Network Working Group R. Housley
Request for Comments: 3280 RSA Laboratories
Obsoletes: 2459 W. Polk
Category: Standards Track NIST
W. Ford
VeriSign
D. Solo
Citigroup
April 2002
Internet X.509 Public Key Infrastructure
Certificate and Certificate Revocation List (CRL) Profile
Status of this Memo
This document specifies an Internet standards track protocol for the
Internet community, and requests discussion and suggestions for
improvements. Please refer to the current edition of the "Internet
Official Protocol Standards" (STD 1) for the standardization state
and status of this protocol. Distribution of this memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2002). All Rights Reserved.
Abstract
This memo profiles the X.509 v3 certificate and X.509 v2 Certificate
Revocation List (CRL) for use in the Internet. An overview of this
approach and model are provided as an introduction. The X.509 v3
certificate format is described in detail, with additional
information regarding the format and semantics of Internet name
forms. Standard certificate extensions are described and two
Internet-specific extensions are defined. A set of required
certificate extensions is specified. The X.509 v2 CRL format is
described in detail, and required extensions are defined. An
algorithm for X.509 certification path validation is described. An
ASN.1 module and examples are provided in the appendices.
This specification is one part of a family of standards for the X.509
Public Key Infrastructure (PKI) for the Internet.
This specification profiles the format and semantics of certificates
and certificate revocation lists (CRLs) for the Internet PKI.
Procedures are described for processing of certification paths in the
Internet environment. Finally, ASN.1 modules are provided in the
appendices for all data structures defined or referenced.
Section 2 describes Internet PKI requirements, and the assumptions
which affect the scope of this document. Section 3 presents an
architectural model and describes its relationship to previous IETF
and ISO/IEC/ITU-T standards. In particular, this document's
relationship with the IETF PEM specifications and the ISO/IEC/ITU-T
X.509 documents are described.
Section 4 profiles the X.509 version 3 certificate, and section 5
profiles the X.509 version 2 CRL. The profiles include the
identification of ISO/IEC/ITU-T and ANSI extensions which may be
useful in the Internet PKI. The profiles are presented in the 1988
Abstract Syntax Notation One (ASN.1) rather than the 1997 ASN.1
syntax used in the most recent ISO/IEC/ITU-T standards.
Section 6 includes certification path validation procedures. These
procedures are based upon the ISO/IEC/ITU-T definition.
Implementations are REQUIRED to derive the same results but are not
required to use the specified procedures.
Procedures for identification and encoding of public key materials
and digital signatures are defined in [PKIXALGS]. Implementations of
this specification are not required to use any particular
cryptographic algorithms. However, conforming implementations which
use the algorithms identified in [PKIXALGS] MUST identify and encode
the public key materials and digital signatures as described in that
specification.
Finally, three appendices are provided to aid implementers. Appendix
A contains all ASN.1 structures defined or referenced within this
specification. As above, the material is presented in the 1988
ASN.1. Appendix B contains notes on less familiar features of the
ASN.1 notation used within this specification. Appendix C contains
examples of a conforming certificate and a conforming CRL.
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This specification obsoletes RFC 2459. This specification differs
from RFC 2459 in five basic areas:
* To promote interoperable implementations, a detailed algorithm
for certification path validation is included in section 6.1 of
this specification; RFC 2459 provided only a high-level
description of path validation.
* An algorithm for determining the status of a certificate using
CRLs is provided in section 6.3 of this specification. This
material was not present in RFC 2459.
* To accommodate new usage models, detailed information describing
the use of delta CRLs is provided in Section 5 of this
specification.
* Identification and encoding of public key materials and digital
signatures are not included in this specification, but are now
described in a companion specification [PKIXALGS].
* Four additional extensions are specified: three certificate
extensions and one CRL extension. The certificate extensions are
subject info access, inhibit any-policy, and freshest CRL. The
freshest CRL extension is also defined as a CRL extension.
* Throughout the specification, clarifications have been
introduced to enhance consistency with the ITU-T X.509
specification. X.509 defines the certificate and CRL format as
well as many of the extensions that appear in this specification.
These changes were introduced to improve the likelihood of
interoperability between implementations based on this
specification with implementations based on the ITU-T
specification.
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 RFC 2119.
2 Requirements and Assumptions
The goal of this specification is to develop a profile to facilitate
the use of X.509 certificates within Internet applications for those
communities wishing to make use of X.509 technology. Such
applications may include WWW, electronic mail, user authentication,
and IPsec. In order to relieve some of the obstacles to using X.509
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certificates, this document defines a profile to promote the
development of certificate management systems; development of
application tools; and interoperability determined by policy.
Some communities will need to supplement, or possibly replace, this
profile in order to meet the requirements of specialized application
domains or environments with additional authorization, assurance, or
operational requirements. However, for basic applications, common
representations of frequently used attributes are defined so that
application developers can obtain necessary information without
regard to the issuer of a particular certificate or certificate
revocation list (CRL).
A certificate user should review the certificate policy generated by
the certification authority (CA) before relying on the authentication
or non-repudiation services associated with the public key in a
particular certificate. To this end, this standard does not
prescribe legally binding rules or duties.
As supplemental authorization and attribute management tools emerge,
such as attribute certificates, it may be appropriate to limit the
authenticated attributes that are included in a certificate. These
other management tools may provide more appropriate methods of
conveying many authenticated attributes.
2.1 Communication and Topology
The users of certificates will operate in a wide range of
environments with respect to their communication topology, especially
users of secure electronic mail. This profile supports users without
high bandwidth, real-time IP connectivity, or high connection
availability. In addition, the profile allows for the presence of
firewall or other filtered communication.
This profile does not assume the deployment of an X.500 Directory
system or a LDAP directory system. The profile does not prohibit the
use of an X.500 Directory or a LDAP directory; however, any means of
distributing certificates and certificate revocation lists (CRLs) may
be used.
2.2 Acceptability Criteria
The goal of the Internet Public Key Infrastructure (PKI) is to meet
the needs of deterministic, automated identification, authentication,
access control, and authorization functions. Support for these
services determines the attributes contained in the certificate as
well as the ancillary control information in the certificate such as
policy data and certification path constraints.
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2.3 User Expectations
Users of the Internet PKI are people and processes who use client
software and are the subjects named in certificates. These uses
include readers and writers of electronic mail, the clients for WWW
browsers, WWW servers, and the key manager for IPsec within a router.
This profile recognizes the limitations of the platforms these users
employ and the limitations in sophistication and attentiveness of the
users themselves. This manifests itself in minimal user
configuration responsibility (e.g., trusted CA keys, rules), explicit
platform usage constraints within the certificate, certification path
constraints which shield the user from many malicious actions, and
applications which sensibly automate validation functions.
2.4 Administrator Expectations
As with user expectations, the Internet PKI profile is structured to
support the individuals who generally operate CAs. Providing
administrators with unbounded choices increases the chances that a
subtle CA administrator mistake will result in broad compromise.
Also, unbounded choices greatly complicate the software that process
and validate the certificates created by the CA.
3 Overview of Approach
Following is a simplified view of the architectural model assumed by
the PKIX specifications.
The components in this model are:
end entity: user of PKI certificates and/or end user system that is
the subject of a certificate;
CA: certification authority;
RA: registration authority, i.e., an optional system to which
a CA delegates certain management functions;
CRL issuer: an optional system to which a CA delegates the
publication of certificate revocation lists;
repository: a system or collection of distributed systems that stores
certificates and CRLs and serves as a means of
distributing these certificates and CRLs to end entities.
Note that an Attribute Authority (AA) might also choose to delegate
the publication of CRLs to a CRL issuer.
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+---+
| C | +------------+
| e | <-------------------->| End entity |
| r | Operational +------------+
| t | transactions ^
| i | and management | Management
| f | transactions | transactions PKI
| i | | users
| c | v
| a | ======================= +--+------------+ ==============
| t | ^ ^
| e | | | PKI
| | v | management
| & | +------+ | entities
| | <---------------------| RA |<----+ |
| C | Publish certificate +------+ | |
| R | | |
| L | | |
| | v v
| R | +------------+
| e | <------------------------------| CA |
| p | Publish certificate +------------+
| o | Publish CRL ^ ^
| s | | | Management
| i | +------------+ | | transactions
| t | <--------------| CRL Issuer |<----+ |
| o | Publish CRL +------------+ v
| r | +------+
| y | | CA |
+---+ +------+
Figure 1 - PKI Entities
3.1 X.509 Version 3 Certificate
Users of a public key require confidence that the associated private
key is owned by the correct remote subject (person or system) with
which an encryption or digital signature mechanism will be used.
This confidence is obtained through the use of public key
certificates, which are data structures that bind public key values
to subjects. The binding is asserted by having a trusted CA
digitally sign each certificate. The CA may base this assertion upon
technical means (a.k.a., proof of possession through a challenge-
response protocol), presentation of the private key, or on an
assertion by the subject. A certificate has a limited valid lifetime
which is indicated in its signed contents. Because a certificate's
signature and timeliness can be independently checked by a
certificate-using client, certificates can be distributed via
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untrusted communications and server systems, and can be cached in
unsecured storage in certificate-using systems.
ITU-T X.509 (formerly CCITT X.509) or ISO/IEC 9594-8, which was first
published in 1988 as part of the X.500 Directory recommendations,
defines a standard certificate format [X.509]. The certificate
format in the 1988 standard is called the version 1 (v1) format.
When X.500 was revised in 1993, two more fields were added, resulting
in the version 2 (v2) format.
The Internet Privacy Enhanced Mail (PEM) RFCs, published in 1993,
include specifications for a public key infrastructure based on X.509
v1 certificates [RFC 1422]. The experience gained in attempts to
deploy RFC 1422 made it clear that the v1 and v2 certificate formats
are deficient in several respects. Most importantly, more fields
were needed to carry information which PEM design and implementation
experience had proven necessary. In response to these new
requirements, ISO/IEC, ITU-T and ANSI X9 developed the X.509 version
3 (v3) certificate format. The v3 format extends the v2 format by
adding provision for additional extension fields. Particular
extension field types may be specified in standards or may be defined
and registered by any organization or community. In June 1996,
standardization of the basic v3 format was completed [X.509].
ISO/IEC, ITU-T, and ANSI X9 have also developed standard extensions
for use in the v3 extensions field [X.509][X9.55]. These extensions
can convey such data as additional subject identification
information, key attribute information, policy information, and
certification path constraints.
However, the ISO/IEC, ITU-T, and ANSI X9 standard extensions are very
broad in their applicability. In order to develop interoperable
implementations of X.509 v3 systems for Internet use, it is necessary
to specify a profile for use of the X.509 v3 extensions tailored for
the Internet. It is one goal of this document to specify a profile
for Internet WWW, electronic mail, and IPsec applications.
Environments with additional requirements may build on this profile
or may replace it.
3.2 Certification Paths and Trust
A user of a security service requiring knowledge of a public key
generally needs to obtain and validate a certificate containing the
required public key. If the public key user does not already hold an
assured copy of the public key of the CA that signed the certificate,
the CA's name, and related information (such as the validity period
or name constraints), then it might need an additional certificate to
obtain that public key. In general, a chain of multiple certificates
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may be needed, comprising a certificate of the public key owner (the
end entity) signed by one CA, and zero or more additional
certificates of CAs signed by other CAs. Such chains, called
certification paths, are required because a public key user is only
initialized with a limited number of assured CA public keys.
There are different ways in which CAs might be configured in order
for public key users to be able to find certification paths. For
PEM, RFC 1422 defined a rigid hierarchical structure of CAs. There
are three types of PEM certification authority:
(a) Internet Policy Registration Authority (IPRA): This
authority, operated under the auspices of the Internet Society,
acts as the root of the PEM certification hierarchy at level 1.
It issues certificates only for the next level of authorities,
PCAs. All certification paths start with the IPRA.
(b) Policy Certification Authorities (PCAs): PCAs are at level 2
of the hierarchy, each PCA being certified by the IPRA. A PCA
shall establish and publish a statement of its policy with respect
to certifying users or subordinate certification authorities.
Distinct PCAs aim to satisfy different user needs. For example,
one PCA (an organizational PCA) might support the general
electronic mail needs of commercial organizations, and another PCA
(a high-assurance PCA) might have a more stringent policy designed
for satisfying legally binding digital signature requirements.
(c) Certification Authorities (CAs): CAs are at level 3 of the
hierarchy and can also be at lower levels. Those at level 3 are
certified by PCAs. CAs represent, for example, particular
organizations, particular organizational units (e.g., departments,
groups, sections), or particular geographical areas.
RFC 1422 furthermore has a name subordination rule which requires
that a CA can only issue certificates for entities whose names are
subordinate (in the X.500 naming tree) to the name of the CA itself.
The trust associated with a PEM certification path is implied by the
PCA name. The name subordination rule ensures that CAs below the PCA
are sensibly constrained as to the set of subordinate entities they
can certify (e.g., a CA for an organization can only certify entities
in that organization's name tree). Certificate user systems are able
to mechanically check that the name subordination rule has been
followed.
The RFC 1422 uses the X.509 v1 certificate formats. The limitations
of X.509 v1 required imposition of several structural restrictions to
clearly associate policy information or restrict the utility of
certificates. These restrictions included:
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(a) a pure top-down hierarchy, with all certification paths
starting from IPRA;
(b) a naming subordination rule restricting the names of a CA's
subjects; and
(c) use of the PCA concept, which requires knowledge of
individual PCAs to be built into certificate chain verification
logic. Knowledge of individual PCAs was required to determine if
a chain could be accepted.
With X.509 v3, most of the requirements addressed by RFC 1422 can be
addressed using certificate extensions, without a need to restrict
the CA structures used. In particular, the certificate extensions
relating to certificate policies obviate the need for PCAs and the
constraint extensions obviate the need for the name subordination
rule. As a result, this document supports a more flexible
architecture, including:
(a) Certification paths start with a public key of a CA in a
user's own domain, or with the public key of the top of a
hierarchy. Starting with the public key of a CA in a user's own
domain has certain advantages. In some environments, the local
domain is the most trusted.
(b) Name constraints may be imposed through explicit inclusion of
a name constraints extension in a certificate, but are not
required.
(c) Policy extensions and policy mappings replace the PCA
concept, which permits a greater degree of automation. The
application can determine if the certification path is acceptable
based on the contents of the certificates instead of a priori
knowledge of PCAs. This permits automation of certification path
processing.
3.3 Revocation
When a certificate is issued, it is expected to be in use for its
entire validity period. However, various circumstances may cause a
certificate to become invalid prior to the expiration of the validity
period. Such circumstances include change of name, change of
association between subject and CA (e.g., an employee terminates
employment with an organization), and compromise or suspected
compromise of the corresponding private key. Under such
circumstances, the CA needs to revoke the certificate.
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X.509 defines one method of certificate revocation. This method
involves each CA periodically issuing a signed data structure called
a certificate revocation list (CRL). A CRL is a time stamped list
identifying revoked certificates which is signed by a CA or CRL
issuer and made freely available in a public repository. Each
revoked certificate is identified in a CRL by its certificate serial
number. When a certificate-using system uses a certificate (e.g.,
for verifying a remote user's digital signature), that system not
only checks the certificate signature and validity but also acquires
a suitably-recent CRL and checks that the certificate serial number
is not on that CRL. The meaning of "suitably-recent" may vary with
local policy, but it usually means the most recently-issued CRL. A
new CRL is issued on a regular periodic basis (e.g., hourly, daily,
or weekly). An entry is added to the CRL as part of the next update
following notification of revocation. An entry MUST NOT be removed
from the CRL until it appears on one regularly scheduled CRL issued
beyond the revoked certificate's validity period.
An advantage of this revocation method is that CRLs may be
distributed by exactly the same means as certificates themselves,
namely, via untrusted servers and untrusted communications.
One limitation of the CRL revocation method, using untrusted
communications and servers, is that the time granularity of
revocation is limited to the CRL issue period. For example, if a
revocation is reported now, that revocation will not be reliably
notified to certificate-using systems until all currently issued CRLs
are updated -- this may be up to one hour, one day, or one week
depending on the frequency that CRLs are issued.
As with the X.509 v3 certificate format, in order to facilitate
interoperable implementations from multiple vendors, the X.509 v2 CRL
format needs to be profiled for Internet use. It is one goal of this
document to specify that profile. However, this profile does not
require the issuance of CRLs. Message formats and protocols
supporting on-line revocation notification are defined in other PKIX
specifications. On-line methods of revocation notification may be
applicable in some environments as an alternative to the X.509 CRL.
On-line revocation checking may significantly reduce the latency
between a revocation report and the distribution of the information
to relying parties. Once the CA accepts a revocation report as
authentic and valid, any query to the on-line service will correctly
reflect the certificate validation impacts of the revocation.
However, these methods impose new security requirements: the
certificate validator needs to trust the on-line validation service
while the repository does not need to be trusted.
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3.4 Operational Protocols
Operational protocols are required to deliver certificates and CRLs
(or status information) to certificate using client systems.
Provisions are needed for a variety of different means of certificate
and CRL delivery, including distribution procedures based on LDAP,
HTTP, FTP, and X.500. Operational protocols supporting these
functions are defined in other PKIX specifications. These
specifications may include definitions of message formats and
procedures for supporting all of the above operational environments,
including definitions of or references to appropriate MIME content
types.
3.5 Management Protocols
Management protocols are required to support on-line interactions
between PKI user and management entities. For example, a management
protocol might be used between a CA and a client system with which a
key pair is associated, or between two CAs which cross-certify each
other. The set of functions which potentially need to be supported
by management protocols include:
(a) registration: This is the process whereby a user first makes
itself known to a CA (directly, or through an RA), prior to that
CA issuing a certificate or certificates for that user.
(b) initialization: Before a client system can operate securely
it is necessary to install key materials which have the
appropriate relationship with keys stored elsewhere in the
infrastructure. For example, the client needs to be securely
initialized with the public key and other assured information of
the trusted CA(s), to be used in validating certificate paths.
Furthermore, a client typically needs to be initialized with its
own key pair(s).
(c) certification: This is the process in which a CA issues a
certificate for a user's public key, and returns that certificate
to the user's client system and/or posts that certificate in a
repository.
(d) key pair recovery: As an option, user client key materials
(e.g., a user's private key used for encryption purposes) may be
backed up by a CA or a key backup system. If a user needs to
recover these backed up key materials (e.g., as a result of a
forgotten password or a lost key chain file), an on-line protocol
exchange may be needed to support such recovery.
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(e) key pair update: All key pairs need to be updated regularly,
i.e., replaced with a new key pair, and new certificates issued.
(f) revocation request: An authorized person advises a CA of an
abnormal situation requiring certificate revocation.
(g) cross-certification: Two CAs exchange information used in
establishing a cross-certificate. A cross-certificate is a
certificate issued by one CA to another CA which contains a CA
signature key used for issuing certificates.
Note that on-line protocols are not the only way of implementing the
above functions. For all functions there are off-line methods of
achieving the same result, and this specification does not mandate
use of on-line protocols. For example, when hardware tokens are
used, many of the functions may be achieved as part of the physical
token delivery. Furthermore, some of the above functions may be
combined into one protocol exchange. In particular, two or more of
the registration, initialization, and certification functions can be
combined into one protocol exchange.
The PKIX series of specifications defines a set of standard message
formats supporting the above functions. The protocols for conveying
these messages in different environments (e.g., e-mail, file
transfer, and WWW) are described in those specifications.
4 Certificate and Certificate Extensions Profile
This section presents a profile for public key certificates that will
foster interoperability and a reusable PKI. This section is based
upon the X.509 v3 certificate format and the standard certificate
extensions defined in [X.509]. The ISO/IEC and ITU-T documents use
the 1997 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 required to
support a PKI for the Internet community.
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 X.509 v3 certificates for informal Internet
electronic mail, IPsec, and WWW applications.
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4.1 Basic Certificate Fields
The X.509 v3 certificate basic syntax is as follows. For signature
calculation, the data that is to be signed is encoded using the ASN.1
distinguished encoding rules (DER) [X.690]. ASN.1 DER encoding is a
tag, length, value encoding system for each element.
TBSCertificate ::= SEQUENCE {
version [0] EXPLICIT Version DEFAULT v1,
serialNumber CertificateSerialNumber,
signature AlgorithmIdentifier,
issuer Name,
validity Validity,
subject Name,
subjectPublicKeyInfo SubjectPublicKeyInfo,
issuerUniqueID [1] IMPLICIT UniqueIdentifier OPTIONAL,
-- If present, version MUST be v2 or v3
subjectUniqueID [2] IMPLICIT UniqueIdentifier OPTIONAL,
-- If present, version MUST be v2 or v3
extensions [3] EXPLICIT Extensions OPTIONAL
-- If present, version MUST be v3
}
Version ::= INTEGER { v1(0), v2(1), v3(2) }
CertificateSerialNumber ::= INTEGER
Validity ::= SEQUENCE {
notBefore Time,
notAfter Time }
Time ::= CHOICE {
utcTime UTCTime,
generalTime GeneralizedTime }
UniqueIdentifier ::= BIT STRING
SubjectPublicKeyInfo ::= SEQUENCE {
algorithm AlgorithmIdentifier,
subjectPublicKey BIT STRING }
Extensions ::= SEQUENCE SIZE (1..MAX) OF Extension
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The following items describe the X.509 v3 certificate for use in the
Internet.
4.1.1 Certificate Fields
The Certificate is a SEQUENCE of three required fields. The fields
are described in detail in the following subsections.
4.1.1.1 tbsCertificate
The field contains the names of the subject and issuer, a public key
associated with the subject, a validity period, and other associated
information. The fields are described in detail in section 4.1.2;
the tbsCertificate usually includes extensions which are described in
section 4.2.
4.1.1.2 signatureAlgorithm
The signatureAlgorithm field contains the identifier for the
cryptographic algorithm used by the CA to sign this certificate.
[PKIXALGS] lists supported signature algorithms, but other signature
algorithms MAY also be supported.
An algorithm identifier is defined by the following ASN.1 structure:
AlgorithmIdentifier ::= SEQUENCE {
algorithm OBJECT IDENTIFIER,
parameters ANY DEFINED BY algorithm OPTIONAL }
The algorithm identifier is used to identify a cryptographic
algorithm. The OBJECT IDENTIFIER component identifies the algorithm
(such as DSA with SHA-1). The contents of the optional parameters
field will vary according to the algorithm identified.
This field MUST contain the same algorithm identifier as the
signature field in the sequence tbsCertificate (section 4.1.2.3).
4.1.1.3 signatureValue
The signatureValue field contains a digital signature computed upon
the ASN.1 DER encoded tbsCertificate. The ASN.1 DER encoded
tbsCertificate is used as the input to the signature function. This
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signature value is encoded as a BIT STRING and included in the
signature field. The details of this process are specified for each
of algorithms listed in [PKIXALGS].
By generating this signature, a CA certifies the validity of the
information in the tbsCertificate field. In particular, the CA
certifies the binding between the public key material and the subject
of the certificate.
4.1.2 TBSCertificate
The sequence TBSCertificate contains information associated with the
subject of the certificate and the CA who issued it. Every
TBSCertificate contains the names of the subject and issuer, a public
key associated with the subject, a validity period, a version number,
and a serial number; some MAY contain optional unique identifier
fields. The remainder of this section describes the syntax and
semantics of these fields. A TBSCertificate usually includes
extensions. Extensions for the Internet PKI are described in Section
4.2.
4.1.2.1 Version
This field describes the version of the encoded certificate. When
extensions are used, as expected in this profile, version MUST be 3
(value is 2). If no extensions are present, but a UniqueIdentifier
is present, the version SHOULD be 2 (value is 1); however version MAY
be 3. If only basic fields are present, the version SHOULD be 1 (the
value is omitted from the certificate as the default value); however
the version MAY be 2 or 3.
Implementations SHOULD be prepared to accept any version certificate.
At a minimum, conforming implementations MUST recognize version 3
certificates.
Generation of version 2 certificates is not expected by
implementations based on this profile.
4.1.2.2 Serial number
The serial number MUST be a positive integer assigned by the CA to
each certificate. It MUST be unique for each certificate issued by a
given CA (i.e., the issuer name and serial number identify a unique
certificate). CAs MUST force the serialNumber to be a non-negative
integer.
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Given the uniqueness requirements above, serial numbers can be
expected to contain long integers. Certificate users MUST be able to
handle serialNumber values up to 20 octets. Conformant CAs MUST NOT
use serialNumber values longer than 20 octets.
Note: Non-conforming CAs may issue certificates with serial numbers
that are negative, or zero. Certificate users SHOULD be prepared to
gracefully handle such certificates.
4.1.2.3 Signature
This field contains the algorithm identifier for the algorithm used
by the CA to sign the certificate.
This field MUST contain the same algorithm identifier as the
signatureAlgorithm field in the sequence Certificate (section
4.1.1.2). The contents of the optional parameters field will vary
according to the algorithm identified. [PKIXALGS] lists the
supported signature algorithms, but other signature algorithms MAY
also be supported.
4.1.2.4 Issuer
The issuer field identifies the entity who has signed and issued the
certificate. The issuer field MUST contain a non-empty distinguished
name (DN). The issuer field is defined as the X.501 type Name
[X.501]. Name is defined by the following ASN.1 structures:
Name ::= CHOICE {
RDNSequence }
RDNSequence ::= SEQUENCE OF RelativeDistinguishedName
RelativeDistinguishedName ::=
SET OF AttributeTypeAndValue
AttributeTypeAndValue ::= SEQUENCE {
type AttributeType,
value AttributeValue }
AttributeType ::= OBJECT IDENTIFIER
AttributeValue ::= ANY DEFINED BY AttributeType
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The Name describes a hierarchical name composed of attributes, such
as country name, and corresponding values, such as US. The type of
the component AttributeValue is determined by the AttributeType; in
general it will be a DirectoryString.
The DirectoryString type is defined as a choice of PrintableString,
TeletexString, BMPString, UTF8String, and UniversalString. The
UTF8String encoding [RFC 2279] is the preferred encoding, and all
certificates issued after December 31, 2003 MUST use the UTF8String
encoding of DirectoryString (except as noted below). Until that
date, conforming CAs MUST choose from the following options when
creating a distinguished name, including their own:
(a) if the character set is sufficient, the string MAY be
represented as a PrintableString;
(b) failing (a), if the BMPString character set is sufficient the
string MAY be represented as a BMPString; and
(c) failing (a) and (b), the string MUST be represented as a
UTF8String. If (a) or (b) is satisfied, the CA MAY still choose
to represent the string as a UTF8String.
Exceptions to the December 31, 2003 UTF8 encoding requirements are as
follows:
(a) CAs MAY issue "name rollover" certificates to support an
orderly migration to UTF8String encoding. Such certificates would
include the CA's UTF8String encoded name as issuer and and the old
name encoding as subject, or vice-versa.
(b) As stated in section 4.1.2.6, the subject field MUST be
populated with a non-empty distinguished name matching the
contents of the issuer field in all certificates issued by the
subject CA regardless of encoding.
The TeletexString and UniversalString are included for backward
compatibility, and SHOULD NOT be used for certificates for new
subjects. However, these types MAY be used in certificates where the
name was previously established. Certificate users SHOULD be
prepared to receive certificates with these types.
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In addition, many legacy implementations support names encoded in the
ISO 8859-1 character set (Latin1String) [ISO 8859-1] but tag them as
TeletexString. TeletexString encodes a larger character set than ISO
8859-1, but it encodes some characters differently. Implementations
SHOULD be prepared to handle both encodings.
As noted above, distinguished names are composed of attributes. This
specification does not restrict the set of attribute types that may
appear in names. However, conforming implementations MUST be
prepared to receive certificates with issuer names containing the set
of attribute types defined below. This specification RECOMMENDS
support for additional attribute types.
Standard sets of attributes have been defined in the X.500 series of
specifications [X.520]. Implementations of this specification MUST
be prepared to receive the following standard attribute types in
issuer and subject (section 4.1.2.6) names:
* country,
* organization,
* organizational-unit,
* distinguished name qualifier,
* state or province name,
* common name (e.g., "Susan Housley"), and
* serial number.
In addition, implementations of this specification SHOULD be prepared
to receive the following standard attribute types in issuer and
subject names:
* locality,
* title,
* surname,
* given name,
* initials,
* pseudonym, and
* generation qualifier (e.g., "Jr.", "3rd", or "IV").
The syntax and associated object identifiers (OIDs) for these
attribute types are provided in the ASN.1 modules in Appendix A.
In addition, implementations of this specification MUST be prepared
to receive the domainComponent attribute, as defined in [RFC 2247].
The Domain Name System (DNS) provides a hierarchical resource
labeling system. This attribute provides a convenient mechanism for
organizations that wish to use DNs that parallel their DNS names.
This is not a replacement for the dNSName component of the
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alternative name field. Implementations are not required to convert
such names into DNS names. The syntax and associated OID for this
attribute type is provided in the ASN.1 modules in Appendix A.
Certificate users MUST be prepared to process the issuer
distinguished name and subject distinguished name (section 4.1.2.6)
fields to perform name chaining for certification path validation
(section 6). Name chaining is performed by matching the issuer
distinguished name in one certificate with the subject name in a CA
certificate.
This specification requires only a subset of the name comparison
functionality specified in the X.500 series of specifications.
Conforming implementations are REQUIRED to implement the following
name comparison rules:
(a) attribute values encoded in different types (e.g.,
PrintableString and BMPString) MAY be assumed to represent
different strings;
(b) attribute values in types other than PrintableString are case
sensitive (this permits matching of attribute values as binary
objects);
(c) attribute values in PrintableString are not case sensitive
(e.g., "Marianne Swanson" is the same as "MARIANNE SWANSON"); and
(d) attribute values in PrintableString are compared after
removing leading and trailing white space and converting internal
substrings of one or more consecutive white space characters to a
single space.
These name comparison rules permit a certificate user to validate
certificates issued using languages or encodings unfamiliar to the
certificate user.
In addition, implementations of this specification MAY use these
comparison rules to process unfamiliar attribute types for name
chaining. This allows implementations to process certificates with
unfamiliar attributes in the issuer name.
Note that the comparison rules defined in the X.500 series of
specifications indicate that the character sets used to encode data
in distinguished names are irrelevant. The characters themselves are
compared without regard to encoding. Implementations of this profile
are permitted to use the comparison algorithm defined in the X.500
series. Such an implementation will recognize a superset of name
matches recognized by the algorithm specified above.
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4.1.2.5 Validity
The certificate validity period is the time interval during which the
CA warrants that it will maintain information about the status of the
certificate. The field 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). Both notBefore and notAfter may be encoded as UTCTime or
GeneralizedTime.
CAs conforming to this profile MUST always encode certificate
validity dates through the year 2049 as UTCTime; certificate validity
dates in 2050 or later MUST be encoded as GeneralizedTime.
The validity period for a certificate is the period of time from
notBefore through notAfter, inclusive.
4.1.2.5.1 UTCTime
The universal time type, UTCTime, is a standard ASN.1 type intended
for representation of dates and time. UTCTime specifies the year
through the two low order digits and time is specified to the
precision of one minute or one second. UTCTime includes either Z
(for Zulu, or Greenwich Mean Time) or a time differential.
For the purposes of this profile, UTCTime values MUST be expressed
Greenwich Mean Time (Zulu) and MUST include seconds (i.e., times are
YYMMDDHHMMSSZ), even where the number of seconds is zero. Conforming
systems MUST interpret the year field (YY) as follows:
Where YY is greater than or equal to 50, the year SHALL be
interpreted as 19YY; and
Where YY is less than 50, the year SHALL be interpreted as 20YY.
4.1.2.5.2 GeneralizedTime
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.
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4.1.2.6 Subject
The subject field identifies the entity associated with the public
key stored in the subject public key field. The subject name MAY be
carried in the subject field and/or the subjectAltName extension. If
the subject is a CA (e.g., the basic constraints extension, as
discussed in 4.2.1.10, is present and the value of cA is TRUE), then
the subject field MUST be populated with a non-empty distinguished
name matching the contents of the issuer field (section 4.1.2.4) in
all certificates issued by the subject CA. If the subject is a CRL
issuer (e.g., the key usage extension, as discussed in 4.2.1.3, is
present and the value of cRLSign is TRUE) then the subject field MUST
be populated with a non-empty distinguished name matching the
contents of the issuer field (section 4.1.2.4) in all CRLs issued by
the subject CRL issuer. If subject naming information is present
only in the subjectAltName extension (e.g., a key bound only to an
email address or URI), then the subject name MUST be an empty
sequence and the subjectAltName extension MUST be critical.
Where it is non-empty, the subject field MUST contain an X.500
distinguished name (DN). The DN MUST be unique for each subject
entity certified by the one CA as defined by the issuer name field.
A CA MAY issue more than one certificate with the same DN to the same
subject entity.
The subject name field is defined as the X.501 type Name.
Implementation requirements for this field are those defined for the
issuer field (section 4.1.2.4). When encoding attribute values of
type DirectoryString, the encoding rules for the issuer field MUST be
implemented. Implementations of this specification MUST be prepared
to receive subject names containing the attribute types required for
the issuer field. Implementations of this specification SHOULD be
prepared to receive subject names containing the recommended
attribute types for the issuer field. The syntax and associated
object identifiers (OIDs) for these attribute types are provided in
the ASN.1 modules in Appendix A. Implementations of this
specification MAY use these comparison rules to process unfamiliar
attribute types (i.e., for name chaining). This allows
implementations to process certificates with unfamiliar attributes in
the subject name.
In addition, legacy implementations exist where an RFC 822 name is
embedded in the subject distinguished name as an EmailAddress
attribute. The attribute value for EmailAddress is of type IA5String
to permit inclusion of the character '@', which is not part of the
PrintableString character set. EmailAddress attribute values are not
case sensitive (e.g., "[email protected]" is the same as
"[email protected]").
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Conforming implementations generating new certificates with
electronic mail addresses MUST use the rfc822Name in the subject
alternative name field (section 4.2.1.7) to describe such identities.
Simultaneous inclusion of the EmailAddress attribute in the subject
distinguished name to support legacy implementations is deprecated
but permitted.
4.1.2.7 Subject Public Key Info
This field is used to carry the public key and identify the algorithm
with which the key is used (e.g., RSA, DSA, or Diffie-Hellman). The
algorithm is identified using the AlgorithmIdentifier structure
specified in section 4.1.1.2. The object identifiers for the
supported algorithms and the methods for encoding the public key
materials (public key and parameters) are specified in [PKIXALGS].
4.1.2.8 Unique Identifiers
These fields MUST only appear if the version is 2 or 3 (section
4.1.2.1). These fields MUST NOT appear if the version is 1. The
subject and issuer unique identifiers are present in the certificate
to handle the possibility of reuse of subject and/or issuer names
over time. This profile RECOMMENDS that names not be reused for
different entities and that Internet certificates not make use of
unique identifiers. CAs conforming to this profile SHOULD NOT
generate certificates with unique identifiers. Applications
conforming to this profile SHOULD be capable of parsing unique
identifiers.
4.1.2.9 Extensions
This field MUST only appear if the version is 3 (section 4.1.2.1).
If present, this field is a SEQUENCE of one or more certificate
extensions. The format and content of certificate extensions in the
Internet PKI is defined in section 4.2.
4.2 Certificate Extensions
The extensions defined for X.509 v3 certificates provide methods for
associating additional attributes with users or public keys and for
managing a certification hierarchy. The X.509 v3 certificate format
also allows communities to define private extensions to carry
information unique to those communities. Each extension in a
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. The following
sections present recommended extensions used within Internet
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certificates and standard locations for information. Communities may
elect to use additional extensions; however, caution ought to be
exercised in adopting any critical extensions in certificates which
might prevent use in a general context.
Each extension includes an OID and an ASN.1 structure. When an
extension appears in a certificate, the OID appears as the field
extnID and the corresponding ASN.1 encoded structure is the value of
the octet string extnValue. A certificate MUST NOT include more than
one instance of a particular extension. For example, a certificate
may contain only one authority key identifier extension (section
4.2.1.1). An extension includes the boolean critical, with a default
value of FALSE. The text for each extension specifies the acceptable
values for the critical field.
Conforming CAs MUST support key identifiers (sections 4.2.1.1 and
4.2.1.2), basic constraints (section 4.2.1.10), key usage (section
4.2.1.3), and certificate policies (section 4.2.1.5) extensions. If
the CA issues certificates with an empty sequence for the subject
field, the CA MUST support the subject alternative name extension
(section 4.2.1.7). Support for the remaining extensions is OPTIONAL.
Conforming CAs MAY support extensions that are not identified within
this specification; certificate issuers are cautioned that marking
such extensions as critical may inhibit interoperability.
At a minimum, applications conforming to this profile MUST recognize
the following extensions: key usage (section 4.2.1.3), certificate
policies (section 4.2.1.5), the subject alternative name (section
4.2.1.7), basic constraints (section 4.2.1.10), name constraints
(section 4.2.1.11), policy constraints (section 4.2.1.12), extended
key usage (section 4.2.1.13), and inhibit any-policy (section
4.2.1.15).
In addition, applications conforming to this profile SHOULD recognize
the authority and subject key identifier (sections 4.2.1.1 and
4.2.1.2), and policy mapping (section 4.2.1.6) extensions.
4.2.1 Standard Extensions
This section identifies standard certificate extensions defined in
[X.509] for use in the Internet PKI. Each extension is associated
with an OID defined in [X.509]. These OIDs are members of the id-ce
arc, which is defined by the following:
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
4.2.1.1 Authority Key Identifier
The authority key identifier extension provides a means of
identifying the public key corresponding to the private key used to
sign a certificate. This extension is used where an issuer has
multiple signing keys (either due to multiple concurrent key pairs or
due to changeover). The identification MAY be based on either the
key identifier (the subject key identifier in the issuer's
certificate) or on the issuer name and serial number.
The keyIdentifier field of the authorityKeyIdentifier extension MUST
be included in all certificates generated by conforming CAs to
facilitate certification path construction. There is one exception;
where a CA distributes its public key in the form of a "self-signed"
certificate, the authority key identifier MAY be omitted. The
signature on a self-signed certificate is generated with the private
key associated with the certificate's subject public key. (This
proves that the issuer possesses both the public and private keys.)
In this case, the subject and authority key identifiers would be
identical, but only the subject key identifier is needed for
certification path building.
The value of the keyIdentifier field SHOULD be derived from the
public key used to verify the certificate's signature or a method
that generates unique values. Two common methods for generating key
identifiers from the public key, and one common method for generating
unique values, are described in section 4.2.1.2. Where a key
identifier has not been previously established, this specification
RECOMMENDS use of one of these methods for generating keyIdentifiers.
Where a key identifier has been previously established, the CA SHOULD
use the previously established identifier.
This profile RECOMMENDS support for the key identifier method by all
certificate users.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
4.2.1.2 Subject Key Identifier
The subject key identifier extension provides a means of identifying
certificates that contain a particular public key.
To facilitate certification path construction, this extension MUST
appear in all conforming CA certificates, that is, all certificates
including the basic constraints extension (section 4.2.1.10) where
the value of cA is TRUE. The value of the subject key identifier
MUST be the value placed in the key identifier field of the Authority
Key Identifier extension (section 4.2.1.1) of certificates issued by
the subject of this certificate.
For CA certificates, subject key identifiers SHOULD be derived from
the public key or a method that generates unique values. Two common
methods for generating key identifiers from the public key are:
(1) The keyIdentifier is composed of the 160-bit SHA-1 hash of the
value of the BIT STRING subjectPublicKey (excluding the tag,
length, and number of unused bits).
(2) The keyIdentifier is composed of a four bit type field with
the value 0100 followed by the least significant 60 bits of the
SHA-1 hash of the value of the BIT STRING subjectPublicKey
(excluding the tag, length, and number of unused bit string bits).
One common method for generating unique values is a monotonically
increasing sequence of integers.
For end entity certificates, the subject key identifier extension
provides a means for identifying certificates containing the
particular public key used in an application. Where an end entity
has obtained multiple certificates, especially from multiple CAs, the
subject key identifier provides a means to quickly identify the set
of certificates containing a particular public key. To assist
applications in identifying the appropriate end entity certificate,
this extension SHOULD be included in all end entity certificates.
For end entity certificates, subject key identifiers SHOULD be
derived from the public key. Two common methods for generating key
identifiers from the public key are identified above.
Where a key identifier has not been previously established, this
specification RECOMMENDS use of one of these methods for generating
keyIdentifiers. Where a key identifier has been previously
established, the CA SHOULD use the previously established identifier.
This extension MUST NOT be marked critical.
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The key usage extension defines the purpose (e.g., encipherment,
signature, certificate signing) of the key contained in the
certificate. The usage restriction might be employed when a key that
could be used for more than one operation is to be restricted. For
example, when an RSA key should be used only to verify signatures on
objects other than public key certificates and CRLs, the
digitalSignature and/or nonRepudiation bits would be asserted.
Likewise, when an RSA key should be used only for key management, the
keyEncipherment bit would be asserted.
This extension MUST appear in certificates that contain public keys
that are used to validate digital signatures on other public key
certificates or CRLs. When this extension appears, it SHOULD be
marked critical.
The digitalSignature bit is asserted when the subject public key
is used with a digital signature mechanism to support security
services other than certificate signing (bit 5), or CRL signing
(bit 6). Digital signature mechanisms are often used for entity
authentication and data origin authentication with integrity.
The nonRepudiation bit is asserted when the subject public key is
used to verify digital signatures used to provide a non-
repudiation service which protects against the signing entity
falsely denying some action, excluding certificate or CRL signing.
In the case of later conflict, a reliable third party may
determine the authenticity of the signed data.
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Further distinctions between the digitalSignature and
nonRepudiation bits may be provided in specific certificate
policies.
The keyEncipherment bit is asserted when the subject public key is
used for key transport. For example, when an RSA key is to be
used for key management, then this bit is set.
The dataEncipherment bit is asserted when the subject public key
is used for enciphering user data, other than cryptographic keys.
The keyAgreement bit is asserted when the subject public key is
used for key agreement. For example, when a Diffie-Hellman key is
to be used for key management, then this bit is set.
The keyCertSign bit is asserted when the subject public key is
used for verifying a signature on public key certificates. If the
keyCertSign bit is asserted, then the cA bit in the basic
constraints extension (section 4.2.1.10) MUST also be asserted.
The cRLSign bit is asserted when the subject public key is used
for verifying a signature on certificate revocation list (e.g., a
CRL, delta CRL, or an ARL). This bit MUST be asserted in
certificates that are used to verify signatures on CRLs.
The meaning of the encipherOnly bit is undefined in the absence of
the keyAgreement bit. When the encipherOnly bit is asserted and
the keyAgreement bit is also set, the subject public key may be
used only for enciphering data while performing key agreement.
The meaning of the decipherOnly bit is undefined in the absence of
the keyAgreement bit. When the decipherOnly bit is asserted and
the keyAgreement bit is also set, the subject public key may be
used only for deciphering data while performing key agreement.
This profile does not restrict the combinations of bits that may be
set in an instantiation of the keyUsage extension. However,
appropriate values for keyUsage extensions for particular algorithms
are specified in [PKIXALGS].
4.2.1.4 Private Key Usage Period
This extension SHOULD NOT be used within the Internet PKI. CAs
conforming to this profile MUST NOT generate certificates that
include a critical private key usage period extension.
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The private key usage period extension allows the certificate issuer
to specify a different validity period for the private key than the
certificate. This extension is intended for use with digital
signature keys. This extension consists of two optional components,
notBefore and notAfter. The private key associated with the
certificate SHOULD NOT be used to sign objects before or after the
times specified by the two components, respectively. CAs conforming
to this profile MUST NOT generate certificates with private key usage
period extensions unless at least one of the two components is
present and the extension is non-critical.
Where used, notBefore and notAfter are represented as GeneralizedTime
and MUST be specified and interpreted as defined in section
4.1.2.5.2.
The certificate policies extension contains a sequence of one or more
policy information terms, each of which consists of an object
identifier (OID) and optional qualifiers. Optional qualifiers, which
MAY be present, are not expected to change the definition of the
policy.
In an end entity certificate, these policy information terms indicate
the policy under which the certificate has been issued and the
purposes for which the certificate may be used. In a CA certificate,
these policy information terms limit the set of policies for
certification paths which include this certificate. When a CA does
not wish to limit the set of policies for certification paths which
include this certificate, it MAY assert the special policy anyPolicy,
with a value of { 2 5 29 32 0 }.
Applications with specific policy requirements are expected to have a
list of those policies which they will accept and to compare the
policy OIDs in the certificate to that list. If this extension is
critical, the path validation software MUST be able to interpret this
extension (including the optional qualifier), or MUST reject the
certificate.
To promote interoperability, this profile RECOMMENDS that policy
information terms consist of only an OID. Where an OID alone is
insufficient, this profile strongly recommends that use of qualifiers
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be limited to those identified in this section. When qualifiers are
used with the special policy anyPolicy, they MUST be limited to the
qualifiers identified in this section.
This specification defines two policy qualifier types for use by
certificate policy writers and certificate issuers. The qualifier
types are the CPS Pointer and User Notice qualifiers.
The CPS Pointer qualifier contains a pointer to a Certification
Practice Statement (CPS) published by the CA. The pointer is in the
form of a URI. Processing requirements for this qualifier are a
local matter. No action is mandated by this specification regardless
of the criticality value asserted for the extension.
User notice is intended for display to a relying party when a
certificate is used. The application software SHOULD display all
user notices in all certificates of the certification path used,
except that if a notice is duplicated only one copy need be
displayed. To prevent such duplication, this qualifier SHOULD only
be present in end entity certificates and CA certificates issued to
other organizations.
The user notice has two optional fields: the noticeRef field and the
explicitText field.
The noticeRef field, if used, names an organization and
identifies, by number, a particular textual statement prepared by
that organization. For example, it might identify the
organization "CertsRUs" and notice number 1. In a typical
implementation, the application software will have a notice file
containing the current set of notices for CertsRUs; the
application will extract the notice text from the file and display
it. Messages MAY be multilingual, allowing the software to select
the particular language message for its own environment.
An explicitText field includes the textual statement directly in
the certificate. The explicitText field is a string with a
maximum size of 200 characters.
If both the noticeRef and explicitText options are included in the
one qualifier and if the application software can locate the notice
text indicated by the noticeRef option, then that text SHOULD be
displayed; otherwise, the explicitText string SHOULD be displayed.
Note: While the explicitText has a maximum size of 200 characters,
some non-conforming CAs exceed this limit. Therefore, certificate
users SHOULD gracefully handle explicitText with more than 200
characters.
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4.2.1.6 Policy Mappings
This extension is used in CA certificates. It lists one or more
pairs of OIDs; each pair includes an issuerDomainPolicy and a
subjectDomainPolicy. The pairing indicates the issuing CA considers
its issuerDomainPolicy equivalent to the subject CA's
subjectDomainPolicy.
The issuing CA's users might accept an issuerDomainPolicy for certain
applications. The policy mapping defines the list of policies
associated with the subject CA that may be accepted as comparable to
the issuerDomainPolicy.
Each issuerDomainPolicy named in the policy mapping extension SHOULD
also be asserted in a certificate policies extension in the same
certificate. Policies SHOULD NOT be mapped either to or from the
special value anyPolicy (section 4.2.1.5).
This extension MAY be supported by CAs and/or applications, and it
MUST be non-critical.
The subject alternative names extension allows additional identities
to be bound to the subject of the certificate. Defined options
include an Internet electronic mail address, a DNS name, an IP
address, and a uniform resource identifier (URI). Other options
exist, including completely local definitions. Multiple name forms,
and multiple instances of each name form, MAY be included. Whenever
such identities are to be bound into a certificate, the subject
alternative name (or issuer alternative name) extension MUST be used;
however, a DNS name MAY be represented in the subject field using the
domainComponent attribute as described in section 4.1.2.4.
Because the subject alternative name is considered to be definitively
bound to the public key, all parts of the subject alternative name
MUST be verified by the CA.
Further, if the only subject identity included in the certificate is
an alternative name form (e.g., an electronic mail address), then the
subject distinguished name MUST be empty (an empty sequence), and the
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subjectAltName extension MUST be present. If the subject field
contains an empty sequence, the subjectAltName extension MUST be
marked critical.
When the subjectAltName extension contains an Internet mail address,
the address MUST be included as an rfc822Name. The format of an
rfc822Name is an "addr-spec" as defined in RFC 822 [RFC 822]. An
addr-spec has the form "local-part@domain". Note that an addr-spec
has no phrase (such as a common name) before it, has no comment (text
surrounded in parentheses) after it, and is not surrounded by "<" and
">". Note that while upper and lower case letters are allowed in an
RFC 822 addr-spec, no significance is attached to the case.
When the subjectAltName extension contains a iPAddress, the address
MUST be stored in the octet string in "network byte order," as
specified in RFC 791 [RFC 791]. The least significant bit (LSB) of
each octet is the LSB of the corresponding byte in the network
address. For IP Version 4, as specified in RFC 791, the octet string
MUST contain exactly four octets. For IP Version 6, as specified in
RFC 1883, the octet string MUST contain exactly sixteen octets [RFC
1883].
When the subjectAltName extension contains a domain name system
label, the domain name MUST be stored in the dNSName (an IA5String).
The name MUST be in the "preferred name syntax," as specified by RFC
1034 [RFC 1034]. Note that while upper and lower case letters are
allowed in domain names, no signifigance is attached to the case. In
addition, while the string " " is a legal domain name, subjectAltName
extensions with a dNSName of " " MUST NOT be used. Finally, the use
of the DNS representation for Internet mail addresses (wpolk.nist.gov
instead of [email protected]) MUST NOT be used; such identities are to
be encoded as rfc822Name.
Note: work is currently underway to specify domain names in
international character sets. Such names will likely not be
accommodated by IA5String. Once this work is complete, this profile
will be revisited and the appropriate functionality will be added.
When the subjectAltName extension contains a URI, the name MUST be
stored in the uniformResourceIdentifier (an IA5String). The name
MUST NOT be a relative URL, and it MUST follow the URL syntax and
encoding rules specified in [RFC 1738]. The name MUST include both a
scheme (e.g., "http" or "ftp") and a scheme-specific-part. The
scheme-specific-part MUST include a fully qualified domain name or IP
address as the host.
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As specified in [RFC 1738], the scheme name is not case-sensitive
(e.g., "http" is equivalent to "HTTP"). The host part is also not
case-sensitive, but other components of the scheme-specific-part may
be case-sensitive. When comparing URIs, conforming implementations
MUST compare the scheme and host without regard to case, but assume
the remainder of the scheme-specific-part is case sensitive.
When the subjectAltName extension contains a DN in the directoryName,
the DN MUST be unique for each subject entity certified by the one CA
as defined by the issuer name field. A CA MAY issue more than one
certificate with the same DN to the same subject entity.
The subjectAltName MAY carry additional name types through the use of
the otherName field. The format and semantics of the name are
indicated through the OBJECT IDENTIFIER in the type-id field. The
name itself is conveyed as value field in otherName. For example,
Kerberos [RFC 1510] format names can be encoded into the otherName,
using using a Kerberos 5 principal name OID and a SEQUENCE of the
Realm and the PrincipalName.
Subject alternative names MAY be constrained in the same manner as
subject distinguished names using the name constraints extension as
described in section 4.2.1.11.
If the subjectAltName extension is present, the sequence MUST contain
at least one entry. Unlike the subject field, conforming CAs MUST
NOT issue certificates with subjectAltNames containing empty
GeneralName fields. For example, an rfc822Name is represented as an
IA5String. While an empty string is a valid IA5String, such an
rfc822Name is not permitted by this profile. The behavior of clients
that encounter such a certificate when processing a certificication
path is not defined by this profile.
Finally, the semantics of subject alternative names that include
wildcard characters (e.g., as a placeholder for a set of names) are
not addressed by this specification. Applications with specific
requirements MAY use such names, but they must define the semantics.
As with 4.2.1.7, this extension is used to associate Internet style
identities with the certificate issuer. Issuer alternative names
MUST be encoded as in 4.2.1.7.
Where present, this extension SHOULD NOT be marked critical.
The subject directory attributes extension is used to convey
identification attributes (e.g., nationality) of the subject. The
extension is defined as a sequence of one or more attributes. This
extension MUST be non-critical.
SubjectDirectoryAttributes ::= SEQUENCE SIZE (1..MAX) OF Attribute
4.2.1.10 Basic Constraints
The basic constraints extension identifies whether the subject of the
certificate is a CA and the maximum depth of valid certification
paths that include this certificate.
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The cA boolean indicates whether the certified public key belongs to
a CA. If the cA boolean is not asserted, then the keyCertSign bit in
the key usage extension MUST NOT be asserted.
The pathLenConstraint field is meaningful only if the cA boolean is
asserted and the key usage extension asserts the keyCertSign bit
(section 4.2.1.3). In this case, it gives the maximum number of non-
self-issued intermediate certificates that may follow this
certificate in a valid certification path. A certificate is self-
issued if the DNs that appear in the subject and issuer fields are
identical and are not empty. (Note: The last certificate in the
certification path is not an intermediate certificate, and is not
included in this limit. Usually, the last certificate is an end
entity certificate, but it can be a CA certificate.) A
pathLenConstraint of zero indicates that only one more certificate
may follow in a valid certification path. Where it appears, the
pathLenConstraint field MUST be greater than or equal to zero. Where
pathLenConstraint does not appear, no limit is imposed.
This extension MUST appear as a critical extension in all CA
certificates that contain public keys used to validate digital
signatures on certificates. This extension MAY appear as a critical
or non-critical extension in CA certificates that contain public keys
used exclusively for purposes other than validating digital
signatures on certificates. Such CA certificates include ones that
contain public keys used exclusively for validating digital
signatures on CRLs and ones that contain key management public keys
used with certificate enrollment protocols. This extension MAY
appear as a critical or non-critical extension in end entity
certificates.
CAs MUST NOT include the pathLenConstraint field unless the cA
boolean is asserted and the key usage extension asserts the
keyCertSign bit.
The name constraints extension, which MUST be used only in a CA
certificate, indicates a name space within which all subject names in
subsequent certificates in a certification path MUST be located.
Restrictions apply to the subject distinguished name and apply to
subject alternative names. Restrictions apply only when the
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specified name form is present. If no name of the type is in the
certificate, the certificate is acceptable.
Name constraints are not applied to certificates whose issuer and
subject are identical (unless the certificate is the final
certificate in the path). (This could prevent CAs that use name
constraints from employing self-issued certificates to implement key
rollover.)
Restrictions are defined in terms of permitted or excluded name
subtrees. Any name matching a restriction in the excludedSubtrees
field is invalid regardless of information appearing in the
permittedSubtrees. This extension MUST be critical.
Within this profile, the minimum and maximum fields are not used with
any name forms, thus minimum MUST be zero, and maximum MUST be
absent.
For URIs, the constraint applies to the host part of the name. The
constraint MAY specify a host or a domain. Examples would be
"foo.bar.com"; and ".xyz.com". When the the constraint begins with
a period, it MAY be expanded with one or more subdomains. That is,
the constraint ".xyz.com" is satisfied by both abc.xyz.com and
abc.def.xyz.com. However, the constraint ".xyz.com" is not satisfied
by "xyz.com". When the constraint does not begin with a period, it
specifies a host.
A name constraint for Internet mail addresses MAY specify a
particular mailbox, all addresses at a particular host, or all
mailboxes in a domain. To indicate a particular mailbox, the
constraint is the complete mail address. For example, "[email protected]"
indicates the root mailbox on the host "xyz.com". To indicate all
Internet mail addresses on a particular host, the constraint is
specified as the host name. For example, the constraint "xyz.com" is
satisfied by any mail address at the host "xyz.com". To specify any
address within a domain, the constraint is specified with a leading
period (as with URIs). For example, ".xyz.com" indicates all the
Internet mail addresses in the domain "xyz.com", but not Internet
mail addresses on the host "xyz.com".
DNS name restrictions are expressed as foo.bar.com. Any DNS name
that can be constructed by simply adding to the left hand side of the
name satisfies the name constraint. For example, www.foo.bar.com
would satisfy the constraint but foo1.bar.com would not.
Legacy implementations exist where an RFC 822 name is embedded in the
subject distinguished name in an attribute of type EmailAddress
(section 4.1.2.6). When rfc822 names are constrained, but the
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certificate does not include a subject alternative name, the rfc822
name constraint MUST be applied to the attribute of type EmailAddress
in the subject distinguished name. The ASN.1 syntax for EmailAddress
and the corresponding OID are supplied in Appendix A.
Restrictions of the form directoryName MUST be applied to the subject
field in the certificate and to the subjectAltName extensions of type
directoryName. Restrictions of the form x400Address MUST be applied
to subjectAltName extensions of type x400Address.
When applying restrictions of the form directoryName, an
implementation MUST compare DN attributes. At a minimum,
implementations MUST perform the DN comparison rules specified in
Section 4.1.2.4. CAs issuing certificates with a restriction of the
form directoryName SHOULD NOT rely on implementation of the full ISO
DN name comparison algorithm. This implies name restrictions MUST be
stated identically to the encoding used in the subject field or
subjectAltName extension.
The syntax of iPAddress MUST be as described in section 4.2.1.7 with
the following additions specifically for Name Constraints. For IPv4
addresses, the ipAddress field of generalName MUST contain eight (8)
octets, encoded in the style of RFC 1519 (CIDR) to represent an
address range [RFC 1519]. For IPv6 addresses, the ipAddress field
MUST contain 32 octets similarly encoded. For example, a name
constraint for "class C" subnet 10.9.8.0 is represented as the octets
0A 09 08 00 FF FF FF 00, representing the CIDR notation
10.9.8.0/255.255.255.0.
The syntax and semantics for name constraints for otherName,
ediPartyName, and registeredID are not defined by this specification.
GeneralSubtrees ::= SEQUENCE SIZE (1..MAX) OF GeneralSubtree
GeneralSubtree ::= SEQUENCE {
base GeneralName,
minimum [0] BaseDistance DEFAULT 0,
maximum [1] BaseDistance OPTIONAL }
BaseDistance ::= INTEGER (0..MAX)
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4.2.1.12 Policy Constraints
The policy constraints extension can be used in certificates issued
to CAs. The policy constraints extension constrains path validation
in two ways. It can be used to prohibit policy mapping or require
that each certificate in a path contain an acceptable policy
identifier.
If the inhibitPolicyMapping field is present, the value indicates the
number of additional certificates that may appear in the path before
policy mapping is no longer permitted. For example, a value of one
indicates that policy mapping may be processed in certificates issued
by the subject of this certificate, but not in additional
certificates in the path.
If the requireExplicitPolicy field is present, the value of
requireExplicitPolicy indicates the number of additional certificates
that may appear in the path before an explicit policy is required for
the entire path. When an explicit policy is required, it is
necessary for all certificates in the path to contain an acceptable
policy identifier in the certificate policies extension. An
acceptable policy identifier is the identifier of a policy required
by the user of the certification path or the identifier of a policy
which has been declared equivalent through policy mapping.
Conforming CAs MUST NOT issue certificates where policy constraints
is a empty sequence. That is, at least one of the
inhibitPolicyMapping field or the requireExplicitPolicy field MUST be
present. The behavior of clients that encounter a empty policy
constraints field is not addressed in this profile.
This extension indicates one or more purposes for which the certified
public key may be used, in addition to or in place of the basic
purposes indicated in the key usage extension. In general, this
extension will appear only in end entity certificates. This
extension is defined as follows:
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ExtKeyUsageSyntax ::= SEQUENCE SIZE (1..MAX) OF KeyPurposeId
KeyPurposeId ::= OBJECT IDENTIFIER
Key purposes may be defined by any organization with a need. Object
identifiers used to identify key purposes MUST be assigned in
accordance with IANA or ITU-T Recommendation X.660 [X.660].
This extension MAY, at the option of the certificate issuer, be
either critical or non-critical.
If the extension is present, then the certificate MUST only be used
for one of the purposes indicated. If multiple purposes are
indicated the application need not recognize all purposes indicated,
as long as the intended purpose is present. Certificate using
applications MAY require that a particular purpose be indicated in
order for the certificate to be acceptable to that application.
If a CA includes extended key usages to satisfy such applications,
but does not wish to restrict usages of the key, the CA can include
the special keyPurposeID anyExtendedKeyUsage. If the
anyExtendedKeyUsage keyPurposeID is present, the extension SHOULD NOT
be critical.
If a certificate contains both a key usage extension and an extended
key usage extension, then both extensions MUST be processed
independently and the certificate MUST only be used for a purpose
consistent with both extensions. If there is no purpose consistent
with both extensions, then the certificate MUST NOT be used for any
purpose.
id-kp-serverAuth OBJECT IDENTIFIER ::= { id-kp 1 }
-- TLS WWW server authentication
-- Key usage bits that may be consistent: digitalSignature,
-- keyEncipherment or keyAgreement
id-kp-clientAuth OBJECT IDENTIFIER ::= { id-kp 2 }
-- TLS WWW client authentication
-- Key usage bits that may be consistent: digitalSignature
-- and/or keyAgreement
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id-kp-codeSigning OBJECT IDENTIFIER ::= { id-kp 3 }
-- Signing of downloadable executable code
-- Key usage bits that may be consistent: digitalSignature
id-kp-emailProtection OBJECT IDENTIFIER ::= { id-kp 4 }
-- E-mail protection
-- Key usage bits that may be consistent: digitalSignature,
-- nonRepudiation, and/or (keyEncipherment or keyAgreement)
id-kp-timeStamping OBJECT IDENTIFIER ::= { id-kp 8 }
-- Binding the hash of an object to a time
-- Key usage bits that may be consistent: digitalSignature
-- and/or nonRepudiation
id-kp-OCSPSigning OBJECT IDENTIFIER ::= { id-kp 9 }
-- Signing OCSP responses
-- Key usage bits that may be consistent: digitalSignature
-- and/or nonRepudiation
4.2.1.14 CRL Distribution Points
The CRL distribution points extension identifies how CRL information
is obtained. The extension SHOULD be non-critical, but this profile
RECOMMENDS support for this extension by CAs and applications.
Further discussion of CRL management is contained in section 5.
The cRLDistributionPoints extension is a SEQUENCE of
DistributionPoint. A DistributionPoint consists of three fields,
each of which is optional: distributionPoint, reasons, and cRLIssuer.
While each of these fields is optional, a DistributionPoint MUST NOT
consist of only the reasons field; either distributionPoint or
cRLIssuer MUST be present. If the certificate issuer is not the CRL
issuer, then the cRLIssuer field MUST be present and contain the Name
of the CRL issuer. If the certificate issuer is also the CRL issuer,
then the cRLIssuer field MUST be omitted and the distributionPoint
field MUST be present. If the distributionPoint field is omitted,
cRLIssuer MUST be present and include a Name corresponding to an
X.500 or LDAP directory entry where the CRL is located.
When the distributionPoint field is present, it contains either a
SEQUENCE of general names or a single value, nameRelativeToCRLIssuer.
If the cRLDistributionPoints extension contains a general name of
type URI, the following semantics MUST be assumed: the URI is a
pointer to the current CRL for the associated reasons and will be
issued by the associated cRLIssuer. The expected values for the URI
are those defined in 4.2.1.7. Processing rules for other values are
not defined by this specification.
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If the DistributionPointName contains multiple values, each name
describes a different mechanism to obtain the same CRL. For example,
the same CRL could be available for retrieval through both LDAP and
HTTP.
If the DistributionPointName contains the single value
nameRelativeToCRLIssuer, the value provides a distinguished name
fragment. The fragment is appended to the X.500 distinguished name
of the CRL issuer to obtain the distribution point name. If the
cRLIssuer field in the DistributionPoint is present, then the name
fragment is appended to the distinguished name that it contains;
otherwise, the name fragment is appended to the certificate issuer
distinguished name. The DistributionPointName MUST NOT use the
nameRealtiveToCRLIssuer alternative when cRLIssuer contains more than
one distinguished name.
If the DistributionPoint omits the reasons field, the CRL MUST
include revocation information for all reasons.
The cRLIssuer identifies the entity who signs and issues the CRL. If
present, the cRLIssuer MUST contain at least one an X.500
distinguished name (DN), and MAY also contain other name forms.
Since the cRLIssuer is compared to the CRL issuer name, the X.501
type Name MUST follow the encoding rules for the issuer name field in
the certificate (section 4.1.2.4).
The inhibit any-policy extension can be used in certificates issued
to CAs. The inhibit any-policy indicates that the special anyPolicy
OID, with the value { 2 5 29 32 0 }, is not considered an explicit
match for other certificate policies. The value indicates the number
of additional certificates that may appear in the path before
anyPolicy is no longer permitted. For example, a value of one
indicates that anyPolicy may be processed in certificates issued by
the subject of this certificate, but not in additional certificates
in the path.
4.2.1.16 Freshest CRL (a.k.a. Delta CRL Distribution Point)
The freshest CRL extension identifies how delta CRL information is
obtained. The extension MUST be non-critical. Further discussion of
CRL management is contained in section 5.
The same syntax is used for this extension and the
cRLDistributionPoints extension, and is described in section
4.2.1.14. The same conventions apply to both extensions.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
4.2.2 Private Internet Extensions
This section defines two extensions for use in the Internet Public
Key Infrastructure. These extensions may be used to direct
applications to on-line information about the issuing CA or the
subject. As the information may be available in multiple forms, each
extension is a sequence of IA5String values, each of which represents
a URI. The URI implicitly specifies the location and format of the
information and the method for obtaining the information.
An object identifier is defined for the private extension. The
object identifier associated with the private extension is defined
under the arc id-pe within the arc id-pkix. Any future extensions
defined for the Internet PKI are also expected to be defined under
the arc id-pe.
The authority information access extension indicates how to access CA
information and services for the issuer of the certificate in which
the extension appears. Information and services may include on-line
validation services and CA policy data. (The location of CRLs is not
specified in this extension; that information is provided by the
cRLDistributionPoints extension.) This extension may be included in
end entity or CA certificates, and it MUST be non-critical.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
Each entry in the sequence AuthorityInfoAccessSyntax describes the
format and location of additional information provided by the CA that
issued the certificate in which this extension appears. The type and
format of the information is specified by the accessMethod field; the
accessLocation field specifies the location of the information. The
retrieval mechanism may be implied by the accessMethod or specified
by accessLocation.
This profile defines two accessMethod OIDs: id-ad-caIssuers and
id-ad-ocsp.
The id-ad-caIssuers OID is used when the additional information lists
CAs that have issued certificates superior to the CA that issued the
certificate containing this extension. The referenced CA issuers
description is intended to aid certificate users in the selection of
a certification path that terminates at a point trusted by the
certificate user.
When id-ad-caIssuers appears as accessMethod, the accessLocation
field describes the referenced description server and the access
protocol to obtain the referenced description. The accessLocation
field is defined as a GeneralName, which can take several forms.
Where the information is available via http, ftp, or ldap,
accessLocation MUST be a uniformResourceIdentifier. Where the
information is available via the Directory Access Protocol (DAP),
accessLocation MUST be a directoryName. The entry for that
directoryName contains CA certificates in the crossCertificatePair
attribute. When the information is available via electronic mail,
accessLocation MUST be an rfc822Name. The semantics of other
id-ad-caIssuers accessLocation name forms are not defined.
The id-ad-ocsp OID is used when revocation information for the
certificate containing this extension is available using the Online
Certificate Status Protocol (OCSP) [RFC 2560].
When id-ad-ocsp appears as accessMethod, the accessLocation field is
the location of the OCSP responder, using the conventions defined in
[RFC 2560].
Additional access descriptors may be defined in other PKIX
specifications.
4.2.2.2 Subject Information Access
The subject information access extension indicates how to access
information and services for the subject of the certificate in which
the extension appears. When the subject is a CA, information and
services may include certificate validation services and CA policy
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data. When the subject is an end entity, the information describes
the type of services offered and how to access them. In this case,
the contents of this extension are defined in the protocol
specifications for the suported services. This extension may be
included in subject or CA certificates, and it MUST be non-critical.
Each entry in the sequence SubjectInfoAccessSyntax describes the
format and location of additional information provided by the subject
of the certificate in which this extension appears. The type and
format of the information is specified by the accessMethod field; the
accessLocation field specifies the location of the information. The
retrieval mechanism may be implied by the accessMethod or specified
by accessLocation.
This profile defines one access method to be used when the subject is
a CA, and one access method to be used when the subject is an end
entity. Additional access methods may be defined in the future in
the protocol specifications for other services.
The id-ad-caRepository OID is used when the subject is a CA, and
publishes its certificates and CRLs (if issued) in a repository. The
accessLocation field is defined as a GeneralName, which can take
several forms. Where the information is available via http, ftp, or
ldap, accessLocation MUST be a uniformResourceIdentifier. Where the
information is available via the directory access protocol (dap),
accessLocation MUST be a directoryName. When the information is
available via electronic mail, accessLocation MUST be an rfc822Name.
The semantics of other name forms of of accessLocation (when
accessMethod is id-ad-caRepository) are not defined by this
specification.
The id-ad-timeStamping OID is used when the subject offers
timestamping services using the Time Stamp Protocol defined in
[PKIXTSA]. Where the timestamping services are available via http or
ftp, accessLocation MUST be a uniformResourceIdentifier. Where the
timestamping services are available via electronic mail,
accessLocation MUST be an rfc822Name. Where timestamping services
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are available using TCP/IP, the dNSName or ipAddress name forms may
be used. The semantics of other name forms of accessLocation (when
accessMethod is id-ad-timeStamping) are not defined by this
specification.
Additional access descriptors may be defined in other PKIX
specifications.
As discussed above, one goal of this X.509 v2 CRL profile is to
foster the creation of an interoperable and reusable Internet PKI.
To achieve this goal, guidelines for the use of extensions are
specified, and some assumptions are made about the nature of
information included in the CRL.
CRLs may be used in a wide range of applications and environments
covering a broad spectrum of interoperability goals and an even
broader spectrum of operational and assurance requirements. This
profile establishes a common baseline for generic applications
requiring broad interoperability. The profile defines a set of
information that can be expected in every CRL. Also, the profile
defines common locations within the CRL for frequently used
attributes as well as common representations for these attributes.
CRL issuers issue CRLs. In general, the CRL issuer is the CA. CAs
publish CRLs to provide status information about the certificates
they issued. However, a CA may delegate this responsibility to
another trusted authority. Whenever the CRL issuer is not the CA
that issued the certificates, the CRL is referred to as an indirect
CRL.
Each CRL has a particular scope. The CRL scope is the set of
certificates that could appear on a given CRL. For example, the
scope could be "all certificates issued by CA X", "all CA
certificates issued by CA X", "all certificates issued by CA X that
have been revoked for reasons of key compromise and CA compromise",
or could be a set of certificates based on arbitrary local
information, such as "all certificates issued to the NIST employees
located in Boulder".
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A complete CRL lists all unexpired certificates, within its scope,
that have been revoked for one of the revocation reasons covered by
the CRL scope. The CRL issuer MAY also generate delta CRLs. A delta
CRL only lists those certificates, within its scope, whose revocation
status has changed since the issuance of a referenced complete CRL.
The referenced complete CRL is referred to as a base CRL. The scope
of a delta CRL MUST be the same as the base CRL that it references.
This profile does not define any private Internet CRL extensions or
CRL entry extensions.
Environments with additional or special purpose requirements may
build on this profile or may replace it.
Conforming CAs are not required to issue CRLs if other revocation or
certificate status mechanisms are provided. When CRLs are issued,
the CRLs MUST be version 2 CRLs, include the date by which the next
CRL will be issued in the nextUpdate field (section 5.1.2.5), include
the CRL number extension (section 5.2.3), and include the authority
key identifier extension (section 5.2.1). Conforming applications
that support CRLs are REQUIRED to process both version 1 and version
2 complete CRLs that provide revocation information for all
certificates issued by one CA. Conforming applications are NOT
REQUIRED to support processing of delta CRLs, indirect CRLs, or CRLs
with a scope other than all certificates issued by one CA.
5.1 CRL Fields
The X.509 v2 CRL syntax is as follows. For signature calculation,
the data that is to be signed is ASN.1 DER encoded. ASN.1 DER
encoding is a tag, length, value encoding system for each element.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
TBSCertList ::= SEQUENCE {
version Version OPTIONAL,
-- if present, MUST be v2
signature AlgorithmIdentifier,
issuer Name,
thisUpdate Time,
nextUpdate Time OPTIONAL,
revokedCertificates SEQUENCE OF SEQUENCE {
userCertificate CertificateSerialNumber,
revocationDate Time,
crlEntryExtensions Extensions OPTIONAL
-- if present, MUST be v2
} OPTIONAL,
crlExtensions [0] EXPLICIT Extensions OPTIONAL
-- if present, MUST be v2
}
-- Version, Time, CertificateSerialNumber, and Extensions
-- are all defined in the ASN.1 in section 4.1
-- AlgorithmIdentifier is defined in section 4.1.1.2
The following items describe the use of the X.509 v2 CRL in the
Internet PKI.
5.1.1 CertificateList Fields
The CertificateList is a SEQUENCE of three required fields. The
fields are described in detail in the following subsections.
5.1.1.1 tbsCertList
The first field in the sequence is the tbsCertList. This field is
itself a sequence containing the name of the issuer, issue date,
issue date of the next list, the optional list of revoked
certificates, and optional CRL extensions. When there are no revoked
certificates, the revoked certificates list is absent. When one or
more certificates are revoked, each entry on the revoked certificate
list is defined by a sequence of user certificate serial number,
revocation date, and optional CRL entry extensions.
5.1.1.2 signatureAlgorithm
The signatureAlgorithm field contains the algorithm identifier for
the algorithm used by the CRL issuer to sign the CertificateList.
The field is of type AlgorithmIdentifier, which is defined in section
4.1.1.2. [PKIXALGS] lists the supported algorithms for this
specification, but other signature algorithms MAY also be supported.
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This field MUST contain the same algorithm identifier as the
signature field in the sequence tbsCertList (section 5.1.2.2).
5.1.1.3 signatureValue
The signatureValue field contains a digital signature computed upon
the ASN.1 DER encoded tbsCertList. The ASN.1 DER encoded tbsCertList
is used as the input to the signature function. This signature value
is encoded as a BIT STRING and included in the CRL signatureValue
field. The details of this process are specified for each of the
supported algorithms in [PKIXALGS].
CAs that are also CRL issuers MAY use one private key to digitally
sign certificates and CRLs, or MAY use separate private keys to
digitally sign certificates and CRLs. When separate private keys are
employed, each of the public keys associated with these private keys
is placed in a separate certificate, one with the keyCertSign bit set
in the key usage extension, and one with the cRLSign bit set in the
key usage extension (section 4.2.1.3). When separate private keys
are employed, certificates issued by the CA contain one authority key
identifier, and the corresponding CRLs contain a different authority
key identifier. The use of separate CA certificates for validation
of certificate signatures and CRL signatures can offer improved
security characteristics; however, it imposes a burden on
applications, and it might limit interoperability. Many applications
construct a certification path, and then validate the certification
path (section 6). CRL checking in turn requires a separate
certification path to be constructed and validated for the CA's CRL
signature validation certificate. Applications that perform CRL
checking MUST support certification path validation when certificates
and CRLs are digitally signed with the same CA private key. These
applications SHOULD support certification path validation when
certificates and CRLs are digitally signed with different CA private
keys.
5.1.2 Certificate List "To Be Signed"
The certificate list to be signed, or TBSCertList, is a sequence of
required and optional fields. The required fields identify the CRL
issuer, the algorithm used to sign the CRL, the date and time the CRL
was issued, and the date and time by which the CRL issuer will issue
the next CRL.
Optional fields include lists of revoked certificates and CRL
extensions. The revoked certificate list is optional to support the
case where a CA has not revoked any unexpired certificates that it
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has issued. The profile requires conforming CRL issuers to use the
CRL number and authority key identifier CRL extensions in all CRLs
issued.
5.1.2.1 Version
This optional field describes the version of the encoded CRL. When
extensions are used, as required by this profile, this field MUST be
present and MUST specify version 2 (the integer value is 1).
5.1.2.2 Signature
This field contains the algorithm identifier for the algorithm used
to sign the CRL. [PKIXALGS] lists OIDs for the most popular
signature algorithms used in the Internet PKI.
This field MUST contain the same algorithm identifier as the
signatureAlgorithm field in the sequence CertificateList (section
5.1.1.2).
5.1.2.3 Issuer Name
The issuer name identifies the entity who has signed and issued the
CRL. The issuer identity is carried in the issuer name field.
Alternative name forms may also appear in the issuerAltName extension
(section 5.2.2). The issuer name field MUST contain an X.500
distinguished name (DN). The issuer name field is defined as the
X.501 type Name, and MUST follow the encoding rules for the issuer
name field in the certificate (section 4.1.2.4).
5.1.2.4 This Update
This field indicates the issue date of this CRL. ThisUpdate may be
encoded as UTCTime or GeneralizedTime.
CRL issuers conforming to this profile MUST encode thisUpdate as
UTCTime for dates through the year 2049. CRL issuers conforming to
this profile MUST encode thisUpdate as GeneralizedTime for dates in
the year 2050 or later.
Where encoded as UTCTime, thisUpdate MUST be specified and
interpreted as defined in section 4.1.2.5.1. Where encoded as
GeneralizedTime, thisUpdate MUST be specified and interpreted as
defined in section 4.1.2.5.2.
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5.1.2.5 Next Update
This field indicates the date by which the next CRL will be issued.
The next CRL could be issued before the indicated date, but it will
not be issued any later than the indicated date. CRL issuers SHOULD
issue CRLs with a nextUpdate time equal to or later than all previous
CRLs. nextUpdate may be encoded as UTCTime or GeneralizedTime.
This profile requires inclusion of nextUpdate in all CRLs issued by
conforming CRL issuers. Note that the ASN.1 syntax of TBSCertList
describes this field as OPTIONAL, which is consistent with the ASN.1
structure defined in [X.509]. The behavior of clients processing
CRLs which omit nextUpdate is not specified by this profile.
CRL issuers conforming to this profile MUST encode nextUpdate as
UTCTime for dates through the year 2049. CRL issuers conforming to
this profile MUST encode nextUpdate as GeneralizedTime for dates in
the year 2050 or later.
Where encoded as UTCTime, nextUpdate MUST be specified and
interpreted as defined in section 4.1.2.5.1. Where encoded as
GeneralizedTime, nextUpdate MUST be specified and interpreted as
defined in section 4.1.2.5.2.
5.1.2.6 Revoked Certificates
When there are no revoked certificates, the revoked certificates list
MUST be absent. Otherwise, revoked certificates are listed by their
serial numbers. Certificates revoked by the CA are uniquely
identified by the certificate serial number. The date on which the
revocation occurred is specified. The time for revocationDate MUST
be expressed as described in section 5.1.2.4. Additional information
may be supplied in CRL entry extensions; CRL entry extensions are
discussed in section 5.3.
5.1.2.7 Extensions
This field may only appear if the version is 2 (section 5.1.2.1). If
present, this field is a sequence of one or more CRL extensions. CRL
extensions are discussed in section 5.2.
5.2 CRL Extensions
The extensions defined by ANSI X9, ISO/IEC, and ITU-T for X.509 v2
CRLs [X.509] [X9.55] provide methods for associating additional
attributes with CRLs. The X.509 v2 CRL format also allows
communities to define private extensions to carry information unique
to those communities. Each extension in a CRL may be designated as
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critical or non-critical. A CRL validation MUST fail if it
encounters a critical extension which it does not know how to
process. However, an unrecognized non-critical extension may be
ignored. The following subsections present those extensions used
within Internet CRLs. Communities may elect to include extensions in
CRLs which are not defined in this specification. However, caution
should be exercised in adopting any critical extensions in CRLs which
might be used in a general context.
Conforming CRL issuers are REQUIRED to include the authority key
identifier (section 5.2.1) and the CRL number (section 5.2.3)
extensions in all CRLs issued.
5.2.1 Authority Key Identifier
The authority key identifier extension provides a means of
identifying the public key corresponding to the private key used to
sign a CRL. The identification can be based on either the key
identifier (the subject key identifier in the CRL signer's
certificate) or on the issuer name and serial number. This extension
is especially useful where an issuer has more than one signing key,
either due to multiple concurrent key pairs or due to changeover.
Conforming CRL issuers MUST use the key identifier method, and MUST
include this extension in all CRLs issued.
The syntax for this CRL extension is defined in section 4.2.1.1.
5.2.2 Issuer Alternative Name
The issuer alternative names extension allows additional identities
to be associated with the issuer of the CRL. Defined options include
an rfc822 name (electronic mail address), a DNS name, an IP address,
and a URI. Multiple instances of a name and multiple name forms may
be included. Whenever such identities are used, the issuer
alternative name extension MUST be used; however, a DNS name MAY be
represented in the issuer field using the domainComponent attribute
as described in section 4.1.2.4.
The issuerAltName extension SHOULD NOT be marked critical.
The OID and syntax for this CRL extension are defined in section
4.2.1.8.
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5.2.3 CRL Number
The CRL number is a non-critical CRL extension which conveys a
monotonically increasing sequence number for a given CRL scope and
CRL issuer. This extension allows users to easily determine when a
particular CRL supersedes another CRL. CRL numbers also support the
identification of complementary complete CRLs and delta CRLs. CRL
issuers conforming to this profile MUST include this extension in all
CRLs.
If a CRL issuer generates delta CRLs in addition to complete CRLs for
a given scope, the complete CRLs and delta CRLs MUST share one
numbering sequence. If a delta CRL and a complete CRL that cover the
same scope are issued at the same time, they MUST have the same CRL
number and provide the same revocation information. That is, the
combination of the delta CRL and an acceptable complete CRL MUST
provide the same revocation information as the simultaneously issued
complete CRL.
If a CRL issuer generates two CRLs (two complete CRLs, two delta
CRLs, or a complete CRL and a delta CRL) for the same scope at
different times, the two CRLs MUST NOT have the same CRL number.
That is, if the this update field (section 5.1.2.4) in the two CRLs
are not identical, the CRL numbers MUST be different.
Given the requirements above, CRL numbers can be expected to contain
long integers. CRL verifiers MUST be able to handle CRLNumber values
up to 20 octets. Conformant CRL issuers MUST NOT use CRLNumber
values longer than 20 octets.
The delta CRL indicator is a critical CRL extension that identifies a
CRL as being a delta CRL. Delta CRLs contain updates to revocation
information previously distributed, rather than all the information
that would appear in a complete CRL. The use of delta CRLs can
significantly reduce network load and processing time in some
environments. Delta CRLs are generally smaller than the CRLs they
update, so applications that obtain delta CRLs consume less network
bandwidth than applications that obtain the corresponding complete
CRLs. Applications which store revocation information in a format
other than the CRL structure can add new revocation information to
the local database without reprocessing information.
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The delta CRL indicator extension contains the single value of type
BaseCRLNumber. The CRL number identifies the CRL, complete for a
given scope, that was used as the starting point in the generation of
this delta CRL. A conforming CRL issuer MUST publish the referenced
base CRL as a complete CRL. The delta CRL contains all updates to
the revocation status for that same scope. The combination of a
delta CRL plus the referenced base CRL is equivalent to a complete
CRL, for the applicable scope, at the time of publication of the
delta CRL.
When a conforming CRL issuer generates a delta CRL, the delta CRL
MUST include a critical delta CRL indicator extension.
When a delta CRL is issued, it MUST cover the same set of reasons and
the same set of certificates that were covered by the base CRL it
references. That is, the scope of the delta CRL MUST be the same as
the scope of the complete CRL referenced as the base. The referenced
base CRL and the delta CRL MUST omit the issuing distribution point
extension or contain identical issuing distribution point extensions.
Further, the CRL issuer MUST use the same private key to sign the
delta CRL and any complete CRL that it can be used to update.
An application that supports delta CRLs can construct a CRL that is
complete for a given scope by combining a delta CRL for that scope
with either an issued CRL that is complete for that scope or a
locally constructed CRL that is complete for that scope.
When a delta CRL is combined with a complete CRL or a locally
constructed CRL, the resulting locally constructed CRL has the CRL
number specified in the CRL number extension found in the delta CRL
used in its construction. In addition, the resulting locally
constructed CRL has the thisUpdate and nextUpdate times specified in
the corresponding fields of the delta CRL used in its construction.
In addition, the locally constructed CRL inherits the issuing
distribution point from the delta CRL.
A complete CRL and a delta CRL MAY be combined if the following four
conditions are satisfied:
(a) The complete CRL and delta CRL have the same issuer.
(b) The complete CRL and delta CRL have the same scope. The two
CRLs have the same scope if either of the following conditions are
met:
(1) The issuingDistributionPoint extension is omitted from
both the complete CRL and the delta CRL.
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(2) The issuingDistributionPoint extension is present in both
the complete CRL and the delta CRL, and the values for each of
the fields in the extensions are the same in both CRLs.
(c) The CRL number of the complete CRL is equal to or greater
than the BaseCRLNumber specified in the delta CRL. That is, the
complete CRL contains (at a minimum) all the revocation
information held by the referenced base CRL.
(d) The CRL number of the complete CRL is less than the CRL
number of the delta CRL. That is, the delta CRL follows the
complete CRL in the numbering sequence.
CRL issuers MUST ensure that the combination of a delta CRL and any
appropriate complete CRL accurately reflects the current revocation
status. The CRL issuer MUST include an entry in the delta CRL for
each certificate within the scope of the delta CRL whose status has
changed since the generation of the referenced base CRL:
(a) If the certificate is revoked for a reason included in the
scope of the CRL, list the certificate as revoked.
(b) If the certificate is valid and was listed on the referenced
base CRL or any subsequent CRL with reason code certificateHold,
and the reason code certificateHold is included in the scope of
the CRL, list the certificate with the reason code removeFromCRL.
(c) If the certificate is revoked for a reason outside the scope
of the CRL, but the certificate was listed on the referenced base
CRL or any subsequent CRL with a reason code included in the scope
of this CRL, list the certificate as revoked but omit the reason
code.
(d) If the certificate is revoked for a reason outside the scope
of the CRL and the certificate was neither listed on the
referenced base CRL nor any subsequent CRL with a reason code
included in the scope of this CRL, do not list the certificate on
this CRL.
The status of a certificate is considered to have changed if it is
revoked, placed on hold, released from hold, or if its revocation
reason changes.
It is appropriate to list a certificate with reason code
removeFromCRL on a delta CRL even if the certificate was not on hold
in the referenced base CRL. If the certificate was placed on hold in
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any CRL issued after the base but before this delta CRL and then
released from hold, it MUST be listed on the delta CRL with
revocation reason removeFromCRL.
A CRL issuer MAY optionally list a certificate on a delta CRL with
reason code removeFromCRL if the notAfter time specified in the
certificate precedes the thisUpdate time specified in the delta CRL
and the certificate was listed on the referenced base CRL or in any
CRL issued after the base but before this delta CRL.
If a certificate revocation notice first appears on a delta CRL, then
it is possible for the certificate validity period to expire before
the next complete CRL for the same scope is issued. In this case,
the revocation notice MUST be included in all subsequent delta CRLs
until the revocation notice is included on at least one explicitly
issued complete CRL for this scope.
An application that supports delta CRLs MUST be able to construct a
current complete CRL by combining a previously issued complete CRL
and the most current delta CRL. An application that supports delta
CRLs MAY also be able to construct a current complete CRL by
combining a previously locally constructed complete CRL and the
current delta CRL. A delta CRL is considered to be the current one
if the current time is between the times contained in the thisUpdate
and nextUpdate fields. Under some circumstances, the CRL issuer may
publish one or more delta CRLs before indicated by the nextUpdate
field. If more than one current delta CRL for a given scope is
encountered, the application SHOULD consider the one with the latest
value in thisUpdate to be the most current one.
The issuing distribution point is a critical CRL extension that
identifies the CRL distribution point and scope for a particular CRL,
and it indicates whether the CRL covers revocation for end entity
certificates only, CA certificates only, attribute certificates only,
or a limited set of reason codes. Although the extension is
critical, conforming implementations are not required to support this
extension.
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The CRL is signed using the CRL issuer's private key. CRL
Distribution Points do not have their own key pairs. If the CRL is
stored in the X.500 Directory, it is stored in the Directory entry
corresponding to the CRL distribution point, which may be different
than the Directory entry of the CRL issuer.
The reason codes associated with a distribution point MUST be
specified in onlySomeReasons. If onlySomeReasons does not appear,
the distribution point MUST contain revocations for all reason codes.
CAs may use CRL distribution points to partition the CRL on the basis
of compromise and routine revocation. In this case, the revocations
with reason code keyCompromise (1), cACompromise (2), and
aACompromise (8) appear in one distribution point, and the
revocations with other reason codes appear in another distribution
point.
If the distributionPoint field is present and contains a URI, the
following semantics MUST be assumed: the object is a pointer to the
most current CRL issued by this CRL issuer. The URI schemes ftp,
http, mailto [RFC1738] and ldap [RFC1778] are defined for this
purpose. The URI MUST be an absolute pathname, not a relative
pathname, and MUST specify the host.
If the distributionPoint field is absent, the CRL MUST contain
entries for all revoked unexpired certificates issued by the CRL
issuer, if any, within the scope of the CRL.
The CRL issuer MUST assert the indirectCRL boolean, if the scope of
the CRL includes certificates issued by authorities other than the
CRL issuer. The authority responsible for each entry is indicated by
the certificate issuer CRL entry extension (section 5.3.4).
5.2.6 Freshest CRL (a.k.a. Delta CRL Distribution Point)
The freshest CRL extension identifies how delta CRL information for
this complete CRL is obtained. The extension MUST be non-critical.
This extension MUST NOT appear in delta CRLs.
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The same syntax is used for this extension as the
cRLDistributionPoints certificate extension, and is described in
section 4.2.1.14. However, only the distribution point field is
meaningful in this context. The reasons and CRLIssuer fields MUST be
omitted from this CRL extension.
Each distribution point name provides the location at which a delta
CRL for this complete CRL can be found. The scope of these delta
CRLs MUST be the same as the scope of this complete CRL. The
contents of this CRL extension are only used to locate delta CRLs;
the contents are not used to validate the CRL or the referenced delta
CRLs. The encoding conventions defined for distribution points in
section 4.2.1.14 apply to this extension.
The CRL entry extensions defined by ISO/IEC, ITU-T, and ANSI X9 for
X.509 v2 CRLs provide methods for associating additional attributes
with CRL entries [X.509] [X9.55]. The X.509 v2 CRL format also
allows communities to define private CRL entry extensions to carry
information unique to those communities. Each extension in a CRL
entry may be designated as critical or non-critical. A CRL
validation MUST fail if it encounters a critical CRL entry extension
which it does not know how to process. However, an unrecognized non-
critical CRL entry extension may be ignored. The following
subsections present recommended extensions used within Internet CRL
entries and standard locations for information. Communities may
elect to use additional CRL entry extensions; however, caution should
be exercised in adopting any critical extensions in CRL entries which
might be used in a general context.
All CRL entry extensions used in this specification are non-critical.
Support for these extensions is optional for conforming CRL issuers
and applications. However, CRL issuers SHOULD include reason codes
(section 5.3.1) and invalidity dates (section 5.3.3) whenever this
information is available.
5.3.1 Reason Code
The reasonCode is a non-critical CRL entry extension that identifies
the reason for the certificate revocation. CRL issuers are strongly
encouraged to include meaningful reason codes in CRL entries;
however, the reason code CRL entry extension SHOULD be absent instead
of using the unspecified (0) reasonCode value.
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The hold instruction code is a non-critical CRL entry extension that
provides a registered instruction identifier which indicates the
action to be taken after encountering a certificate that has been
placed on hold.
Conforming applications which encounter an id-holdinstruction-
callissuer MUST call the certificate issuer or reject the
certificate. Conforming applications which encounter an id-
holdinstruction-reject MUST reject the certificate. The hold
instruction id-holdinstruction-none is semantically equivalent to the
absence of a holdInstructionCode, and its use is strongly deprecated
for the Internet PKI.
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5.3.3 Invalidity Date
The invalidity date is a non-critical CRL entry extension that
provides the date on which it is known or suspected that the private
key was compromised or that the certificate otherwise became invalid.
This date may be earlier than the revocation date in the CRL entry,
which is the date at which the CA processed the revocation. When a
revocation is first posted by a CRL issuer in a CRL, the invalidity
date may precede the date of issue of earlier CRLs, but the
revocation date SHOULD NOT precede the date of issue of earlier CRLs.
Whenever this information is available, CRL issuers are strongly
encouraged to share it with CRL users.
The GeneralizedTime values included in this field MUST be expressed
in Greenwich Mean Time (Zulu), and MUST be specified and interpreted
as defined in section 4.1.2.5.2.
This CRL entry extension identifies the certificate issuer associated
with an entry in an indirect CRL, that is, a CRL that has the
indirectCRL indicator set in its issuing distribution point
extension. If this extension is not present on the first entry in an
indirect CRL, the certificate issuer defaults to the CRL issuer. On
subsequent entries in an indirect CRL, if this extension is not
present, the certificate issuer for the entry is the same as that for
the preceding entry. This field is defined as follows:
If used by conforming CRL issuers, this extension MUST always be
critical. If an implementation ignored this extension it could not
correctly attribute CRL entries to certificates. This specification
RECOMMENDS that implementations recognize this extension.
6 Certification Path Validation
Certification path validation procedures for the Internet PKI are
based on the algorithm supplied in [X.509]. Certification path
processing verifies the binding between the subject distinguished
name and/or subject alternative name and subject public key. The
binding is limited by constraints which are specified in the
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certificates which comprise the path and inputs which are specified
by the relying party. The basic constraints and policy constraints
extensions allow the certification path processing logic to automate
the decision making process.
This section describes an algorithm for validating certification
paths. Conforming implementations of this specification are not
required to implement this algorithm, but MUST provide functionality
equivalent to the external behavior resulting from this procedure.
Any algorithm may be used by a particular implementation so long as
it derives the correct result.
In section 6.1, the text describes basic path validation. Valid
paths begin with certificates issued by a trust anchor. The
algorithm requires the public key of the CA, the CA's name, and any
constraints upon the set of paths which may be validated using this
key.
The selection of a trust anchor is a matter of policy: it could be
the top CA in a hierarchical PKI; the CA that issued the verifier's
own certificate(s); or any other CA in a network PKI. The path
validation procedure is the same regardless of the choice of trust
anchor. In addition, different applications may rely on different
trust anchor, or may accept paths that begin with any of a set of
trust anchor.
Section 6.2 describes methods for using the path validation algorithm
in specific implementations. Two specific cases are discussed: the
case where paths may begin with one of several trusted CAs; and where
compatibility with the PEM architecture is required.
Section 6.3 describes the steps necessary to determine if a
certificate is revoked or on hold status when CRLs are the revocation
mechanism used by the certificate issuer.
6.1 Basic Path Validation
This text describes an algorithm for X.509 path processing. A
conformant implementation MUST include an X.509 path processing
procedure that is functionally equivalent to the external behavior of
this algorithm. However, support for some of the certificate
extensions processed in this algorithm are OPTIONAL for compliant
implementations. Clients that do not support these extensions MAY
omit the corresponding steps in the path validation algorithm.
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For example, clients are NOT REQUIRED to support the policy mapping
extension. Clients that do not support this extension MAY omit the
path validation steps where policy mappings are processed. Note that
clients MUST reject the certificate if it contains an unsupported
critical extension.
The algorithm presented in this section validates the certificate
with respect to the current date and time. A conformant
implementation MAY also support validation with respect to some point
in the past. Note that mechanisms are not available for validating a
certificate with respect to a time outside the certificate validity
period.
The trust anchor is an input to the algorithm. There is no
requirement that the same trust anchor be used to validate all
certification paths. Different trust anchors MAY be used to validate
different paths, as discussed further in Section 6.2.
The primary goal of path validation is to verify the binding between
a subject distinguished name or a subject alternative name and
subject public key, as represented in the end entity certificate,
based on the public key of the trust anchor. This requires obtaining
a sequence of certificates that support that binding. The procedure
performed to obtain this sequence of certificates is outside the
scope of this specification.
To meet this goal, the path validation process verifies, among other
things, that a prospective certification path (a sequence of n
certificates) satisfies the following conditions:
(a) for all x in {1, ..., n-1}, the subject of certificate x is
the issuer of certificate x+1;
(b) certificate 1 is issued by the trust anchor;
(c) certificate n is the certificate to be validated; and
(d) for all x in {1, ..., n}, the certificate was valid at the
time in question.
When the trust anchor is provided in the form of a self-signed
certificate, this self-signed certificate is not included as part of
the prospective certification path. Information about trust anchors
are provided as inputs to the certification path validation algorithm
(section 6.1.1).
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A particular certification path may not, however, be appropriate for
all applications. Therefore, an application MAY augment this
algorithm to further limit the set of valid paths. The path
validation process also determines the set of certificate policies
that are valid for this path, based on the certificate policies
extension, policy mapping extension, policy constraints extension,
and inhibit any-policy extension. To achieve this, the path
validation algorithm constructs a valid policy tree. If the set of
certificate policies that are valid for this path is not empty, then
the result will be a valid policy tree of depth n, otherwise the
result will be a null valid policy tree.
A certificate is self-issued if the DNs that appear in the subject
and issuer fields are identical and are not empty. In general, the
issuer and subject of the certificates that make up a path are
different for each certificate. However, a CA may issue a
certificate to itself to support key rollover or changes in
certificate policies. These self-issued certificates are not counted
when evaluating path length or name constraints.
This section presents the algorithm in four basic steps: (1)
initialization, (2) basic certificate processing, (3) preparation for
the next certificate, and (4) wrap-up. Steps (1) and (4) are
performed exactly once. Step (2) is performed for all certificates
in the path. Step (3) is performed for all certificates in the path
except the final certificate. Figure 2 provides a high-level
flowchart of this algorithm.
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+-------+
| START |
+-------+
|
V
+----------------+
| Initialization |
+----------------+
|
+<--------------------+
| |
V |
+----------------+ |
| Process Cert | |
+----------------+ |
| |
V |
+================+ |
| IF Last Cert | |
| in Path | |
+================+ |
| | |
THEN | | ELSE |
V V |
+----------------+ +----------------+ |
| Wrap up | | Prepare for | |
+----------------+ | Next Cert | |
| +----------------+ |
V | |
+-------+ +--------------+
| STOP |
+-------+
Figure 2. Certification Path Processing Flowchart
6.1.1 Inputs
This algorithm assumes the following seven inputs are provided to the
path processing logic:
(a) a prospective certification path of length n.
(b) the current date/time.
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(c) user-initial-policy-set: A set of certificate policy
identifiers naming the policies that are acceptable to the
certificate user. The user-initial-policy-set contains the
special value any-policy if the user is not concerned about
certificate policy.
(d) trust anchor information, describing a CA that serves as a
trust anchor for the certification path. The trust anchor
information includes:
(1) the trusted issuer name,
(2) the trusted public key algorithm,
(3) the trusted public key, and
(4) optionally, the trusted public key parameters associated
with the public key.
The trust anchor information may be provided to the path
processing procedure in the form of a self-signed certificate.
The trusted anchor information is trusted because it was delivered
to the path processing procedure by some trustworthy out-of-band
procedure. If the trusted public key algorithm requires
parameters, then the parameters are provided along with the
trusted public key.
(e) initial-policy-mapping-inhibit, which indicates if policy
mapping is allowed in the certification path.
(f) initial-explicit-policy, which indicates if the path must be
valid for at least one of the certificate policies in the user-
initial-policy-set.
(g) initial-any-policy-inhibit, which indicates whether the
anyPolicy OID should be processed if it is included in a
certificate.
6.1.2 Initialization
This initialization phase establishes eleven state variables based
upon the seven inputs:
(a) valid_policy_tree: A tree of certificate policies with their
optional qualifiers; each of the leaves of the tree represents a
valid policy at this stage in the certification path validation.
If valid policies exist at this stage in the certification path
validation, the depth of the tree is equal to the number of
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certificates in the chain that have been processed. If valid
policies do not exist at this stage in the certification path
validation, the tree is set to NULL. Once the tree is set to
NULL, policy processing ceases.
Each node in the valid_policy_tree includes four data objects: the
valid policy, a set of associated policy qualifiers, a set of one
or more expected policy values, and a criticality indicator. If
the node is at depth x, the components of the node have the
following semantics:
(1) The valid_policy is a single policy OID representing a
valid policy for the path of length x.
(2) The qualifier_set is a set of policy qualifiers associated
with the valid policy in certificate x.
(3) The criticality_indicator indicates whether the
certificate policy extension in certificate x was marked as
critical.
(4) The expected_policy_set contains one or more policy OIDs
that would satisfy this policy in the certificate x+1.
The initial value of the valid_policy_tree is a single node with
valid_policy anyPolicy, an empty qualifier_set, an
expected_policy_set with the single value anyPolicy, and a
criticality_indicator of FALSE. This node is considered to be at
depth zero.
Figure 3 is a graphic representation of the initial state of the
valid_policy_tree. Additional figures will use this format to
describe changes in the valid_policy_tree during path processing.
Figure 3. Initial value of the valid_policy_tree state variable
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(b) permitted_subtrees: A set of root names for each name type
(e.g., X.500 distinguished names, email addresses, or ip
addresses) defining a set of subtrees within which all subject
names in subsequent certificates in the certification path MUST
fall. This variable includes a set for each name type: the
initial value for the set for Distinguished Names is the set of
all Distinguished names; the initial value for the set of RFC822
names is the set of all RFC822 names, etc.
(c) excluded_subtrees: A set of root names for each name type
(e.g., X.500 distinguished names, email addresses, or ip
addresses) defining a set of subtrees within which no subject name
in subsequent certificates in the certification path may fall.
This variable includes a set for each name type, and the initial
value for each set is empty.
(d) explicit_policy: an integer which indicates if a non-NULL
valid_policy_tree is required. The integer indicates the number of
non-self-issued certificates to be processed before this
requirement is imposed. Once set, this variable may be decreased,
but may not be increased. That is, if a certificate in the path
requires a non-NULL valid_policy_tree, a later certificate can not
remove this requirement. If initial-explicit-policy is set, then
the initial value is 0, otherwise the initial value is n+1.
(e) inhibit_any-policy: an integer which indicates whether the
anyPolicy policy identifier is considered a match. The integer
indicates the number of non-self-issued certificates to be
processed before the anyPolicy OID, if asserted in a certificate,
is ignored. Once set, this variable may be decreased, but may not
be increased. That is, if a certificate in the path inhibits
processing of anyPolicy, a later certificate can not permit it.
If initial-any-policy-inhibit is set, then the initial value is 0,
otherwise the initial value is n+1.
(f) policy_mapping: an integer which indicates if policy mapping
is permitted. The integer indicates the number of non-self-issued
certificates to be processed before policy mapping is inhibited.
Once set, this variable may be decreased, but may not be
increased. That is, if a certificate in the path specifies policy
mapping is not permitted, it can not be overridden by a later
certificate. If initial-policy-mapping-inhibit is set, then the
initial value is 0, otherwise the initial value is n+1.
(g) working_public_key_algorithm: the digital signature algorithm
used to verify the signature of a certificate. The
working_public_key_algorithm is initialized from the trusted
public key algorithm provided in the trust anchor information.
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(h) working_public_key: the public key used to verify the
signature of a certificate. The working_public_key is initialized
from the trusted public key provided in the trust anchor
information.
(i) working_public_key_parameters: parameters associated with the
current public key, that may be required to verify a signature
(depending upon the algorithm). The working_public_key_parameters
variable is initialized from the trusted public key parameters
provided in the trust anchor information.
(j) working_issuer_name: the issuer distinguished name expected
in the next certificate in the chain. The working_issuer_name is
initialized to the trusted issuer provided in the trust anchor
information.
(k) max_path_length: this integer is initialized to n, is
decremented for each non-self-issued certificate in the path, and
may be reduced to the value in the path length constraint field
within the basic constraints extension of a CA certificate.
Upon completion of the initialization steps, perform the basic
certificate processing steps specified in 6.1.3.
6.1.3 Basic Certificate Processing
The basic path processing actions to be performed for certificate i
(for all i in [1..n]) are listed below.
(a) Verify the basic certificate information. The certificate
MUST satisfy each of the following:
(1) The certificate was signed with the
working_public_key_algorithm using the working_public_key and
the working_public_key_parameters.
(2) The certificate validity period includes the current time.
(3) At the current time, the certificate is not revoked and is
not on hold status. This may be determined by obtaining the
appropriate CRL (section 6.3), status information, or by out-
of-band mechanisms.
(4) The certificate issuer name is the working_issuer_name.
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(b) If certificate i is self-issued and it is not the final
certificate in the path, skip this step for certificate i.
Otherwise, verify that the subject name is within one of the
permitted_subtrees for X.500 distinguished names, and verify that
each of the alternative names in the subjectAltName extension
(critical or non-critical) is within one of the permitted_subtrees
for that name type.
(c) If certificate i is self-issued and it is not the final
certificate in the path, skip this step for certificate i.
Otherwise, verify that the subject name is not within one of the
excluded_subtrees for X.500 distinguished names, and verify that
each of the alternative names in the subjectAltName extension
(critical or non-critical) is not within one of the
excluded_subtrees for that name type.
(d) If the certificate policies extension is present in the
certificate and the valid_policy_tree is not NULL, process the
policy information by performing the following steps in order:
(1) For each policy P not equal to anyPolicy in the
certificate policies extension, let P-OID denote the OID in
policy P and P-Q denote the qualifier set for policy P.
Perform the following steps in order:
(i) If the valid_policy_tree includes a node of depth i-1
where P-OID is in the expected_policy_set, create a child
node as follows: set the valid_policy to OID-P; set the
qualifier_set to P-Q, and set the expected_policy_set to
{P-OID}.
For example, consider a valid_policy_tree with a node of
depth i-1 where the expected_policy_set is {Gold, White}.
Assume the certificate policies Gold and Silver appear in
the certificate policies extension of certificate i. The
Gold policy is matched but the Silver policy is not. This
rule will generate a child node of depth i for the Gold
policy. The result is shown as Figure 4.
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+-----------------+
| Red |
+-----------------+
| {} |
+-----------------+ node of depth i-1
| FALSE |
+-----------------+
| {Gold, White} |
+-----------------+
|
|
|
V
+-----------------+
| Gold |
+-----------------+
| {} |
+-----------------+ node of depth i
| uninitialized |
+-----------------+
| {Gold} |
+-----------------+
Figure 4. Processing an exact match
(ii) If there was no match in step (i) and the
valid_policy_tree includes a node of depth i-1 with the
valid policy anyPolicy, generate a child node with the
following values: set the valid_policy to P-OID; set the
qualifier_set to P-Q, and set the expected_policy_set to
{P-OID}.
For example, consider a valid_policy_tree with a node of
depth i-1 where the valid_policy is anyPolicy. Assume the
certificate policies Gold and Silver appear in the
certificate policies extension of certificate i. The Gold
policy does not have a qualifier, but the Silver policy has
the qualifier Q-Silver. If Gold and Silver were not matched
in (i) above, this rule will generate two child nodes of
depth i, one for each policy. The result is shown as Figure
5.
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Figure 5. Processing unmatched policies when a leaf node
specifies anyPolicy
(2) If the certificate policies extension includes the policy
anyPolicy with the qualifier set AP-Q and either (a)
inhibit_any-policy is greater than 0 or (b) i<n and the
certificate is self-issued, then:
For each node in the valid_policy_tree of depth i-1, for each
value in the expected_policy_set (including anyPolicy) that
does not appear in a child node, create a child node with the
following values: set the valid_policy to the value from the
expected_policy_set in the parent node; set the qualifier_set
to AP-Q, and set the expected_policy_set to the value in the
valid_policy from this node.
For example, consider a valid_policy_tree with a node of depth
i-1 where the expected_policy_set is {Gold, Silver}. Assume
anyPolicy appears in the certificate policies extension of
certificate i, but Gold and Silver do not. This rule will
generate two child nodes of depth i, one for each policy. The
result is shown below as Figure 6.
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Figure 6. Processing unmatched policies when the certificate
policies extension specifies anyPolicy
(3) If there is a node in the valid_policy_tree of depth i-1
or less without any child nodes, delete that node. Repeat this
step until there are no nodes of depth i-1 or less without
children.
For example, consider the valid_policy_tree shown in Figure 7
below. The two nodes at depth i-1 that are marked with an 'X'
have no children, and are deleted. Applying this rule to the
resulting tree will cause the node at depth i-2 that is marked
with an 'Y' to be deleted. The following application of the
rule does not cause any nodes to be deleted, and this step is
complete.
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(4) If the certificate policies extension was marked as
critical, set the criticality_indicator in all nodes of depth i
to TRUE. If the certificate policies extension was not marked
critical, set the criticality_indicator in all nodes of depth i
to FALSE.
(e) If the certificate policies extension is not present, set the
valid_policy_tree to NULL.
(f) Verify that either explicit_policy is greater than 0 or the
valid_policy_tree is not equal to NULL;
If any of steps (a), (b), (c), or (f) fails, the procedure
terminates, returning a failure indication and an appropriate reason.
If i is not equal to n, continue by performing the preparatory steps
listed in 6.1.4. If i is equal to n, perform the wrap-up steps
listed in 6.1.5.
6.1.4 Preparation for Certificate i+1
To prepare for processing of certificate i+1, perform the following
steps for certificate i:
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(a) If a policy mapping extension is present, verify that the
special value anyPolicy does not appear as an issuerDomainPolicy
or a subjectDomainPolicy.
(b) If a policy mapping extension is present, then for each
issuerDomainPolicy ID-P in the policy mapping extension:
(1) If the policy_mapping variable is greater than 0, for each
node in the valid_policy_tree of depth i where ID-P is the
valid_policy, set expected_policy_set to the set of
subjectDomainPolicy values that are specified as equivalent to
ID-P by the policy mapping extension.
If no node of depth i in the valid_policy_tree has a
valid_policy of ID-P but there is a node of depth i with a
valid_policy of anyPolicy, then generate a child node of the
node of depth i-1 that has a valid_policy of anyPolicy as
follows:
(i) set the valid_policy to ID-P;
(ii) set the qualifier_set to the qualifier set of the
policy anyPolicy in the certificate policies extension of
certificate i;
(iii) set the criticality_indicator to the criticality of
the certificate policies extension of certificate i;
(iv) and set the expected_policy_set to the set of
subjectDomainPolicy values that are specified as equivalent
to ID-P by the policy mappings extension.
(2) If the policy_mapping variable is equal to 0:
(i) delete each node of depth i in the valid_policy_tree
where ID-P is the valid_policy.
(ii) If there is a node in the valid_policy_tree of depth
i-1 or less without any child nodes, delete that node.
Repeat this step until there are no nodes of depth i-1 or
less without children.
(c) Assign the certificate subject name to working_issuer_name.
(d) Assign the certificate subjectPublicKey to
working_public_key.
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(e) If the subjectPublicKeyInfo field of the certificate contains
an algorithm field with non-null parameters, assign the parameters
to the working_public_key_parameters variable.
If the subjectPublicKeyInfo field of the certificate contains an
algorithm field with null parameters or parameters are omitted,
compare the certificate subjectPublicKey algorithm to the
working_public_key_algorithm. If the certificate subjectPublicKey
algorithm and the working_public_key_algorithm are different, set
the working_public_key_parameters to null.
(f) Assign the certificate subjectPublicKey algorithm to the
working_public_key_algorithm variable.
(g) If a name constraints extension is included in the
certificate, modify the permitted_subtrees and excluded_subtrees
state variables as follows:
(1) If permittedSubtrees is present in the certificate, set
the permitted_subtrees state variable to the intersection of
its previous value and the value indicated in the extension
field. If permittedSubtrees does not include a particular name
type, the permitted_subtrees state variable is unchanged for
that name type. For example, the intersection of nist.gov and
csrc.nist.gov is csrc.nist.gov. And, the intersection of
nist.gov and rsasecurity.com is the empty set.
(2) If excludedSubtrees is present in the certificate, set the
excluded_subtrees state variable to the union of its previous
value and the value indicated in the extension field. If
excludedSubtrees does not include a particular name type, the
excluded_subtrees state variable is unchanged for that name
type. For example, the union of the name spaces nist.gov and
csrc.nist.gov is nist.gov. And, the union of nist.gov and
rsasecurity.com is both name spaces.
(h) If the issuer and subject names are not identical:
(1) If explicit_policy is not 0, decrement explicit_policy by
1.
(2) If policy_mapping is not 0, decrement policy_mapping by 1.
(3) If inhibit_any-policy is not 0, decrement inhibit_any-
policy by 1.
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(i) If a policy constraints extension is included in the
certificate, modify the explicit_policy and policy_mapping state
variables as follows:
(1) If requireExplicitPolicy is present and is less than
explicit_policy, set explicit_policy to the value of
requireExplicitPolicy.
(2) If inhibitPolicyMapping is present and is less than
policy_mapping, set policy_mapping to the value of
inhibitPolicyMapping.
(j) If the inhibitAnyPolicy extension is included in the
certificate and is less than inhibit_any-policy, set inhibit_any-
policy to the value of inhibitAnyPolicy.
(k) Verify that the certificate is a CA certificate (as specified
in a basicConstraints extension or as verified out-of-band).
(l) If the certificate was not self-issued, verify that
max_path_length is greater than zero and decrement max_path_length
by 1.
(m) If pathLengthConstraint is present in the certificate and is
less than max_path_length, set max_path_length to the value of
pathLengthConstraint.
(n) If a key usage extension is present, verify that the
keyCertSign bit is set.
(o) Recognize and process any other critical extension present in
the certificate. Process any other recognized non-critical
extension present in the certificate.
If check (a), (k), (l), (n) or (o) fails, the procedure terminates,
returning a failure indication and an appropriate reason.
If (a), (k), (l), (n) and (o) have completed successfully, increment
i and perform the basic certificate processing specified in 6.1.3.
6.1.5 Wrap-up procedure
To complete the processing of the end entity certificate, perform the
following steps for certificate n:
(a) If certificate n was not self-issued and explicit_policy is
not 0, decrement explicit_policy by 1.
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(b) If a policy constraints extension is included in the
certificate and requireExplicitPolicy is present and has a value
of 0, set the explicit_policy state variable to 0.
(c) Assign the certificate subjectPublicKey to
working_public_key.
(d) If the subjectPublicKeyInfo field of the certificate contains
an algorithm field with non-null parameters, assign the parameters
to the working_public_key_parameters variable.
If the subjectPublicKeyInfo field of the certificate contains an
algorithm field with null parameters or parameters are omitted,
compare the certificate subjectPublicKey algorithm to the
working_public_key_algorithm. If the certificate subjectPublicKey
algorithm and the working_public_key_algorithm are different, set
the working_public_key_parameters to null.
(e) Assign the certificate subjectPublicKey algorithm to the
working_public_key_algorithm variable.
(f) Recognize and process any other critical extension present in
the certificate n. Process any other recognized non-critical
extension present in certificate n.
(g) Calculate the intersection of the valid_policy_tree and the
user-initial-policy-set, as follows:
(i) If the valid_policy_tree is NULL, the intersection is
NULL.
(ii) If the valid_policy_tree is not NULL and the user-
initial-policy-set is any-policy, the intersection is the
entire valid_policy_tree.
(iii) If the valid_policy_tree is not NULL and the user-
initial-policy-set is not any-policy, calculate the
intersection of the valid_policy_tree and the user-initial-
policy-set as follows:
1. Determine the set of policy nodes whose parent nodes
have a valid_policy of anyPolicy. This is the
valid_policy_node_set.
2. If the valid_policy of any node in the
valid_policy_node_set is not in the user-initial-policy-set
and is not anyPolicy, delete this node and all its children.
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3. If the valid_policy_tree includes a node of depth n with
the valid_policy anyPolicy and the user-initial-policy-set
is not any-policy perform the following steps:
a. Set P-Q to the qualifier_set in the node of depth n
with valid_policy anyPolicy.
b. For each P-OID in the user-initial-policy-set that is
not the valid_policy of a node in the
valid_policy_node_set, create a child node whose parent
is the node of depth n-1 with the valid_policy anyPolicy.
Set the values in the child node as follows: set the
valid_policy to P-OID; set the qualifier_set to P-Q; copy
the criticality_indicator from the node of depth n with
the valid_policy anyPolicy; and set the
expected_policy_set to {P-OID}.
c. Delete the node of depth n with the valid_policy
anyPolicy.
4. If there is a node in the valid_policy_tree of depth n-1
or less without any child nodes, delete that node. Repeat
this step until there are no nodes of depth n-1 or less
without children.
If either (1) the value of explicit_policy variable is greater than
zero, or (2) the valid_policy_tree is not NULL, then path processing
has succeeded.
6.1.6 Outputs
If path processing succeeds, the procedure terminates, returning a
success indication together with final value of the
valid_policy_tree, the working_public_key, the
working_public_key_algorithm, and the working_public_key_parameters.
6.2 Using the Path Validation Algorithm
The path validation algorithm describes the process of validating a
single certification path. While each certification path begins with
a specific trust anchor, there is no requirement that all
certification paths validated by a particular system share a single
trust anchor. An implementation that supports multiple trust anchors
MAY augment the algorithm presented in section 6.1 to further limit
the set of valid certification paths which begin with a particular
trust anchor. For example, an implementation MAY modify the
algorithm to apply name constraints to a specific trust anchor during
the initialization phase, or the application MAY require the presence
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of a particular alternative name form in the end entity certificate,
or the application MAY impose requirements on application-specific
extensions. Thus, the path validation algorithm presented in section
6.1 defines the minimum conditions for a path to be considered valid.
The selection of one or more trusted CAs is a local decision. A
system may provide any one of its trusted CAs as the trust anchor for
a particular path. The inputs to the path validation algorithm may
be different for each path. The inputs used to process a path may
reflect application-specific requirements or limitations in the trust
accorded a particular trust anchor. For example, a trusted CA may
only be trusted for a particular certificate policy. This
restriction can be expressed through the inputs to the path
validation procedure.
It is also possible to specify an extended version of the above
certification path processing procedure which results in default
behavior identical to the rules of PEM [RFC 1422]. In this extended
version, additional inputs to the procedure are a list of one or more
Policy Certification Authority (PCA) names and an indicator of the
position in the certification path where the PCA is expected. At the
nominated PCA position, the CA name is compared against this list.
If a recognized PCA name is found, then a constraint of
SubordinateToCA is implicitly assumed for the remainder of the
certification path and processing continues. If no valid PCA name is
found, and if the certification path cannot be validated on the basis
of identified policies, then the certification path is considered
invalid.
6.3 CRL Validation
This section describes the steps necessary to determine if a
certificate is revoked or on hold status when CRLs are the revocation
mechanism used by the certificate issuer. Conforming implementations
that support CRLs are not required to implement this algorithm, but
they MUST be functionally equivalent to the external behavior
resulting from this procedure. Any algorithm may be used by a
particular implementation so long as it derives the correct result.
This algorithm assumes that all of the needed CRLs are available in a
local cache. Further, if the next update time of a CRL has passed,
the algorithm assumes a mechanism to fetch a current CRL and place it
in the local CRL cache.
This algorithm defines a set of inputs, a set of state variables, and
processing steps that are performed for each certificate in the path.
The algorithm output is the revocation status of the certificate.
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6.3.1 Revocation Inputs
To support revocation processing, the algorithm requires two inputs:
(a) certificate: The algorithm requires the certificate serial
number and issuer name to determine whether a certificate is on a
particular CRL. The basicConstraints extension is used to
determine whether the supplied certificate is associated with a CA
or an end entity. If present, the algorithm uses the
cRLDistributionsPoint and freshestCRL extensions to determine
revocation status.
(b) use-deltas: This boolean input determines whether delta CRLs
are applied to CRLs.
Note that implementations supporting legacy PKIs, such as RFC 1422
and X.509 version 1, will need an additional input indicating
whether the supplied certificate is associated with a CA or an end
entity.
6.3.2 Initialization and Revocation State Variables
To support CRL processing, the algorithm requires the following state
variables:
(a) reasons_mask: This variable contains the set of revocation
reasons supported by the CRLs and delta CRLs processed so far.
The legal members of the set are the possible revocation reason
values: unspecified, keyCompromise, caCompromise,
affiliationChanged, superseded, cessationOfOperation,
certificateHold, privilegeWithdrawn, and aACompromise. The
special value all-reasons is used to denote the set of all legal
members. This variable is initialized to the empty set.
(b) cert_status: This variable contains the status of the
certificate. This variable may be assigned one of the following
values: unspecified, keyCompromise, caCompromise,
affiliationChanged, superseded, cessationOfOperation,
certificateHold, removeFromCRL, privilegeWithdrawn, aACompromise,
the special value UNREVOKED, or the special value UNDETERMINED.
This variable is initialized to the special value UNREVOKED.
(c) interim_reasons_mask: This contains the set of revocation
reasons supported by the CRL or delta CRL currently being
processed.
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Note: In some environments, it is not necessary to check all reason
codes. For example, some environments are only concerned with
caCompromise and keyCompromise for CA certificates. This algorithm
checks all reason codes. Additional processing and state variables
may be necessary to limit the checking to a subset of the reason
codes.
6.3.3 CRL Processing
This algorithm begins by assuming the certificate is not revoked.
The algorithm checks one or more CRLs until either the certificate
status is determined to be revoked or sufficient CRLs have been
checked to cover all reason codes.
For each distribution point (DP) in the certificate CRL distribution
points extension, for each corresponding CRL in the local CRL cache,
while ((reasons_mask is not all-reasons) and (cert_status is
UNREVOKED)) perform the following:
(a) Update the local CRL cache by obtaining a complete CRL, a
delta CRL, or both, as required:
(1) If the current time is after the value of the CRL next
update field, then do one of the following:
(i) If use-deltas is set and either the certificate or the
CRL contains the freshest CRL extension, obtain a delta CRL
with the a next update value that is after the current time
and can be used to update the locally cached CRL as
specified in section 5.2.4.
(ii) Update the local CRL cache with a current complete
CRL, verify that the current time is before the next update
value in the new CRL, and continue processing with the new
CRL. If use-deltas is set, then obtain the current delta
CRL that can be used to update the new locally cached
complete CRL as specified in section 5.2.4.
(2) If the current time is before the value of the next update
field and use-deltas is set, then obtain the current delta CRL
that can be used to update the locally cached complete CRL as
specified in section 5.2.4.
(b) Verify the issuer and scope of the complete CRL as follows:
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(1) If the DP includes cRLIssuer, then verify that the issuer
field in the complete CRL matches cRLIssuer in the DP and that
the complete CRL contains an issuing distribution point
extension with the indrectCRL boolean asserted. Otherwise,
verify that the CRL issuer matches the certificate issuer.
(2) If the complete CRL includes an issuing distribution point
(IDP) CRL extension check the following:
(i) If the distribution point name is present in the IDP
CRL extension and the distribution field is present in the
DP, then verify that one of the names in the IDP matches one
of the names in the DP. If the distribution point name is
present in the IDP CRL extension and the distribution field
is omitted from the DP, then verify that one of the names in
the IDP matches one of the names in the cRLIssuer field of
the DP.
(ii) If the onlyContainsUserCerts boolean is asserted in
the IDP CRL extension, verify that the certificate does not
include the basic constraints extension with the cA boolean
asserted.
(iii) If the onlyContainsCACerts boolean is asserted in the
IDP CRL extension, verify that the certificate includes the
basic constraints extension with the cA boolean asserted.
(iv) Verify that the onlyContainsAttributeCerts boolean is
not asserted.
(c) If use-deltas is set, verify the issuer and scope of the
delta CRL as follows:
(1) Verify that the delta CRL issuer matches complete CRL
issuer.
(2) If the complete CRL includes an issuing distribution point
(IDP) CRL extension, verify that the delta CRL contains a
matching IDP CRL extension. If the complete CRL omits an IDP
CRL extension, verify that the delta CRL also omits an IDP CRL
extension.
(3) Verify that the delta CRL authority key identifier
extension matches complete CRL authority key identifier
extension.
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(d) Compute the interim_reasons_mask for this CRL as follows:
(1) If the issuing distribution point (IDP) CRL extension is
present and includes onlySomeReasons and the DP includes
reasons, then set interim_reasons_mask to the intersection of
reasons in the DP and onlySomeReasons in IDP CRL extension.
(2) If the IDP CRL extension includes onlySomeReasons but the
DP omits reasons, then set interim_reasons_mask to the value of
onlySomeReasons in IDP CRL extension.
(3) If the IDP CRL extension is not present or omits
onlySomeReasons but the DP includes reasons, then set
interim_reasons_mask to the value of DP reasons.
(4) If the IDP CRL extension is not present or omits
onlySomeReasons and the DP omits reasons, then set
interim_reasons_mask to the special value all-reasons.
(e) Verify that interim_reasons_mask includes one or more reasons
that is not included in the reasons_mask.
(f) Obtain and validate the certification path for the complete CRL
issuer. If a key usage extension is present in the CRL issuer's
certificate, verify that the cRLSign bit is set.
(g) Validate the signature on the complete CRL using the public key
validated in step (f).
(h) If use-deltas is set, then validate the signature on the delta
CRL using the public key validated in step (f).
(i) If use-deltas is set, then search for the certificate on the
delta CRL. If an entry is found that matches the certificate issuer
and serial number as described in section 5.3.4, then set the
cert_status variable to the indicated reason as follows:
(1) If the reason code CRL entry extension is present, set the
cert_status variable to the value of the reason code CRL entry
extension.
(2) If the reason code CRL entry extension is not present, set
the cert_status variable to the value unspecified.
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(j) If (cert_status is UNREVOKED), then search for the
certificate on the complete CRL. If an entry is found that
matches the certificate issuer and serial number as described in
section 5.3.4, then set the cert_status variable to the indicated
reason as described in step (i).
(k) If (cert_status is removeFromCRL), then set cert_status to
UNREVOKED.
If ((reasons_mask is all-reasons) OR (cert_status is not UNREVOKED)),
then the revocation status has been determined, so return
cert_status.
If the revocation status has not been determined, repeat the process
above with any available CRLs not specified in a distribution point
but issued by the certificate issuer. For the processing of such a
CRL, assume a DP with both the reasons and the cRLIssuer fields
omitted and a distribution point name of the certificate issuer.
That is, the sequence of names in fullName is generated from the
certificate issuer field as well as the certificate issuerAltName
extension. If the revocation status remains undetermined, then
return the cert_status UNDETERMINED.
7 References
[ISO 10646] ISO/IEC 10646-1:1993. International Standard --
Information technology -- Universal Multiple-Octet Coded
Character Set (UCS) -- Part 1: Architecture and Basic
Multilingual Plane.
[RFC 822] Crocker, D., "Standard for the format of ARPA Internet
text messages", STD 11, RFC 822, August 1982.
[RFC 1034] Mockapetris, P., "Domain Names - Concepts and
Facilities", STD 13, RFC 1034, November 1987.
[RFC 1422] Kent, S., "Privacy Enhancement for Internet Electronic
Mail: Part II: Certificate-Based Key Management," RFC
1422, February 1993.
[RFC 1423] Balenson, D., "Privacy Enhancement for Internet
Electronic Mail: Part III: Algorithms, Modes, and
Identifiers," RFC 1423, February 1993.
Housley, et. al. Standards Track [Page 86]
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
[RFC 1510] Kohl, J. and C. Neuman, "The Kerberos Network
Authentication Service (V5)," RFC 1510, September 1993.
[RFC 1519] Fuller, V., T. Li, J. Yu and K. Varadhan, "Classless
Inter-Domain Routing (CIDR): An Address Assignment and
Aggregation Strategy", RFC 1519, September 1993.
[RFC 1738] Berners-Lee, T., L. Masinter and M. McCahill, "Uniform
Resource Locators (URL)", RFC 1738, December 1994.
[RFC 1778] Howes, T., S. Kille, W. Yeong and C. Robbins, "The String
Representation of Standard Attribute Syntaxes," RFC 1778,
March 1995.
[RFC 1883] Deering, S. and R. Hinden. "Internet Protocol, Version 6
(IPv6) Specification", RFC 1883, December 1995.
[RFC 2044] F. Yergeau, F., "UTF-8, a transformation format of
Unicode and ISO 10646", RFC 2044, October 1996.
[RFC 2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC 2247] Kille, S., M. Wahl, A. Grimstad, R. Huber and S.
Sataluri, "Using Domains in LDAP/X.500 Distinguished
Names", RFC 2247, January 1998.
[RFC 2252] Wahl, M., A. Coulbeck, T. Howes and S. Kille,
"Lightweight Directory Access Protocol (v3): Attribute
Syntax Definitions", RFC 2252, December 1997.
[RFC 2277] Alvestrand, H., "IETF Policy on Character Sets and
Languages", BCP 18, RFC 2277, January 1998.
[RFC 2279] Yergeau, F., "UTF-8, a transformation format of ISO
10646", RFC 2279, January 1998.
[RFC 2459] Housley, R., W. Ford, W. Polk and D. Solo, "Internet
X.509 Public Key Infrastructure: Certificate and CRL
Profile", RFC 2459, January 1999.
[RFC 2560] Myers, M., R. Ankney, A. Malpani, S. Galperin and C.
Adams, "Online Certificate Status Protocal - OCSP", June
1999.
[SDN.701] SDN.701, "Message Security Protocol 4.0", Revision A,
1997-02-06.
Housley, et. al. Standards Track [Page 87]
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
[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.520] ITU-T Recommendation X.520: Information Technology - Open
Systems Interconnection - The Directory: Selected
Attribute Types, 1993.
[X.660] ITU-T Recommendation X.660 Information Technology - ASN.1
encoding rules: Specification of Basic Encoding Rules
(BER), Canonical Encoding Rules (CER) and Distinguished
Encoding Rules (DER), 1997.
[X.690] ITU-T Recommendation X.690 Information Technology - Open
Systems Interconnection - Procedures for the operation of
OSI Registration Authorities: General procedures, 1992.
[X9.55] ANSI X9.55-1995, Public Key Cryptography For The
Financial Services Industry: Extensions To Public Key
Certificates And Certificate Revocation Lists, 8
December, 1995.
[PKIXALGS] Bassham, L., Polk, W. and R. Housley, "Algorithms and
Identifiers for the Internet X.509 Public Key
Infrastructure Certificate and Certificate Revocation
Lists (CRL) Profile", RFC 3279, April 2002.
[PKIXTSA] Adams, C., Cain, P., Pinkas, D. and R. Zuccherato,
"Internet X.509 Public Key Infrastructure Time-Stamp
Protocol (TSP)", RFC 3161, August 2001.
8 Intellectual Property Rights
The IETF has been notified of intellectual property rights claimed in
regard to some or all of the specification contained in this
document. For more information consult the online list of claimed
rights (see http://www.ietf.org/ipr.html).
The IETF takes no position regarding the validity or scope of any
intellectual property or other rights that might be claimed to
pertain to the implementation or use of the technology described in
this document or the extent to which any license under such rights
might or might not be available; neither does it represent that it
has made any effort to identify any such rights. Information on the
IETF's procedures with respect to rights in standards-track and
Housley, et. al. Standards Track [Page 88]
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
standards-related documentation can be found in BCP 11. Copies of
claims of rights made available for publication and any assurances of
licenses to be made available, or the result of an attempt made to
obtain a general license or permission for the use of such
proprietary rights by implementors or users of this specification can
be obtained from the IETF Secretariat.
9 Security Considerations
The majority of this specification is devoted to the format and
content of certificates and CRLs. Since certificates and CRLs are
digitally signed, no additional integrity service is necessary.
Neither certificates nor CRLs need be kept secret, and unrestricted
and anonymous access to certificates and CRLs has no security
implications.
However, security factors outside the scope of this specification
will affect the assurance provided to certificate users. This
section highlights critical issues to be considered by implementers,
administrators, and users.
The procedures performed by CAs and RAs to validate the binding of
the subject's identity to their public key greatly affect the
assurance that ought to be placed in the certificate. Relying
parties might wish to review the CA's certificate practice statement.
This is particularly important when issuing certificates to other
CAs.
The use of a single key pair for both signature and other purposes is
strongly discouraged. Use of separate key pairs for signature and
key management provides several benefits to the users. The
ramifications associated with loss or disclosure of a signature key
are different from loss or disclosure of a key management key. Using
separate key pairs permits a balanced and flexible response.
Similarly, different validity periods or key lengths for each key
pair may be appropriate in some application environments.
Unfortunately, some legacy applications (e.g., SSL) use a single key
pair for signature and key management.
The protection afforded private keys is a critical security factor.
On a small scale, failure of users to protect their private keys will
permit an attacker to masquerade as them, or decrypt their personal
information. On a larger scale, compromise of a CA's private signing
key may have a catastrophic effect. If an attacker obtains the
private key unnoticed, the attacker may issue bogus certificates and
CRLs. Existence of bogus certificates and CRLs will undermine
confidence in the system. If such a compromise is detected, all
certificates issued to the compromised CA MUST be revoked, preventing
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services between its users and users of other CAs. Rebuilding after
such a compromise will be problematic, so CAs are advised to
implement a combination of strong technical measures (e.g., tamper-
resistant cryptographic modules) and appropriate management
procedures (e.g., separation of duties) to avoid such an incident.
Loss of a CA's private signing key may also be problematic. The CA
would not be able to produce CRLs or perform normal key rollover.
CAs SHOULD maintain secure backup for signing keys. The security of
the key backup procedures is a critical factor in avoiding key
compromise.
The availability and freshness of revocation information affects the
degree of assurance that ought to be placed in a certificate. While
certificates expire naturally, events may occur during its natural
lifetime which negate the binding between the subject and public key.
If revocation information is untimely or unavailable, the assurance
associated with the binding is clearly reduced. Relying parties
might not be able to process every critical extension that can appear
in a CRL. CAs SHOULD take extra care when making revocation
information available only through CRLs that contain critical
extensions, particularly if support for those extensions is not
mandated by this profile. For example, if revocation information is
supplied using a combination of delta CRLs and full CRLs, and the
delta CRLs are issued more frequently than the full CRLs, then
relying parties that cannot handle the critical extensions related to
delta CRL processing will not be able to obtain the most recent
revocation information. Alternatively, if a full CRL is issued
whenever a delta CRL is issued, then timely revocation information
will be available to all relying parties. Similarly, implementations
of the certification path validation mechanism described in section 6
that omit revocation checking provide less assurance than those that
support it.
The certification path validation algorithm depends on the certain
knowledge of the public keys (and other information) about one or
more trusted CAs. The decision to trust a CA is an important
decision as it ultimately determines the trust afforded a
certificate. The authenticated distribution of trusted CA public
keys (usually in the form of a "self-signed" certificate) is a
security critical out-of-band process that is beyond the scope of
this specification.
In addition, where a key compromise or CA failure occurs for a
trusted CA, the user will need to modify the information provided to
the path validation routine. Selection of too many trusted CAs makes
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the trusted CA information difficult to maintain. On the other hand,
selection of only one trusted CA could limit users to a closed
community of users.
The quality of implementations that process certificates also affects
the degree of assurance provided. The path validation algorithm
described in section 6 relies upon the integrity of the trusted CA
information, and especially the integrity of the public keys
associated with the trusted CAs. By substituting public keys for
which an attacker has the private key, an attacker could trick the
user into accepting false certificates.
The binding between a key and certificate subject cannot be stronger
than the cryptographic module implementation and algorithms used to
generate the signature. Short key lengths or weak hash algorithms
will limit the utility of a certificate. CAs are encouraged to note
advances in cryptology so they can employ strong cryptographic
techniques. In addition, CAs SHOULD decline to issue certificates to
CAs or end entities that generate weak signatures.
Inconsistent application of name comparison rules can result in
acceptance of invalid X.509 certification paths, or rejection of
valid ones. The X.500 series of specifications defines rules for
comparing distinguished names that require comparison of strings
without regard to case, character set, multi-character white space
substring, or leading and trailing white space. This specification
relaxes these requirements, requiring support for binary comparison
at a minimum.
CAs MUST encode the distinguished name in the subject field of a CA
certificate identically to the distinguished name in the issuer field
in certificates issued by that CA. If CAs use different encodings,
implementations might fail to recognize name chains for paths that
include this certificate. As a consequence, valid paths could be
rejected.
In addition, name constraints for distinguished names MUST be stated
identically to the encoding used in the subject field or
subjectAltName extension. If not, then name constraints stated as
excludedSubTrees will not match and invalid paths will be accepted
and name constraints expressed as permittedSubtrees will not match
and valid paths will be rejected. To avoid acceptance of invalid
paths, CAs SHOULD state name constraints for distinguished names as
permittedSubtrees wherever possible.
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Appendix A. Psuedo-ASN.1 Structures and OIDs
This section describes data objects used by conforming PKI components
in an "ASN.1-like" syntax. This syntax is a hybrid of the 1988 and
1993 ASN.1 syntaxes. The 1988 ASN.1 syntax is augmented with 1993
UNIVERSAL Types UniversalString, BMPString and UTF8String.
The ASN.1 syntax does not permit the inclusion of type statements in
the ASN.1 module, and the 1993 ASN.1 standard does not permit use of
the new UNIVERSAL types in modules using the 1988 syntax. As a
result, this module does not conform to either version of the ASN.1
standard.
This appendix may be converted into 1988 ASN.1 by replacing the
definitions for the UNIVERSAL Types with the 1988 catch-all "ANY".
-- UNIVERSAL Types defined in 1993 and 1998 ASN.1
-- and required by this specification
UniversalString ::= [UNIVERSAL 28] IMPLICIT OCTET STRING
-- UniversalString is defined in ASN.1:1993
BMPString ::= [UNIVERSAL 30] IMPLICIT OCTET STRING
-- BMPString is the subtype of UniversalString and models
-- the Basic Multilingual Plane of ISO/IEC/ITU 10646-1
UTF8String ::= [UNIVERSAL 12] IMPLICIT OCTET STRING
-- The content of this type conforms to RFC 2279.
Attribute ::= SEQUENCE {
type AttributeType,
values SET OF AttributeValue }
-- at least one value is required
AttributeType ::= OBJECT IDENTIFIER
AttributeValue ::= ANY
AttributeTypeAndValue ::= SEQUENCE {
type AttributeType,
value AttributeValue }
-- suggested naming attributes: Definition of the following
-- information object set may be augmented to meet local
-- requirements. Note that deleting members of the set may
-- prevent interoperability with conforming implementations.
-- presented in pairs: the AttributeType followed by the
-- type definition for the corresponding AttributeValue
--Arc for standard naming attributes
id-at OBJECT IDENTIFIER ::= { joint-iso-ccitt(2) ds(5) 4 }
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TBSCertificate ::= SEQUENCE {
version [0] Version DEFAULT v1,
serialNumber CertificateSerialNumber,
signature AlgorithmIdentifier,
issuer Name,
validity Validity,
subject Name,
subjectPublicKeyInfo SubjectPublicKeyInfo,
issuerUniqueID [1] IMPLICIT UniqueIdentifier OPTIONAL,
-- If present, version MUST be v2 or v3
subjectUniqueID [2] IMPLICIT UniqueIdentifier OPTIONAL,
-- If present, version MUST be v2 or v3
extensions [3] Extensions OPTIONAL
-- If present, version MUST be v3 -- }
Version ::= INTEGER { v1(0), v2(1), v3(2) }
CertificateSerialNumber ::= INTEGER
Validity ::= SEQUENCE {
notBefore Time,
notAfter Time }
Time ::= CHOICE {
utcTime UTCTime,
generalTime GeneralizedTime }
UniqueIdentifier ::= BIT STRING
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SubjectPublicKeyInfo ::= SEQUENCE {
algorithm AlgorithmIdentifier,
subjectPublicKey BIT STRING }
Extensions ::= SEQUENCE SIZE (1..MAX) OF Extension
TBSCertList ::= SEQUENCE {
version Version OPTIONAL,
-- if present, MUST be v2
signature AlgorithmIdentifier,
issuer Name,
thisUpdate Time,
nextUpdate Time OPTIONAL,
revokedCertificates SEQUENCE OF SEQUENCE {
userCertificate CertificateSerialNumber,
revocationDate Time,
crlEntryExtensions Extensions OPTIONAL
-- if present, MUST be v2
} OPTIONAL,
crlExtensions [0] Extensions OPTIONAL }
-- if present, MUST be v2
-- Version, Time, CertificateSerialNumber, and Extensions were
-- defined earlier for use in the certificate structure
AlgorithmIdentifier ::= SEQUENCE {
algorithm OBJECT IDENTIFIER,
parameters ANY DEFINED BY algorithm OPTIONAL }
-- contains a value of the type
-- registered for use with the
-- algorithm object identifier value
-- X.400 address syntax starts here
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ORAddress ::= SEQUENCE {
built-in-standard-attributes BuiltInStandardAttributes,
built-in-domain-defined-attributes
BuiltInDomainDefinedAttributes OPTIONAL,
-- see also teletex-domain-defined-attributes
extension-attributes ExtensionAttributes OPTIONAL }
-- Built-in Standard Attributes
BuiltInStandardAttributes ::= SEQUENCE {
country-name CountryName OPTIONAL,
administration-domain-name AdministrationDomainName OPTIONAL,
network-address [0] IMPLICIT NetworkAddress OPTIONAL,
-- see also extended-network-address
terminal-identifier [1] IMPLICIT TerminalIdentifier OPTIONAL,
private-domain-name [2] PrivateDomainName OPTIONAL,
organization-name [3] IMPLICIT OrganizationName OPTIONAL,
-- see also teletex-organization-name
numeric-user-identifier [4] IMPLICIT NumericUserIdentifier
OPTIONAL,
personal-name [5] IMPLICIT PersonalName OPTIONAL,
-- see also teletex-personal-name
organizational-unit-names [6] IMPLICIT OrganizationalUnitNames
OPTIONAL }
-- see also teletex-organizational-unit-names
-- Note - upper bounds on string types, such as TeletexString, are
-- measured in characters. Excepting PrintableString or IA5String, a
-- significantly greater number of octets will be required to hold
-- such a value. As a minimum, 16 octets, or twice the specified
-- upper bound, whichever is the larger, should be allowed for
-- TeletexString. For UTF8String or UniversalString at least four
-- times the upper bound should be allowed.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
AuthorityKeyIdentifier ::= SEQUENCE {
keyIdentifier [0] KeyIdentifier OPTIONAL,
authorityCertIssuer [1] GeneralNames OPTIONAL,
authorityCertSerialNumber [2] CertificateSerialNumber OPTIONAL }
-- authorityCertIssuer and authorityCertSerialNumber MUST both
-- be present or both be absent
CAs MUST force the serialNumber to be a non-negative integer, that
is, the sign bit in the DER encoding of the INTEGER value MUST be
zero - this can 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 an integer value.
As noted in section 4.1.2.2, serial numbers can be expected to
contain long integers. Certificate users MUST be able to handle
serialNumber values up to 20 octets in length. Conformant CAs MUST
NOT use serialNumber values longer than 20 octets.
As noted in section 5.2.3, CRL numbers can be expected to contain
long integers. CRL validators MUST be able to handle cRLNumber
values up to 20 octets in length. Conformant CRL issuers MUST NOT
use cRLNumber values longer than 20 octets.
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The construct "SEQUENCE SIZE (1..MAX) OF" appears in several ASN.1
constructs. A valid ASN.1 sequence will have zero or more entries.
The SIZE (1..MAX) construct constrains the sequence to have at least
one entry. MAX indicates the upper bound is unspecified.
Implementations are free to choose an upper bound that suits their
environment.
The construct "positiveInt ::= INTEGER (0..MAX)" defines positiveInt
as a subtype of INTEGER containing integers greater than or equal to
zero. The upper bound is unspecified. Implementations are free to
select an upper bound that suits their environment.
The character string type PrintableString supports a very basic Latin
character set: the lower case letters 'a' through 'z', upper case
letters 'A' through 'Z', the digits '0' through '9', eleven special
characters ' = ( ) + , - . / : ? and space.
Implementers should note that the at sign ('@') and underscore ('_')
characters are not supported by the ASN.1 type PrintableString.
These characters often appear in internet addresses. Such addresses
MUST be encoded using an ASN.1 type that supports them. They are
usually encoded as IA5String in either the emailAddress attribute
within a distinguished name or the rfc822Name field of GeneralName.
Conforming implementations MUST NOT encode strings which include
either the at sign or underscore character as PrintableString.
The character string type TeletexString is a superset of
PrintableString. TeletexString supports a fairly standard (ASCII-
like) Latin character set, Latin characters with non-spacing accents
and Japanese characters.
Named bit lists are BIT STRINGs where the values have been assigned
names. This specification makes use of named bit lists in the
definitions for the key usage, CRL distribution points and freshest
CRL certificate extensions, as well as the freshest CRL and issuing
distribution point CRL extensions. When DER encoding a named bit
list, trailing zeroes MUST be omitted. That is, the encoded value
ends with the last named bit that is set to one.
The character string type UniversalString supports any of the
characters allowed by ISO 10646-1 [ISO 10646]. ISO 10646-1 is the
Universal multiple-octet coded Character Set (UCS). ISO 10646-1
specifies the architecture and the "basic multilingual plane" -- a
large standard character set which includes all major world character
standards.
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The character string type UTF8String was introduced in the 1997
version of ASN.1, and UTF8String was added to the list of choices for
DirectoryString in the 2001 version of X.520 [X.520]. UTF8String is
a universal type and has been assigned tag number 12. The content of
UTF8String was defined by RFC 2044 [RFC 2044] and updated in RFC 2279
[RFC 2279].
In anticipation of these changes, and in conformance with IETF Best
Practices codified in RFC 2277 [RFC 2277], IETF Policy on Character
Sets and Languages, this document includes UTF8String as a choice in
DirectoryString and the CPS qualifier extensions.
Implementers should note that the DER encoding of the SET OF values
requires ordering of the encodings of the values. In particular,
this issue arises with respect to distinguished names.
Implementers should note that the DER encoding of SET or SEQUENCE
components whose value is the DEFAULT omit the component from the
encoded certificate or CRL. For example, a BasicConstraints
extension whose cA value is FALSE would omit the cA boolean from the
encoded certificate.
Object Identifiers (OIDs) are used throughout this specification to
identify certificate policies, public key and signature algorithms,
certificate extensions, etc. There is no maximum size for OIDs.
This specification mandates support for OIDs which have arc elements
with values that are less than 2^28, that is, they MUST be between 0
and 268,435,455, inclusive. This allows each arc element to be
represented within a single 32 bit word. Implementations MUST also
support OIDs where the length of the dotted decimal (see [RFC 2252],
section 4.1) string representation can be up to 100 bytes
(inclusive). Implementations MUST be able to handle OIDs with up to
20 elements (inclusive). CAs SHOULD NOT issue certificates which
contain OIDs that exceed these requirements. Likewise, CRL issuers
SHOULD NOT issue CRLs which contain OIDs that exceed these
requirements.
Implementors are warned that the X.500 standards community has
developed a series of extensibility rules. These rules determine
when an ASN.1 definition can be changed without assigning a new
object identifier (OID). For example, at least two extension
definitions included in RFC 2459 [RFC 2459], the predecessor to this
profile document, have different ASN.1 definitions in this
specification, but the same OID is used. If unknown elements appear
within an extension, and the extension is not marked critical, those
unknown elements ought to be ignored, as follows:
(a) ignore all unknown bit name assignments within a bit string;
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(b) ignore all unknown named numbers in an ENUMERATED type or
INTEGER type that is being used in the enumerated style, provided
the number occurs as an optional element of a SET or SEQUENCE; and
(c) ignore all unknown elements in SETs, at the end of SEQUENCEs,
or in CHOICEs where the CHOICE is itself an optional element of a
SET or SEQUENCE.
If an extension containing unexpected values is marked critical, the
implementation MUST reject the certificate or CRL containing the
unrecognized extension.
Appendix C. Examples
This section contains four examples: three certificates and a CRL.
The first two certificates and the CRL comprise a minimal
certification path.
Section C.1 contains an annotated hex dump of a "self-signed"
certificate issued by a CA whose distinguished name is
cn=us,o=gov,ou=nist. The certificate contains a DSA public key with
parameters, and is signed by the corresponding DSA private key.
Section C.2 contains an annotated hex dump of an end entity
certificate. The end entity certificate contains a DSA public key,
and is signed by the private key corresponding to the "self-signed"
certificate in section C.1.
Section C.3 contains a dump of an end entity certificate which
contains an RSA public key and is signed with RSA and MD5. This
certificate is not part of the minimal certification path.
Section C.4 contains an annotated hex dump of a CRL. The CRL is
issued by the CA whose distinguished name is cn=us,o=gov,ou=nist and
the list of revoked certificates includes the end entity certificate
presented in C.2.
This section contains an annotated hex dump of a 699 byte version 3
certificate. The certificate contains the following information:
(a) the serial number is 23 (17 hex);
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(b) the certificate is signed with DSA and the SHA-1 hash algorithm;
(c) the issuer's distinguished name is OU=NIST; O=gov; C=US
(d) and the subject's distinguished name is OU=NIST; O=gov; C=US
(e) the certificate was issued on June 30, 1997 and will expire on
December 31, 1997;
(f) the certificate contains a 1024 bit DSA public key with
parameters;
(g) the certificate contains a subject key identifier extension
generated using method (1) of section 4.2.1.2; and
(h) the certificate is a CA certificate (as indicated through the
basic constraints extension.)
This section contains an annotated hex dump of a 730 byte version 3
certificate. The certificate contains the following information:
(a) the serial number is 18 (12 hex);
(b) the certificate is signed with DSA and the SHA-1 hash algorithm;
(c) the issuer's distinguished name is OU=nist; O=gov; C=US
(d) and the subject's distinguished name is CN=Tim Polk; OU=nist;
O=gov; C=US
(e) the certificate was valid from July 30, 1997 through December 1,
1997;
(f) the certificate contains a 1024 bit DSA public key;
(g) the certificate is an end entity certificate, as the basic
constraints extension is not present;
(h) the certificate contains an authority key identifier extension
matching the subject key identifier of the certificate in Appendix
C.1; and
(i) the certificate includes one alternative name - an RFC 822
address of "[email protected]".
This section contains an annotated hex dump of a 654 byte version 3
certificate. The certificate contains the following information:
(a) the serial number is 256;
(b) the certificate is signed with RSA and the SHA-1 hash algorithm;
(c) the issuer's distinguished name is OU=NIST; O=gov; C=US
(d) and the subject's distinguished name is CN=Tim Polk; OU=NIST;
O=gov; C=US
(e) the certificate was issued on May 21, 1996 at 09:58:26 and
expired on May 21, 1997 at 09:58:26;
(f) the certificate contains a 1024 bit RSA public key;
(g) the certificate is an end entity certificate (not a CA
certificate);
(h) the certificate includes an alternative subject name of
"<http://www.itl.nist.gov/div893/staff/polk/index.html>" and an
alternative issuer name of "<http://www.nist.gov/>" - both are URLs;
(i) the certificate include an authority key identifier extension
and a certificate policies extension specifying the policy OID
2.16.840.1.101.3.2.1.48.9; and
Housley, et. al. Standards Track [Page 122]
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
(j) the certificate includes a critical key usage extension
specifying that the public key is intended for verification of
digital signatures.
This section contains an annotated hex dump of a version 2 CRL with
one extension (cRLNumber). The CRL was issued by OU=NIST; O=gov;
C=US on August 7, 1997; the next scheduled issuance was September 7,
1997. The CRL includes one revoked certificates: serial number 18
(12 hex), which was revoked on July 31, 1997 due to keyCompromise.
The CRL itself is number 18, and it was signed with DSA and SHA-1.
RFC 3280 Internet X.509 Public Key Infrastructure April 2002
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