This is a purely informative rendering of an RFC that includes verified errata. This rendering may not be used as a reference.

The following 'Verified' errata have been incorporated in this document: EID 3205, EID 3238, EID 4080
Internet Engineering Task Force (IETF)                         G. Huston
Request for Comments: 6487                                 G. Michaelson
Category: Standards Track                                     R. Loomans
ISSN: 2070-1721                                                    APNIC
                                                           February 2012


             A Profile for X.509 PKIX Resource Certificates

Abstract

   This document defines a standard profile for X.509 certificates for
   the purpose of supporting validation of assertions of "right-of-use"
   of Internet Number Resources (INRs).  The certificates issued under
   this profile are used to convey the issuer's authorization of the
   subject to be regarded as the current holder of a "right-of-use" of
   the INRs that are described in the certificate.  This document
   contains the normative specification of Certificate and Certificate
   Revocation List (CRL) syntax in the Resource Public Key
   Infrastructure (RPKI).  This document also specifies profiles for the
   format of certificate requests and specifies the Relying Party RPKI
   certificate path validation procedure.

Status of This Memo

   This is an Internet Standards Track document.

   This document is a product of the Internet Engineering Task Force
   (IETF).  It represents the consensus of the IETF community.  It has
   received public review and has been approved for publication by the
   Internet Engineering Steering Group (IESG).  Further information on
   Internet Standards is available in Section 2 of RFC 5741.

   Information about the current status of this document, any errata,
   and how to provide feedback on it may be obtained at
   http://www.rfc-editor.org/info/rfc6487.

Copyright Notice

   Copyright (c) 2012 IETF Trust and the persons identified as the
   document authors.  All rights reserved.

   This document is subject to BCP 78 and the IETF Trust's Legal
   Provisions Relating to IETF Documents
   (http://trustee.ietf.org/license-info) in effect on the date of
   publication of this document.  Please review these documents
   carefully, as they describe your rights and restrictions with respect
   to this document.  Code Components extracted from this document must
   include Simplified BSD License text as described in Section 4.e of
   the Trust Legal Provisions and are provided without warranty as
   described in the Simplified BSD License.

Table of Contents

   1.  Introduction . . . . . . . . . . . . . . . . . . . . . . . . .  4
     1.1.  Terminology  . . . . . . . . . . . . . . . . . . . . . . .  5
   2.  Describing Resources in Certificates . . . . . . . . . . . . .  5
   3.  End-Entity (EE) Certificates and Signing Functions in the RPKI  5
   4.  Resource Certificates  . . . . . . . . . . . . . . . . . . . .  6
     4.1.  Version  . . . . . . . . . . . . . . . . . . . . . . . . .  6
     4.2.  Serial Number  . . . . . . . . . . . . . . . . . . . . . .  6
     4.3.  Signature Algorithm  . . . . . . . . . . . . . . . . . . .  6
     4.4.  Issuer . . . . . . . . . . . . . . . . . . . . . . . . . .  7
     4.5.  Subject  . . . . . . . . . . . . . . . . . . . . . . . . .  7
     4.6.  Validity . . . . . . . . . . . . . . . . . . . . . . . . .  7
       4.6.1.  notBefore  . . . . . . . . . . . . . . . . . . . . . .  8
       4.6.2.  notAfter . . . . . . . . . . . . . . . . . . . . . . .  8
     4.7.  Subject Public Key Info  . . . . . . . . . . . . . . . . .  8
     4.8.  Resource Certificate Extensions  . . . . . . . . . . . . .  8
       4.8.1.  Basic Constraints  . . . . . . . . . . . . . . . . . .  8
       4.8.2.  Subject Key Identifier . . . . . . . . . . . . . . . .  9
       4.8.3.  Authority Key Identifier . . . . . . . . . . . . . . .  9
       4.8.4.  Key Usage  . . . . . . . . . . . . . . . . . . . . . .  9
       4.8.5.  Extended Key Usage . . . . . . . . . . . . . . . . . .  9
       4.8.6.  CRL Distribution Points  . . . . . . . . . . . . . . . 10
       4.8.7.  Authority Information Access . . . . . . . . . . . . . 10
       4.8.8.  Subject Information Access . . . . . . . . . . . . . . 11
       4.8.9.  Certificate Policies . . . . . . . . . . . . . . . . . 12
       4.8.10. IP Resources . . . . . . . . . . . . . . . . . . . . . 12
       4.8.11. AS Resources . . . . . . . . . . . . . . . . . . . . . 12
   5.  Resource Certificate Revocation Lists  . . . . . . . . . . . . 13
   6.  Resource Certificate Requests  . . . . . . . . . . . . . . . . 13
     6.1.  PCKS#10 Profile  . . . . . . . . . . . . . . . . . . . . . 14
       6.1.1.  PKCS#10 Resource Certificate Request Template Fields . 14
     6.2.  CRMF Profile . . . . . . . . . . . . . . . . . . . . . . . 15
       6.2.1.  CRMF Resource Certificate Request Template Fields  . . 15
       6.2.2.  Resource Certificate Request Control Fields  . . . . . 16
     6.3.  Certificate Extension Attributes in Certificate Requests . 16
   7.  Resource Certificate Validation  . . . . . . . . . . . . . . . 17
     7.1.  Resource Extension Validation  . . . . . . . . . . . . . . 17
     7.2.  Resource Certification Path Validation . . . . . . . . . . 18
   8.  Design Notes . . . . . . . . . . . . . . . . . . . . . . . . . 19
   9.  Operational Considerations for Profile Agility . . . . . . . . 22
   10. Security Considerations  . . . . . . . . . . . . . . . . . . . 24
   11. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 25
   12. References . . . . . . . . . . . . . . . . . . . . . . . . . . 25
     12.1. Normative References . . . . . . . . . . . . . . . . . . . 25
     12.2. Informative References . . . . . . . . . . . . . . . . . . 26
   Appendix A.  Example Resource Certificate  . . . . . . . . . . . . 27
   Appendix B.  Example Certificate Revocation List . . . . . . . . . 31

1.  Introduction

   This document defines a standard profile for X.509 certificates
   [X.509] for use in the context of certification of Internet Number
   Resources (INRs), i.e., IP Addresses and Autonomous System (AS)
   numbers.  Such certificates are termed "resource certificates".  A
   resource certificate is a certificate that conforms to the PKIX
   profile [RFC5280], and that conforms to the constraints specified in
   this profile.  A resource certificate attests that the issuer has
   granted the subject a "right-of-use" for a listed set of IP addresses
   and/or Autonomous System numbers.

   This document is referenced by Section 7 of the "Certificate Policy
   (CP) for the Resource Public Key Infrastructure (RPKI)" [RFC6484].
   It is an integral part of that policy and the normative specification
   for certificate and Certificate Revocation List (CRL) syntax used in
   the RPKI.  The document also specifies profiles for the format of
   certificate requests, and the relying party (RP) RPKI certificate
   path validation procedure.

   Resource certificates are to be used in a manner that is consistent
   with the RPKI Certificate Policy (CP) [RFC6484].  They are issued by
   entities that assign and/or allocate public INRs, and thus the RPKI
   is aligned with the public INR distribution function.  When an INR is
   allocated or assigned by a number registry to an entity, this
   allocation can be described by an associated resource certificate.
   This certificate is issued by the number registry, and it binds the
   certificate subject's key to the INRs enumerated in the certificate.
   One or two critical extensions, the IP Address Delegation or AS
   Identifier Delegation Extensions [RFC3779], enumerate the INRs that
   were allocated or assigned by the issuer to the subject.

   Relying party (RP) validation of a resource certificate is performed
   in the manner specified in Section 7.1.  This validation procedure
   differs from that described in Section 6 of [RFC5280], such that:

   o  additional validation processing imposed by the INR extensions is
      required,

   o  a confirmation of a public key match between the CRL issuer and
      the resource certificate issuer is required, and

   o  the resource certificate is required to conform to this profile.

   This profile defines those fields that are used in a resource
   certificate that MUST be present for the certificate to be valid.
   Any extensions not explicitly mentioned MUST be absent.  The same
   applies to the CRLs used in the RPKI, that are also profiled in this

   document.  A Certification Authority (CA) conforming to the RPKI CP
   MUST issue certificates and CRLs consistent with this profile.

1.1.  Terminology

   It is assumed that the reader is familiar with the terms and concepts
   described in "Internet X.509 Public Key Infrastructure Certificate
   and Certificate Revocation List (CRL) Profile" [RFC5280], and "X.509
   Extensions for IP Addresses and AS Identifiers" [RFC3779].

   The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
   "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
   document are to be interpreted as described in [RFC2119].

2.  Describing Resources in Certificates

   The framework for describing an association between the subject of a
   certificate and the INRs currently under the subject's control is
   described in [RFC3779].  This profile further requires that:

   o  Every resource certificate MUST contain either the IP Address
      Delegation or the Autonomous System Identifier Delegation
      extension, or both.

   o  These extensions MUST be marked as critical.

   o  The sorted canonical format describing INRs, with maximal spanning
      ranges and maximal spanning prefix masks, as defined in [RFC3779],
      MUST be used for the resource extension field, except where the
      "inherit" construct is used instead.

   When validating a resource certificate, an RP MUST verify that the
   INRs described in the issuer's resource certificate encompass the
   INRs of the resource certificate being validated.  In this context,
   "encompass" allows for the issuer's INRs to be the same as, or a
   strict superset of, the subject's INRs.

3.  End-Entity (EE) Certificates and Signing Functions in the RPKI

   As noted in [RFC6480], the primary function of end-entity (EE)
   certificates in the RPKI is the verification of signed objects that
   relate to the usage of the INRs described in the certificate, e.g.,
   Route Origin Authorizations (ROAs) and manifests.

   The private key associated with an EE certificate is used to sign a
   single RPKI signed object, i.e., the EE certificate is used to
   validate only one object.  The EE certificate is embedded in the
   object as part of a Cryptographic Message Syntax (CMS) signed-data

   structure [RFC6488].  Because of the one-to-one relationship between
   the EE certificate and the signed object, revocation of the
   certificate effectively revokes the corresponding signed object.

   An EE certificate may be used to validate a sequence of signed
   objects, where each signed object in the sequence overwrites the
   previous instance of the signed object in the repository publication
   point, such that only one instance of the signed object is published
   at any point in time (e.g., an EE certificate MAY be used to sign a
   sequence of manifests [RFC6486]).  Such EE certificates are termed
   "sequential use" EE certificates.

   EE certificates used to validate only one instance of a signed
   object, and are not used thereafter or in any other validation
   context, are termed "one-time-use" EE certificates.

4.  Resource Certificates

   A resource certificate is a valid X.509 public key certificate,
   consistent with the PKIX profile [RFC5280], containing the fields
   listed in this section.  Only the differences from [RFC5280] are
   noted below.

   Unless specifically noted as being OPTIONAL, all the fields listed
   here MUST be present, and any other fields MUST NOT appear in a
   conforming resource certificate.  Where a field value is specified
   here, this value MUST be used in conforming resource certificates.

4.1.  Version

   As resource certificates are X.509 version 3 certificates, the
   version MUST be 3 (i.e., the value of this field is 2).

   RPs need not process version 1 or version 2 certificates (in contrast
   to [RFC5280]).

4.2.  Serial Number

   The serial number value is a positive integer that is unique for each
   certificate issued by a given CA.

4.3.  Signature Algorithm

   The algorithm used in this profile is specified in [RFC6485].

4.4.  Issuer

   The value of this field is a valid X.501 distinguished name.

   An issuer name MUST contain one instance of the CommonName attribute
   and MAY contain one instance of the serialNumber attribute.  If both
   attributes are present, it is RECOMMENDED that they appear as a set.
   The CommonName attribute MUST be encoded using the ASN.1 type
   PrintableString [X.680].  Issuer names are not intended to be
   descriptive of the identity of issuer.

   The RPKI does not rely on issuer names being globally unique, for
   reasons of security.  However, it is RECOMMENDED that issuer names be
   generated in a fashion that minimizes the likelihood of collisions.
   See Section 8 for (non-normative) suggested name-generation
   mechanisms that fulfill this recommendation.

4.5.  Subject

   The value of this field is a valid X.501 distinguished name
   [RFC4514], and is subject to the same constraints as the issuer name.

   In the RPKI, the subject name is determined by the issuer, not
   proposed by the subject [RFC6481].  Each distinct subordinate CA and
   EE certified by the issuer MUST be identified using a subject name
   that is unique per issuer.  In this context, "distinct" is defined as
   an entity and a given public key.  An issuer SHOULD use a different
   subject name if the subject's key pair has changed (i.e., when the CA
   issues a certificate as part of re-keying the subject.)  Subject
   names are not intended to be descriptive of the identity of subject.

4.6.  Validity

   The certificate validity period is represented as a SEQUENCE of two
   dates: the date on which the certificate validity period begins
   (notBefore) and the date on which the certificate validity period
   ends (notAfter).

   While a CA is typically advised against issuing a certificate with a
   validity period that spans a greater period of time than the validity
   period of the CA's certificate that will be used to validate the
   issued certificate, in the context of this profile, a CA MAY have
   valid grounds to issue a subordinate certificate with a validity
   period that exceeds the validity period of the CA's certificate.

4.6.1.  notBefore

   The "notBefore" time SHOULD be no earlier than the time of
   certificate generation.

   In the RPKI, it is valid for a certificate to have a value for this
   field that pre-dates the same field value in any superior
   certificate.  Relying Parties SHOULD NOT attempt to infer from this
   time information that a certificate was valid at a time in the past,
   or that it will be valid at a time in the future, as the scope of an
   RP's test of validity of a certificate refers specifically to
   validity at the current time.

4.6.2.  notAfter

   The "notAfter" time represents the anticipated lifetime of the
   current resource allocation or assignment arrangement between the
   issuer and the subject.

   It is valid for a certificate to have a value for this field that
   post-dates the same field value in any superior certificate.  The
   same caveats apply to RP's assumptions relating to the certificate's
   validity at any time other than the current time.

4.7.  Subject Public Key Info

   The algorithm used in this profile is specified in [RFC6485].

4.8.  Resource Certificate Extensions

   The following X.509 v3 extensions MUST be present in a conforming
   resource certificate, except where explicitly noted otherwise.  Each
   extension in a resource certificate is designated as either critical
   or non-critical.  A certificate-using system MUST reject the
   certificate if it encounters a critical extension it does not
   recognize; however, a non-critical extension MAY be ignored if it is
   not recognized [RFC5280].

4.8.1.  Basic Constraints

   The Basic Constraints extension field is a critical extension in the
   resource certificate profile, and MUST be present when the subject is
   a CA, and MUST NOT be present otherwise.

   The issuer determines whether the "cA" boolean is set.

   The Path Length Constraint is not specified for RPKI certificates,
   and MUST NOT be present.

4.8.2.  Subject Key Identifier

   This extension MUST appear in all resource certificates.  This
   extension is non-critical.

   The Key Identifier used for resource certificates is the 160-bit
   SHA-1 hash of the value of the DER-encoded ASN.1 bit string of the
   Subject Public Key, as described in Section 4.2.1.2 of [RFC5280].

4.8.3.  Authority Key Identifier

   This extension MUST appear in all resource certificates, with the
   exception of a CA who issues a "self-signed" certificate.  In a self-
   signed certificate, a CA MAY include this extension, and set it equal
   to the Subject Key Identifier.  The authorityCertIssuer and
   authorityCertSerialNumber fields MUST NOT be present.  This extension
   is non-critical.

   The Key Identifier used for resource certificates is the 160-bit
   SHA-1 hash of the value of the DER-encoded ASN.1 bit string of the
   issuer's public key, as described in Section 4.2.1.1 of [RFC5280].

4.8.4.  Key Usage

   This extension is a critical extension and MUST be present.

   In certificates issued to certification authorities only, the
   keyCertSign and CRLSign bits are set to TRUE, and these MUST be the
   only bits set to TRUE.

   In EE certificates, the digitalSignature bit MUST be set to TRUE and
   MUST be the only bit set to TRUE.

4.8.5.  Extended Key Usage

   The Extended Key Usage (EKU) extension MUST NOT appear in any CA
   certificate in the RPKI.  This extension also MUST NOT appear in EE
   certificates used to verify RPKI objects (e.g., ROAs or manifests.
   The extension MUST NOT be marked critical.

   The EKU extension MAY appear in EE certificates issued to routers or
   other devices.  Permitted values for the EKU OIDs will be specified
   in Standards Track RFCs issued by other IETF working groups that
   adopt the RPKI profile and that identify application-specific
   requirements that motivate the use of such EKUs.

4.8.6.  CRL Distribution Points

   This extension MUST be present, except in "self-signed" certificates,
   and it is non-critical.  In a self-signed certificate, this extension
   MUST be omitted.

   In this profile, the scope of the CRL is specified to be all
   certificates issued by this CA issuer.

   The CRL Distribution Points (CRLDP) extension identifies the
   location(s) of the CRL(s) associated with certificates issued by this
   issuer.  The RPKI uses the URI [RFC3986] form of object
   identification.  The preferred URI access mechanism is a single rsync
   URI ("rsync://") [RFC5781] that references a single inclusive CRL for
   each issuer.

   In this profile, the certificate issuer is also the CRL issuer,
   implying that the CRLIssuer field MUST be omitted, and the
   distributionPoint field MUST be present.  The Reasons field MUST be
   omitted.

   The distributionPoint MUST contain the fullName field, and MUST NOT
   contain a nameRelativeToCRLIssuer.  The form of the generalName MUST
   be of type URI.

   The sequence of distributionPoint values MUST contain only a single
   DistributionPoint.  The DistributionPoint MAY contain more than one
   URI value.  An rsync URI [RFC5781] MUST be present in the
   DistributionPoint and MUST reference the most recent instance of this
   issuer's CRL.  Other access form URIs MAY be used in addition to the
   rsync URI, representing alternate access mechanisms for this CRL.

4.8.7.  Authority Information Access

   In the context of the RPKI, this extension identifies the publication
   point of the certificate of the issuer of the certificate in which
   the extension appears.  In this profile, a single reference to the
   publication point of the immediate superior certificate MUST be
   present, except for a "self-signed" certificate, in which case the
   extension MUST be omitted.  This extension is non-critical.

   This profile uses a URI form of object identification.  The preferred
   URI access mechanisms is "rsync", and an rsync URI [RFC5781] MUST be
   specified with an accessMethod value of id-ad-caIssuers.  The URI
   MUST reference the point of publication of the certificate where this
   Issuer is the subject (the issuer's immediate superior certificate).
   Other accessMethod URIs referencing the same object MAY also be
   included in the value sequence of this extension.

   A CA MUST use a persistent URL name scheme for CA certificates that
   it issues [RFC6481].  This implies that a reissued certificate
   overwrites a previously issued certificate (to the same subject) in
   the publication repository.  In this way, certificates subordinate to
   the reissued (CA) certificate can maintain a constant Authority
   Information Access (AIA) extension pointer and thus need not be
   reissued when the parent certificate is reissued.

4.8.8.  Subject Information Access

   In the context of the RPKI, this Subject Information Access (SIA)
   extension identifies the publication point of products signed by the
   subject of the certificate.

4.8.8.1.  SIA for CA Certificates

   This extension MUST be present and MUST be marked non-critical.

   This extension MUST have an instance of an accessMethod of id-ad-
   caRepository, with an accessLocation form of a URI that MUST specify
   an rsync URI [RFC5781].  This URI points to the directory containing
   all published material issued by this CA, i.e., all valid CA
   certificates, published EE certificates, the current CRL, manifest,
   and signed objects validated via EE certificates that have been
   issued by this CA [RFC6481].  Other accessDescription elements with
   an accessMethod of id-ad-caRepository MAY be present.  In such cases,
   the accessLocation values describe alternate supported URI access
   mechanisms for the same directory.  The ordering of URIs in this
   accessDescription sequence reflect the CA's relative preferences for
   access methods to be used by RPs, with the first element of the
   sequence being the most preferred by the CA.

   This extension MUST have an instance of an AccessDescription with an
   accessMethod of id-ad-rpkiManifest,

         id-ad OBJECT IDENTIFIER ::= { id-pkix 48 }

         id-ad-rpkiManifest OBJECT IDENTIFIER ::= { id-ad 10 }

   with an rsync URI [RFC5781] form of accessLocation.  The URI points
   to the CA's manifest of published objects [RFC6486] as an object URL.
   Other accessDescription elements MAY exist for the id-ad-rpkiManifest
   accessMethod, where the accessLocation value indicates alternate
   access mechanisms for the same manifest object.

4.8.8.2.  SIA for EE Certificates

   This extension MUST be present and MUST be marked non-critical.

   This extension MUST have an instance of an accessMethod of id-ad-
   signedObject,

         id-ad-signedObject OBJECT IDENTIFIER ::= { id-ad 11 }

   with an accessLocation form of a URI that MUST include an rsync URI
   [RFC5781].  This URI points to the signed object that is verified
   using this EE certificate [RFC6481].  Other accessDescription
   elements may exist for the id-ad-signedObject accessMethod, where the
   accessLocation value indicates alternate URI access mechanisms for
   the same object, ordered in terms of the EE's relative preference for
   supported access mechanisms.

   Other AccessMethods MUST NOT be used for an EE certificates's SIA.

4.8.9.  Certificate Policies

   This extension MUST be present and MUST be marked critical.  It MUST
   include exactly one policy, as specified in the RPKI CP [RFC6484]

4.8.10.  IP Resources

   Either the IP Resources extension, or the AS Resources extension, or
   both, MUST be present in all RPKI certificates, and if present, MUST
   be marked critical.

   This extension contains the list of IP address resources as per
   [RFC3779].  The value may specify the "inherit" element for a
   particular Address Family Identifier (AFI) value.  In the context of
   resource certificates describing public number resources for use in
   the public Internet, the Subsequent AFI (SAFI) value MUST NOT be
   used.

   This extension MUST either specify a non-empty set of IP address
   records, or use the "inherit" setting to indicate that the IP address
   resource set of this certificate is inherited from that of the
   certificate's issuer.

4.8.11.  AS Resources

   Either the AS Resources extension, or the IP Resources extension, or
   both, MUST be present in all RPKI certificates, and if present, MUST
   be marked critical.

   This extension contains the list of AS number resources as per
   [RFC3779], or it may specify the "inherit" element.  Routing Domain
   Identifier (RDI) values are NOT supported in this profile and MUST
   NOT be used.

   This extension MUST either specify a non-empty set of AS number
   records, or use the "inherit" setting to indicate that the AS number
   resource set of this certificate is inherited from that of the
   certificate's issuer.

5.  Resource Certificate Revocation Lists

   Each CA MUST issue a version 2 CRL that is consistent with [RFC5280].
   RPs are NOT required to process version 1 CRLs (in contrast to
   [RFC5280]).  The CRL issuer is the CA.  CRLs conforming to this
   profile MUST NOT include Indirect or Delta CRLs.  The scope of each
   CRL MUST be all certificates issued by this CA.

   The issuer name is as in Section 4.4 above.

   Where two or more CRLs are issued by the same CA, the CRL with the
   highest value of the "CRL Number" field supersedes all other CRLs
   issued by this CA.

   The algorithm used in CRLs issued under this profile is specified in
   [RFC6485].

   The contents of the CRL are a list of all non-expired certificates
   that have been revoked by the CA.

      An RPKI CA MUST include the two extensions, Authority Key Identifier 
   and CRL Number, in every CRL that it issues.  RPs MUST be prepared to
   process CRLs with these extensions.  No other CRL extensions are
   allowed. The extensions mentioned above MUST NOT appear more than 
   once each.
EID 3205 (Verified) is as follows:

Section: 5

Original Text:

   An RPKI CA MUST include the two extensions, Authority Key Identifier
   and CRL Number, in every CRL that it issues.  RPs MUST be prepared to
   process CRLs with these extensions.  No other CRL extensions are
   allowed.

Corrected Text:

   An RPKI CA MUST include the two extensions, Authority Key Identifier
   and CRL Number, in every CRL that it issues.  RPs MUST be prepared to
   process CRLs with these extensions.  No other CRL extensions are
   allowed. The extensions mentioned above MUST NOT appear more than 
   once each.
Notes:
The clarification:

"The extensions mentioned above MUST NOT appear more than once each."

is added.
For each revoked resource certificate, only the two fields, Serial Number and Revocation Date, MUST be present, and all other fields MUST NOT be present. No CRL entry extensions are supported in this profile, and CRL entry extensions MUST NOT be present in a CRL. 6. Resource Certificate Requests A resource certificate request MAY use either of PKCS#10 or Certificate Request Message Format (CRMF). A CA MUST support certificate issuance in PKCS#10 and a CA MAY support CRMF requests. Note that there is no certificate response defined in this profile. For CA certificate requests, the CA places the resource certificate in the repository, as per [RFC6484]. No response is defined for EE certificate requests. 6.1. PCKS#10 Profile This profile refines the specification in [RFC2986], as it relates to resource certificates. A Certificate Request Message object, formatted according to PKCS#10, is passed to a CA as the initial step in issuing a certificate. With the exception of the SubjectPublicKeyinfo and the SIA extension request, the CA is permitted to alter any field in the request when issuing a certificate. 6.1.1. PKCS#10 Resource Certificate Request Template Fields This profile applies the following additional requirements to fields that MAY appear in a CertificationRequestInfo: Version This field is mandatory and MUST have the value 0. Subject This field SHOULD be empty (i.e., NULL), in which case the CA MUST generate a subject name that is unique in the context of certificates issued by this CA. This field is allowed to be non-empty only for a re-key/reissuance request, and only if the CA has adopted a policy (in its Certificate Practice Statement (CPS)) that permits reuse of names in these circumstances.
EID 4080 (Verified) is as follows:

Section: 6.1.1

Original Text:

This field MAY be omitted.  If present, the value of this field
SHOULD be empty (i.e., NULL), in which case the CA MUST
generate a subject name that is unique in the context of
certificates issued by this CA.  This field is allowed to be
non-empty only for a re-key/reissuance request, and only if the
CA has adopted a policy (in its Certificate Practice Statement
(CPS)) that permits reuse of names in these circumstances.

Corrected Text:

This field
SHOULD be empty (i.e., NULL), in which case the CA MUST
generate a subject name that is unique in the context of
certificates issued by this CA.  This field is allowed to be
non-empty only for a re-key/reissuance request, and only if the
CA has adopted a policy (in its Certificate Practice Statement
(CPS)) that permits reuse of names in these circumstances.

Notes:
Submitted after consultation with the responsible AD and WG chairs.

The subject field included in the PKCS#10 request can't be omitted because the ASN.1 in RFC 2986 doesn’t allow subject to be omitted - there’s no “OPTIONAL” in the ASN.1:

CertificationRequestInfo ::= SEQUENCE {
version INTEGER { v1(0) } (v1,...),
subject Name,
subjectPKInfo SubjectPublicKeyInfo{{ PKInfoAlgorithms }},
attributes [0] Attributes{{ CRIAttributes }}
}

In other words, four fields are included in every certificate request. If there’s no subject field it’s a NULL (see RFC5280 for omitting subjects) and if there’s no attributes it’s an empty sequence. version and subjectPKInfo (subject public key information) are always present.
SubjectPublicKeyInfo This field specifies the subject's public key and the algorithm with which the key is used. The algorithm used in this profile is specified in [RFC6485]. Attributes [RFC2986] defines the attributes field as key-value pairs where the key is an OID and the value's structure depends on the key. The only attribute used in this profile is the extensionRequest attribute as defined in [RFC2985]. This attribute contains certificate extensions. The profile for extensions in certificate requests is specified in Section 6.3. This profile applies the following additional constraint to fields that MAY appear in a CertificationRequest Object: signatureAlgorithm The signatureAlgorithm value is specified in [RFC6485]. 6.2. CRMF Profile This profile refines the Certificate Request Message Format (CRMF) specification in [RFC4211], as it relates to resource certificates. A Certificate Request Message object, formatted according to the CRMF, is passed to a CA as the initial step in certificate issuance. With the exception of the SubjectPublicKeyinfo and the SIA extension request, the CA is permitted to alter any requested field when issuing the certificate. 6.2.1. CRMF Resource Certificate Request Template Fields This profile applies the following additional requirements to fields that may appear in a Certificate Request Template: version This field SHOULD be omitted. If present, it MUST specify a request for a version 3 Certificate. serialNumber This field MUST be omitted. signingAlgorithm This field MUST be omitted. issuer This MUST be omitted in this profile. Validity This field MAY be omitted. If omitted, the CA will issue a Certificate with Validity dates as determined by the CA. If specified, then the CA MAY override the requested values with dates as determined by the CA. Subject This field MAY be omitted. If present, the value of this field SHOULD be empty (i.e., NULL), in which case the CA MUST generate a subject name that is unique in the context of certificates issued by this CA. This field is allowed to be non-empty only for a re-key/reissuance request, and only if the CA has adopted a policy (in its CPS) that permits the reuse of names in these circumstances. PublicKey This field MUST be present. extensions The profile for extensions in certificate requests is specified in Section 6.3. 6.2.2. Resource Certificate Request Control Fields The following control fields are supported in this profile: Authenticator Control The intended model of authentication of the subject is a "long term" model, and the guidance offered in [RFC4211] is that the Authenticator Control field be used. 6.3. Certificate Extension Attributes in Certificate Requests The following extensions MAY appear in a PKCS#10 or CRMF Certificate Request. Any other extensions MUST NOT appear in a Certificate Request. This profile places the following additional constraints on these extensions: BasicConstraints If this is omitted, then the CA will issue an EE certificate (hence no BasicConstraints extension will be included). The pathLengthConstraint is not supported in this profile, and this field MUST be omitted. The CA MAY honor the cA boolean if set to TRUE (CA Certificate Request). If this bit is set, then it indicates that the subject is requesting a CA certificate. The CA MUST honor the cA bit if set to FALSE (EE Certificate Request), in which case the corresponding EE certificate will not contain a Basic Constraints extension. KeyUsage The CA MAY honor KeyUsage extensions of keyCertSign and cRLSign if present, as long as this is consistent with the BasicConstraints SubjectType sub-field, when specified. ExtendedKeyUsage The CA MAY honor ExtendedKeyUsage extensions in requests for EE certificates that are issued to routers or other devices, consistent with values specified in Standards Track RFCs that adopt this profile and that identify application-specific requirements that motivate the use of such EKUs.
EID 3238 (Verified) is as follows:

Section: 6.3

Original Text:

 ExtendedKeyUsage
         The CA MAY honor ExtendedKeyUsage extensions of keyCertSign and
         cRLSign if present, as long as this is consistent with the
         BasicConstraints SubjectType sub-field, when specified.

Corrected Text:

 ExtendedKeyUsage
         The CA MAY honor ExtendedKeyUsage extensions in requests for EE
         certificates that are issued to routers or other devices, consistent with values
         specified in Standards Track RFCs that adopt this profile and that identify
         application-specific requirements that motivate the use of such EKUs.
Notes:
The current text appears to be the result of a "cut and paste" error. It is essentially identical to the text
for the Key Usage extension, and names two fields that appear in that extension, not in an EKU extension. The text I propose above parallels what appears in Section 4.8.5, which describes how an
EKU MAY be used in RPKI certificates.
SubjectInformationAccess This field MUST be present, and the field value SHOULD be honored by the CA if it conforms to the requirements set forth in Section 4.8.8. If the CA is unable to honor the requested value for this field, then the CA MUST reject the Certificate Request. 7. Resource Certificate Validation This section describes the resource certificate validation procedure. This refines the generic procedure described in Section 6 of [RFC5280]. 7.1. Resource Extension Validation The IP Resources and AS Resources extensions [RFC3779] define critical extensions for INRs. These are ASN.1 encoded representations of the IPv4 and IPv6 address range and an AS number set. Valid resource certificates MUST have a valid IP address and/or AS number resource extension. In order to validate a resource certificate, the resource extension MUST also be validated. This validation process relies on definitions of comparison of resource sets: more specific Given two contiguous IP address ranges or two contiguous AS number ranges, A and B, A is "more specific" than B if range B includes all IP addresses or AS numbers described by range A, and if range B is larger than range A. equal Given two contiguous IP address ranges or two contiguous AS number ranges, A and B, A is "equal" to B if range A describes precisely the same collection of IP addresses or AS numbers described by range B. The definition of "inheritance" in [RFC3779] is equivalent to this "equality" comparison. encompass Given two IP address and AS number sets, X and Y, X "encompasses" Y if, for every contiguous range of IP addresses or AS numbers elements in set Y, the range element is either "more specific" than or "equal" to a contiguous range element within the set X. Validation of a certificate's resource extension in the context of a certification path (see Section 7.2 entails that for every adjacent pair of certificates in the certification path (certificates 'x' and 'x + 1'), the number resources described in certificate 'x' "encompass" the number resources described in certificate 'x + 1', and the resources described in the trust anchor information "encompass" the resources described in the first certificate in the certification path. 7.2. Resource Certification Path Validation Validation of signed resource data using a target resource certificate consists of verifying that the digital signature of the signed resource data is valid, using the public key of the target resource certificate, and also validating the resource certificate in the context of the RPKI, using the path validation process. This path validation process verifies, among other things, that a prospective certification path (a sequence of n certificates) satisfies the following conditions: 1. for all 'x' in {1, ..., n-1}, the subject of certificate 'x' is the issuer of certificate ('x' + 1); 2. certificate '1' is issued by a trust anchor; 3. certificate 'n' is the certificate to be validated; and 4. for all 'x' in {1, ..., n}, certificate 'x' is valid. Certificate validation entails verifying that all of the following conditions hold, in addition to the certification path validation criteria specified in Section 6 of [RFC5280]: 1. The certificate can be verified using the issuer's public key and the signature algorithm 2. The current time lies within the certificate's Validity From and To values. 3. The certificate contains all fields that MUST be present, as defined by this specification, and contains values for selected fields that are defined as allowable values by this specification. 4. No field, or field value, that this specification defines as MUST NOT be present is used in the certificate. 5. The issuer has not revoked the certificate. A revoked certificate is identified by the certificate's serial number being listed on the issuer's current CRL, as identified by the CRLDP of the certificate, the CRL is itself valid, and the public key used to verify the signature on the CRL is the same public key used to verify the certificate itself. 6. The resource extension data is "encompassed" by the resource extension data contained in a valid certificate where this issuer is the subject (the previous certificate in the context of the ordered sequence defined by the certification path). 7. The certification path originates with a certificate issued by a trust anchor, and there exists a signing chain across the certification path where the subject of Certificate 'x' in the certification path matches the issuer in Certificate 'x + 1' in the certification path, and the public key in Certificate 'x' can verify the signature value in Certificate 'x+1'. A certificate validation algorithm MAY perform these tests in any chosen order. Certificates and CRLs used in this process MAY be found in a locally maintained cache, maintained by a regular synchronization across the distributed publication repository structure [RFC6481]. There exists the possibility of encountering certificate paths that are arbitrarily long, or attempting to generate paths with loops as means of creating a potential denial-of-service (DOS) attack on an RP. An RP executing this procedure MAY apply further heuristics to guide the certification path validation process to a halt in order to avoid some of the issues associated with attempts to validate such malformed certification path structures. Implementations of resource certificate validation MAY halt with a validation failure if the certification path length exceeds a locally defined configuration parameter. 8. Design Notes The following notes provide some additional commentary on the considerations that lie behind some of the design choices that were made in the design of this certificate profile. These notes are non-normative, i.e., this section of the document does not constitute a formal part of the profile specification, and the interpretation of key words as defined in RFC 2119 are not applicable in this section of the document. Certificate Extensions: This profile does not permit the use of any other critical or non-critical extensions. The rationale for this restriction is that the resource certificate profile is intended for a specific defined use. In this context, having certificates with additional non-critical extensions that RPs may see as valid certificates without understanding the extensions is inappropriate, because if the RP were in a position to understand the extensions, it would contradict or qualify this original judgment of validity in some way. This profile takes the position of minimalism over extensibility. The specific goal for the associated RPKI is to precisely match the INR allocation structure through an aligned certificate structure that describes the allocation and its context within the INR distribution hierarchy. The profile defines a resource certificate that is structured to meet these requirements. Certification Authorities and Key Values: This profile uses a definition of an instance of a CA as a combination of a named entity and a key pair. Within this definition, a CA instance cannot rollover a key pair. However, the entity can generate a new instance of a CA with a new key pair and roll over all the signed subordinate products to the new CA [RFC6489]. This has a number of implications in terms of subject name management, CRL Scope, and repository publication point management. CRL Scope and Key Values: For CRL Scope, this profile specifies that a CA issues a single CRL at a time, and the scope of the CRL is all certificates issued by this CA. Because the CA instance is bound to a single key pair, this implies that the CA's public key, the key used to validate the CA's CRL, and the key used to validate the certificates revoked by that CRL are all the same key value. Repository Publication Point: The definition of a CA affects the design of the repository publication system. In order to minimize the amount of forced re-certification on key rollover events, a repository publication regime that uses the same repository publication point for all CA instances that refers to the same entity, but with different key values, will minimize the extent of re-generation of certificates to only immediate subordinate certificates. This is described in [RFC6489]. Subject Name: This profile specifies that subject names must be unique per issuer, and does not specify that subject names must be globally unique (in terms of assured uniqueness). This is due to the nature of the RPKI as a distributed PKI, implying that there is no ready ability for certification authorities to coordinate a simple RPKI-wide unique name space without resorting to additional critical external dependencies. CAs are advised to use subject name generation procedures that minimize the potential for name clashes. One way to achieve this is for a CA to use a subject name practice that uses the CommonName component of the Distinguished Name as a constant value for any given entity that is the subject of CA-issued certificates, and set the serialNumber component of the Distinguished Name to a value that is derived from the hash of the subject public key value. If the CA elects not to use the serialNumber component of the DistinguishedName, then it is considered beneficial that a CA generates CommonNames that have themselves a random component that includes significantly more than 40 bits of entropy in the name. Some non-normative recommendations to achieve this include: 1) Hash of the subject public key (encoded as ASCII HEX). example: cn="999d99d564de366a29cd8468c45ede1848e2cc14" 2) A Universally Unique IDentifier (UUID) [RFC4122] example: cn="6437d442-6fb5-49ba-bbdb-19c260652098" 3) A randomly generated ASCII HEX encoded string of length 20 or greater: example: cn="0f8fcc28e3be4869bc5f8fa114db05e1"> (A string of 20 ASCII HEX digits would have 80-bits of entropy) 4) An internal database key or subscriber ID combined with one of the above example: cn="<DBkey1> (6437d442-6fb5-49ba-bbdb- 19c2606520980)" (The issuing CA may wish to be able to extract the database key or subscriber ID from the commonName. Since only the issuing CA would need to be able to parse the commonName, the database key and the source of entropy (e.g., a UUID) could be separated in any way that the CA wants, as long as it conforms to the rules for PrintableString. The separator could be a space character, parenthesis, hyphen, slash, question mark, etc. 9. Operational Considerations for Profile Agility This profile requires that relying parties reject certificates or CRLs that do not conform to the profile. (Through the remainder of this section, the term "certificate" is used to refer to both certificates and CRLs.) This includes certificates that contain extensions that are prohibited, but that are otherwise valid as per [RFC5280]. This means that any change in the profile (e.g., extensions, permitted attributes or optional fields, or field encodings) for certificates used in the RPKI will not be backward compatible. In a general PKI context, this constraint probably would cause serious problems. In the RPKI, several factors minimize the difficulty of effecting changes of this sort. Note that the RPKI is unique in that every relying party (RP) requires access to every certificate issued by the CAs in this system. An important update of the certificates used in the RPKI must be supported by all CAs and RPs in the system, lest views of the RPKI data differ across RPs. Thus, incremental changes require very careful coordination. It would not be appropriate to introduce a new extension, or authorize use of an extant, standard extension, for a security-relevant purpose on a piecemeal basis. One might imagine that the "critical" flag in X.509 certificate extensions could be used to ameliorate this problem. However, this solution is not comprehensive and does not address the problem of adding a new, security-critical extension. (This is because such an extension needs to be supported universally, by all CAs and RPs.) Also, while some standard extensions can be marked either critical or non-critical, at the discretion of the issuer, not all have this property, i.e., some standard extensions are always non-critical. Moreover, there is no notion of criticality for attributes within a name or optional fields within a field or an extension. Thus, the critical flag is not a solution to this problem. In typical PKI deployments, there are few CAs and many RPs. However, in the RPKI, essentially every CA in the RPKI is also an RP. Thus the set of entities that will need to change in order to issue certificates under a new format is the same set of entities that will need to change to accept these new certificates. To the extent that this is literally true, it says that CA/RP coordination for a change is tightly linked anyway. In reality, there is an important exception to this general observation. Small ISPs and holders of provider-independent allocations are expected to use managed CA services, offered by Regional Internet Registries (RIRs) and potentially by wholesale Internet Service Providers (ISPs). This reduces the number of distinct CA implementations that are needed and makes it easier to effect changes for certificate issuance. It seems very likely that these entities also will make use of RP software provided by their managed CA service provider, which reduces the number of distinct RP software implementations. Also note that many small ISPs (and holders of provider-independent allocations) employ default routes, and thus need not perform RP validation of RPKI data, eliminating these entities as RPs. Widely available PKI RP software does not cache large numbers of certificates, an essential strategy for the RPKI. It does not process manifest or ROA data structures, essential elements of the RPKI repository system. Experience shows that such software deals poorly with revocation status data. Thus, extant RP software is not adequate for the RPKI, although some open source tools (e.g., OpenSSL and cryptlib) can be used as building blocks for an RPKI RP implementation. Thus, it is anticipated that RPs will make use of software that is designed specifically for the RPKI environment and is available from a limited number of open sources. Several RIRs and two companies are providing such software today. Thus it is feasible to coordinate change to this software among the small number of developers/maintainers. If the resource certificate profile is changed in the future, e.g., by adding a new extension or changing the allowed set of name attributes or encoding of these attributes, the following procedure will be employed to effect deployment in the RPKI. The model is analogous to that described in [RPKI-ALG], but is simpler. A new document will be issued as an update to this RFC. The CP for the RPKI [RFC6484] will be updated to reference the new certificate profile. The new CP will define a new policy OID for certificates issued under the new certificate profile. The updated CP also will define a timeline for transition to the new certificate (CRL) format. This timeline will define 3 phases and associated dates: 1. At the end of phase 1, all RPKI CAs MUST be capable of issuing certificates under the new profile, if requested by a subject. Any certificate issued under the new format will contain the new policy OID. 2. During phase 2, CAs MUST issue certificates under the new profile, and these certificates MUST coexist with certificates issued under the old format. (CAs will continue to issue certificates under the old OID/format as well.) The old and new certificates MUST be identical, except for the policy OID and any new extensions, encodings, etc. The new certificates, and associated signed objects, will coexist in the RPKI repository system during this phase, analogous to what is required by an algorithm transition for the RPKI [RPKI-ALG]. Relying parties MAY make use of the old or the new certificate formats when processing signed objects retrieved from the RPKI repository system. During this phase, a relying party that elects to process both formats will acquire the same values for all certificate fields that overlap between the old and new formats. Thus if either certificate format is verifiable, the relying party accepts the data from that certificate. This allows CAs to issue certificates under the new format before all relying parties are prepared to process that format. 3. At the beginning of phase 3, all relying parties MUST be capable of processing certificates under the new format. During this phase, CAs will issue new certificates ONLY under the new format. Certificates issued under the old OID will be replaced with certificates containing the new policy OID. The repository system will no longer require matching old and new certificates under the different formats. At the end of phase 3, all certificates under the old OID will have been replaced. The resource certificate profile RFC will be replaced to remove support for the old certificate format, and the CP will be replaced to remove reference to the old policy OID and to the old resource certificate profile RFC. The system will have returned to a new, steady state. 10. Security Considerations The Security Considerations of [RFC5280] and [RFC3779] apply to resource certificates. The Security Considerations of [RFC2986] and [RFC4211] apply to resource certificate certification requests. A resource certificate PKI cannot in and of itself resolve any forms of ambiguity relating to uniqueness of assertions of rights of use in the event that two or more valid certificates encompass the same resource. If the issuance of resource certificates is aligned to the status of resource allocations and assignments, then the information conveyed in a certificate is no better than the information in the allocation and assignment databases. This profile requires that the key used to sign an issued certificate be the same key used to sign the CRL that can revoke the certificate, implying that the certification path used to validate the signature on a certificate is the same as that used to validate the signature of the CRL that can revoke the certificate. It is noted that this is a tighter constraint than required in X.509 PKIs, and there may be a risk in using a path validation implementation that is capable of using separate validation paths for a certificate and the corresponding CRL. If there are subject name collisions in the RPKI as a result of CAs not following the guidelines provided here relating to ensuring sufficient entropy in constructing subject names, and this is combined with the situation that an RP uses an implementation of validation path construction that is not in conformance with this RPKI profile, then it is possible that the subject name collisions can cause an RP to conclude that an otherwise valid certificate has been revoked. 11. Acknowledgements The authors would like to particularly acknowledge the valued contribution from Stephen Kent in reviewing this document and proposing numerous sections of text that have been incorporated into the document. The authors also acknowledge the contributions of Sandy Murphy, Robert Kisteleki, Randy Bush, Russ Housley, Ricardo Patara, and Rob Austein in the preparation and subsequent review of this document. The document also reflects review comments received from Roque Gagliano, Sean Turner, and David Cooper. 12. References 12.1. Normative References [RFC2119] Bradner, S., "Key words for use in RFCs to Indicate Requirement Levels", BCP 14, RFC 2119, March 1997. [RFC2986] Nystrom, M. and B. Kaliski, "PKCS #10: Certification Request Syntax Specification Version 1.7", RFC 2986, November 2000. [RFC3779] Lynn, C., Kent, S., and K. Seo, "X.509 Extensions for IP Addresses and AS Identifiers", RFC 3779, June 2004. [RFC4211] Schaad, J., "Internet X.509 Public Key Infrastructure Certificate Request Message Format (CRMF)", RFC 4211, September 2005. [RFC5280] Cooper, D., Santesson, S., Farrell, S., Boeyen, S., Housley, R., and W. Polk, "Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile", RFC 5280, May 2008. [RFC5781] Weiler, S., Ward, D., and R. Housley, "The rsync URI Scheme", RFC 5781, February 2010. [RFC6484] Kent, S., Kong, D., Seo, K., and R. Watro, "Certificate Policy (CP) for the Resource Public Key Infrastructure (RPKI)", BCP 173, RFC 6484, February 2012. [RFC6485] Huston, G., "The Profile for Algorithms and Key Sizes for Use in the Resource Public Key Infrastructure (RPKI)", RFC 6485, February 2012. [X.509] ITU-T, "Recommendation X.509: The Directory - Authentication Framework", 2000. [X.680] ITU-T, "Recommendation X.680 (2002) | ISO/IEC 8824- 1:2002, Information technology - Abstract Syntax Notation One (ASN.1): Specification of basic notation", 2002. 12.2. Informative References [RFC2985] Nystrom, M. and B. Kaliski, "PKCS #9: Selected Object Classes and Attribute Types Version 2.0", RFC 2985, November 2000. [RFC3986] Berners-Lee, T., Fielding, R., and L. Masinter, "Uniform Resource Identifier (URI): Generic Syntax", STD 66, RFC 3986, January 2005. [RFC4122] Leach, P., Mealling, M., and R. Salz, "A Universally Unique IDentifier (UUID) URN Namespace", RFC 4122, July 2005. [RFC4514] Zeilenga, K., "Lightweight Directory Access Protocol (LDAP): String Representation of Distinguished Names", RFC 4514, June 2006. [RFC6480] Lepinski, M. and S. Kent, "An Infrastructure to Support Secure Internet Routing", RFC 6480, February 2012. [RFC6481] Huston, G., Loomans, R., and G. Michaelson, "A Profile for Resource Certificate Repository Structure", RFC 6481, February 2012. [RFC6486] Austein, R., Huston, G., Kent, S., and M. Lepinski, "Manifests for the Resource Public Key Infrastructure (RPKI)", RFC 6486, February 2012. [RFC6488] Lepinski, M., Chi, A., and S. Kent, "Signed Object Template for the Resource Public Key Infrastructure (RPKI)", RFC 6488, February 2012. [RFC6489] Huston, G., Michaelson, G., and S. Kent, "Certification Authority (CA) Key Rollover in the Resource Public Key Infrastructure (RPKI)", BCP 174, RFC 6489, February 2012. [RPKI-ALG] Gagliano, R., Kent, S., and S. Turner, "Algorithm Agility Procedure for RPKI", Work in Progress, November 2011. Appendix A. Example Resource Certificate The following is an example resource certificate. Certificate Name: 9JfgAEcq7Q-47IwMC5CJIJr6EJs.cer Data: Version: 3 (0x2) Serial: 1500 (0x5dc) Signature Algorithm: SHA256WithRSAEncryption Issuer: CN=APNIC Production-CVPQSgUkLy7pOXdNeVWGvnFX_0s Validity Not Before: Oct 25 12:50:00 2008 GMT Not After : Jan 31 00:00:00 2010 GMT Subject: CN=A91872ED Subject Public Key Info: Public Key Algorithm: rsaEncryption RSA Public Key: (2048 bit) Modulus (2048 bit): 00:bb:fb:4a:af:a4:b9:dc:d0:fa:6f:67:cc:27:39: 34:d1:80:40:37:de:88:d1:64:a2:f1:b3:fa:c6:7f: bb:51:df:e1:c7:13:92:c3:c8:a2:aa:8c:d1:11:b3: aa:99:c0:ac:54:d3:65:83:c6:13:bf:0d:9f:33:2d: 39:9f:ab:5f:cd:a3:e9:a1:fb:80:7d:1d:d0:2b:48: a5:55:e6:24:1f:06:41:35:1d:00:da:1f:99:85:13: 26:39:24:c5:9a:81:15:98:fb:5f:f9:84:38:e5:d6: 70:ce:5a:02:ca:dd:61:85:b3:43:2d:0b:35:d5:91: 98:9d:da:1e:0f:c2:f6:97:b7:97:3e:e6:fc:c1:c4: 3f:30:c4:81:03:25:99:09:4c:e2:4a:85:e7:46:4b: 60:63:02:43:46:51:4d:ed:fd:a1:06:84:f1:4e:98: 32:da:27:ee:80:82:d4:6b:cf:31:ea:21:af:6f:bd: 70:34:e9:3f:d7:e4:24:cd:b8:e0:0f:8e:80:eb:11: 1f:bc:c5:7e:05:8e:5c:7b:96:26:f8:2c:17:30:7d: 08:9e:a4:72:66:f5:ca:23:2b:f2:ce:54:ec:4d:d9: d9:81:72:80:19:95:57:da:91:00:d9:b1:e8:8c:33: 4a:9d:3c:4a:94:bf:74:4c:30:72:9b:1e:f5:8b:00: 4d:e3 Exponent: 65537 (0x10001) X509v3 extensions: X509v3 Subject Key Identifier: F4:97:E0:00:47:2A:ED:0F:B8:EC:8C:0C:0B:90:89: 20:9A:FA:10:9B X509v3 Authority Key Identifier: keyid:09:53:D0:4A:05:24:2F:2E:E9:39:77:4D:79: 55:86:BE:71:57:FF:4B X509v3 Key Usage: critical Certificate Sign, CRL Sign X509v3 Basic Constraints: critical CA:TRUE X509v3 CRL Distribution Points: URI:rsync://rpki.apnic.net/repository/A3C38A24 D60311DCAB08F31979BDBE39/CVPQSgUkLy7pOXdNe VWGvnFX_0s.crl Authority Information Access: CA Issuers - URI:rsync://rpki.apnic.net/repos itory/8BDFC7DED5FD11DCB14CF4B1A703F9B7/CVP QSgUkLy7pOXdNeVWGvnFX_0s.cer X509v3 Certificate Policies: critical Policy: 1.3.6.1.5.5.7.14.2 Subject Information Access: CA Repository - URI:rsync://rpki.apnic.net/mem ber_repository/A91872ED/06A83982887911DD81 3F432B2086D636/ Manifest - URI:rsync://rpki.apnic.net/member_r epository/A91872ED/06A83982887911DD813F432 B2086D636/9JfgAEcq7Q-47IwMC5CJIJr6EJs.mft sbgp-autonomousSysNum: critical Autonomous System Numbers: 24021 38610 131072 131074 sbgp-ipAddrBlock: critical IPv4: 203.133.248.0/22 203.147.108.0/23 Signature Algorithm: sha256WithRSAEncryption 51:4c:77:e4:21:64:80:e9:35:30:20:9f:d8:4b:88:60:b8:1f: 73:24:9d:b5:17:60:65:6a:28:cc:43:4b:68:97:ca:76:07:eb: dc:bd:a2:08:3c:8c:56:38:c6:0a:1e:a8:af:f5:b9:42:02:6b: 77:e0:b1:1c:4a:88:e6:6f:b6:17:d3:59:41:d7:a0:62:86:59: 29:79:26:76:34:d1:16:2d:75:05:cb:b2:99:bf:ca:c6:68:1b: b6:a9:b0:f4:43:2e:df:e3:7f:3c:b3:72:1a:99:fa:5d:94:a1: eb:57:9c:9a:2c:87:d6:40:32:c9:ff:a6:54:b8:91:87:fd:90: 55:ef:12:3e:1e:2e:cf:c5:ea:c3:4c:09:62:4f:88:00:a0:7f: cd:67:83:bc:27:e1:74:2c:18:4e:3f:12:1d:ef:29:0f:e3:27: 00:ce:14:eb:f0:01:f0:36:25:a2:33:a8:c6:2f:31:18:22:30: cf:ca:97:43:ed:84:75:53:ab:b7:6c:75:f7:2f:55:5c:2e:82: 0a:be:91:59:bf:c9:06:ef:bb:b4:a2:71:9e:03:b1:25:8e:29: 7a:30:88:66:b4:f2:16:6e:df:ad:78:ff:d3:b2:9c:29:48:e3: be:87:5c:fc:20:2b:df:da:ca:30:58:c3:04:c9:63:72:48:8c: 0a:5f:97:71 Appendix B. Example Certificate Revocation List The following is an example Certificate Revocation List. CRL Name: q66IrWSGuBE7jqx8PAUHAlHCqRw.crl Data: Version: 2 Signature Algorithm: Hash: SHA256, Encryption: RSA Issuer: CN=Demo Production APNIC CA - Not for real use, E=ca@apnic.net This Update: Thu Jul 27 06:30:34 2006 GMT Next Update: Fri Jul 28 06:30:34 2006 GMT Authority Key Identifier: Key Identifier: ab:ae:88:ad:64:86:b8:11:3b:8e:ac:7c:3c:05: 07:02:51:c2:a9:1c CRLNumber: 4 Revoked Certificates: 1 Serial Number: 1 Revocation Date: Mon Jul 17 05:10:19 2006 GMT Serial Number: 2 Revocation Date: Mon Jul 17 05:12:25 2006 GMT Serial Number: 4 Revocation Date: Mon Jul 17 05:40:39 2006 GMT Signature: b2:5a:e8:7c:bd:a8:00:0f:03:1a:17:fd:40:2c:46: 0e:d5:64:87:e7:e7:bc:10:7d:b6:3e:39:21:a9:12: f4:5a:d8:b8:d4:bd:57:1a:7d:2f:7c:0d:c6:4f:27: 17:c8:0e:ae:8c:89:ff:00:f7:81:97:c3:a1:6a:0a: f7:d2:46:06:9a:d1:d5:4d:78:e1:b7:b0:58:4d:09: d6:7c:1e:a0:40:af:86:5d:8c:c9:48:f6:e6:20:2e: b9:b6:81:03:0b:51:ac:23:db:9f:c1:8e:d6:94:54: 66:a5:68:52:ee:dd:0f:10:5d:21:b8:b8:19:ff:29: 6f:51:2e:c8:74:5c:2a:d2:c5:fa:99:eb:c5:c2:a2: d0:96:fc:54:b3:ba:80:4b:92:7f:85:54:76:c9:12: cb:32:ea:1d:12:7b:f8:f9:a2:5c:a1:b1:06:8e:d8: c5:42:61:00:8c:f6:33:11:29:df:6e:b2:cc:c3:7c: d3:f3:0c:8d:5c:49:a5:fb:49:fd:e7:c4:73:68:0a: 09:0e:6d:68:a9:06:52:3a:36:4f:19:47:83:59:da: 02:5b:2a:d0:8a:7a:33:0a:d5:ce:be:b5:a2:7d:8d: 59:a1:9d:ee:60:ce:77:3d:e1:86:9a:84:93:90:9f: 34:a7:02:40:59:3a:a5:d1:18:fb:6f:fc:af:d4:02: d9 Authors' Addresses Geoff Huston APNIC EMail: gih@apnic.net URI: http://www.apnic.net George Michaelson APNIC EMail: ggm@apnic.net URI: http://www.apnic.net Robert Loomans APNIC EMail: robertl@apnic.net URI: http://www.apnic.net

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