifies a mandatory-to-use 'current'
+ algorithm suite for use by all BGPsec speakers.
+
+ It is anticipated that, in the future, [RFC8208] or its successor
+ will be updated to specify a transition from the 'current' algorithm
+ suite to a 'new' algorithm suite. During the period of transition,
+ all BGPsec UPDATE messages SHOULD simultaneously use both the
+ 'current' algorithm suite and the 'new' algorithm suite. (Note that
+ Sections 3 and 4 specify how the BGPsec_PATH attribute can contain
+ signatures, in parallel, for two algorithm suites.) Once the
+ transition is complete, the use of the old 'current' algorithm will
+ be deprecated, the use of the 'new' algorithm will be mandatory, and
+ a subsequent 'even newer' algorithm suite may be specified as
+ "recommended to implement". Once the transition has successfully
+ been completed in this manner, BGPsec speakers SHOULD include only a
+ single Signature_Block (corresponding to the 'new' algorithm).
+
+6.2. Considerations for the SKI Size
+
+ Depending on the method of generating key identifiers [RFC7093], the
+ size of the SKI in an RPKI router certificate may vary. The SKI
+ field in the BGPsec_PATH attribute has a fixed size of 20 octets (see
+ Figure 7). If the SKI is longer than 20 octets, then use the
+ leftmost 20 octets of the SKI (excluding the tag and length)
+ [RFC7093]. If the SKI value is shorter than 20 octets, then pad the
+ SKI (excluding the tag and length) to the right (least significant
+ octets) with octets having "0" values.
+
+6.3. Extensibility Considerations
+
+ This section discusses potential changes to BGPsec that would require
+ substantial changes to the processing of the BGPsec_PATH and thus
+ necessitate a new version of BGPsec. Examples of such changes
+ include:
+
+ o A new type of signature algorithm that produces signatures of
+ variable length
+
+ o A new type of signature algorithm for which the number of
+ signatures in the Signature_Block is not equal to the number of
+ ASes in the Secure_Path (e.g., aggregate signatures)
+
+ o Changes to the data that is protected by the BGPsec signatures
+ (e.g., attributes other than the AS path)
+
+ In the case that such a change to BGPsec were 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 --
+
+
+
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+
+
+ let's call it "BGPsec_PATH_Two" -- that is designed to accommodate
+ the desired changes to BGPsec. In such a case, [RFC8208] or its
+ successor would be updated to specify algorithm suites appropriate
+ for the new version of BGPsec.
+
+ At this point, a transition would begin that is analogous to the
+ algorithm transition discussed in Section 6.1. During the transition
+ period, all BGPsec speakers SHOULD simultaneously include both the
+ BGPsec_PATH attribute and the new BGPsec_PATH_Two attribute. Once
+ the transition is complete, the use of BGPsec_PATH could then be
+ deprecated, at which point BGPsec speakers should include only the
+ new BGPsec_PATH_Two attribute. Such a process could facilitate a
+ transition to a new BGPsec semantics in a backwards-compatible
+ fashion.
+
+7. Operations and Management Considerations
+
+ Some operations and management issues that are closely relevant to
+ BGPsec protocol specification and deployment are highlighted here.
+ The best practices concerning operations and deployment of BGPsec are
+ provided in [RFC8207].
+
+7.1. Capability Negotiation Failure
+
+ Section 2.2 describes the negotiation required to establish a
+ BGPsec-capable peering session. Not only must the BGPsec capability
+ be exchanged (and agreed on), but the BGP multiprotocol extension
+ [RFC4760] for the same AFI and the 4-byte AS capability [RFC6793]
+ MUST also be exchanged. Failure to properly negotiate a BGPsec
+ session -- due to a missing capability, for example -- may still
+ result in the exchange of BGP (unsigned) UPDATE messages. It is
+ RECOMMENDED that an implementation log the failure to properly
+ negotiate a BGPsec session. Also, an implementation MUST have the
+ ability to prevent a BGP session from being established if configured
+ to only use BGPsec.
+
+7.2. Preventing Misuse of pCount=0
+
+ A peer that is an Internet Exchange Point (IXP) (i.e., route server)
+ with a transparent AS is expected to set pCount=0 in its Secure_Path
+ Segment while forwarding an UPDATE message to a peer (see
+ Section 4.2). Clearly, such an IXP MUST configure its BGPsec router
+ to set pCount=0 in its Secure_Path Segment. This also means that a
+ BGPsec speaker MUST be configured so that it permits pCount=0 from an
+ IXP peer. Two other cases where pCount is set to 0 are in the
+ contexts of an AS confederation (see Section 4.3) and of AS migration
+ [RFC8206]. In these two cases, pCount=0 is set and accepted within
+ the same AS (albeit the AS has two different identities). Note that
+
+
+
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+
+ if a BGPsec speaker does not expect a peer AS to set its pCount=0 and
+ if an UPDATE message received from that peer violates this, then the
+ UPDATE message MUST be considered to be in error (see the list of
+ checks in Section 5.2). See Section 8.4 for a discussion of security
+ considerations concerning pCount=0.
+
+7.3. Early Termination of Signature Verification
+
+ During the validation of a BGPsec UPDATE message, route processor
+ performance speedup can be achieved by incorporating the following
+ observations. An UPDATE message is deemed 'Valid' if at least one of
+ the Signature_Blocks is marked as 'Valid' (see Section 5.2).
+ Therefore, if an UPDATE message contains two Signature_Blocks and the
+ first one verified is found 'Valid', then the second Signature_Block
+ does not have to be verified. And if the UPDATE message is chosen
+ for best path, then the BGPsec speaker adds its signature (generated
+ with the respective algorithm) to each of the two Signature_Blocks
+ and forwards the UPDATE message. Also, a BGPsec UPDATE message is
+ deemed 'Not Valid' if at least one signature in each of the
+ Signature_Blocks is invalid. This principle can also be used for
+ route processor workload savings, i.e., the verification for a
+ Signature_Block terminates early when the first invalid signature is
+ encountered.
+
+7.4. Non-deterministic Signature Algorithms
+
+ Many signature algorithms are non-deterministic. That is, many
+ signature algorithms will produce different signatures each time they
+ are run (even when they are signing the same data with the same key).
+ Therefore, if a BGPsec router receives a BGPsec UPDATE message from a
+ peer and later receives a second BGPsec UPDATE message from the same
+ peer for the same prefix with the same Secure_Path and SKIs, the
+ second UPDATE message MAY differ from the first UPDATE message in the
+ signature fields (for a non-deterministic signature algorithm).
+ However, the two sets of signature fields will not differ if the
+ sender caches and reuses the previous signature. For a deterministic
+ signature algorithm, the signature fields MUST be identical between
+ the two UPDATE messages. On the basis of these observations, an
+ implementation MAY incorporate optimizations in update validation
+ processing.
+
+7.5. Private AS Numbers
+
+ It is possible that a stub customer of an ISP employs a private AS
+ number. Such a stub customer cannot publish a ROA in the Global RPKI
+ for the private AS number and the prefixes that they use. Also, the
+ Global RPKI cannot support private AS numbers (i.e., BGPsec speakers
+ in private ASes cannot be issued router certificates in the Global
+
+
+
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+
+ RPKI). For interactions between the stub customer (with the private
+ AS number) and the ISP, the following two scenarios are possible:
+
+ 1. The stub customer sends an unsigned BGP UPDATE message for a
+ prefix to the ISP's AS. An edge BGPsec speaker in the ISP's AS
+ may choose to propagate the prefix to its non-BGPsec and BGPsec
+ peers. If so, the ISP's edge BGPsec speaker MUST strip the
+ AS_PATH with the private AS number and then (a) re-originate the
+ prefix without any signatures towards its non-BGPsec peer and
+ (b) re-originate the prefix including its own signature towards
+ its BGPsec peer. In both cases (i.e., (a) and (b)), the prefix
+ MUST have a ROA in the Global RPKI authorizing the ISP's AS to
+ originate it.
+
+ 2. The ISP and the stub customer may use a local RPKI repository
+ (using a mechanism such as one of the mechanisms described in
+ [SLURM]). Then, there can be a ROA for the prefix originated by
+ the stub AS, and the eBGP speaker in the stub AS can be a BGPsec
+ speaker having a router certificate, albeit the ROA and router
+ certificate are valid only locally. With this arrangement, the
+ stub AS sends a signed UPDATE message for the prefix to the ISP's
+ AS. An edge BGPsec speaker in the ISP's AS validates the UPDATE
+ message, using RPKI data based on the local RPKI view. Further,
+ it may choose to propagate the prefix to its non-BGPsec and
+ BGPsec peers. If so, the ISP's edge BGPsec speaker MUST strip
+ the Secure_Path and the Signature Segment received from the stub
+ AS with the private AS number and then (a) re-originate the
+ prefix without any signatures towards its non-BGPsec peer and
+ (b) re-originate the prefix including its own signature towards
+ its BGPsec peer. In both cases (i.e., (a) and (b)), the prefix
+ MUST have a ROA in the Global RPKI authorizing the ISP's AS to
+ originate it.
+
+ It is possible that private AS numbers are used in an AS
+ confederation [RFC5065]. The BGPsec protocol requires that when a
+ BGPsec UPDATE message propagates through a confederation, each
+ Member-AS that forwards it to a peer Member-AS MUST sign the UPDATE
+ message (see Section 4.3). However, the Global RPKI cannot support
+ private AS numbers. In order for the BGPsec speakers in Member-ASes
+ with private AS numbers to have digital certificates, there MUST be a
+ mechanism in place in the confederation that allows the establishment
+ of a local, customized view of the RPKI, augmenting the Global RPKI
+ repository data as needed. Since this mechanism (for augmenting and
+ maintaining a local image of RPKI data) operates locally within an AS
+ or AS confederation, it need not be standard based. However, a
+ standard-based mechanism can be used (see [SLURM]). Recall that in
+ order to prevent exposure of the internals of AS confederations, a
+
+
+
+
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+
+ BGPsec speaker exporting to a non-member removes all
+ intra-confederation Secure_Path Segments and Signatures (see
+ Section 4.3).
+
+7.6. Robustness Considerations for Accessing RPKI Data
+
+ The deployment structure, technologies, and best practices concerning
+ Global RPKI data to reach routers (via local RPKI caches) are
+ described in [RFC6810], [RFC8210], [RFC8181], [RFC7115], [RFC8207],
+ and [RFC8182]. For example, Serial-Number-based incremental update
+ mechanisms are used for efficient transfer of just the data records
+ that have changed since the last update [RFC6810] [RFC8210]. The
+ update notification file is used by Relying Parties (RPs) to discover
+ whether any changes exist between the state of the Global RPKI
+ repository and the RP's cache [RFC8182]. The notification describes
+ the location of (1) the files containing the snapshot and
+ (2) incremental deltas, which can be used by the RP to synchronize
+ with the repository. Making use of these technologies and best
+ practices results in enabling robustness, efficiency, and better
+ security for the BGPsec routers and RPKI caches in terms of the flow
+ of RPKI data from repositories to RPKI caches to routers. With these
+ mechanisms, it is believed that an attacker wouldn't be able to
+ meaningfully correlate RPKI data flows with BGPsec RP (or router)
+ actions, thus avoiding attacks that may attempt to determine the set
+ of ASes interacting with an RP via the interactions between the RP
+ and RPKI servers.
+
+7.7. Graceful Restart
+
+ During Graceful Restart (GR), restarting and receiving BGPsec
+ speakers MUST follow the procedures specified in [RFC4724] for
+ restarting and receiving BGP speakers, respectively. In particular,
+ the behavior of retaining the forwarding state for the routes in the
+ Loc-RIB [RFC4271] and marking them as stale, as well as not
+ differentiating between stale routing information and other
+ information during forwarding, will be the same as the behavior
+ specified in [RFC4724].
+
+7.8. Robustness of Secret Random Number in ECDSA
+
+ The Elliptic Curve Digital Signature Algorithm (ECDSA) with curve
+ P-256 is used for signing UPDATE messages in BGPsec [RFC8208]. For
+ ECDSA, it is stated in Section 6.3 of [FIPS186-4] that a new secret
+ random number "k" shall be generated prior to the generation of each
+ digital signature. A high-entropy random bit generator (RBG) must be
+ used for generating "k", and any potential bias in the "k" generation
+ algorithm must be mitigated (see the methods described in [FIPS186-4]
+ and [SP800-90A]).
+
+
+
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+
+
+7.9. Incremental/Partial Deployment Considerations
+
+ What will migration from BGP to BGPsec look like? What are the
+ benefits for the first adopters? Initially, small groups of
+ contiguous ASes would be doing BGPsec. There would possibly be one
+ or more such groups in different geographic regions of the global
+ Internet. Only the routes originated within each group and
+ propagated within its borders would get the benefits of cryptographic
+ AS path protection. As BGPsec adoption grows, each group grows in
+ size, and eventually they join together to form even larger
+ BGPsec-capable groups of contiguous ASes. The benefit for early
+ adopters starts with AS path security within the regions of
+ contiguous ASes spanned by their respective groups. Over time, they
+ would see those regions of contiguous ASes grow much larger.
+
+ During partial deployment, if an AS in the path doesn't support
+ BGPsec, then BGP goes back to traditional mode, i.e., BGPsec UPDATE
+ messages are converted to unsigned UPDATE messages before forwarding
+ to that AS (see Section 4.4). At this point, the assurance that the
+ UPDATE message propagated via the sequence of ASes listed is lost.
+ In other words, for the BGPsec routers residing in the ASes starting
+ from the origin AS to the AS before the one not supporting BGPsec,
+ the assurance can still be provided, but not beyond that (for the
+ UPDATE messages in consideration).
+
+8. Security Considerations
+
+ For a discussion of the BGPsec threat model and related security
+ considerations, please see RFC 7132 [RFC7132].
+
+8.1. Security Guarantees
+
+ When used in conjunction with origin validation (see RFC 6483
+ [RFC6483] and RFC 6811 [RFC6811]), a BGPsec speaker who receives a
+ valid BGPsec UPDATE message containing a route advertisement for a
+ given prefix is provided with the following security guarantees:
+
+ o The origin AS number corresponds to an AS that has been
+ authorized, in the RPKI, by the IP address space holder to
+ originate route advertisements for the given prefix.
+
+ o For each AS in the path, a BGPsec speaker authorized by the holder
+ of the AS number intentionally chose (in accordance with local
+ policy) to propagate the route advertisement to the subsequent AS
+ in the path.
+
+
+
+
+
+
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+
+ That is, the recipient of a valid BGPsec UPDATE message is assured
+ that the UPDATE message propagated via the sequence of ASes listed in
+ the Secure_Path portion of the BGPsec_PATH attribute. (It should be
+ noted that BGPsec does not offer any guarantee that the data packets
+ would flow along the indicated path; it only guarantees that the BGP
+ UPDATE message conveying the path indeed propagated along the
+ indicated path.) Furthermore, the recipient is assured that this
+ path terminates in an AS that has been authorized by the IP address
+ space holder as a legitimate destination for traffic to the given
+ prefix.
+
+ Note that although BGPsec provides a mechanism for an AS to validate
+ that a received UPDATE message has certain security properties, the
+ use of such a mechanism to influence route selection is completely a
+ matter of local policy. Therefore, a BGPsec speaker can make no
+ assumptions about the validity of a route received from an external
+ (eBGP) BGPsec peer. That is, a compliant BGPsec peer may (depending
+ on the local policy of the peer) send UPDATE messages that fail the
+ validity test in Section 5. Thus, a BGPsec speaker MUST completely
+ validate all BGPsec UPDATE messages received from external peers.
+ (Validation of UPDATE messages received from internal peers is also a
+ matter of local policy; see Section 5.)
+
+8.2. On the Removal of BGPsec Signatures
+
+ There may be cases where a BGPsec speaker deems 'Valid' (as per the
+ validation algorithm in Section 5.2) a BGPsec UPDATE message that
+ contains both a 'Valid' and a 'Not Valid' Signature_Block. That is,
+ the UPDATE message contains two sets of signatures corresponding to
+ two algorithm suites, and one set of signatures verifies correctly
+ and the other set of signatures fails to verify. In this case, the
+ protocol specifies that a BGPsec speaker choosing to propagate the
+ route advertisement in such an UPDATE message MUST add its signature
+ to each of the Signature_Blocks (see Section 4.2). Thus, the BGPsec
+ speaker creates a signature using both algorithm suites and creates a
+ new UPDATE message that contains both the 'Valid' and the 'Not Valid'
+ set of signatures (from its own vantage point).
+
+ To understand the reason for such a design decision, consider the
+ case where the BGPsec speaker receives an UPDATE message with both a
+ set of algorithm A signatures that are 'Valid' and a set of algorithm
+ B signatures that are 'Not Valid'. In such a case, it is possible
+ (perhaps even likely, depending on the state of the algorithm
+ transition) that some of the BGPsec speaker's peers (or other
+ entities further downstream in the BGP topology) do not support
+ algorithm A. Therefore, if the BGPsec speaker were to remove the
+ 'Not Valid' set of signatures corresponding to algorithm B, such
+ entities would treat the message as though it were unsigned. By
+
+
+
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+
+RFC 8205 BGPsec Protocol September 2017
+
+
+ including the 'Not Valid' set of signatures when propagating a route
+ advertisement, the BGPsec speaker ensures that downstream entities
+ have as much information as possible to make an informed opinion
+ about the validation status of a BGPsec UPDATE message.
+
+ Note also that during a period of partial BGPsec deployment, a
+ downstream entity might reasonably treat unsigned messages
+ differently from BGPsec UPDATE messages that contain a single set of
+ 'Not Valid' signatures. That is, by removing the set of 'Not Valid'
+ signatures, the BGPsec speaker might actually cause a downstream
+ entity to 'upgrade' the status of a route advertisement from
+ 'Not Valid' to unsigned. Finally, note that in the above scenario,
+ the BGPsec speaker might have deemed algorithm A signatures 'Valid'
+ only because of some issue with the RPKI state local to its AS (for
+ example, its AS might not yet have obtained a Certificate Revocation
+ List (CRL) indicating that a key used to verify an algorithm A
+ signature belongs to a newly revoked certificate). In such a case,
+ it is highly desirable for a downstream entity to treat the UPDATE
+ message as 'Not Valid' (due to the revocation) and not as 'unsigned'
+ (which would happen if the 'Not Valid' Signature_Blocks were removed
+ en route).
+
+ A similar argument applies to the case where a BGPsec speaker (for
+ some reason, such as a lack of viable alternatives) selects as its
+ best path (to a given prefix) a route obtained via a 'Not Valid'
+ BGPsec UPDATE message. In such a case, the BGPsec speaker should
+ propagate a signed BGPsec UPDATE message, adding its signature to the
+ 'Not Valid' signatures that already exist. Again, this is to ensure
+ that downstream entities are able to make an informed decision and
+ not erroneously treat the route as unsigned. It should also be noted
+ that due to possible differences in RPKI data observed at different
+ vantage points in the network, a BGPsec UPDATE message deemed 'Not
+ Valid' at an upstream BGPsec speaker may be deemed 'Valid' by another
+ BGP speaker downstream.
+
+ Indeed, when a BGPsec speaker signs an outgoing UPDATE message, it is
+ not attesting to a belief that all signatures prior to its own
+ signature are valid. Instead, it is merely asserting that:
+
+ o The BGPsec speaker received the given route advertisement with the
+ indicated prefix, AFI, SAFI, and Secure_Path, and
+
+ o The BGPsec speaker chose to propagate an advertisement for this
+ route to the peer (implicitly) indicated by the 'Target AS
+ Number'.
+
+
+
+
+
+
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+
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+
+
+8.3. Mitigation of Denial-of-Service Attacks
+
+ The BGPsec update validation procedure is a potential target for
+ denial-of-service attacks against a BGPsec speaker. The mitigation
+ of denial-of-service attacks that are specific to the BGPsec protocol
+ is considered here.
+
+ To mitigate the effectiveness of such denial-of-service attacks,
+ BGPsec speakers should implement an update validation algorithm that
+ performs expensive checks (e.g., signature verification) after
+ performing checks that are less expensive (e.g., syntax checks). The
+ validation algorithm specified in Section 5.2 was chosen so as to
+ perform checks that are likely to be expensive after checks that are
+ likely to be inexpensive. However, the relative cost of performing
+ required validation steps may vary between implementations, and thus
+ the algorithm specified in Section 5.2 may not provide the best
+ denial-of-service protection for all implementations.
+
+ Additionally, sending UPDATE messages with very long AS paths (and
+ hence a large number of signatures) is a potential mechanism to
+ conduct denial-of-service attacks. For this reason, it is important
+ that an implementation of the validation algorithm stops attempting
+ to verify signatures as soon as an invalid signature is found. (This
+ ensures that long sequences of invalid signatures cannot be used for
+ denial-of-service attacks.) Furthermore, implementations can
+ mitigate such attacks by only performing validation on UPDATE
+ messages that, if valid, would be selected as the best path. That
+ is, if an UPDATE message contains a route that would lose out in best
+ path selection for other reasons (e.g., a very long AS path), then it
+ is not necessary to determine the BGPsec-validity status of the
+ route.
+
+8.4. Additional Security Considerations
+
+ The mechanism of setting the pCount field to 0 is included in this
+ specification to enable route servers in the control path to
+ participate in BGPsec without increasing the length of the AS path.
+ Two other scenarios where pCount=0 is utilized are in the contexts of
+ an AS confederation (see Section 4.3) and of AS migration [RFC8206].
+ In these two scenarios, pCount=0 is set and also accepted within the
+ same AS (albeit the AS has two different identities). However,
+ entities other than route servers, confederation ASes, or migrating
+ ASes could conceivably use this mechanism (set the pCount to 0) to
+ attract traffic (by reducing the length of the AS path)
+ illegitimately. This risk is largely mitigated if every BGPsec
+ speaker follows the operational guidance in Section 7.2 for
+ configuration for setting pCount=0 and/or accepting pCount=0 from a
+ peer. However, note that a recipient of a BGPsec UPDATE message
+
+
+
+Lepinski & Sriram Standards Track [Page 36]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+ within which an upstream entity two or more hops away has set pCount
+ to 0 is unable to verify for themselves whether pCount was set to 0
+ legitimately.
+
+ There is a possibility of passing a BGPsec UPDATE message via
+ tunneling between colluding ASes. For example, let's say that AS-X
+ does not peer with AS-Y but colludes with AS-Y, and it signs and
+ sends a BGPsec UPDATE message to AS-Y by tunneling. AS-Y can then
+ further sign and propagate the BGPsec UPDATE message to its peers.
+ It is beyond the scope of the BGPsec protocol to detect this form of
+ malicious behavior. BGPsec is designed to protect messages sent
+ within BGP (i.e., within the control plane) -- not when the control
+ plane is bypassed.
+
+ A variant of the collusion by tunneling mentioned above can happen in
+ the context of AS confederations. When a BGPsec router (outside of a
+ confederation) is forwarding an UPDATE message to a Member-AS in the
+ confederation, it signs the UPDATE message to the public AS number of
+ the confederation and not to the member's AS number (see
+ Section 4.3). The Member-AS can tunnel the signed UPDATE message to
+ another Member-AS as received (i.e., without adding a signature).
+ The UPDATE message can then be propagated using BGPsec to other
+ confederation members or to BGPsec neighbors outside of the
+ confederation. This kind of operation is possible, but no grave
+ security or reachability compromise is feared for the following
+ reasons:
+
+ o The confederation members belong to one organization, and strong
+ internal trust is expected.
+
+ o Recall that the signatures that are internal to the confederation
+ MUST be removed prior to forwarding the UPDATE message to an
+ outside BGPsec router (see Section 4.3).
+
+ BGPsec does not provide protection against attacks at the transport
+ layer. As with any BGP session, an adversary on the path between a
+ BGPsec speaker and its peer is able to perform attacks such as
+ modifying valid BGPsec UPDATE messages to cause them to fail
+ validation, injecting (unsigned) BGP UPDATE messages without
+ BGPsec_PATH attributes, injecting BGPsec UPDATE messages with
+ BGPsec_PATH attributes that fail validation, or causing the peer to
+ tear down the BGP session. The use of BGPsec does nothing to
+ increase the power of an on-path adversary -- in particular, even an
+ on-path adversary cannot cause a BGPsec speaker to believe that a
+ BGPsec-invalid route is valid. However, as with any BGP session,
+ BGPsec sessions SHOULD be protected by appropriate transport security
+ mechanisms (see the Security Considerations section in [RFC4271]).
+
+
+
+
+Lepinski & Sriram Standards Track [Page 37]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+ There is a possibility of replay attacks, defined as follows. In the
+ context of BGPsec, a replay attack occurs when a malicious BGPsec
+ speaker in the AS path suppresses a prefix withdrawal (implicit or
+ explicit). Further, a replay attack is said to occur also when a
+ malicious BGPsec speaker replays a previously received BGPsec
+ announcement for a prefix that has since been withdrawn. The
+ mitigation strategy for replay attacks involves router certificate
+ rollover; please see [ROLLOVER] for details.
+
+9. IANA Considerations
+
+ IANA has registered a new BGP capability described in Section 2.1 in
+ the "Capability Codes" registry's "IETF Review" range [RFC8126]. The
+ description for the new capability is "BGPsec Capability". This
+ document is the reference for the new capability.
+
+ IANA has also registered a new path attribute described in Section 3
+ in the "BGP Path Attributes" registry. The code for this new
+ attribute is "BGPsec_PATH". This document is the reference for the
+ new attribute.
+
+ IANA has defined the "BGPsec Capability" registry in the "Resource
+ Public Key Infrastructure (RPKI)" group. The registry is as shown in
+ Figure 10, with values assigned from Section 2.1:
+
+ +------+------------------------------------+------------+
+ | Bits | Field | Reference |
+ +------+------------------------------------+------------+
+ | 0-3 | Version | [RFC8205] |
+ | | Value = 0x0 | |
+ +------+------------------------------------+------------+
+ | 4 | Direction | [RFC8205] |
+ | |(Both possible values 0 and 1 are | |
+ | | fully specified by this RFC) | |
+ +------+------------------------------------+------------+
+ | 5-7 | Unassigned | [RFC8205] |
+ | | Value = 000 (in binary) | |
+ +------+------------------------------------+------------+
+
+ Figure 10: IANA Registry for BGPsec Capability
+
+ The Direction bit (fourth bit) has a value of either 0 or 1, and both
+ values are fully specified by this document. Future Version values
+ and future values of the Unassigned bits are assigned using the
+ "Standards Action" registration procedures defined in RFC 8126
+ [RFC8126].
+
+
+
+
+
+Lepinski & Sriram Standards Track [Page 38]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+ IANA has defined the "BGPsec_PATH Flags" registry in the "Resource
+ Public Key Infrastructure (RPKI)" group. The registry is as shown in
+ Figure 11, with one value assigned from Section 3.1:
+
+ +------+-------------------------------------------+------------+
+ | Flag | Description | Reference |
+ +------+-------------------------------------------+------------+
+ | 0 | Confed_Segment | [RFC8205] |
+ | | Bit value = 1 means Flag set | |
+ | | (indicates Confed_Segment) | |
+ | | Bit value = 0 is default | |
+ +------+-------------------------------------------+------------+
+ | 1-7 | Unassigned | [RFC8205] |
+ | | Value: All 7 bits set to zero | |
+ +------+-------------------------------------------+------------+
+
+ Figure 11: IANA Registry for BGPsec_PATH Flags Field
+
+ Future values of the Unassigned bits are assigned using the
+ "Standards Action" registration procedures defined in RFC 8126
+ [RFC8126].
+
+10. References
+
+10.1. Normative References
+
+ [IANA-AF] IANA, "Address Family Numbers",
+ <https://www.iana.org/assignments/address-family-numbers>.
+
+ [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
+ Requirement Levels", BCP 14, RFC 2119,
+ DOI 10.17487/RFC2119, March 1997,
+ <https://www.rfc-editor.org/info/rfc2119>.
+
+ [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>.
+
+ [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>.
+
+
+
+Lepinski & Sriram Standards Track [Page 39]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+ [RFC5065] Traina, P., McPherson, D., and J. Scudder, "Autonomous
+ System Confederations for BGP", RFC 5065,
+ DOI 10.17487/RFC5065, August 2007,
+ <https://www.rfc-editor.org/info/rfc5065>.
+
+ [RFC5492] Scudder, J. and R. Chandra, "Capabilities Advertisement
+ with BGP-4", RFC 5492, DOI 10.17487/RFC5492, February
+ 2009, <https://www.rfc-editor.org/info/rfc5492>.
+
+ [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>.
+
+ [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>.
+
+ [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>.
+
+ [RFC8126] Cotton, M., Leiba, B., and T. Narten, "Guidelines for
+ Writing an IANA Considerations Section in RFCs", BCP 26,
+ RFC 8126, DOI 10.17487/RFC8126, June 2017,
+ <https://www.rfc-editor.org/info/rfc8126>.
+
+ [RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
+ 2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
+ May 2017, <https://www.rfc-editor.org/info/rfc8174>.
+
+ [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>.
+
+
+
+Lepinski & Sriram Standards Track [Page 40]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+10.2. Informative References
+
+ [Borchert] Borchert, O. and M. Baer, "Subject: Modification request:
+ draft-ietf-sidr-bgpsec-protocol-14", message to the IETF
+ SIDR WG Mailing List, 10 February 2016,
+ <https://mailarchive.ietf.org/arch/msg/
+ sidr/8B_e4CNxQCUKeZ_AUzsdnn2f5Mu>.
+
+ [FIPS186-4]
+ National Institute of Standards and Technology, "Digital
+ Signature Standard (DSS)", NIST FIPS Publication
+ 186-4, DOI 10.6028/NIST.FIPS.186-4, July 2013,
+ <http://nvlpubs.nist.gov/nistpubs/FIPS/
+ NIST.FIPS.186-4.pdf>.
+
+ [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>.
+
+ [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>.
+
+ [RFC6810] Bush, R. and R. Austein, "The Resource Public Key
+ Infrastructure (RPKI) to Router Protocol", RFC 6810,
+ DOI 10.17487/RFC6810, January 2013,
+ <https://www.rfc-editor.org/info/rfc6810>.
+
+ [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>.
+
+ [RFC7093] Turner, S., Kent, S., and J. Manger, "Additional Methods
+ for Generating Key Identifiers Values", RFC 7093,
+ DOI 10.17487/RFC7093, December 2013,
+ <https://www.rfc-editor.org/info/rfc7093>.
+
+
+
+
+
+
+
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+
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+
+
+ [RFC7115] Bush, R., "Origin Validation Operation Based on the
+ Resource Public Key Infrastructure (RPKI)", BCP 185,
+ RFC 7115, DOI 10.17487/RFC7115, January 2014,
+ <https://www.rfc-editor.org/info/rfc7115>.
+
+ [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>.
+
+ [RFC8181] Weiler, S., Sonalker, A., and R. Austein, "A Publication
+ Protocol for the Resource Public Key Infrastructure
+ (RPKI)", July 2017,
+ <https://www.rfc-editor.org/info/rfc8181>.
+
+ [RFC8182] Bruijnzeels, T., Muravskiy, O., Weber, B., and R. Austein,
+ "The RPKI Repository Delta Protocol (RRDP)", RFC 8182,
+ DOI 10.17487/RFC8182, July 2017,
+ <https://www.rfc-editor.org/info/rfc8182>.
+
+ [RFC8206] George, W. and S. Murphy, "BGPsec Considerations for
+ Autonomous System (AS) Migration", RFC 8206,
+ DOI 10.17487/RFC8206, September 2017,
+ <https://www.rfc-editor.org/info/rfc8206>.
+
+ [RFC8207] Bush, R., "BGPsec Operational Considerations", BCP 211,
+ RFC 8207, DOI 10.17487/RFC8207, September 2017,
+ <https://www.rfc-editor.org/info/rfc8207>.
+
+ [RFC8210] Bush, R. and R. Austein, "The Resource Public Key
+ Infrastructure (RPKI) to Router Protocol, Version 1",
+ RFC 8210, DOI 10.17487/RFC8210, September 2017,
+ <https://www.rfc-editor.org/info/rfc8210>.
+
+ [ROLLOVER] Weis, B., Gagliano, R., and K. Patel, "BGPsec Router
+ Certificate Rollover", Work in Progress,
+ draft-ietf-sidrops-bgpsec-rollover-01, August 2017.
+
+ [SLURM] Mandelberg, D., Ma, D., and T. Bruijnzeels, "Simplified
+ Local internet nUmber Resource Management with the RPKI",
+ Work in Progress, draft-ietf-sidr-slurm-04, March 2017.
+
+ [SP800-90A]
+ National Institute of Standards and Technology,
+ "Recommendation for Random Number Generation Using
+ Deterministic Random Bit Generators", NIST SP 800-90A
+ Rev 1, DOI 10.6028/NIST.SP.800-90Ar1, June 2015,
+ <http://nvlpubs.nist.gov/nistpubs/SpecialPublications/
+ NIST.SP.800-90Ar1.pdf>.
+
+
+
+Lepinski & Sriram Standards Track [Page 42]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+Acknowledgements
+
+ The authors would like to thank Michael Baer, Oliver Borchert, David
+ Mandelberg, Mehmet Adalier, Sean Turner, Wes George, Jeff Haas,
+ Alvaro Retana, Nevil Brownlee, Matthias Waehlisch, Tim Polk, Russ
+ Mundy, Wes Hardaker, Sharon Goldberg, Ed Kern, 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. Thanks are also due to many IESG
+ reviewers whose comments greatly helped improve the clarity,
+ accuracy, and presentation in the document.
+
+ The authors particularly wish to acknowledge Oliver Borchert and
+ Michael Baer for their review and suggestions [Borchert] concerning
+ the sequence of octets to be hashed (Figures 8 and 9 in Sections 4.2
+ and 5.2, respectively). This was an important contribution based on
+ their implementation experience.
+
+
+
+
+
+
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+
+
+Contributors
+
+ The following people have 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
+ Email: housley@vigilsec.com
+
+ Stephen Kent
+ BBN Technologies
+ Email: kent@alum.mit.edu
+
+ Warren Kumari
+ Google
+ Email: warren@kumari.net
+
+ Doug Montgomery
+ USA National Institute of Standards and Technology
+ Email: dougm@nist.gov
+
+ Chris Morrow
+ Google, Inc.
+ Email: morrowc@google.com
+
+ Sandy Murphy
+ SPARTA, Inc., a Parsons Company
+ 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
+
+
+
+Lepinski & Sriram Standards Track [Page 44]
+
+RFC 8205 BGPsec Protocol September 2017
+
+
+Authors' Addresses
+
+ Matthew Lepinski (editor)
+ New College of Florida
+ 5800 Bay Shore Road
+ Sarasota, FL 34243
+ United States of America
+
+ Email: mlepinski@ncf.edu
+
+
+ Kotikalapudi Sriram (editor)
+ USA National Institute of Standards and Technology
+ 100 Bureau Drive
+ Gaithersburg, MD 20899
+ United States of America
+
+ Email: kotikalapudi.sriram@nist.gov
+
+
+
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