One document matched: draft-ietf-pkix-ac509prof-01.txt
Differences from draft-ietf-pkix-ac509prof-00.txt
An Internet Attribute Certificate
Profile for Authorization
<draft-ietf-pkix-ac509prof-01.txt>
Status of this Memo
This document is an Internet-Draft and is in full conformance with
all provisions of Section 10 of [RFC2026].
Internet-Drafts are working documents of the Internet Engineering
Task Force (IETF), its areas, and its working groups. Note that
other groups may also distribute working documents as Internet-
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as reference material or to cite them other than as "work in
progress."
The list of current Internet-Drafts can be accessed at
http://www.ietf.org/ietf/1id-abstracts.txt
The list of Internet-Draft Shadow Directories can be accessed at
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<<Comments are contained in angle brackets like this.>>
Abstract
Authorization services are required for numerous Internet protocols,
including TLS, IPSec, and S/MIME. The X.509 Attribute Certificate
provides a structure that can form the basis for such services
[X.509]. This specification defines a profile for the use of X.509
Attribute Certificates to provide authorization services for
Internet protocols. Some optional features are also specified which
are not required for conformance to the base profile.
Table of Contents
Status of this Memo.............................................1
Abstract........................................................1
Table of Contents...............................................1
1. Introduction.................................................3
2. Terminology..................................................5
3. Requirements.................................................6
4. The AC Profile...............................................7
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4.1 X.509 Attribute Certificate Definition.................7
4.2 Object Identifiers.....................................8
4.3 Profile of Standard Fields.............................9
4.3.1 version..........................................9
4.3.2 owner...........................................10
4.3.3 issuer..........................................10
4.3.4 signature.......................................10
4.3.5 serialNumber....................................11
4.3.6 attrCertValidityPeriod..........................11
4.3.7 attributes......................................12
4.3.8 issuerUniqueID..................................12
4.3.9 extensions......................................12
4.4 Extensions............................................12
4.4.1 Audit Identity..................................12
4.4.2 AC Targeting....................................13
4.4.3 authorityKeyIdentifier..........................14
4.4.4 authorityInformationAccess......................14
4.4.5 crlDistributionPoints...........................15
4.5 Attribute Types.......................................15
4.5.1 Service Authentication Info.....................16
4.5.2 Access Identity.................................16
4.5.3 Charging Identity...............................16
4.5.4 Group...........................................17
4.5.5 Role............................................17
4.5.6 Clearance.......................................17
4.6 PKC Extensions........................................18
4.6.1 AAControls......................................18
4.7 Profile of AC Issuer's PKC............................19
5. Attribute Certificate Validation............................19
6. Revocation..................................................21
6.1.1 "Never revoke" method...........................21
6.1.2 "Pointer from above" method.....................22
6.1.3 "Pointer in AC" method..........................22
7. Optional Features...........................................22
7.1 Attribute Encryption..................................22
7.2 Proxying..............................................23
7.3 Use of ObjectDigestInfo...............................25
7.4 AC Chaining...........................................26
8. Security Considerations.....................................27
9. References..................................................27
Author's Addresses.............................................28
Full Copyright Statement.......................................28
Appendix A: "Compilable" ASN.1 Module..........................29
Appendix B: Samples............................................32
Appendix C: Changes this version / Open Issues.................32
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1. Introduction
The key words "MUST", "REQUIRED", "SHOULD", "RECOMMENDED", and "MAY"
in this document are to be interpreted as described in [RFC2119].
A server makes an access control decision when a client requests
access to a resource offered by that server. The server must ensure
that the client is authorized to access that resource. The server
decision is based on the access control policy, the context of the
request, and the identity and authorizations of the client. The
access control policy and the context of the request are readily
available to the server. Certificates may be used to provide
identity and authorization information about the client.
Similar access control decisions are made in other network
environments, such as a store-and-forward electronic mail
environment. That is, access control decisions are not limited to
client-server protocol environments.
X.509 public key certificates (PKCs) [X.509],[RFC2459] bind an
identity and a public key. The identity may be used to support
identity-based access control decisions after the client proves that
it has access to the private key that corresponds to the public key
contained in the PKC. The public key is used to validate digital
signatures or cryptographic key management operations. However, not
all access control decisions are identity-based. Rule-based, role-
based, and rank-based access control decisions require additional
information. For example, information about a client's ability to
pay for a resource access may be more important than the client's
identity. Authorization information to support such access control
decisions may be placed in a PKC extension or placed in a separate
attribute certificate (AC).
The placement of authorization information in PKCs is usually
undesirable for two reasons. First, authorization information does
not have the same lifetime as the binding of the identity and the
public key. When authorization information is placed in a PKC
extension, the general result is the shortening of the PKC useful
lifetime. Second, the PKC issuer is not usually authoritative for
the authorization information. This results in additional steps for
the PKC issuer to obtain authorization information from the
authoritative source.
For these reasons, it is often better to separate this authorization
information from the PKC. Yet, this authorization information also
needs to be protected in a fashion similar to a PKC. An attribute
certificate (AC) provides this protection, and it is simply a
digitally signed (or certified) set of attributes.
An AC is a structure similar to a PKC; the main difference being
that it contains no public key. An AC may contain attributes that
specify group membership, role, security clearance, and other access
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control information associated with the AC owner. The syntax for the
AC is defined in Recommendation X.509 (making the term "X.509
certificate" ambiguous). This document specifies a profile of the
X.509 AC suitable for use with authorization information within
Internet protocols.
When making an access control decision based on an AC, an access
control decision function may need to ensure that the appropriate AC
owner is the entity that has requested access. For example, one way
in which the linkage between the request and the AC can be achieved
is if the AC has a "pointer" to a PKC for the requester and that PKC
has been used to authenticate the access request.
As there is often confusion about the difference between PKCs and
ACs, an analogy may help. A PKC can be considered to be like a
passport: it identifies the owner, tends to last for a long time and
should not be trivial to obtain. An AC is more like an entry visa:
it is typically issued by a different authority and does not last
for as long a time. As acquiring an entry visa typically requires
presenting a passport, getting a visa can be a simpler process.
In conjunction with authentication services, ACs provide a means to
securely provide authorization information to applications. However,
there are a number of possible communication paths that an AC may
take.
In some environments it is suitable for a client to "push" an AC to
a server. This means that no new connections between the client and
server are required. It also means that no search burden is imposed
on servers, which improves performance.
In other cases, it is more suitable for a client simply to
authenticate to the server and for the server to request ("pull")
the client's AC from an AC issuer or a repository. A major benefit
of the "pull" model is that it can be implemented without changes to
the client or client-server protocol. It is also more suitable for
some inter-domain cases where the client's rights should be assigned
within the server's domain, rather than within the client's "home"
domain.
There are a number of possible exchanges that can occur and three
entities involved (client, server and AC issuer). In addition the
use of a directory service or other repository for AC retrieval MAY
be supported.
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Figure 1 shows an abstract view of the exchanges that may involve
ACs. This profile does not specify protocol for these exchanges.
+--------------+
| | Server Acquisition
| AC Issuer +----------------------------+
| | |
+--+-----------+ |
| |
| Client |
| Acquisition |
| |
+--+-----------+ +--+------------+
| | AC "push" | |
| Client +-------------------------+ Server |
| | (part of app. protocol) | |
+--+-----------+ +--+------------+
| |
| Client | Server
| Lookup +--------------+ | Lookup
| | | |
+---------------+ Repository +---------+
| |
+--------------+
Figure 1: AC Exchanges
The remainder of the document is structured as follows:-
Section 2 defines some terminology
Section 3 specifies the requirements that this profile is to meet
Section 4 contains the profile of the X.509 AC
Section 5 specifies rules for AC validation
Section 6 specifies rules for AC revocation checks
Section 7 specifies optional features which MAY be supported but for
which support is not required for conformance to this profile
Appendices contain a "compilable" ASN.1 module for this
specification, samples and a list of changes and open issues.
2. Terminology
For simplicity, we use the terms client and server in this
specification. This is not intended to indicate that ACs are only to
be used in client-server environments, e.g. in the S/MIME v3
context, the mail user agent would, by turns, be both "client" and
"server" in the sense the terms are used here.
Term Meaning
AA Attribute Authority, the entity that issues the
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AC, synonymous in this specification with "AC
issuer"
AC Attribute Certificate
AC user any entity that parses or processes an AC
AC verifier any entity that checks the validity of an AC and
then makes use of the result
AC issuer the entity which signs the AC, synonymous in this
specification with "AA"
AC owner the entity indicated (perhaps indirectly) in the
owner field of the AC
Client the entity which is requesting the action for
which authorization checks are to be made
Proxying In this specification, Proxying is used to mean
the situation where an application server acts as
an application client on behalf of a user.
Proxying here does not mean granting of authority.
PKC Public Key Certificate - uses the type ASN.1
Certificate defined in X.509 and profiled in RFC
2459. This (non-standard) acronym is used in order
to avoid confusion about the term "X.509
certificate".
Server the entity which requires that the authorization
checks are made
3. Requirements
This Attribute Certificate profile meets the following requirements.
Time/Validity requirements:
1. Support for short-lived or long-lived ACs is required. Typical
validity periods might be measured in hours, as opposed to
months for X.509 public key certificates. Short validity
periods mean that ACs can be useful without a revocation
mechanism.
Attribute Types:
2. Issuers of ACs should be able to define their own attribute
types for use within closed domains.
3. Some standard attribute types should be defined which can be
contained within ACs, for example "access identity", "group",
"role", "clearance", "audit identity", "charging id" etc.
4. Standard attribute types should be defined so that it is
possible for an AC verifier to distinguish between e.g. the
"Administrators group" as defined by Baltimore and the
"Administrators group" as defined by SPYRUS.
Targeting of ACs:
5. It should be possible to "target" an AC. This means that a
given AC may be "targeted" at one, or a small number of,
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servers in the sense that a trustworthy non- target will reject
the AC for authorization decisions.
Push vs. Pull
6. ACs should be defined so that they can either be "pushed" by
the client to the server, or "pulled" by the server from a
repository or other network service (which may be an online AC
issuer).
4. The AC Profile
This section presents a profile for attribute certificates that will
foster interoperability. This section is based upon the X.509
attribute certificate format defined in [X.509]. The ISO/IEC/ITU
documents use the 1993 version of ASN.1; while this document uses
the 1988 ASN.1 syntax, the encoded certificate and standard
extensions are equivalent. This section also defines private
extensions for the Internet community.
Attribute certificates may be used in a wide range of applications
and environments covering a broad spectrum of interoperability goals
and a broader spectrum of operational and assurance requirements.
The goal of this document is to establish a common baseline for
generic applications requiring broad interoperability and limited
special purpose requirements. In particular, the emphasis will be
on supporting the use of attribute certificates for informal
Internet electronic mail, IPSec, and WWW applications.
Conforming implementations MUST support the profile specified in
this section.
4.1 X.509 Attribute Certificate Definition
X.509 contains the definition of an Attribute Certificate given
below. Types that are not defined can be found in [RFC2459].
AttributeCertificate ::= SEQUENCE {
acinfo AttributeCertificateInfo
signatureAlgorithm AlgorithmIdentifier,
signatureValue BIT STRING
}
AttributeCertificateInfo ::= SEQUENCE {
version AttCertVersion DEFAULT v1,
owner Owner,
issuer AttCertIssuer,
signature AlgorithmIdentifier,
serialNumber CertificateSerialNumber,
attrCertValidityPeriod AttCertValidityPeriod
attributes SEQUENCE OF Attribute,
issuerUniqueID UniqueIdentifier OPTIONAL,
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extensions Extensions OPTIONAL
}
AttCertVersion ::= INTEGER {v1(0), v2(1) }
Owner ::= SEQUENCE {
baseCertificateID [0] IssuerSerial OPTIONAL,
-- the issuer and serial number of
-- the owner's Public Key Certificate
entityName [1] GeneralNames OPTIONAL,
-- the name of the claimant or role
objectDigestInfo [2] ObjectDigestInfo OPTIONAL
-- if present, version must be v2
}
ObjectDigestInfo ::= SEQUENCE {
digestAlgorithm AlgorithmIdentifier,
objectDigest OCTET STRING
}
AttCertIssuer ::= SEQUENCE {
issuerName GeneralNames OPTIONAL,
baseCertificateId [0] IssuerSerial OPTIONAL
}
IssuerSerial ::= SEQUENCE {
issuer GeneralNames,
serial CertificateSerialNumber,
issuerUID UniqueIdentifier OPTIONAL
}
AttCertValidityPeriod ::= SEQUENCE {
notBeforeTime GeneralizedTime,
notAfterTime GeneralizedTime
}
4.2 Object Identifiers
This section lists the new object identifiers which are defined in
this specification. Some of these are required only for support of
optional features and are not required for conformance to this
profile.
The following OIDs are imported from [RFC2459]:
id-pkix OBJECT IDENTIFIER ::= { iso(1) identified-organization(3)
dod(6) internet(1) security(5) mechanisms(5) pkix(7) }
id-mod OBJECT IDENTIFIER ::= { id-pkix 0 }
id-pe OBJECT IDENTIFIER ::= { id-pkix 1 }
id-ad OBJECT IDENTIFIER ::= { id-pkix 48 }
The following new ASN.1 module OID is defined:
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id-mod-attribute-cert OBJECT IDENTIFIER ::= { id-mod 12 }
The following AC extension OIDs are defined:
id-pe-ac-auditIdentity OBJECT IDENTIFIER ::= { id-pe 4 }
id-pe-ac-targeting OBJECT IDENTIFIER ::= { id-pe 5 }
id-pe-ac-proxying OBJECT IDENTIFIER ::= { id-pe 7 }
The following registeredID form of name for targets and proxies is
defined (see section 4.4.2 below):
id-pe-ac-targeting-all OBJECT IDENTIIFIER ::=
{ id-pe-ac-targeting 1 }
The following PKC extension OIDs are defined:
id-pe-aaControls OBJECT IDENTIFIER ::= { id-pe 6 }
The following attribute OIDs are defined:
id-aca OBJECT IDENTIFIER ::= { id-pkix 10 }
id-aca-authenticationInfo OBJECT IDENTIFIER ::= { id-aca 1 }
id-aca-accessIdentity OBJECT IDENTIFIER ::= { id-aca 2 }
id-aca-chargingIdentity OBJECT IDENTIFIER ::= { id-aca 3 }
id-aca-group OBJECT IDENTIFIER ::= { id-aca 4 }
id-aca-role OBJECT IDENTIFIER ::= { id-aca 5 }
id-aca-encAttrs OBJECT IDENTIFIER ::= { id-aca 6 }
The following new access methods for an authorityInfoAccess
extension are defined:
id-ad-noRevStat OBJECT IDENTIFIER ::= { id-ad 3 }
id-ad-acRevStatusLocation OBJECT IDENTIFIER ::= { id-ad 4 }
4.3 Profile of Standard Fields
For all GeneralName fields in this profile the otherName,
x400Address, ediPartyName and registeredID options MUST NOT be used
unless otherwise specified (e.g. as in the description of targeting
extension).
This means that conforming implementations MUST be able to support
the dNSName, directoryName, uniformResourceIdentifier and iPAddress
fields in all cases where GeneralName is used. The MUST support
requirements for each of these fields are as specified in [RFC2459],
(mainly in section 4.2.1.7).
4.3.1 version
This must be the default value of v1, i.e. not present in encoding,
except where the owner is identified using the optional
objectDigestInfo field, as specified in section 7.3.
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4.3.2 owner
For any protocol where the AC is passed in an authenticated message
or session, and where the authentication is based on the use of an
X.509 public key certificate (PKC), the owner field SHOULD use the
baseCertificateID.
With the baseCertificateID option, the owner's PKC serialNumber and
issuer MUST be identical to the AC owner field. The PKC issuer MUST
have a non-NULL X.500 name which is to be present as the single
value of the owner.baseCertificateID.issuer construct in the
directoryName field. The owner.baseCertificateID.issuerUID field
MUST only be used if the owner's PKC contains an issuerUniqueID
field.
The above means that the baseCertificateID is only usable with PKC
profiles (like RFC2459) which mandate that the PKC issuer field
contain a value.
If the owner field uses the entityName option and the underlying
authentication is based on a PKC, then the entityName MUST be the
same as the PKC subject field, or, if the PKC subject is a "NULL"
DN, then the entityName field MUST be identical to one of the values
of the PKC subjectAltName field extension. Note that [RFC2459]
mandates that the subjectAltNames extension be present if the PKC
subject is a "NULL" DN.
In any other case where the owner field uses the entityName option
then only one name SHOULD be present.
Implementations conforming to this profile are not required to
support the use of the objectDigest field. However, section 7.3
specifies how this optional feature MAY be used.
Any protocol conforming to this profile SHOULD specify which AC
owner option is to be used and how this fits with e.g. peer-entity
authentication in the protocol.
4.3.3 issuer
ACs conforming to this profile MUST use the issuerName choice, which
MUST contain one and only one GeneralName, which MUST contain its
non-null value in the directoryName field. This means that all AC
issuers MUST have non-NULL X.500 names.
Part of the reason for the use of the issuerName field is that it
allows the AC verifier to be independent of the AC issuer's public
key infrastructure. Using the baseCertificateId field to reference
the AC issuer would mean that the AC verifier would have such a
dependency.
4.3.4 signature
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Contains the algorithm identifier used to validate the AC signature.
This MUST be one of the following algorithms defined in [RFC2459]
section 7.2: md5WithRSAEncryption, id-dsa-with-sha1 or sha-
1WithRSAEncryption, or ecdsa-with-SHA1 defined in [ECDSA] section
3.2.
id-dsa-with-sha1 MUST be supported by all AC users. The other
algorithms SHOULD be supported.
4.3.5 serialNumber
For any conforming AC, the issuer/serialNumber pair MUST form a
unique combination, even if ACs are very short-lived (one second is
the shortest possible validity due to the use of GeneralizedTime).
AC issuers MUST force the serialNumber to be a positive integer,
that is, the topmost bit in the DER encoding of the INTEGER value
MUST NOT be a `1'B - this is to be done by adding a leading
(leftmost) `00'H octet if necessary. This removes a potential
ambiguity in mapping between a string of octets and a serialNumber.
Given the uniqueness and timing requirements above serial numbers
can be expected to contain long integers, i.e. AC users MUST be able
to handle more than 32 bit integers here.
There is no requirement that the serial numbers used by any AC
issuer follow any particular ordering, in particular, they need not
be monotonically increasing with time.
4.3.6 attrCertValidityPeriod
The attrCertValidityPeriod (a.k.a. validity) field specifies the
period for which the AC issuer expects that the binding between the
owner and the attributes fields will be valid.
The generalized time type, GeneralizedTime, is a standard ASN.1 type
for variable precision representation of time. Optionally, the
GeneralizedTime field can include a representation of the time
differential between local and Greenwich Mean Time.
For the purposes of this profile, GeneralizedTime values MUST be
expressed Greenwich Mean Time (Zulu) and MUST include seconds (i.e.,
times are YYYYMMDDHHMMSSZ), even where the number of seconds is
zero. GeneralizedTime values MUST NOT include fractional seconds.
(Note that the above is as specified in [RFC2459], section
4.1.2.5.2.)
Note that AC users MUST be able to handle the case where an AC is
issued, which (at the time of parsing), has its entire validity
period in the future (a "post-dated" AC). This is valid for some
applications, e.g. backup.
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4.3.7 attributes
The attributes field gives information about the AC owner. When the
AC is used for authorization this will often contain a set of
privileges.
The attributes field contains a SEQUENCE OF Attribute. For a given
AC each attribute type in the sequence MUST be unique, that is, only
one instance of each attribute type can occur in a single AC. Each
instance can however, be multi-valued.
AC users MUST be able to handle multiple values for all attribute
types.
Note that a conforming AC MAY contain an empty SEQUENCE, that is, no
attributes at all. <<Note: This is no longer required since we've
dropped support for restrictions, so it will disappear in the next
revision unless there's an explicit consensus for keeping it.>>
Some standard attribute types are defined in section 4.5.
4.3.8 issuerUniqueID
This field MUST NOT be used.
4.3.9 extensions
The extensions field generally gives information about the AC as
opposed to information about the AC owner.
Section 4.4 defines the extensions that MAY be used with this
profile. An AC that has no extensions conforms to the profile. If
any other critical extension is used, then the AC does not conform
to this profile. An AC that contains additional non-critical
extensions still conforms.
4.4 Extensions.
4.4.1 Audit Identity
In some circumstances it is required (e.g. by data protection/data
privacy legislation) that audit trails do not contain records which
directly identify individuals. This may make the use of the owner
field of the AC unsuitable for use in audit trails.
In order to allow for such cases an AC MAY contain an audit identity
extension. Ideally it SHOULD be infeasible to derive the AC owner's
identity from the audit identity value except with the co-operation
of the AC issuer.
The value of the audit identity plus the AC issuer/serial should
then be used for audit/logging purposes. If the value of the audit
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identity is suitably chosen then a server/service administrator can
track the behavior of an AC owner without being able to identify the
AC owner.
The server/service administrator in combination with the AC issuer
MUST be able to identify the AC owner in cases where misbehavior is
detected. This means that the AC issuer MUST be able to map
"backwards" from the audit identity to the actual identity of the AC
owner.
Of course, auditing could be based on the AC issuer/serial pair,
however, this method doesn't allow tracking the same AC owner across
different ACs. This means that an audit identity is only useful if
it lasts for longer than the typical AC lifetime - how much longer
is an issue for the AC issuer implementation. Auditing could also be
based on the AC owner's PKC issuer/serial however, this will often
allow the server/service administrator identify the AC owner.
As the AC verifier might otherwise use the AC subject or some other
identifying value for audit purposes, this extension MUST be
critical when used.
Protocols that use ACs will often expose the identity of the AC
owner in the bits on-the-wire. In such cases, an "opaque" audit
identity does not make use of the AC anonymous, it simply ensures
that the ensuing audit trails are "semi-anonymous".
name id-pe-ac-auditIdentity
OID { id-pe 4 }
syntax OCTET STRING
criticality must be TRUE
4.4.2 AC Targeting
In order to allow that an AC is "targeted", the target information
extension MAY be used to specify a number of servers/services. The
intent is that the AC should only be usable at the specified
servers/services - an (honest) AC verifier who is not amongst the
named servers/services MUST reject the AC.
If this extension is not present then the AC is not targeted and may
be accepted by any server.
The targeting information simply consists of a list of named targets
or groups.
The following syntax is used to represent the targeting information:
Targets ::= SEQUENCE OF Target
Target ::= CHOICE {
targetName [0] GeneralName,
targetGroup [1] GeneralName
}
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We represent a special target, called "ALL" which is a wildcard as a
targetName with the registeredID choice and a value of {id-pe-ac-
targeting 1}. This is an exception to the general rule stated above
about the use of GeneralName choices.
The targets check passes if:
the targets field contains one targetName which
is the "ALL" value,
or,
the current server (recipient) is one of the
targetName fields in the targets part,
or,
the current server is a member of one of the
targetGroup fields in the targets part.
How the membership of a target within a targetGroup is determined is
not defined here. It is assumed that any given target "knows" the
names of the targetGroup's to which it belongs or can otherwise
determine its membership. For example, if the targetGroup were to be
a DNS domain and the AC verifier knows the DNS domain to which it
belongs or it the targetGroup were "PRINTERS" and the AC verifier
"knows" that it's a printer or print server.
name id-pe-ac-targeting
OID { id-pe 5 }
syntax Targets
criticality must be TRUE
4.4.3 authorityKeyIdentifier
The authorityKeyIdentifier extension as profiled in [RFC2459] MAY be
used to assist the AC verifier in checking the signature of the AC.
The [RFC2459] description should be read as if "CA" meant "AC
issuer". As with PKCs this extension SHOULD be included in ACs.
name id-ce-authorityKeyIdentifier
OID { id-ce 35 }
syntax AuthorityKeyIdentifier
criticality MUST be FALSE
4.4.4 authorityInformationAccess
The authorityInformationAccess extension as profiled in [RFC2459]
MAY be used to assist the AC verifier in checking the revocation
status of the AC. See section 6 on revocation below for details.
The following accessMethod is used to indicate that revocation
status checking is not provided for this AC:
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id-ad-noRevStat OBJECT IDENTIFIER ::=
{ id-ad 3 }
The following accessMethod is used to indicate that revocation
status checking is provided for this AC, using the OCSP protocol
defined in [RFC2560]:
id-ad-ocsp OBJECT IDENTIFIER ::=
{ id-ad 1 }
The following accessMethod is used to indicate that revocation
status checking is provided "below" this PKC or AC:
id-ad-acRevStatusLocation OBJECT IDENTIFIER ::=
{ id-ad 4 }
The accessLocation field MUST contain a NULL directoryName.
name id-ce-authorityInfoAccess
OID { id-pe 1 }
syntax AuthorityInfoAccessSyntax
criticality MUST be TRUE
4.4.5 crlDistributionPoints
The crlDistributionPoints extension as profiled in [RFC2459] MAY be
used to assist the AC verifier in checking the revocation status of
the AC. See section 6 on revocation below for details.
name id-ce-cRLDistributionPoints
OID { id-ce 31 }
syntax CRLDistPointsSyntax
criticality SHOULD be FALSE
4.5 Attribute Types
Some of the attribute types defined below make use of the
IetfAttrSyntax type defined below. The reasons for using this type
are:
1. It allows a separation between the AC issuer and the attribute
policy authority. This is useful for situations where a single
policy authority (e.g. an organization) allocates attribute
values, but where multiple AC issuers are deployed for
performance, network or other reasons.
2. The syntaxes allowed for values are restricted to OCTET STRING
and OID, which reduces some of the matching complexities
associated with GeneralName. All multi-valued attributes using
this syntax are restricted so that each value MUST use the same
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choice of value syntax, that is, it is not allowed that one
value use an OID but that a second value uses a string.
IetfAttrSyntax ::= SEQUENCE OF SEQUENCE {
policyAuthority[0] GeneralNames OPTIONAL,
values SEQUENCE OF CHOICE {
octets OCTET STRING,
oid OBJECT IDENTIFIER,
string UTF8String
}
}
4.5.1 Service Authentication Info
This attribute type identifies the AC owner to the server/service by
a name and with optional authentication information. Typically this
will contain a username/password pair for a "legacy" application
(and hence MAY need to be encrypted).
This attribute type will typically be encrypted if the authInfo
field contains sensitive information (e.g. a password).
name id-aca-authenticationInfo
OID { id-aca 1 }
Syntax SvceAuthInfo
values: Multiple allowed
SvceAuthInfo ::= SEQUENCE {
service GeneralName,
ident GeneralName,
authInfo OCTET STRING OPTIONAL
}
4.5.2 Access Identity
An access identity identifies the AC owner to the server/service.
For this attribute the authInfo field MUST NOT be present.
name id-aca-accessIdentity
OID { id-aca 2 }
syntax SvceAuthInfo
values: Multiple allowed
4.5.3 Charging Identity
This attribute type identifies the AC owner for charging purposes.
Note that, in general, the charging identity will be different from
other identities of the owner, for example, when the ownerĘs company
is to be charged for service.
name id-aca-chargingIdentity
OID { id-aca 3 }
syntax IetfAttrSyntax
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values: Multiple allowed
4.5.4 Group
This attribute carries information about group memberships of the AC
owner.
<<Might it be more useful to define OS-specific group attribute
types which map to UNIX gids and/or NT SIDs? Even with that,
application defined groups will be needed - should they use a
standard group attribute or should appX-group attribute types be
defined for each?>>
name id-aca-group
OID { id-aca 4 }
syntax IetfAttrSyntax
values: Multiple allowed
4.5.5 Role
This attribute carries information about role allocations of the AC
owner.
name id-aca-role
OID { id-aca 5 }
syntax IetfAttrSyntax
values: Multiple allowed
4.5.6 Clearance
This attribute (imported from [X.501]) carries clearance (security
labeling) information about the AC owner.
name { id-at-clearance }
OID { joint-iso-ccitt(2) ds(5) module(1) selected-
attribute-types(5) clearance (55) }
syntax Clearance - imported from [X.501]
values Multiple allowed
Clearance ::= SEQUENCE {
policyId OBJECT IDENTIFIER,
classList ClassList DEFAULT {unclassified},
securityCategories
SET OF SecurityCategory OPTIONAL
}
ClassList ::= BIT STRING {
unmarked (0),
unclassified (1),
restricted (2)
confidential (3),
secret (4),
topSecret (5)
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}
SecurityCategory ::= SEQUENCE {
type [0] IMPLICIT OBJECT IDENTIFIER,
value [1] ANY DEFINED BY type
}
-- original syntax with MACRO
-- <<is the above equivalent??>>
-- SecurityCategory ::= SEQUENCE {
-- type [0] IMPLICIT SECURITY-CATEGORY,
-- value [1] ANY DEFINED BY type
-- }
--
-- SECURITY-CATEGORY MACRO ::=
-- BEGIN
-- TYPE NOTATION ::= type | empty
-- VALUE NOTATION ::= value (VALUE OBJECT IDENTIFIER)
-- END
4.6 PKC Extensions
Public key certificate extensions which assist in AC handling are
defined in this section. At the moment only one new extension is
defined.
4.6.1 AAControls
During AC validation a relying party has to answer the question "is
this AC issuer trusted to issue ACs containing this attribute"? The
AAControls PKC extension, intended to be used in CA and AC Issuer
PKCs, MAY be used to help answer the question. The use of AAControls
is further described in section 5.
id-pe-aaControls OBJECT IDENTIFIER ::= { id-pe 6 }
aaControls EXTENSION ::= {
SYNTAX AAControls
IDENTIFIED BY { id-pe-aaControls}
}
AAControls ::= SEQUENCE {
pathLenConstraint INTEGER (0..MAX) OPTIONAL,
permittedAttrs [0] AttrSpec OPTIONAL,
excludedAttrs [1] AttrSpec OPTIONAL,
permitUnSpecified BOOLEAN DEFAULT TRUE
}
AttrSpec::= SEQUENCE OF OBJECT IDENTIFIER
The aaControls extension is used as follows:
The pathLenConstraint if present is interpreted as in [RFC2459], but
now restricts the allowed "distance" between the AA CA, (a CA
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directly trusted to include AAControls in its PKCs), and the AC
issuer.
The permittedAttrs field specifies a set of attribute types that any
AC issuer below this AA CA is allowed to include in ACs. If this
field is not present, it means that no attribute types are
explicitly allowed (though the permitUnSpecified field may open
things up).
The excludedAttrs field specifies a set of attribute types that no
AC issuer is allowed to include in ACs. If this field is not
present, it means that no attribute types are explicitly disallowed
(though the permitUnSpecified field may close things down).
The permitUnSpecified field specifies how to handle attribute types
which are not present in either the permittedAttrs or excludedAttrs
fields. TRUE (the default) means that any unspecified attribute type
is allowed in ACs; FALSE means that no unspecified attribute type is
allowed.
4.7 Profile of AC Issuer's PKC
The AC Issuer's PKC MUST conform to [RFC2459] and MUST NOT
explicitly indicate that the AC issuer can't sign. In order to avoid
confusion (e.g. over serial numbers or revocations) an AC issuer
MUST NOT also be a PKC Issuer (i.e. it can't be a CA as well), so
the AC Issuer's PKC MUST NOT have a basicConstraints extension with
isACA set to TRUE.
If the AC issuer supports revocation of ACs then the AC issuer's PKC
SHOULD contain an authorityInfoAccess extension with a new
accessMethod which assists the AC verifier in checking the status of
an AC.
The new accessMethod is:
id-ad-acRevStatusLocation OBJECT IDENTIFIER ::= { id-ad 4}
The accessLocation field MUST contain a single GeneralName
containing either an X.500 Name or a URL. If accessLocation contains
an X.500 Name, then this is the name of a directory entry where a
revocation list for ACs issued by this AC issuer should be present
as a value of the atributeCertificateRevocationList attribute. If
accessLocation contains a URI, then this specifies the transport
used for OCSP [RFC2560] requests. The AC issuer MUST, of course,
maintain an OCSP responder at this location.
Note that in contrast to the use of authorityInfoAccess described in
section 4.4.4, in this case the extension is not present in the AC,
but rather in the AC issuer's PKC.
5. Attribute Certificate Validation
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This section describes a basic set of rules that all "valid" ACs
MUST satisfy. Some additional checks are also described which AC
verifiers MAY choose to implement.
To be valid an AC MUST satisfy all of the following:
1. The AC signature must be cryptographically correct and the AC
issuer's PKC MUST be verified in accordance with [RFC2459].
2. The AC issuer's PKC MUST also conform to the profile specified
in section 4.7 above.
3. If the AC issuer is not directly trusted as an AC issuer (by
configuration or otherwise), then the AC issuer's certification
path must satisfy the additional PKC checks described below
4. The time for which the AC is being evaluated MUST be within the
AC validity (if the evaluation time is equal to either
notBeforeTime or notAfterTime then the AC is timely, i.e. this
check succeeds). Note that in some applications, the evaluation
time MAY not be the same as the current time.
5. The AC targeting check MUST pass (see section 4.4.3 above)
6. If the AC contains any "unsupported" critical extensions then
the AC MUST be rejected.
"Support" for an extension in this context means:
a. the AC verifier MUST be able to parse the extension value, and,
b. where the extension value SHOULD cause the AC to be rejected, the
AC verifier MUST reject the AC.
The following additional certification path checks (referred to in
(2) above) MUST all succeed:
1. Some CA on the AC's certificate path MUST be directly trusted
to issue PKCs which precede the AC issuer in the certification
path, call this CA the "AA CA".
2. All PKC's on the path from the AA CA down to and including the
AC issuer's PKC MUST contain an aaControls extension as defined
below (the PKC with the AA CA's as subject need not contain
this extension).
3. Only those attributes in the AC which are allowed according to
all of the aaControls extension values in all of the PKCs from
the AA CA to the AC issuer, may be used for authorization
decisions, all other attributes MUST be ignored (note that this
check MUST be applied to the set of attributes following
attribute decryption and that in such cases the id-aca-encAttrs
type MUST also be checked).
Additional Checks:
1. The AC MAY be rejected on the basis of further AC verifier
configuration, for example an AC verifier may be configured to
reject ACs which contain or lack certain attribute types.
2. If the AC verifier provides an interface that allows
applications to query the contents of the AC, then the AC
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verifier MAY filter the attributes from the AC on the basis of
configured information, e.g. an AC verifier might be configured
not to return certain attributes to certain targets.
6. Revocation
<<Input is solicited on the suitability of the 3-scheme approach.>>
In many environments, the validity period of an AC is less than the
time required to issue and distribute revocation information.
Therefore, short-lived ACs typically do not require revocation
support. However, long-lived ACs and environments where ACs enable
high value transactions MAY require revocation support.
The basic approach taken is to allow use of the following AC
revocation related schemes.
"Never revoke" scheme: ACs may be marked so that the relying party
understands that no revocation status information will be made
available.
"Pointer from above" scheme: The PKC (or AC see section 7.4) of an
AC issuer may "point" to sources of revocation status information
for all ACs issued by that AC issuer, (with the exception of those
marked using the never-revoke method above).
"Pointer in AC" scheme: ACs may be marked (like PKCs) to "point" to
sources of revocation status information (using an
authorityInfoAccess or crlDistributionPoints extension in the AC
itself).
The never revoke scheme requires a new authorityInfoAccess
accessMethod. The pointer from above scheme also requires a new
authorityInfoAccess accessMethod. The pointer in AC scheme is as
specified in [RFC2459] and [RFC2560].
The never revoke scheme MUST be supported, the other schemes SHOULD
be supported.
6.1.1 "Never revoke" method
Where an AC issuer does not support revocation status checks for a
particular AC, then an authority information access extension (id-
pe-authorityInfoAccess) with an id-ad-noRevStat accessMethod as
specified in section 4.4.4 above MUST be present and critical in the
AC to indicate this.
Where no authority information access is present with this
accessMethod, then the AC issuer is implicitly stating that
revocation status checks are supported and one of the other methods
below MUST be provided to allow AC verifiers to establish the
revocation status of the AC.
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6.1.2 "Pointer from above" method
In this case the AC issuer's PKC contains an authority information
access extension with an id-ad-acRevStatusLocation accessMethod as
described in section 4.7 above.
6.1.3 "Pointer in AC" method
AC revocation status MAY be checked using the methods described in
[RFC2459], but substituting the AC issuer wherever a CA is
mentioned.
In these cases, the AC contains either an authorityInfoAccess or
crlDistributionPoints extensions as defined in [RFC2459] and
[RFC2560] respectively.
7. Optional Features
This section specifies features that MAY be implemented. Conformance
to this specification does NOT require support for these features.
7.1 Attribute Encryption
Where an AC will be carried in clear within an application protocol
or where an AC contains some sensitive information (e.g. a legacy
application username/password) then encryption of AC attributes MAY
be needed.
When a set of attributes are to be encrypted within an AC, the
cryptographic message syntax, EnvelopedData structure [CMS] is used
to carry the ciphertext(s) and associated per-recipient keying
information.
This type of attribute encryption is targeted, which means that
before the AC is signed the attributes have been encrypted for a set
of predetermined recipients.
The AC then contains the ciphertext(s) inside its signed data. The
"enveloped-data" (id-envelopedData) ContentType is used and the
content field will contain the EnvelopedData type.
The set of ciphertexts is included into the AC as the value of an
encrypted attributes attribute. Only one encrypted attributes
attribute can be present in an AC - however it MAY be multi-valued
and each of its values will contain an EnvelopedData.
Each value can contain a set of attributes (each possibly a multi-
valued attribute) encrypted for a set of recipients.
The cleartext that is encrypted has the type:
ACClearAttrs ::= SEQUENCE {
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acIssuer GeneralName,
acSerial INTEGER,
attrs SEQUENCE OF Attribute
}
The DER encoding of the ACClearAttrs structure is used as the
encryptedContent field of the EnvelopedData, i.e. the DER encoding
MUST be embedded in an OCTET STRING.
The acIssuer and acSerial fields are present to prevent ciphertext
stealing - when an AC verifier has successfully decrypted an
encrypted attribute it MUST then check that the AC issuer and
serialNumber fields contain the same values. This prevents a
malicious AC issuer from copying ciphertext from another AC issuer's
AC into an AC issued by the malicious AC issuer.
The procedure for an AC issuer when encrypting attributes is
illustrated by the following (any other procedure that gives the
same result MAY be used):
1. Identify the sets of attributes that are to be encrypted for
each set of recipients.
2. For each attribute set which is to be encrypted:
2.1. Create an EnvelopedData structure for the data for this
set of recipients.
2.2. Encode the EnvelopedData as a value of the
EncryptedAttributes attribute
2.3. Ensure the cleartext attribute(s) are not present in the
to-be-signed AC
3. Add the EncryptedAttribute (with its multiple values) to the
AC
Note that the rule that each attribute type (the OID) only occurs
once may not hold after decryption. That is, an AC MAY contain the
same attribute type both in clear and in encrypted form (and indeed
more than once if the decryptor is a recipient for more than one
EnvelopedData). One approach implementers may choose, would be to
merge attributes values following decryption in order to re-
establish the "once only" constraint.
name id-aca-encAttrs
OID { id-aca 6}
Syntax ContentInfo
values Multiple Allowed
If an AC contains attributes apparently encrypted for the AC
verifier then the decryption process MUST not fail - if decryption
fails then the AC MUST be rejected.
7.2 Proxying
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In some circumstances, a server needs to proxy an AC when it acts as
a client (for another server) on behalf of the AC owner. Such
proxying needs to be under the AC issuer's control, so that not
every AC is proxiable and so that a given proxiable AC can be
proxied in a targeted fashion. Support for chains of proxies (with
more than one intermediate server) is also sometimes required.
In order to meet this requirement we define another extension:
ProxyInfo, similar to the targeting extension.
When this extension is present the AC verifier must check that the
entity from which the AC was received was allowed to send it and
that the AC is allowed to be used by this verifier.
The proxying information consists of a set of proxy information,
each of which is a set of targeting information. If the verifier and
the sender of the AC are both named in the same proxy set then the
AC can be accepted (the exact rule is given below).
The effect is that the AC owner can send the AC to any valid target
which can then only proxy to targets which are in one of the same
"proxy sets" as itself.
The following data structure is used to represent the
targeting/proxying information.
ProxyInfo ::= SEQUENCE OF Targets
A proxy check succeeds if
(
the identity of the sender as established by
the underlying authentication service matches
the owner field of the AC
and
(
the current server "matches" any one of
the proxy sets (where "matches" is as for
the direct check above)
)
)
or
(
the identity of the sender as established by
the underlying authentication service "matches"
one of the proxy sets (call it set "A")
and
(
the current server is one of the targetName
fields in the set "A"
or
the current server is a member of one of the
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targetGroup fields in set "A".
)
)
Where an AC is proxied more than once a number of targets will be on
the path from the original client, which is normally, but not
always, the AC owner. In such cases prevention of AC "stealing"
requires that the AC verifier MUST check that all targets on the
path are members of the same proxy set. It is the responsibility of
the AC using protocol to ensure that a trustworthy list of targets
on the path is available to the AC verifier.
name id-pe-ac-proxying
OID { id-pe 7 }
syntax ProxyInfo
criticality must be TRUE
7.3 Use of ObjectDigestInfo
<<In order to keep it simple, I've only allowed for a hash over a
key, a hash over a certificate is thus not supported. If this or any
other form of hash were allowed, then we'll need a
digestedObjectInfo extension as well.>>
In some environments it may be required that the AC is not linked
either to an identity (via entityName) or to a PKC (via
baseCertificateID). The objectDigestInfo choice in the owner field
allows support for this requirement.
If the owner is identified via the objectDigestInfo field then the
AC version field MUST contain v2 (i.e. the integer 1).
The basic idea is to link the AC to an object by placing a hash of
that object into the owner field of the AC. For example, this allows
production of ACs that are linked to public keys rather than names
or certificates, or production of ACs which contain privileges
associated with an executable object (e.g. a Java class).
In order to link an AC to a public key the hash must be calculated
over the representation of that public key which would be present in
a PKC, specifically, the input for the hash algorithm MUST be the
DER encoding of a SubjectPublicKeyInfo representation of the key.
Note: This includes the AlgorithmIdentifier as well as the BIT
STRING. The rules given in [RFC2459] and [ECDSA] for encoding keys
MUST be followed.
Note that if the public key value used as input to the hash function
has been extracted from a PKC, then it is possible that the
SubjectPublicKeyInfo from that PKC is NOT the value which should be
hashed. This can occur if, e.g. DSA Dss-parms are inherited as
described in section 7.3.3 of [RFC2459]. The correct input for
hashing in this context will include the value of the parameters
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inherited from the CA's PKC, and thus may differ from the
SubjectPublicKeyInfo present in the PKC.
Implementations which support this feature MUST be able to handle
the representations of keys for the algorithms specified in section
7.3 of [RFC2459] and those specified in [ECDSA].
7.4 AC Chaining
Section 5 above specifies a way of embedding AAControls into PKCs in
order to control the attribute types for which an AA will be trusted
by an AC verifier.
There are two drawbacks to this mechanism:
- PKC issuers have to know about authorization attribute types
- It is likely to require more frequent changes to AA's PKCs
These problems can be avoided by placing the equivalent information
into an AC for which the owner is an AA. However, this mechanism
requires chaining of ACs and thus imposes possibly significant costs
both in terms of implementation and deployment complexity.
In order to use this feature, an AC verifier presented with an AC,
(belonging say to an end entity, call this EE-AC), must retrieve an
AC which is owned by the issuer of EE-AC (call this AA-AC). The AC
verifier next verifies AA-AC, extracts the AAControls information
from AA-AC and uses this to decide which attributes from EE-AC
should be trusted.
Of course, the issuer of AA-AC may or may not be directly trusted by
the AC verifier for the required attributes. In such a case, the AC
verifier may have to retrieve another AC (AA2-AC), etc. until it
finds one issued by a directly trusted AC issuer for each of the
relevant attributes.
AC verifiers which support this feature MUST also support the use of
aaControls placed within PKCs.
When verifying an AC, the verifier needs to determine when a chain
of ACs is needed.
When AAControls are present in an AC, they are placed as an
extension of the AC, using the same extension defined in section
4.6.1 above.
When chaining ACs the following additional verification rules apply
1. EE-AC.issuer and AA-AC.owner MUST contain the same value
2. At the time of evaluation all ACs in the chain MUST be valid
<<probably needs more about the AC chain validation algorithm>>
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8. Security Considerations
Implementers MUST ensure that following validation of an AC, only
attributes that the issuer is trusted to issue are used in
authorization decisions. Other attributes, which MAY be present MUST
be ignored.
There is often a requirement to map between the authentication
supplied by a particular protocol (e.g. TLS, S/MIME) and the AC
owner's identity. If the authentication uses PKCs then this mapping
is straightforward. However, it is envisaged that ACs will also be
used in environments where the owner may be authenticated using
other means. Implementers SHOULD be very careful in mapping the
authenticated identity to the AC owner.
9. References
[CMC] Myers, M., et al. "Certificate Management Messages over
CMS",
draft-ietf-pkix-cmc-03.txt, March 1999.
[CMP] Adams, C., Farrell, S., "Internet X.509 Public Key
Infrastructure - Certificate Management Protocols",
RFC2510.
[CMS] Housley, R., "Cryptographic Message Syntax",
draft-ietf-smime-cms-12.txt, March 1999.
[ESS] Hoffman, P., "Enhanced Security Services for S/MIME",
draft-ietf-smime-ess-12.txt, March 1999.
[ECDSA] D. Johnson, W. Polk, "Internet X.509 Public Key
Infrastructure Representation of Elliptic Curve Digital
Signature Algorithm (ECDSA) Keys and Signatures in
Internet X.509 Public Key Infrastructure Certificates"
draft-ietf-pkix-ipki-ecdsa-01.txt, June 1999.
[RFC2459] Housley, R., Ford, W., Polk, T, & Solo, D., "Internet
Public Key Infrastructure - X.509 Certificate and CRL
profile", RFC2459.
[RFC2560] Myers, M., et al., " X.509 Internet Public Key
Infrastructure - Online Certificate Status Protocol -
OCSP", RFC2560.
[RFC2026] Bradner, S., "The Internet Standards Process -- Revision
3", RFC 2026, BCP 9, October 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", RFC 2119.
[X.501] ITU-T Recommendation X.501 : Information Technology -
Open Systems Interconnection - The Directory: Models,
1993.
[X.509] ITU-T Recommendation X.509 (1997 E): Information
Technology - Open Systems Interconnection - The
Directory: Authentication Framework, June 1997.
[X.208-88] CCITT Recommendation X.208: Specification of Abstract
Syntax Notation One (ASN.1). 1988.
Farrell & Housley [Page 27]
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[X.209-88] CCITT Recommendation X.209: Specification of Basic
Encoding Rules for Abstract Syntax Notation One (ASN.1).
1988.
[X.501-88] CCITT Recommendation X.501: The Directory - Models.
1988.
[X.509-88] CCITT Recommendation X.509: The Directory -
Authentication Framework. 1988.
[X.509-97] ITU-T Recommendation X.509: The Directory -
Authentication Framework. 1997.
[FPDAM] ISO 9594-8 Information Technology ū Open systems
Interconnection - The Directory: Authentication
Framework - Proposed Draft Amendment 1: Certificate
Extensions, April 1999.
Author's Addresses
Stephen Farrell,
Baltimore Technologies
61/62 Fitzwilliam Lane,
Dublin 2,
IRELAND
tel: +353-1-647-3000
email: stephen.farrell@baltimore.ie
Russell Housley,
SPYRUS,
381 Elden Street,
Suite 1120,
Herndon, VA 20170,
USA
email: housley@spyrus.com
Full Copyright Statement
Copyright (C) The Internet Society (date). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it
or assist in its implementation may be prepared, copied, published
and distributed, in whole or in part, without restriction of any
kind, provided that the above copyright notice and this paragraph
are included on all such copies and derivative works. In addition,
the ASN.1 module presented in Appendix B may be used in whole or in
part without inclusion of the copyright notice. However, this
document itself may not be modified in any way, such as by removing
the copyright notice or references to the Internet Society or other
Internet organizations, except as needed for the purpose of
developing Internet standards in which case the procedures for
copyrights defined in the Internet Standards process shall be
followed, or as required to translate it into languages other than
English.
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The limited permissions granted above are perpetual and will not be
revoked by the Internet Society or its successors or assigns. This
document and the information contained herein is provided on an "AS
IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK
FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT
NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN
WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF
MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Appendix A: "Compilable" ASN.1 Module
PKIXAttributeCertificate {iso(1) identified-organization(3) dod(6)
internet(1) security(5) mechanisms(5) pkix(7) id-mod(0)
id-mod-attribute-cert(12)}
DEFINITIONS EXPLICIT TAGS ::=
BEGIN
-- EXPORTS ALL --
IMPORTS
-- PKIX Certificate Extensions
Attribute, AlgorithmIdentifier, CertificateSerialNumber,
Extensions, UniqueIdentifier,
id-pkix, id-pe, id-kp, id-ad
FROM PKIX1Explicit88 {iso(1) identified-organization(3)
dod(6) internet(1) security(5) mechanisms(5)
pkix(7) id-mod(0) id-pkix1-explicit-88(1)}
GeneralName, GeneralNames
FROM PKIX1Implicit88 {iso(1) identified-organization(3)
dod(6) internet(1) security(5) mechanisms(5)
pkix(7) id-mod(0) id-pkix1-implicit-88(2)} ;
id-pe-ac-auditIdentity OBJECT IDENTIFIER ::= { id-pe 4 }
id-pe-ac-targeting OBJECT IDENTIFIER ::= { id-pe 5 }
id-pe-aaControls OBJECT IDENTIFIER ::= { id-pe 6 }
id-pe-ac-proxying OBJECT IDENTIFIER ::= { id-pe 7 }
id-pe-ac-targeting-all OBJECT IDENTIFIER ::=
{ id-pe-ac-targeting 1 }
id-aca OBJECT IDENTIFIER ::= { id-pkix 10 }
id-aca-authenticationInfo OBJECT IDENTIFIER ::= { id-aca 1 }
id-aca-accessIdentity OBJECT IDENTIFIER ::= { id-aca 2 }
id-aca-chargingIdentity OBJECT IDENTIFIER ::= { id-aca 3 }
id-aca-group OBJECT IDENTIFIER ::= { id-aca 4 }
id-aca-role OBJECT IDENTIFIER ::= { id-aca 5 }
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id-aca-encAttrs OBJECT IDENTIFIER ::= { id-aca 6 }
id-ad-noRevStat OBJECT IDENTIFIER ::= { id-ad 3 }
id-ad-acRevStatusLocation OBJECT IDENTIFIER ::= { id-ad 4 }
AttributeCertificate ::= SEQUENCE {
acinfo AttributeCertificateInfo,
signatureAlgorithm AlgorithmIdentifier,
signatureValue BIT STRING
}
AttributeCertificateInfo ::= SEQUENCE {
version AttCertVersion DEFAULT v1,
owner Owner,
issuer AttCertIssuer,
signature AlgorithmIdentifier,
serialNumber CertificateSerialNumber,
attrCertValidityPeriod AttCertValidityPeriod,
attributes SEQUENCE OF Attribute,
issuerUniqueID UniqueIdentifier OPTIONAL,
extensions Extensions OPTIONAL
}
AttCertVersion ::= INTEGER {v1(0), v2(1) }
Owner ::= SEQUENCE {
baseCertificateID [0] IssuerSerial OPTIONAL,
-- the issuer and serial number of
-- the owner's Public Key Certificate
entityName [1] GeneralNames OPTIONAL,
-- the name of the claimant or role
objectDigestInfo [2] ObjectDigestInfo OPTIONAL
-- if present, version must be v2
}
ObjectDigestInfo ::= SEQUENCE {
digestAlgorithm AlgorithmIdentifier,
objectDigest OCTET STRING
}
AttCertIssuer ::= SEQUENCE {
issuerName GeneralNames OPTIONAL,
baseCertificateId [0] IssuerSerial OPTIONAL
}
IssuerSerial ::= SEQUENCE {
issuer GeneralNames,
serial CertificateSerialNumber,
issuerUID UniqueIdentifier OPTIONAL
}
AttCertValidityPeriod ::= SEQUENCE {
notBeforeTime GeneralizedTime,
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INTERNET-DRAFT October 1999
notAfterTime GeneralizedTime
}
Targets ::= SEQUENCE OF Target
Target ::= CHOICE {
targetName [0] GeneralName,
targetGroup [1] GeneralName
}
IetfAttrSyntax ::= SEQUENCE OF SEQUENCE {
policyAuthority[0] GeneralNames OPTIONAL,
values SEQUENCE OF CHOICE {
octets OCTET STRING,
oid OBJECT IDENTIFIER,
string UTF8String
}
}
SvceAuthInfo ::= SEQUENCE {
service GeneralName,
ident GeneralName,
authInfo OCTET STRING OPTIONAL
}
Clearance ::= SEQUENCE {
policyId OBJECT IDENTIFIER,
classList ClassList DEFAULT {unclassified},
securityCategories
SET OF SecurityCategory OPTIONAL
}
ClassList ::= BIT STRING {
unmarked (0),
unclassified (1),
restricted (2),
confidential (3),
secret (4),
topSecret (5)
}
SecurityCategory ::= SEQUENCE {
type [0] IMPLICIT OBJECT IDENTIFIER,
value [1] ANY DEFINED BY type
}
AAControls ::= SEQUENCE {
pathLenConstraint INTEGER (0..MAX) OPTIONAL,
permittedAttrs [0] AttrSpec OPTIONAL,
excludedAttrs [1] AttrSpec OPTIONAL,
permitUnSpecified BOOLEAN DEFAULT TRUE
}
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AttrSpec::= SEQUENCE OF OBJECT IDENTIFIER
ACClearAttrs ::= SEQUENCE {
acIssuer GeneralName,
acSerial INTEGER,
attrs SEQUENCE OF Attribute
}
ProxyInfo ::= SEQUENCE OF Targets
END
Appendix B: Samples
<<TBS>>
Appendix C: Changes this version / Open Issues
This appendix lists major changes since the previous revision and
open issues to be resolved (in order of occurrence in the body of
the document).
Major changes since last revision:
1. Re-structured conformance to profile + options as per Oslo
consensus
2. Moved acquisition protocol (LAAP)_to separate I-D
3. Removed restrictions entirely
4. Added new AC revocation options
5. Added optional support for use of objectDigestInfo for keys
6. Added optional support for chains of ACs
7. Changed some syntax:
Added UTF8String to IetfAttrSyntax value choice
Split target & proxy extensions, removed owner from proxyInfo
8. Allocated PKIX OIDs (note: check with repository before using
these, the PKIX arc is currently available at
http://www.imc.org/ietf-pkix/pkix-oid.asn)
9. Added compiled ASN.1 module
Open issues remaining:
1. Should an AC without any attributes be allowed?
2. Should OS-specific group attribute types be defined?
3. Is the expansion of the SecurityCategory MACRO correct?
4. Are three revocation schemes needed? Correct?
5. Should more types of objectDigestInfo be allowed?
6. AC chain section needs more description of chain validation.
7. Samples - should they be a separate draft?
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